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qcacld-3.0: Add QDF status

Forráskód böngészése 
Replace CDF status with QDF status

Change-Id: I7170c8ae4c5bd97a8f0f383af637bb2ec312f082
CRs-Fixed: 981188
This commit is contained in:
Anurag Chouhan
2016-02-18 18:00:46 +05:30
committed by Gerrit - the friendly Code Review server
szülő ffb2154eff
commit fb54ab0eac
178 fájl változott, egészen pontosan 9643 új sor hozzáadva és 9779 régi sor törölve
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14
core/bmi/inc/bmi.h
Fájl megtekintése

@@ -38,7 +38,7 @@
#include "hif.h"
struct ol_context;
CDF_STATUS ol_cds_init(cdf_device_t cdf_dev, void *hif_ctx);
QDF_STATUS ol_cds_init(cdf_device_t cdf_dev, void *hif_ctx);
void ol_cds_free(void);
/**
@@ -64,22 +64,22 @@ void ol_init_ini_config(struct ol_context *ol_ctx,
struct ol_config_info *cfg);
#ifdef HIF_PCI
void bmi_cleanup(struct ol_context *scn);
CDF_STATUS bmi_done(struct ol_context *ol_ctx);
CDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx);
QDF_STATUS bmi_done(struct ol_context *ol_ctx);
QDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx);
#else
static inline void bmi_cleanup(struct ol_context *scn)
{
return;
}
static inline CDF_STATUS bmi_done(struct ol_context *ol_ctx)
static inline QDF_STATUS bmi_done(struct ol_context *ol_ctx)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
static inline QDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
#endif /* _BMI_H_ */

6
core/bmi/inc/ol_fw.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2014, 2016 The Linux Foundation. All rights reserved.
* Copyright (c) 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -48,9 +48,9 @@
#define AR6320_DEV_VERSION 0x1000000
#ifdef HIF_PCI
void ol_target_failure(void *instance, CDF_STATUS status);
void ol_target_failure(void *instance, QDF_STATUS status);
#else
static inline void ol_target_failure(void *instance, CDF_STATUS status)
static inline void ol_target_failure(void *instance, QDF_STATUS status)
{
return;
}

106
core/bmi/src/bmi.c
Fájl megtekintése

@@ -37,7 +37,7 @@
/* Enable BMI_TEST COMMANDs; The Value 0x09 is randomly choosen */
#define BMI_TEST_ENABLE (0x09)
static CDF_STATUS
static QDF_STATUS
bmi_command_test(uint32_t command, uint32_t address, uint8_t *data,
uint32_t length, struct ol_context *ol_ctx)
{
@@ -53,10 +53,10 @@ bmi_command_test(uint32_t command, uint32_t address, uint8_t *data,
default:
break;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS bmi_init(struct ol_context *ol_ctx)
QDF_STATUS bmi_init(struct ol_context *ol_ctx)
{
struct bmi_info *info = GET_BMI_CONTEXT(ol_ctx);
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -65,12 +65,12 @@ CDF_STATUS bmi_init(struct ol_context *ol_ctx)
if (!scn) {
BMI_ERR("Invalid scn Context");
bmi_assert(0);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
if (!cdf_dev->dev) {
BMI_ERR("%s: Invalid Device Pointer", __func__);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
info->bmi_done = false;
@@ -81,7 +81,7 @@ CDF_STATUS bmi_init(struct ol_context *ol_ctx)
&info->bmi_cmd_da, 0);
if (!info->bmi_cmd_buff) {
BMI_ERR("No Memory for BMI Command");
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
}
@@ -94,12 +94,12 @@ CDF_STATUS bmi_init(struct ol_context *ol_ctx)
goto end;
}
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
end:
cdf_os_mem_free_consistent(cdf_dev, MAX_BMI_CMDBUF_SZ,
info->bmi_cmd_buff, info->bmi_cmd_da, 0);
info->bmi_cmd_buff = NULL;
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
void bmi_cleanup(struct ol_context *ol_ctx)
@@ -128,22 +128,22 @@ void bmi_cleanup(struct ol_context *ol_ctx)
}
CDF_STATUS bmi_done(struct ol_context *ol_ctx)
QDF_STATUS bmi_done(struct ol_context *ol_ctx)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (NO_BMI)
return status;
status = bmi_done_local(ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
BMI_ERR("BMI_DONE Failed status:%d", status);
return status;
}
CDF_STATUS
QDF_STATUS
bmi_get_target_info(struct bmi_target_info *targ_info,
struct ol_context *ol_ctx)
{
@@ -158,12 +158,12 @@ bmi_get_target_info(struct bmi_target_info *targ_info,
if (info->bmi_done) {
BMI_ERR("BMI Phase is Already Done");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("%s:BMI CMD/RSP Buffer is NULL", __func__);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
cid = BMI_GET_TARGET_INFO;
@@ -175,11 +175,11 @@ bmi_get_target_info(struct bmi_target_info *targ_info,
BMI_EXCHANGE_TIMEOUT_MS);
if (status) {
BMI_ERR("Failed to target info: status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(targ_info, bmi_rsp_buff, length);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#ifdef FEATURE_BMI_2
@@ -194,7 +194,7 @@ static inline uint32_t bmi_get_test_addr(void)
}
#endif
CDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
QDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
{
uint8_t data[10], out[10];
uint32_t address;
@@ -202,12 +202,12 @@ CDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
struct hif_opaque_softc *scn = ol_ctx->scn;
if (NO_BMI)
return CDF_STATUS_SUCCESS; /* no BMI for Q6 bring up */
return QDF_STATUS_SUCCESS; /* no BMI for Q6 bring up */
if (!scn) {
BMI_ERR("Invalid scn context");
bmi_assert(0);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
#ifdef CONFIG_CNSS
if (BMI_TEST_ENABLE == cnss_get_bmi_setup()) {
@@ -215,7 +215,7 @@ CDF_STATUS bmi_download_firmware(struct ol_context *ol_ctx)
BMI_DBG("ret:%d writing data:%s\n", ret, data);
address = bmi_get_test_addr();
if (bmi_init(ol_ctx) != CDF_STATUS_SUCCESS) {
if (bmi_init(ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_WARN("BMI_INIT Failed; No Memory!");
goto end;
}
@@ -229,7 +229,7 @@ end:
return bmi_firmware_download(ol_ctx);
}
CDF_STATUS bmi_read_soc_register(uint32_t address, uint32_t *param,
QDF_STATUS bmi_read_soc_register(uint32_t address, uint32_t *param,
struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -248,7 +248,7 @@ CDF_STATUS bmi_read_soc_register(uint32_t address, uint32_t *param,
if (info->bmi_done) {
BMI_DBG("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
BMI_DBG("BMI Read SOC Register:device: 0x%p, address: 0x%x",
@@ -266,15 +266,15 @@ CDF_STATUS bmi_read_soc_register(uint32_t address, uint32_t *param,
bmi_rsp_buff, &param_len, BMI_EXCHANGE_TIMEOUT_MS);
if (status) {
BMI_DBG("Unable to read from the device; status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(param, bmi_rsp_buff, sizeof(*param));
BMI_DBG("BMI Read SOC Register: Exit value: %d", *param);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
QDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -292,7 +292,7 @@ CDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
if (info->bmi_done) {
BMI_DBG("Command disallowed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
BMI_DBG("SOC Register Write:device:0x%p, addr:0x%x, param:%d",
@@ -311,14 +311,14 @@ CDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
NULL, NULL, 0);
if (status) {
BMI_ERR("Unable to write to the device: status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
BMI_DBG("BMI Read SOC Register: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmilz_data(uint8_t *buffer, uint32_t length, struct ol_context *ol_ctx)
{
uint32_t cid;
@@ -337,7 +337,7 @@ bmilz_data(uint8_t *buffer, uint32_t length, struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
BMI_DBG("BMI Send LZ Data: device: 0x%p, length: %d",
@@ -363,17 +363,17 @@ bmilz_data(uint8_t *buffer, uint32_t length, struct ol_context *ol_ctx)
if (status) {
BMI_ERR("Failed to write to the device: status:%d",
status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
remaining -= txlen;
}
BMI_DBG("BMI LZ Data: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS bmi_sign_stream_start(uint32_t address, uint8_t *buffer,
QDF_STATUS bmi_sign_stream_start(uint32_t address, uint8_t *buffer,
uint32_t length, struct ol_context *ol_ctx)
{
uint32_t cid;
@@ -394,7 +394,7 @@ CDF_STATUS bmi_sign_stream_start(uint32_t address, uint8_t *buffer,
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
BMI_ERR("Sign Stream start:device:0x%p, addr:0x%x, length:%d",
@@ -431,16 +431,16 @@ CDF_STATUS bmi_sign_stream_start(uint32_t address, uint8_t *buffer,
if (status) {
BMI_ERR("Unable to write to the device: status:%d",
status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
remaining -= txlen;
}
BMI_DBG("BMI SIGN Stream Start: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmilz_stream_start(uint32_t address, struct ol_context *ol_ctx)
{
uint32_t cid;
@@ -457,7 +457,7 @@ bmilz_stream_start(uint32_t address, struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_DBG("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
BMI_DBG("BMI LZ Stream Start: (device: 0x%p, address: 0x%x)",
scn, address);
@@ -473,23 +473,23 @@ bmilz_stream_start(uint32_t address, struct ol_context *ol_ctx)
if (status) {
BMI_ERR("Unable to Start LZ Stream to the device status:%d",
status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
BMI_DBG("BMI LZ Stream: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_fast_download(uint32_t address, uint8_t *buffer,
uint32_t length, struct ol_context *ol_ctx)
{
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
uint32_t last_word = 0;
uint32_t last_word_offset = length & ~0x3;
uint32_t unaligned_bytes = length & 0x3;
status = bmilz_stream_start(address, ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
goto end;
/* copy the last word into a zero padded buffer */
@@ -499,13 +499,13 @@ bmi_fast_download(uint32_t address, uint8_t *buffer,
status = bmilz_data(buffer, last_word_offset, ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
goto end;
if (unaligned_bytes)
status = bmilz_data((uint8_t *) &last_word, 4, ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
/*
* Close compressed stream and open a new (fake) one.
* This serves mainly to flush Target caches.
@@ -517,23 +517,23 @@ end:
/**
* ol_cds_init() - API to initialize global CDS OL Context
* @cdf_dev: CDF Device
* @cdf_dev: QDF Device
* @hif_ctx: HIF Context
*
* Return: Success/Failure
*/
CDF_STATUS ol_cds_init(cdf_device_t cdf_dev, void *hif_ctx)
QDF_STATUS ol_cds_init(cdf_device_t cdf_dev, void *hif_ctx)
{
struct ol_context *ol_info;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (NO_BMI)
return CDF_STATUS_SUCCESS; /* no BMI for Q6 bring up */
return QDF_STATUS_SUCCESS; /* no BMI for Q6 bring up */
status = cds_alloc_context(cds_get_global_context(), CDF_MODULE_ID_BMI,
status = cds_alloc_context(cds_get_global_context(), QDF_MODULE_ID_BMI,
(void **)&ol_info, sizeof(*ol_info));
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("%s: CDS Allocation failed for ol_bmi context",
__func__);
return status;
@@ -555,10 +555,10 @@ CDF_STATUS ol_cds_init(cdf_device_t cdf_dev, void *hif_ctx)
*/
void ol_cds_free(void)
{
struct ol_context *ol_info = cds_get_context(CDF_MODULE_ID_BMI);
struct ol_context *ol_info = cds_get_context(QDF_MODULE_ID_BMI);
if (NO_BMI)
return;
cds_free_context(cds_get_global_context(), CDF_MODULE_ID_BMI, ol_info);
cds_free_context(cds_get_global_context(), QDF_MODULE_ID_BMI, ol_info);
}

60
core/bmi/src/bmi_1.c
Fájl megtekintése

@@ -30,7 +30,7 @@
/* APIs visible to the driver */
CDF_STATUS
QDF_STATUS
bmi_read_memory(uint32_t address,
uint8_t *buffer, uint32_t length, struct ol_context *ol_ctx)
{
@@ -48,12 +48,12 @@ bmi_read_memory(uint32_t address,
if (info->bmi_done) {
BMI_DBG("command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!info->bmi_cmd_buff || !info->bmi_rsp_buff) {
BMI_ERR("BMI Initialization hasn't done");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
bmi_assert(BMI_COMMAND_FITS(BMI_DATASZ_MAX + sizeof(cid) +
@@ -88,7 +88,7 @@ bmi_read_memory(uint32_t address,
BMI_EXCHANGE_TIMEOUT_MS);
if (status) {
BMI_ERR("Unable to read from the device");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (remaining == rxlen) {
cdf_mem_copy(&buffer[length - remaining + align],
@@ -103,10 +103,10 @@ bmi_read_memory(uint32_t address,
}
BMI_DBG("BMI Read Memory: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
QDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -124,12 +124,12 @@ CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff) {
BMI_ERR("BMI initialization hasn't done");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
bmi_assert(BMI_COMMAND_FITS(BMI_DATASZ_MAX + header));
@@ -170,7 +170,7 @@ CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
if (status) {
BMI_ERR("Unable to write to the device; status:%d",
status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
remaining -= txlen;
address += txlen;
@@ -178,10 +178,10 @@ CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
BMI_DBG("BMI Write Memory: Exit");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_execute(uint32_t address, A_UINT32 *param, struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -198,12 +198,12 @@ bmi_execute(uint32_t address, A_UINT32 *param, struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("%s:BMI CMD/RSP Buffer is NULL", __func__);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
bmi_assert(BMI_COMMAND_FITS(size));
@@ -228,40 +228,40 @@ bmi_execute(uint32_t address, A_UINT32 *param, struct ol_context *ol_ctx)
bmi_rsp_buff, &param_len, 0);
if (status) {
BMI_ERR("Unable to read from the device status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(param, bmi_rsp_buff, sizeof(*param));
BMI_DBG("BMI Execute: Exit (param: %d)", *param);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
inline CDF_STATUS
inline QDF_STATUS
bmi_no_command(struct ol_context *ol_ctx)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_firmware_download(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
CDF_STATUS status;
QDF_STATUS status;
struct bmi_target_info targ_info;
struct hif_target_info *tgt_info = hif_get_target_info_handle(scn);
cdf_mem_zero(&targ_info, sizeof(targ_info));
/* Initialize BMI */
status = bmi_init(ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI Initialization Failed err:%d", status);
return status;
}
/* Get target information */
status = bmi_get_target_info(&targ_info, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI Target Info get failed: status:%d", status);
return status;
}
@@ -271,19 +271,19 @@ bmi_firmware_download(struct ol_context *ol_ctx)
/* Configure target */
status = ol_configure_target(ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI Configure Target Failed status:%d", status);
return status;
}
status = ol_download_firmware(ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
BMI_ERR("BMI Download Firmware Failed Status:%d", status);
return status;
}
CDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
QDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
int status;
@@ -295,18 +295,18 @@ CDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
if (!scn) {
BMI_ERR("Invalid scn context");
bmi_assert(0);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
if (!cdf_dev->dev) {
BMI_ERR("%s: Invalid device pointer", __func__);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
info = GET_BMI_CONTEXT(ol_ctx);
if (info->bmi_done) {
BMI_DBG("bmi_done_local skipped");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
cmd = info->bmi_cmd_da;
@@ -320,7 +320,7 @@ CDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
if (!info->bmi_cmd_buff) {
BMI_ERR("Invalid scn BMICmdBuff");
bmi_assert(0);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
cdf_mem_copy(info->bmi_cmd_buff, &cid, sizeof(cid));
@@ -329,7 +329,7 @@ CDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
sizeof(cid), NULL, NULL, 0);
if (status) {
BMI_ERR("Failed to write to the device; status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (info->bmi_cmd_buff) {
@@ -346,5 +346,5 @@ CDF_STATUS bmi_done_local(struct ol_context *ol_ctx)
info->bmi_rsp_da = 0;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}

102
core/bmi/src/bmi_2.c
Fájl megtekintése

@@ -33,7 +33,7 @@
*/
#define BMI_LOAD_IMAGE 18
CDF_STATUS
QDF_STATUS
bmi_no_command(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -49,12 +49,12 @@ bmi_no_command(struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_ERR("Command disallowed: BMI DONE ALREADY");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("No Memory Allocated for BMI CMD/RSP Buffer");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
cid = BMI_NO_COMMAND;
@@ -66,18 +66,18 @@ bmi_no_command(struct ol_context *ol_ctx)
if (status) {
BMI_ERR("Failed to write bmi no command status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, length);
if (ret != 0) {
BMI_ERR("bmi no command response error ret 0x%x", ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_done_local(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -94,17 +94,17 @@ bmi_done_local(struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("No Memory Allocated for BMI CMD/RSP Buffer");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
if (!cdf_dev->dev) {
BMI_ERR("%s Invalid Device pointer", __func__);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
cid = BMI_DONE;
@@ -117,13 +117,13 @@ bmi_done_local(struct ol_context *ol_ctx)
if (status) {
BMI_ERR("Failed to close BMI on target status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, length);
if (ret != 0) {
BMI_ERR("BMI DONE response failed:%d", ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (info->bmi_cmd_buff) {
@@ -140,10 +140,10 @@ bmi_done_local(struct ol_context *ol_ctx)
info->bmi_rsp_da = 0;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
QDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
struct ol_context *ol_ctx)
{
uint32_t cid;
@@ -164,12 +164,12 @@ CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("BMI Initialization is not happened");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
bmi_assert(BMI_COMMAND_FITS(BMI_DATASZ_MAX + header));
@@ -207,20 +207,20 @@ CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
BMI_EXCHANGE_TIMEOUT_MS);
if (status) {
BMI_ERR("BMI Write Memory Failed status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, rsp_len);
if (ret != 0) {
BMI_ERR("BMI Write memory response fail: %x", ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
remaining -= txlen; address += txlen;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_read_memory(uint32_t address, uint8_t *buffer,
uint32_t length, struct ol_context *ol_ctx)
{
@@ -240,11 +240,11 @@ bmi_read_memory(uint32_t address, uint8_t *buffer,
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("BMI Initialization is not done");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
bmi_assert(BMI_COMMAND_FITS(BMI_DATASZ_MAX + size));
@@ -278,14 +278,14 @@ bmi_read_memory(uint32_t address, uint8_t *buffer,
if (status) {
BMI_ERR("BMI Read memory failed status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, rsp_len);
if (ret != 0) {
BMI_ERR("bmi read memory response fail %x", ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&buffer[length - remaining],
@@ -293,10 +293,10 @@ bmi_read_memory(uint32_t address, uint8_t *buffer,
remaining -= rxlen; address += rxlen;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS
QDF_STATUS
bmi_execute(uint32_t address, uint32_t *param, struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -312,12 +312,12 @@ bmi_execute(uint32_t address, uint32_t *param, struct ol_context *ol_ctx)
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("No Memory Allocated for bmi buffers");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
cid = BMI_EXECUTE;
@@ -330,24 +330,24 @@ bmi_execute(uint32_t address, uint32_t *param, struct ol_context *ol_ctx)
if (status) {
BMI_ERR("Failed to do BMI_EXECUTE status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, length);
if (ret != 0) {
BMI_ERR("%s: ret 0x%x", __func__, ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static CDF_STATUS
static QDF_STATUS
bmi_load_image(dma_addr_t address,
uint32_t size, struct ol_context *ol_ctx)
{
uint32_t cid;
CDF_STATUS status;
QDF_STATUS status;
uint32_t offset;
uint32_t length;
uint8_t ret = 0;
@@ -362,12 +362,12 @@ bmi_load_image(dma_addr_t address,
if (info->bmi_done) {
BMI_ERR("Command disallowed");
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if (!bmi_cmd_buff || !bmi_rsp_buff) {
BMI_ERR("No Memory Allocated for BMI CMD/RSP Buffer");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
bmi_assert(BMI_COMMAND_FITS(sizeof(cid) + sizeof(address)));
@@ -396,41 +396,41 @@ bmi_load_image(dma_addr_t address,
if (status) {
BMI_ERR("BMI Load Image Failed; status:%d", status);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_copy(&ret, bmi_rsp_buff, length);
if (ret != 0) {
BMI_ERR("%s: ret 0x%x", __func__, ret);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static CDF_STATUS bmi_enable(struct ol_context *ol_ctx)
static QDF_STATUS bmi_enable(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
struct bmi_target_info targ_info;
struct image_desc_info image_desc_info;
CDF_STATUS status;
QDF_STATUS status;
struct hif_target_info *tgt_info;
struct bmi_info *info = GET_BMI_CONTEXT(ol_ctx);
if (!scn) {
BMI_ERR("Invalid scn context");
bmi_assert(0);
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
tgt_info = hif_get_target_info_handle(scn);
if (info->bmi_cmd_buff == NULL || info->bmi_rsp_buff == NULL) {
BMI_ERR("bmi_open failed!");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
status = bmi_get_target_info(&targ_info, ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
return status;
BMI_DBG("%s: target type 0x%x, target ver 0x%x", __func__,
@@ -441,13 +441,13 @@ static CDF_STATUS bmi_enable(struct ol_context *ol_ctx)
if (cnss_get_fw_image(&image_desc_info) != 0) {
BMI_ERR("Failed to get fw image");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
status = bmi_load_image(image_desc_info.bdata_addr,
image_desc_info.bdata_size,
ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Load board data failed! status:%d", status);
return status;
}
@@ -455,27 +455,27 @@ static CDF_STATUS bmi_enable(struct ol_context *ol_ctx)
status = bmi_load_image(image_desc_info.fw_addr,
image_desc_info.fw_size,
ol_ctx);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
BMI_ERR("Load fw image failed! status:%d", status);
return status;
}
CDF_STATUS bmi_firmware_download(struct ol_context *ol_ctx)
QDF_STATUS bmi_firmware_download(struct ol_context *ol_ctx)
{
CDF_STATUS status;
QDF_STATUS status;
if (NO_BMI)
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
status = bmi_init(ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI_INIT Failed status:%d", status);
goto end;
}
status = bmi_enable(ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI_ENABLE failed status:%d\n", status);
goto err_bmi_enable;
}

40
core/bmi/src/i_bmi.h
Fájl megtekintése

@@ -75,16 +75,16 @@
/* BMI LOGGING WRAPPERS */
#define BMI_LOG(level, args...) CDF_TRACE(CDF_MODULE_ID_BMI, \
#define BMI_LOG(level, args...) QDF_TRACE(QDF_MODULE_ID_BMI, \
level, ##args)
#define BMI_ERR(args ...) BMI_LOG(CDF_TRACE_LEVEL_ERROR, args)
#define BMI_DBG(args ...) BMI_LOG(CDF_TRACE_LEVEL_DEBUG, args)
#define BMI_WARN(args ...) BMI_LOG(CDF_TRACE_LEVEL_WARN, args)
#define BMI_INFO(args ...) BMI_LOG(CDF_TRACE_LEVEL_INFO, args)
#define BMI_ERR(args ...) BMI_LOG(QDF_TRACE_LEVEL_ERROR, args)
#define BMI_DBG(args ...) BMI_LOG(QDF_TRACE_LEVEL_DEBUG, args)
#define BMI_WARN(args ...) BMI_LOG(QDF_TRACE_LEVEL_WARN, args)
#define BMI_INFO(args ...) BMI_LOG(QDF_TRACE_LEVEL_INFO, args)
/* End of BMI Logging Wrappers */
/* BMI Assert Wrappers */
#define bmi_assert CDF_BUG
#define bmi_assert QDF_BUG
/*
* Although we had envisioned BMI to run on top of HTC, this is not how the
* final implementation ended up. On the Target side, BMI is a part of the BSP
@@ -146,7 +146,7 @@ struct bmi_info {
* struct ol_context - Structure to hold OL context
* @bmi: BMI info
* @cal_in_flash: For Firmware Flash Download
* @cdf_dev: CDF Device
* @cdf_dev: QDF Device
* @scn: HIF Context
* @ramdump_work: WorkQueue for Ramdump collection
* @tgt_def: Target Defnition pointer
@@ -167,26 +167,26 @@ struct ol_context {
#define GET_BMI_CONTEXT(ol_ctx) ((struct bmi_info *)ol_ctx)
CDF_STATUS bmi_execute(uint32_t address, uint32_t *param,
QDF_STATUS bmi_execute(uint32_t address, uint32_t *param,
struct ol_context *ol_ctx);
CDF_STATUS bmi_init(struct ol_context *ol_ctx);
CDF_STATUS bmi_no_command(struct ol_context *ol_ctx);
CDF_STATUS bmi_read_memory(uint32_t address, uint8_t *buffer, uint32_t length,
QDF_STATUS bmi_init(struct ol_context *ol_ctx);
QDF_STATUS bmi_no_command(struct ol_context *ol_ctx);
QDF_STATUS bmi_read_memory(uint32_t address, uint8_t *buffer, uint32_t length,
struct ol_context *ol_ctx);
CDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
QDF_STATUS bmi_write_memory(uint32_t address, uint8_t *buffer, uint32_t length,
struct ol_context *ol_ctx);
CDF_STATUS bmi_fast_download(uint32_t address, uint8_t *buffer, uint32_t length,
QDF_STATUS bmi_fast_download(uint32_t address, uint8_t *buffer, uint32_t length,
struct ol_context *ol_ctx);
CDF_STATUS bmi_read_soc_register(uint32_t address,
QDF_STATUS bmi_read_soc_register(uint32_t address,
uint32_t *param, struct ol_context *ol_ctx);
CDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
QDF_STATUS bmi_write_soc_register(uint32_t address, uint32_t param,
struct ol_context *ol_ctx);
CDF_STATUS bmi_get_target_info(struct bmi_target_info *targ_info,
QDF_STATUS bmi_get_target_info(struct bmi_target_info *targ_info,
struct ol_context *ol_ctx);
CDF_STATUS bmi_firmware_download(struct ol_context *ol_ctx);
CDF_STATUS bmi_done_local(struct ol_context *ol_ctx);
CDF_STATUS ol_download_firmware(struct ol_context *ol_ctx);
CDF_STATUS ol_configure_target(struct ol_context *ol_ctx);
QDF_STATUS bmi_firmware_download(struct ol_context *ol_ctx);
QDF_STATUS bmi_done_local(struct ol_context *ol_ctx);
QDF_STATUS ol_download_firmware(struct ol_context *ol_ctx);
QDF_STATUS ol_configure_target(struct ol_context *ol_ctx);
void ramdump_work_handler(void *arg);
struct ol_config_info *ol_get_ini_handle(struct ol_context *ol_ctx);
#endif

148
core/bmi/src/ol_fw.c
Fájl megtekintése

@@ -124,7 +124,7 @@ static int ol_check_fw_hash(const u8 *data, u32 fw_size, ATH_BIN_FILE file)
digest, SHA256_DIGEST_SIZE);
cdf_trace_hex_dump(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
hash, SHA256_DIGEST_SIZE);
ret = CDF_STATUS_E_FAILURE;
ret = QDF_STATUS_E_FAILURE;
}
#endif
end:
@@ -280,7 +280,7 @@ __ol_transfer_bin_file(struct ol_context *ol_ctx, ATH_BIN_FILE file,
if (!fw_entry || !fw_entry->data) {
BMI_ERR("Invalid fw_entries");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
fw_entry_size = fw_entry->size;
@@ -290,7 +290,7 @@ __ol_transfer_bin_file(struct ol_context *ol_ctx, ATH_BIN_FILE file,
if (ol_check_fw_hash(fw_entry->data, fw_entry_size, file)) {
BMI_ERR("Hash Check failed for file:%s", filename);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
goto end;
}
#endif
@@ -303,7 +303,7 @@ __ol_transfer_bin_file(struct ol_context *ol_ctx, ATH_BIN_FILE file,
if (!temp_eeprom) {
BMI_ERR("%s: Memory allocation failed", __func__);
release_firmware(fw_entry);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cdf_mem_copy(temp_eeprom, (uint8_t *) fw_entry->data,
@@ -363,7 +363,7 @@ __ol_transfer_bin_file(struct ol_context *ol_ctx, ATH_BIN_FILE file,
if (fw_entry_size < sizeof(SIGN_HEADER_T)) {
BMI_ERR("Invalid binary size %d", fw_entry_size);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
goto end;
}
@@ -379,7 +379,7 @@ __ol_transfer_bin_file(struct ol_context *ol_ctx, ATH_BIN_FILE file,
sizeof(SIGN_HEADER_T), ol_ctx);
if (status != EOK) {
BMI_ERR("unable to start sign stream");
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
goto end;
}
@@ -449,7 +449,7 @@ end:
if (status != EOK) {
BMI_ERR("%s, BMI operation failed: %d", __func__, __LINE__);
release_firmware(fw_entry);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
release_firmware(fw_entry);
@@ -558,7 +558,7 @@ void ramdump_work_handler(void *data)
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_failure_state)),
(uint8_t *)&host_interest_address,
sizeof(uint32_t)) != CDF_STATUS_SUCCESS) {
sizeof(uint32_t)) != QDF_STATUS_SUCCESS) {
BMI_ERR("HifDiagReadiMem FW Dump Area Pointer failed!");
ol_copy_ramdump(ramdump_scn);
cnss_device_crashed();
@@ -569,7 +569,7 @@ void ramdump_work_handler(void *data)
if (hif_diag_read_mem(ramdump_scn, host_interest_address,
(uint8_t *) &dram_dump_values[0],
4 * sizeof(uint32_t)) != CDF_STATUS_SUCCESS) {
4 * sizeof(uint32_t)) != QDF_STATUS_SUCCESS) {
BMI_ERR("HifDiagReadiMem FW Dump Area failed!");
goto out_fail;
}
@@ -607,7 +607,7 @@ void ol_schedule_fw_indication_work(struct hif_opaque_softc *scn)
}
#endif
void ol_target_failure(void *instance, CDF_STATUS status)
void ol_target_failure(void *instance, QDF_STATUS status)
{
struct ol_context *ol_ctx = instance;
struct hif_opaque_softc *scn = ol_ctx->scn;
@@ -663,7 +663,7 @@ void ol_target_failure(void *instance, CDF_STATUS status)
return;
}
CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
QDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
{
uint32_t param;
#ifdef CONFIG_CNSS
@@ -680,18 +680,18 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_app_host_interest)),
(uint8_t *) &param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *) &param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("bmi_write_memory for htc version failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* set the firmware mode to STA/IBSS/AP */
{
if (bmi_read_memory(hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("bmi_read_memory for setting fwmode failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* TODO following parameters need to be re-visited. */
@@ -711,9 +711,9 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI WRITE for setting fwmode failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
@@ -722,18 +722,18 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
/* set the firmware to disable CDC max perf WAR */
if (bmi_read_memory(hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *) &param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *) &param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI READ for setting cdc max perf failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
param |= HI_OPTION_DISABLE_CDC_MAX_PERF_WAR;
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("setting cdc max perf failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
#endif /* CONFIG_CDC_MAX_PERF_WAR */
@@ -747,19 +747,19 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (!ret && cap.cap_flag & CNSS_HAS_EXTERNAL_SWREG) {
if (bmi_read_memory(hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("bmi_read_memory for setting"
"external SWREG failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
param |= HI_OPTION_USE_EXT_LDO;
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI WRITE for setting external SWREG fail");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
#endif
@@ -768,18 +768,18 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (ini_cfg->enable_lpass_support) {
if (bmi_read_memory(hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *) &param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *) &param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI READ:Setting LPASS Support failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
param |= HI_OPTION_DBUART_SUPPORT;
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_option_flag2)),
(uint8_t *)&param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *)&param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI_READ for setting LPASS Support fail");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
#endif
@@ -794,9 +794,9 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_be)),
(uint8_t *) &param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *) &param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("setting host CPU BE mode failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
@@ -805,12 +805,12 @@ CDF_STATUS ol_configure_target(struct ol_context *ol_ctx)
if (bmi_write_memory(
hif_hia_item_address(target_type,
offsetof(struct host_interest_s, hi_fw_swap)),
(uint8_t *) &param, 4, ol_ctx) != CDF_STATUS_SUCCESS) {
(uint8_t *) &param, 4, ol_ctx) != QDF_STATUS_SUCCESS) {
BMI_ERR("BMI WRITE failed setting FW data/desc swap flags");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static int
@@ -821,11 +821,11 @@ ol_check_dataset_patch(struct hif_opaque_softc *scn, uint32_t *address)
}
CDF_STATUS ol_fw_populate_clk_settings(A_refclk_speed_t refclk,
QDF_STATUS ol_fw_populate_clk_settings(A_refclk_speed_t refclk,
struct cmnos_clock_s *clock_s)
{
if (!clock_s)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
switch (refclk) {
case SOC_REFCLK_48_MHZ:
@@ -876,20 +876,20 @@ CDF_STATUS ol_fw_populate_clk_settings(A_refclk_speed_t refclk,
clock_s->pll_settling_time = 1024;
clock_s->refclk_hz = 0;
default:
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
clock_s->refclk_hz = refclk_speed_to_hz[refclk];
clock_s->wlan_pll.refdiv = 0;
clock_s->wlan_pll.outdiv = 1;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
QDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *hif = ol_ctx->scn;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
uint32_t addr = 0;
uint32_t reg_val = 0;
uint32_t mem_val = 0;
@@ -927,14 +927,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
addr = (RTC_SOC_BASE_ADDRESS | EFUSE_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read EFUSE Addr");
goto end;
}
status = ol_fw_populate_clk_settings(EFUSE_XTAL_SEL_GET(reg_val),
&clock_s);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to set clock settings");
goto end;
}
@@ -944,7 +944,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_SOC_BASE_ADDRESS | BB_PLL_CONFIG_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read PLL_CONFIG Addr");
goto end;
}
@@ -954,14 +954,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val |= (BB_PLL_CONFIG_FRAC_SET(clock_s.wlan_pll.rnfrac) |
BB_PLL_CONFIG_OUTDIV_SET(clock_s.wlan_pll.outdiv));
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_CONFIG Addr");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back PLL_CONFIG Addr");
goto end;
}
@@ -971,7 +971,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_WMAC_BASE_ADDRESS | WLAN_PLL_SETTLE_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read PLL_SETTLE Addr");
goto end;
}
@@ -980,14 +980,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val &= ~WLAN_PLL_SETTLE_TIME_MASK;
reg_val |= WLAN_PLL_SETTLE_TIME_SET(clock_s.pll_settling_time);
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_SETTLE Addr");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back PLL_SETTLE Addr");
goto end;
}
@@ -997,7 +997,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_SOC_BASE_ADDRESS | SOC_CORE_CLK_CTRL_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read CLK_CTRL Addr");
goto end;
}
@@ -1006,14 +1006,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val &= ~SOC_CORE_CLK_CTRL_DIV_MASK;
reg_val |= SOC_CORE_CLK_CTRL_DIV_SET(1);
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write CLK_CTRL Addr");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back CLK_CTRL Addr");
goto end;
}
@@ -1023,7 +1023,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
mem_val = 1;
status = bmi_write_memory(cmnos_core_clk_div_addr,
(uint8_t *) &mem_val, 4, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write CLK_DIV Addr");
goto end;
}
@@ -1032,7 +1032,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_WMAC_BASE_ADDRESS | WLAN_PLL_CONTROL_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read PLL_CTRL Addr");
goto end;
}
@@ -1044,14 +1044,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
WLAN_PLL_CONTROL_DIV_SET(clock_s.wlan_pll.div) |
WLAN_PLL_CONTROL_NOPWD_SET(1));
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_CTRL Addr");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back PLL_CTRL Addr");
goto end;
}
@@ -1063,7 +1063,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
status = bmi_read_soc_register((RTC_WMAC_BASE_ADDRESS |
RTC_SYNC_STATUS_OFFSET), &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read RTC_SYNC_STATUS Addr");
goto end;
}
@@ -1073,7 +1073,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_WMAC_BASE_ADDRESS | WLAN_PLL_CONTROL_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read PLL_CTRL Addr for CTRL_BYPASS");
goto end;
}
@@ -1082,14 +1082,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val &= ~WLAN_PLL_CONTROL_BYPASS_MASK;
reg_val |= WLAN_PLL_CONTROL_BYPASS_SET(0);
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_CTRL Addr for CTRL_BYPASS");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back PLL_CTRL Addr for CTRL_BYPASS");
goto end;
}
@@ -1100,7 +1100,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
status = bmi_read_soc_register((RTC_WMAC_BASE_ADDRESS |
RTC_SYNC_STATUS_OFFSET), &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read SYNC_STATUS Addr");
goto end;
}
@@ -1110,7 +1110,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_SOC_BASE_ADDRESS | SOC_CPU_CLOCK_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read CPU_CLK Addr");
goto end;
}
@@ -1119,14 +1119,14 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val &= ~SOC_CPU_CLOCK_STANDARD_MASK;
reg_val |= SOC_CPU_CLOCK_STANDARD_SET(1);
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write CPU_CLK Addr");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back CPU_CLK Addr");
goto end;
}
@@ -1136,7 +1136,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val = 0;
addr = (RTC_WMAC_BASE_ADDRESS | WLAN_PLL_CONTROL_OFFSET);
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read PLL_CTRL Addr for NOPWD");
goto end;
}
@@ -1144,13 +1144,13 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
reg_val &= ~WLAN_PLL_CONTROL_NOPWD_MASK;
status = bmi_write_soc_register(addr, reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_CTRL Addr for NOPWD");
goto end;
}
reg_val = 0;
status = bmi_read_soc_register(addr, &reg_val, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to read back PLL_CTRL Addr for NOPWD");
goto end;
}
@@ -1160,7 +1160,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
mem_val = 1;
status = bmi_write_memory(cmnos_cpu_pll_init_done_addr,
(uint8_t *) &mem_val, 4, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write PLL_INIT Addr");
goto end;
}
@@ -1168,7 +1168,7 @@ CDF_STATUS ol_patch_pll_switch(struct ol_context *ol_ctx)
mem_val = TARGET_CPU_FREQ;
status = bmi_write_memory(cmnos_cpu_speed_addr,
(uint8_t *) &mem_val, 4, ol_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to write CPU_SPEED Addr");
goto end;
}
@@ -1184,7 +1184,7 @@ end:
void ol_transfer_codeswap_struct(struct ol_context *ol_ctx)
{
struct codeswap_codeseg_info wlan_codeswap;
CDF_STATUS rv;
QDF_STATUS rv;
if (cnss_get_codeswap_struct(&wlan_codeswap)) {
BMI_ERR("%s: failed to get codeswap structure", __func__);
@@ -1195,7 +1195,7 @@ void ol_transfer_codeswap_struct(struct ol_context *ol_ctx)
(uint8_t *) &wlan_codeswap, sizeof(wlan_codeswap),
ol_ctx);
if (rv != CDF_STATUS_SUCCESS) {
if (rv != QDF_STATUS_SUCCESS) {
BMI_ERR("Failed to Write 0xa0000 to Target");
return;
}
@@ -1203,12 +1203,12 @@ void ol_transfer_codeswap_struct(struct ol_context *ol_ctx)
}
#endif
CDF_STATUS ol_download_firmware(struct ol_context *ol_ctx)
QDF_STATUS ol_download_firmware(struct ol_context *ol_ctx)
{
struct hif_opaque_softc *scn = ol_ctx->scn;
uint32_t param, address = 0;
int status = !EOK;
CDF_STATUS ret;
QDF_STATUS ret;
struct hif_target_info *tgt_info = hif_get_target_info_handle(scn);
struct ol_config_info *ini_cfg = ol_get_ini_handle(ol_ctx);
uint32_t target_type = tgt_info->target_type;
@@ -1220,7 +1220,7 @@ CDF_STATUS ol_download_firmware(struct ol_context *ol_ctx)
target_type,
target_version)) {
BMI_ERR("%s: No FW files from CNSS driver", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
#endif
/* Transfer Board Data from Target EEPROM to Target RAM */
@@ -1237,7 +1237,7 @@ CDF_STATUS ol_download_firmware(struct ol_context *ol_ctx)
ret = ol_patch_pll_switch(ol_ctx);
if (ret != CDF_STATUS_SUCCESS) {
if (ret != QDF_STATUS_SUCCESS) {
BMI_ERR("pll switch failed. status %d", ret);
return ret;
}

39
core/cdf/inc/cdf_lock.h
Fájl megtekintése

@@ -39,7 +39,6 @@
*/
/* Include Files */
#include "cdf_status.h"
#include "qdf_status.h"
#include "i_cdf_lock.h"
@@ -107,10 +106,10 @@ cdf_semaphore_release(cdf_device_t osdev, cdf_semaphore_t *m)
* a failure.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_init(cdf_mutex_t *lock);
QDF_STATUS cdf_mutex_init(cdf_mutex_t *lock);
/**
* cdf_mutex_acquire () - acquire a CDF lock
@@ -122,10 +121,10 @@ CDF_STATUS cdf_mutex_init(cdf_mutex_t *lock);
* lock in the locked state with the calling thread as its owner.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock);
QDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock);
/**
* cdf_mutex_release() - release a CDF lock
@@ -138,10 +137,10 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock);
* initialized, an error is returned.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock);
QDF_STATUS cdf_mutex_release(cdf_mutex_t *lock);
/**
* cdf_mutex_destroy() - destroy a CDF lock
@@ -159,10 +158,10 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock);
* been re-initialized.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock);
QDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock);
/**
* cdf_spinlock_init() - initialize a spinlock
@@ -217,7 +216,7 @@ static inline void cdf_spin_unlock_bh(cdf_spinlock_t *lock)
* CDF status success : if wake lock is initialized
* CDF status fialure : if wake lock was not initialized
*/
CDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *lock, const char *name);
QDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *lock, const char *name);
/**
* cdf_wake_lock_acquire() - acquires a wake lock
@@ -228,7 +227,7 @@ CDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *lock, const char *name);
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason);
QDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason);
/**
* cdf_wake_lock_timeout_acquire() - acquires a wake lock with a timeout
@@ -239,7 +238,7 @@ CDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason);
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock,
QDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock,
uint32_t msec, uint32_t reason);
/**
@@ -251,7 +250,7 @@ CDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock,
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason);
QDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason);
/**
* cdf_wake_lock_destroy() - destroys a wake lock
@@ -261,15 +260,15 @@ CDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason);
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_destroy(cdf_wake_lock_t *pLock);
QDF_STATUS cdf_wake_lock_destroy(cdf_wake_lock_t *pLock);
struct hif_pm_runtime_lock;
typedef struct hif_pm_runtime_lock *cdf_runtime_lock_t;
CDF_STATUS cdf_runtime_pm_get(void);
CDF_STATUS cdf_runtime_pm_put(void);
CDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock);
CDF_STATUS cdf_runtime_pm_allow_suspend(cdf_runtime_lock_t lock);
QDF_STATUS cdf_runtime_pm_get(void);
QDF_STATUS cdf_runtime_pm_put(void);
QDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock);
QDF_STATUS cdf_runtime_pm_allow_suspend(cdf_runtime_lock_t lock);
cdf_runtime_lock_t cdf_runtime_lock_init(const char *name);
void cdf_runtime_lock_deinit(cdf_runtime_lock_t lock);
@@ -281,7 +280,7 @@ void cdf_runtime_lock_deinit(cdf_runtime_lock_t lock);
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock);
QDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock);
/**
* cdf_spinlock_release() - release a spin lock
@@ -291,7 +290,7 @@ CDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock);
* CDF status success : if wake lock is acquired
* CDF status fialure : if wake lock was not acquired
*/
CDF_STATUS cdf_spinlock_release(cdf_spinlock_t *pLock);
QDF_STATUS cdf_spinlock_release(cdf_spinlock_t *pLock);
#define cdf_spin_lock(_lock) __cdf_spin_lock(_lock)
#define cdf_spin_unlock(_lock) __cdf_spin_unlock(_lock)

19
core/cdf/inc/cdf_mc_timer.h
Fájl megtekintése

@@ -36,7 +36,6 @@
/* Include Files */
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_lock.h>
#include <i_cdf_mc_timer.h>
@@ -150,7 +149,7 @@ CDF_TIMER_STATE cdf_mc_timer_get_current_state(cdf_mc_timer_t *pTimer);
* within the tx thread flow.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
#ifdef TIMER_MANAGER
@@ -158,13 +157,13 @@ CDF_TIMER_STATE cdf_mc_timer_get_current_state(cdf_mc_timer_t *pTimer);
cdf_mc_timer_init_debug(timer, timerType, callback, userdata, \
__FILE__, __LINE__)
CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
QDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
CDF_TIMER_TYPE timerType,
cdf_mc_timer_callback_t callback,
void *userData, char *fileName,
uint32_t lineNum);
#else
CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
QDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
cdf_mc_timer_callback_t callback,
void *userData);
#endif
@@ -187,10 +186,10 @@ CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
* been re-initialized.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer);
QDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer);
/**
* cdf_mc_timer_start() - start a CDF Timer object
@@ -206,10 +205,10 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer);
* or has been cancelled.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime);
QDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime);
/**
* cdf_mc_timer_stop() - stop a CDF Timer
@@ -221,10 +220,10 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime);
* was created and can be started again via a call to cdf_mc_timer_start().
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer);
QDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer);
/**
* cdf_mc_timer_get_system_ticks() - get the system time in 10ms ticks

6
core/cdf/inc/cdf_nbuf.h
Fájl megtekintése

@@ -95,7 +95,7 @@ typedef __cdf_nbuf_queue_t cdf_nbuf_queue_t;
*
* Return: Status of the operation
*/
static inline CDF_STATUS
static inline QDF_STATUS
cdf_nbuf_map(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
{
return __cdf_nbuf_map(osdev, buf, dir);
@@ -123,7 +123,7 @@ cdf_nbuf_unmap(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
*
* Return: Status of the operation
*/
static inline CDF_STATUS
static inline QDF_STATUS
cdf_nbuf_map_single(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
{
return __cdf_nbuf_map_single(osdev, buf, dir);
@@ -448,7 +448,7 @@ static inline cdf_nbuf_t cdf_nbuf_copy(cdf_nbuf_t buf)
*
* Return: Status of the call - 0 successful
*/
static inline CDF_STATUS cdf_nbuf_cat(cdf_nbuf_t dst, cdf_nbuf_t src)
static inline QDF_STATUS cdf_nbuf_cat(cdf_nbuf_t dst, cdf_nbuf_t src)
{
return __cdf_nbuf_cat(dst, src);
}

112
core/cdf/inc/cdf_status.h
Fájl megtekintése

@@ -1,112 +0,0 @@
/*
* Copyright (c) 2014-2015 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
*
* Permission to use, copy, modify, and/or distribute this software for
* any purpose with or without fee is hereby granted, provided that the
* above copyright notice and this permission notice appear in all
* copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
* WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
* AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
* DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
* PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
* TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
* PERFORMANCE OF THIS SOFTWARE.
*/
/*
* This file was originally distributed by Qualcomm Atheros, Inc.
* under proprietary terms before Copyright ownership was assigned
* to the Linux Foundation.
*/
#if !defined(__CDF_STATUS_H)
#define __CDF_STATUS_H
#include <qdf_status.h>
/**
* DOC: cdf_status
*
* Connectivity driver framework (CDF) status codes
*
* Basic status codes/definitions used by CDF
*/
/**
* typedef CDF_STATUS - CDF error codes
* @CDF_STATUS_SUCCESS: success
* @CDF_STATUS_E_RESOURCES: system resource(other than memory) not available
* @CDF_STATUS_E_NOMEM: not enough memory
* @CDF_STATUS_E_AGAIN: try again
* @CDF_STATUS_E_INVAL: invalid request
* @CDF_STATUS_E_FAULT: system fault
* @CDF_STATUS_E_ALREADY: another request already in progress
* @CDF_STATUS_E_BADMSG: bad message
* @CDF_STATUS_E_BUSY: device or resource busy
* @CDF_STATUS_E_CANCELED: request cancelled
* @CDF_STATUS_E_ABORTED: request aborted
* @CDF_STATUS_E_NOSUPPORT: request not supported
* @CDF_STATUS_E_PERM: operation not permitted
* @CDF_STATUS_E_EMPTY: empty condition
* @CDF_STATUS_E_EXISTS: existence failure
* @CDF_STATUS_E_TIMEOUT: operation timeout
* @CDF_STATUS_E_FAILURE: unknown reason do not use unless nothign else applies
* @CDF_STATUS_NOT_INITIALIZED: resource not initialized
* @CDF_STATUS_E_NULL_VALUE: request is null
* @CDF_STATUS_PMC_PENDING: request pendign in pmc
* @CDF_STATUS_PMC_DISABLED: pmc is disabled
* @CDF_STATUS_PMC_NOT_NOW: pmc not ready now
* @CDF_STATUS_PMC_AC_POWER: pmc ac power
* @CDF_STATUS_PMC_SYS_ERROR: pmc system error
* @CDF_STATUS_HEARTBEAT_TMOUT: hearbeat timeout error
* @CDF_STATUS_NTH_BEACON_DELIVERY: Nth beacon delivery
* @CDF_STATUS_CSR_WRONG_STATE: csr in wrong state
* @CDF_STATUS_FT_PREAUTH_KEY_SUCCESS: ft preauth key success
* @CDF_STATUS_FT_PREAUTH_KEY_FAILED: ft preauth key failed
* @CDF_STATUS_CMD_NOT_QUEUED: command not queued
* @CDF_STATUS_FW_MSG_TIMEDOUT: target message timeout
* @CDF_STATUS_MAX: not a realy value just a place holder for max
*/
typedef enum {
CDF_STATUS_SUCCESS,
CDF_STATUS_E_RESOURCES,
CDF_STATUS_E_NOMEM,
CDF_STATUS_E_AGAIN,
CDF_STATUS_E_INVAL,
CDF_STATUS_E_FAULT,
CDF_STATUS_E_ALREADY,
CDF_STATUS_E_BADMSG,
CDF_STATUS_E_BUSY,
CDF_STATUS_E_CANCELED,
CDF_STATUS_E_ABORTED,
CDF_STATUS_E_NOSUPPORT,
CDF_STATUS_E_PERM,
CDF_STATUS_E_EMPTY,
CDF_STATUS_E_EXISTS,
CDF_STATUS_E_TIMEOUT,
CDF_STATUS_E_FAILURE,
CDF_STATUS_NOT_INITIALIZED,
CDF_STATUS_E_NULL_VALUE,
CDF_STATUS_PMC_PENDING,
CDF_STATUS_PMC_DISABLED,
CDF_STATUS_PMC_NOT_NOW,
CDF_STATUS_PMC_AC_POWER,
CDF_STATUS_PMC_SYS_ERROR,
CDF_STATUS_HEARTBEAT_TMOUT,
CDF_STATUS_NTH_BEACON_DELIVERY,
CDF_STATUS_CSR_WRONG_STATE,
CDF_STATUS_FT_PREAUTH_KEY_SUCCESS,
CDF_STATUS_FT_PREAUTH_KEY_FAILED,
CDF_STATUS_CMD_NOT_QUEUED,
CDF_STATUS_FW_MSG_TIMEDOUT,
CDF_STATUS_MAX
} CDF_STATUS;
#define CDF_IS_STATUS_SUCCESS(status) (CDF_STATUS_SUCCESS == (status))
#endif /* if !defined __CDF_STATUS_H */

3
core/cdf/inc/cdf_trace.h
Fájl megtekintése

@@ -40,7 +40,6 @@
/* Include Files */
#include <cdf_types.h> /* For CDF_MODULE_ID... */
#include <stdarg.h> /* For va_list... */
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_nbuf.h>
#include <cds_packet.h>
@@ -265,7 +264,7 @@ bool cdf_trace_get_level(CDF_MODULE_ID module, CDF_TRACE_LEVEL level);
typedef void (*tp_cdf_trace_cb)(void *pMac, tp_cdf_trace_record, uint16_t);
void cdf_trace(uint8_t module, uint8_t code, uint16_t session, uint32_t data);
void cdf_trace_register(CDF_MODULE_ID, tp_cdf_trace_cb);
CDF_STATUS cdf_trace_spin_lock_init(void);
QDF_STATUS cdf_trace_spin_lock_init(void);
void cdf_trace_init(void);
void cdf_trace_enable(uint32_t, uint8_t enable);
void cdf_trace_dump_all(void *, uint8_t, uint8_t, uint32_t, uint32_t);

2
core/cdf/inc/cdf_util.h
Fájl megtekintése

@@ -48,7 +48,7 @@
*/
#define cdf_likely(_expr) __cdf_likely(_expr)
CDF_INLINE_FN int cdf_status_to_os_return(CDF_STATUS status)
CDF_INLINE_FN int cdf_status_to_os_return(QDF_STATUS status)
{
return __cdf_status_to_os_return(status);
}

126
core/cdf/src/cdf_lock.c
Fájl megtekintése

@@ -82,29 +82,29 @@ enum {
* a failure.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_init(cdf_mutex_t *lock)
QDF_STATUS cdf_mutex_init(cdf_mutex_t *lock)
{
/* check for invalid pointer */
if (lock == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed in", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* check for 'already initialized' lock */
if (LINUX_LOCK_COOKIE == lock->cookie) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: already initialized lock", __func__);
return CDF_STATUS_E_BUSY;
return QDF_STATUS_E_BUSY;
}
if (in_interrupt()) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s cannot be called from interrupt context!!!",
__func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* initialize new lock */
@@ -114,7 +114,7 @@ CDF_STATUS cdf_mutex_init(cdf_mutex_t *lock)
lock->processID = 0;
lock->refcount = 0;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -127,10 +127,10 @@ CDF_STATUS cdf_mutex_init(cdf_mutex_t *lock)
* lock in the locked state with the calling thread as its owner.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
QDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
{
int rc;
/* check for invalid pointer */
@@ -138,14 +138,14 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed in", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* check if lock refers to an initialized object */
if (LINUX_LOCK_COOKIE != lock->cookie) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: uninitialized lock", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (in_interrupt()) {
@@ -153,7 +153,7 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
"%s cannot be called from interrupt context!!!",
__func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if ((lock->processID == current->pid) &&
(lock->state == LOCK_ACQUIRED)) {
@@ -163,7 +163,7 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
"%s: %x %d %d", __func__, lock, current->pid,
lock->refcount);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* acquire a Lock */
mutex_lock(&lock->m_lock);
@@ -172,7 +172,7 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: unable to lock mutex (rc = %d)", __func__, rc);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
#ifdef CDF_NESTED_LOCK_DEBUG
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO,
@@ -182,14 +182,14 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
lock->processID = current->pid;
lock->refcount++;
lock->state = LOCK_ACQUIRED;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} else {
/* lock is already destroyed */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Lock is already destroyed", __func__);
mutex_unlock(&lock->m_lock);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
@@ -204,17 +204,17 @@ CDF_STATUS cdf_mutex_acquire(cdf_mutex_t *lock)
* initialized, an error is returned.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
QDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
{
/* check for invalid pointer */
if (lock == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed in", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* check if lock refers to an uninitialized object */
@@ -222,7 +222,7 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: uninitialized lock", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (in_interrupt()) {
@@ -230,7 +230,7 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
"%s cannot be called from interrupt context!!!",
__func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* CurrentThread = GetCurrentThreadId();
@@ -247,7 +247,7 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
__func__, lock->processID, current->pid);
#endif
CDF_ASSERT(0);
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
if ((lock->processID == current->pid) &&
(lock->state == LOCK_ACQUIRED)) {
@@ -260,7 +260,7 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
lock->refcount);
#endif
if (lock->refcount)
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
lock->processID = 0;
lock->refcount = 0;
@@ -272,7 +272,7 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
"%s: Freeing lock %x %d %d", lock, lock->processID,
lock->refcount);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -291,36 +291,36 @@ CDF_STATUS cdf_mutex_release(cdf_mutex_t *lock)
* been re-initialized.
*
* Return:
* CDF_STATUS_SUCCESS: lock was successfully initialized
* QDF_STATUS_SUCCESS: lock was successfully initialized
* CDF failure reason codes: lock is not initialized and can't be used
*/
CDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock)
QDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock)
{
/* check for invalid pointer */
if (NULL == lock) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed in", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (LINUX_LOCK_COOKIE != lock->cookie) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: uninitialized lock", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (in_interrupt()) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s cannot be called from interrupt context!!!",
__func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* check if lock is released */
if (!mutex_trylock(&lock->m_lock)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: lock is not released", __func__);
return CDF_STATUS_E_BUSY;
return QDF_STATUS_E_BUSY;
}
lock->cookie = 0;
lock->state = LOCK_DESTROYED;
@@ -329,7 +329,7 @@ CDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock)
mutex_unlock(&lock->m_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -340,10 +340,10 @@ CDF_STATUS cdf_mutex_destroy(cdf_mutex_t *lock)
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock)
QDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock)
{
spin_lock(&pLock->spinlock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -354,10 +354,10 @@ CDF_STATUS cdf_spinlock_acquire(cdf_spinlock_t *pLock)
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_spinlock_release(cdf_spinlock_t *pLock)
QDF_STATUS cdf_spinlock_release(cdf_spinlock_t *pLock)
{
spin_unlock(&pLock->spinlock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -390,14 +390,14 @@ static const char *cdf_wake_lock_name(cdf_wake_lock_t *pLock)
* CDF status success : if wake lock is initialized
* CDF status failure : if wake lock was not initialized
*/
CDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *pLock, const char *name)
QDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *pLock, const char *name)
{
#if defined CONFIG_CNSS
cnss_pm_wake_lock_init(pLock, name);
#elif defined(WLAN_OPEN_SOURCE) && defined(CONFIG_HAS_WAKELOCK)
wake_lock_init(pLock, WAKE_LOCK_SUSPEND, name);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -409,7 +409,7 @@ CDF_STATUS cdf_wake_lock_init(cdf_wake_lock_t *pLock, const char *name)
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason)
QDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason)
{
host_diag_log_wlock(reason, cdf_wake_lock_name(pLock),
WIFI_POWER_EVENT_DEFAULT_WAKELOCK_TIMEOUT,
@@ -419,7 +419,7 @@ CDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason)
#elif defined(WLAN_OPEN_SOURCE) && defined(CONFIG_HAS_WAKELOCK)
wake_lock(pLock);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -431,7 +431,7 @@ CDF_STATUS cdf_wake_lock_acquire(cdf_wake_lock_t *pLock, uint32_t reason)
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock, uint32_t msec,
QDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock, uint32_t msec,
uint32_t reason)
{
/* Wakelock for Rx is frequent.
@@ -448,7 +448,7 @@ CDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock, uint32_t msec,
#elif defined(WLAN_OPEN_SOURCE) && defined(CONFIG_HAS_WAKELOCK)
wake_lock_timeout(pLock, msecs_to_jiffies(msec));
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -460,7 +460,7 @@ CDF_STATUS cdf_wake_lock_timeout_acquire(cdf_wake_lock_t *pLock, uint32_t msec,
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason)
QDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason)
{
host_diag_log_wlock(reason, cdf_wake_lock_name(pLock),
WIFI_POWER_EVENT_DEFAULT_WAKELOCK_TIMEOUT,
@@ -470,7 +470,7 @@ CDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason)
#elif defined(WLAN_OPEN_SOURCE) && defined(CONFIG_HAS_WAKELOCK)
wake_unlock(pLock);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -481,14 +481,14 @@ CDF_STATUS cdf_wake_lock_release(cdf_wake_lock_t *pLock, uint32_t reason)
* CDF status success : if wake lock is acquired
* CDF status failure : if wake lock was not acquired
*/
CDF_STATUS cdf_wake_lock_destroy(cdf_wake_lock_t *pLock)
QDF_STATUS cdf_wake_lock_destroy(cdf_wake_lock_t *pLock)
{
#if defined CONFIG_CNSS
cnss_pm_wake_lock_destroy(pLock);
#elif defined(WLAN_OPEN_SOURCE) && defined(CONFIG_HAS_WAKELOCK)
wake_lock_destroy(pLock);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -504,7 +504,7 @@ CDF_STATUS cdf_wake_lock_destroy(cdf_wake_lock_t *pLock)
* return: success if the bus is up and a get has been issued
* otherwise an error code.
*/
CDF_STATUS cdf_runtime_pm_get(void)
QDF_STATUS cdf_runtime_pm_get(void)
{
void *ol_sc;
int ret;
@@ -515,15 +515,15 @@ CDF_STATUS cdf_runtime_pm_get(void)
CDF_ASSERT(0);
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: HIF context is null!", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
ret = hif_pm_runtime_get(ol_sc);
if (ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -534,9 +534,9 @@ CDF_STATUS cdf_runtime_pm_get(void)
*
* This api will return a failure if the hif module hasn't been initialized
*
* return: CDF_STATUS_SUCCESS if the put is performed
* return: QDF_STATUS_SUCCESS if the put is performed
*/
CDF_STATUS cdf_runtime_pm_put(void)
QDF_STATUS cdf_runtime_pm_put(void)
{
void *ol_sc;
int ret;
@@ -547,15 +547,15 @@ CDF_STATUS cdf_runtime_pm_put(void)
CDF_ASSERT(0);
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: HIF context is null!", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
ret = hif_pm_runtime_put(ol_sc);
if (ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -564,9 +564,9 @@ CDF_STATUS cdf_runtime_pm_put(void)
*
* The lock can only be acquired once per lock context and is tracked.
*
* return: CDF_STATUS_SUCCESS or failure code.
* return: QDF_STATUS_SUCCESS or failure code.
*/
CDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock)
QDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock)
{
void *ol_sc;
int ret;
@@ -577,15 +577,15 @@ CDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock)
CDF_ASSERT(0);
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: HIF context is null!", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
ret = hif_pm_runtime_prevent_suspend(ol_sc, lock);
if (ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -594,9 +594,9 @@ CDF_STATUS cdf_runtime_pm_prevent_suspend(cdf_runtime_lock_t lock)
*
* The lock can only be acquired once per lock context and is tracked.
*
* return: CDF_STATUS_SUCCESS or failure code.
* return: QDF_STATUS_SUCCESS or failure code.
*/
CDF_STATUS cdf_runtime_pm_allow_suspend(cdf_runtime_lock_t lock)
QDF_STATUS cdf_runtime_pm_allow_suspend(cdf_runtime_lock_t lock)
{
void *ol_sc;
int ret;
@@ -607,15 +607,15 @@ CDF_STATUS cdf_runtime_pm_allow_suspend(cdf_runtime_lock_t lock)
CDF_ASSERT(0);
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: HIF context is null!", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
ret = hif_pm_runtime_allow_suspend(ol_sc, lock);
if (ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

90
core/cdf/src/cdf_mc_timer.c
Fájl megtekintése

@@ -96,7 +96,7 @@ static void cdf_linux_timer_callback(unsigned long data)
{
cdf_mc_timer_t *timer = (cdf_mc_timer_t *) data;
cds_msg_t msg;
CDF_STATUS vStatus;
QDF_STATUS vStatus;
unsigned long flags;
cdf_mc_timer_callback_t callback = NULL;
@@ -122,15 +122,15 @@ static void cdf_linux_timer_callback(unsigned long data)
* not been updated this is a rare race condition!
*/
timer->state = CDF_TIMER_STATE_STOPPED;
vStatus = CDF_STATUS_E_ALREADY;
vStatus = QDF_STATUS_E_ALREADY;
break;
case CDF_TIMER_STATE_STOPPED:
vStatus = CDF_STATUS_E_ALREADY;
vStatus = QDF_STATUS_E_ALREADY;
break;
case CDF_TIMER_STATE_UNUSED:
vStatus = CDF_STATUS_E_EXISTS;
vStatus = QDF_STATUS_E_EXISTS;
break;
case CDF_TIMER_STATE_RUNNING:
@@ -146,18 +146,18 @@ static void cdf_linux_timer_callback(unsigned long data)
userData = timer->userData;
threadId = timer->platformInfo.threadID;
type = timer->type;
vStatus = CDF_STATUS_SUCCESS;
vStatus = QDF_STATUS_SUCCESS;
break;
default:
CDF_ASSERT(0);
vStatus = CDF_STATUS_E_FAULT;
vStatus = QDF_STATUS_E_FAULT;
break;
}
spin_unlock_irqrestore(&timer->platformInfo.spinlock, flags);
if (CDF_STATUS_SUCCESS != vStatus) {
if (QDF_STATUS_SUCCESS != vStatus) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"TIMER callback called in a wrong state=%d",
timer->state);
@@ -182,7 +182,7 @@ static void cdf_linux_timer_callback(unsigned long data)
msg.bodyptr = userData;
msg.bodyval = 0;
if (cds_mq_post_message(CDS_MQ_ID_SYS, &msg) == CDF_STATUS_SUCCESS)
if (cds_mq_post_message(CDS_MQ_ID_SYS, &msg) == QDF_STATUS_SUCCESS)
return;
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
@@ -335,11 +335,11 @@ void cdf_mc_timer_exit(void)
* within the tx thread flow.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
#ifdef TIMER_MANAGER
CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
QDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
CDF_TIMER_TYPE timerType,
cdf_mc_timer_callback_t callback,
void *userData, char *fileName,
@@ -352,7 +352,7 @@ CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null params being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
timer->ptimerNode = cdf_mem_malloc(sizeof(cdf_mc_timer_node_t));
@@ -362,7 +362,7 @@ CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
"%s: Not able to allocate memory for timeNode",
__func__);
CDF_ASSERT(0);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cdf_mem_set(timer->ptimerNode, sizeof(cdf_mc_timer_node_t), 0);
@@ -377,7 +377,7 @@ CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
cdf_spin_unlock_irqrestore(&cdf_timer_list_lock);
if (QDF_STATUS_SUCCESS != qdf_status) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Unable to insert node into List cdf_status %d",
"%s: Unable to insert node into List qdf_status %d",
__func__, qdf_status);
}
@@ -398,10 +398,10 @@ CDF_STATUS cdf_mc_timer_init_debug(cdf_mc_timer_t *timer,
timer->platformInfo.threadID = 0;
timer->state = CDF_TIMER_STATE_STOPPED;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#else
CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
QDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
cdf_mc_timer_callback_t callback,
void *userData)
{
@@ -410,7 +410,7 @@ CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null params being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* set the various members of the timer structure
@@ -430,7 +430,7 @@ CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
timer->platformInfo.threadID = 0;
timer->state = CDF_TIMER_STATE_STOPPED;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -452,11 +452,11 @@ CDF_STATUS cdf_mc_timer_init(cdf_mc_timer_t *timer, CDF_TIMER_TYPE timerType,
* been re-initialized.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
#ifdef TIMER_MANAGER
CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
QDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
{
QDF_STATUS status = QDF_STATUS_SUCCESS;
unsigned long flags;
@@ -466,7 +466,7 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null timer pointer being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* Check if timer refers to an uninitialized object */
@@ -474,7 +474,7 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Cannot destroy uninitialized timer", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
cdf_spin_lock_irqsave(&cdf_timer_list_lock);
@@ -550,12 +550,12 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
* been re-initialized.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
QDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
unsigned long flags;
/* check for invalid pointer */
@@ -563,7 +563,7 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null timer pointer being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
/* check if timer refers to an uninitialized object */
@@ -571,36 +571,36 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Cannot destroy uninitialized timer", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
spin_lock_irqsave(&timer->platformInfo.spinlock, flags);
switch (timer->state) {
case CDF_TIMER_STATE_STARTING:
vStatus = CDF_STATUS_E_BUSY;
vStatus = QDF_STATUS_E_BUSY;
break;
case CDF_TIMER_STATE_RUNNING:
/* Stop the timer first */
del_timer(&(timer->platformInfo.Timer));
vStatus = CDF_STATUS_SUCCESS;
vStatus = QDF_STATUS_SUCCESS;
break;
case CDF_TIMER_STATE_STOPPED:
vStatus = CDF_STATUS_SUCCESS;
vStatus = QDF_STATUS_SUCCESS;
break;
case CDF_TIMER_STATE_UNUSED:
vStatus = CDF_STATUS_E_ALREADY;
vStatus = QDF_STATUS_E_ALREADY;
break;
default:
vStatus = CDF_STATUS_E_FAULT;
vStatus = QDF_STATUS_E_FAULT;
break;
}
if (CDF_STATUS_SUCCESS == vStatus) {
if (QDF_STATUS_SUCCESS == vStatus) {
timer->platformInfo.cookie = LINUX_INVALID_TIMER_COOKIE;
timer->state = CDF_TIMER_STATE_UNUSED;
spin_unlock_irqrestore(&timer->platformInfo.spinlock, flags);
@@ -632,10 +632,10 @@ CDF_STATUS cdf_mc_timer_destroy(cdf_mc_timer_t *timer)
* or has been cancelled.
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
QDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
{
unsigned long flags;
@@ -647,7 +647,7 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s Null timer pointer being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* check if timer refers to an uninitialized object */
@@ -656,7 +656,7 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
"%s: Cannot start uninitialized timer", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* check if timer has expiration time less than 10 ms */
@@ -665,7 +665,7 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
"%s: Cannot start a timer with expiration less than 10 ms",
__func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* make sure the remainer of the logic isn't interrupted */
@@ -677,7 +677,7 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Cannot start timer in state = %d ", __func__,
timer->state);
return CDF_STATUS_E_ALREADY;
return QDF_STATUS_E_ALREADY;
}
/* start the timer */
@@ -701,7 +701,7 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
spin_unlock_irqrestore(&timer->platformInfo.spinlock, flags);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -714,10 +714,10 @@ CDF_STATUS cdf_mc_timer_start(cdf_mc_timer_t *timer, uint32_t expirationTime)
* was created and can be started again via a call to cdf_mc_timer_start().
*
* Return:
* CDF_STATUS_SUCCESS - Timer is initialized successfully
* QDF_STATUS_SUCCESS - Timer is initialized successfully
* CDF failure status - Timer initialization failed
*/
CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
QDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
{
unsigned long flags;
@@ -729,7 +729,7 @@ CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s Null timer pointer being passed", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* check if timer refers to an uninitialized object */
@@ -738,7 +738,7 @@ CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
"%s: Cannot stop uninitialized timer", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* ensure the timer state is correct */
@@ -749,7 +749,7 @@ CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Cannot stop timer in state = %d",
__func__, timer->state);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
timer->state = CDF_TIMER_STATE_STOPPED;
@@ -760,7 +760,7 @@ CDF_STATUS cdf_mc_timer_stop(cdf_mc_timer_t *timer)
try_allowing_sleep(timer->type);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

2
core/cdf/src/cdf_memory.c
Fájl megtekintése

@@ -307,7 +307,7 @@ void *cdf_mem_malloc_debug(size_t size, char *fileName, uint32_t lineNum)
cdf_spin_unlock_irqrestore(&cdf_mem_list_lock);
if (QDF_STATUS_SUCCESS != qdf_status) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Unable to insert node into List cdf_status %d",
"%s: Unable to insert node into List qdf_status %d",
__func__, qdf_status);
}

26
core/cdf/src/cdf_nbuf.c
Fájl megtekintése

@@ -44,7 +44,7 @@
#include <cdf_nbuf.h>
#include <cdf_memory.h>
#include <cdf_trace.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_lock.h>
/* Packet Counter */
@@ -230,9 +230,9 @@ void __cdf_nbuf_free(struct sk_buff *skb)
* @skb: Pointer to network buffer
* @dir: Direction
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS
QDF_STATUS
__cdf_nbuf_map(cdf_device_t osdev, struct sk_buff *skb, cdf_dma_dir_t dir)
{
#ifdef CDF_OS_DEBUG
@@ -252,7 +252,7 @@ __cdf_nbuf_map(cdf_device_t osdev, struct sk_buff *skb, cdf_dma_dir_t dir)
return __cdf_nbuf_map_single(osdev, skb, dir);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -284,9 +284,9 @@ __cdf_nbuf_unmap(cdf_device_t osdev, struct sk_buff *skb, cdf_dma_dir_t dir)
* @skb: Pointer to network buffer
* @dir: Direction
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS
QDF_STATUS
__cdf_nbuf_map_single(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
{
cdf_dma_addr_t paddr;
@@ -294,15 +294,15 @@ __cdf_nbuf_map_single(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
/* tempory hack for simulation */
#ifdef A_SIMOS_DEVHOST
NBUF_CB_PADDR(buf) = paddr = buf->data;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
#else
/* assume that the OS only provides a single fragment */
NBUF_CB_PADDR(buf) = paddr =
dma_map_single(osdev->dev, buf->data,
skb_end_pointer(buf) - buf->data, dir);
return dma_mapping_error(osdev->dev, paddr)
? CDF_STATUS_E_FAILURE
: CDF_STATUS_SUCCESS;
? QDF_STATUS_E_FAILURE
: QDF_STATUS_SUCCESS;
#endif /* #ifdef A_SIMOS_DEVHOST */
}
@@ -328,9 +328,9 @@ __cdf_nbuf_unmap_single(cdf_device_t osdev, cdf_nbuf_t buf, cdf_dma_dir_t dir)
* @skb: Pointer to network buffer
* @cksum: Pointer to checksum value
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS
QDF_STATUS
__cdf_nbuf_set_rx_cksum(struct sk_buff *skb, cdf_nbuf_rx_cksum_t *cksum)
{
switch (cksum->l4_result) {
@@ -347,9 +347,9 @@ __cdf_nbuf_set_rx_cksum(struct sk_buff *skb, cdf_nbuf_rx_cksum_t *cksum)
default:
pr_err("ADF_NET:Unknown checksum type\n");
cdf_assert(0);
return CDF_STATUS_E_NOSUPPORT;
return QDF_STATUS_E_NOSUPPORT;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

4
core/cdf/src/cdf_trace.c
Fájl megtekintése

@@ -554,11 +554,11 @@ void cdf_trace(uint8_t module, uint8_t code, uint16_t session, uint32_t data)
*
* Return : nothing
*/
CDF_STATUS cdf_trace_spin_lock_init(void)
QDF_STATUS cdf_trace_spin_lock_init(void)
{
spin_lock_init(&ltrace_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

5
core/cdf/src/i_cdf_atomic.h
Fájl megtekintése

@@ -27,18 +27,17 @@
#ifndef I_CDF_ATOMIC_H
#define I_CDF_ATOMIC_H
#include <cdf_status.h> /* CDF_STATUS */
#include <qdf_status.h> /* QDF_STATUS */
#include <linux/atomic.h>
typedef atomic_t __cdf_atomic_t;
static inline CDF_STATUS __cdf_atomic_init(__cdf_atomic_t *v)
static inline QDF_STATUS __cdf_atomic_init(__cdf_atomic_t *v)
{
atomic_set(v, 0);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline int32_t __cdf_atomic_read(__cdf_atomic_t *v)

21
core/cdf/src/i_cdf_defer.h
Fájl megtekintése

@@ -35,7 +35,6 @@
#include <net/cnss.h>
#endif
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_trace.h>
@@ -52,7 +51,7 @@ typedef struct {
extern void __cdf_defer_func(struct work_struct *work);
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_init_work(__cdf_work_t *work, cdf_defer_fn_t func, void *arg)
{
/*Initilize func and argument in work struct */
@@ -63,38 +62,38 @@ __cdf_init_work(__cdf_work_t *work, cdf_defer_fn_t func, void *arg)
#else
INIT_WORK(&work->work, __cdf_defer_func);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS __cdf_schedule_work(__cdf_work_t *work)
static inline QDF_STATUS __cdf_schedule_work(__cdf_work_t *work)
{
schedule_work(&work->work);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS __cdf_init_bh(cdf_handle_t hdl,
static inline QDF_STATUS __cdf_init_bh(cdf_handle_t hdl,
struct tasklet_struct *bh,
cdf_defer_fn_t func, void *arg)
{
tasklet_init(bh, (__cdf_bh_fn_t) func, (unsigned long)arg);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_sched_bh(cdf_handle_t hdl, struct tasklet_struct *bh)
{
tasklet_schedule(bh);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_disable_bh(cdf_handle_t hdl, struct tasklet_struct *bh)
{
tasklet_kill(bh);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif /*_I_CDF_DEFER_H*/

12
core/cdf/src/i_cdf_lock.h
Fájl megtekintése

@@ -101,12 +101,12 @@ typedef int cdf_wake_lock_t;
* __cdf_semaphore_init() - initialize the semaphore
* @m: Semaphore object
*
* Return: CDF_STATUS_SUCCESS
* Return: QDF_STATUS_SUCCESS
*/
static inline CDF_STATUS __cdf_semaphore_init(struct semaphore *m)
static inline QDF_STATUS __cdf_semaphore_init(struct semaphore *m)
{
sema_init(m, 1);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -138,14 +138,14 @@ __cdf_semaphore_release(cdf_device_t osdev, struct semaphore *m)
* __cdf_spinlock_init() - initialize spin lock
* @lock: Spin lock object
*
* Return: CDF_STATUS_SUCCESS
* Return: QDF_STATUS_SUCCESS
*/
static inline CDF_STATUS __cdf_spinlock_init(__cdf_spinlock_t *lock)
static inline QDF_STATUS __cdf_spinlock_init(__cdf_spinlock_t *lock)
{
spin_lock_init(&lock->spinlock);
lock->flags = 0;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#define __cdf_spinlock_destroy(lock)

26
core/cdf/src/i_cdf_nbuf.h
Fájl megtekintése

@@ -38,7 +38,7 @@
#include <linux/etherdevice.h>
#include <linux/dma-mapping.h>
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
/*
* Use socket buffer as the underlying implentation as skbuf .
@@ -334,11 +334,11 @@ typedef void (*cdf_nbuf_trace_update_t)(char *);
__cdf_nbuf_t __cdf_nbuf_alloc(__cdf_device_t osdev, size_t size, int reserve,
int align, int prio);
void __cdf_nbuf_free(struct sk_buff *skb);
CDF_STATUS __cdf_nbuf_map(__cdf_device_t osdev,
QDF_STATUS __cdf_nbuf_map(__cdf_device_t osdev,
struct sk_buff *skb, cdf_dma_dir_t dir);
void __cdf_nbuf_unmap(__cdf_device_t osdev,
struct sk_buff *skb, cdf_dma_dir_t dir);
CDF_STATUS __cdf_nbuf_map_single(__cdf_device_t osdev,
QDF_STATUS __cdf_nbuf_map_single(__cdf_device_t osdev,
struct sk_buff *skb, cdf_dma_dir_t dir);
void __cdf_nbuf_unmap_single(__cdf_device_t osdev,
struct sk_buff *skb, cdf_dma_dir_t dir);
@@ -356,16 +356,16 @@ void __cdf_nbuf_trace_update(struct sk_buff *buf, char *event_string);
*
* Return: CDF status
*/
static inline CDF_STATUS __cdf_os_to_status(signed int error)
static inline QDF_STATUS __cdf_os_to_status(signed int error)
{
switch (error) {
case 0:
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
case ENOMEM:
case -ENOMEM:
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
default:
return CDF_STATUS_E_NOSUPPORT;
return QDF_STATUS_E_NOSUPPORT;
}
}
@@ -397,13 +397,13 @@ static inline size_t __cdf_nbuf_len(struct sk_buff *skb)
* Link tow nbufs the new buf is piggybacked into the older one. The older
* (src) skb is released.
*
* Return: CDF_STATUS (status of the call) if failed the src skb
* Return: QDF_STATUS (status of the call) if failed the src skb
* is released
*/
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_nbuf_cat(struct sk_buff *dst, struct sk_buff *src)
{
CDF_STATUS error = 0;
QDF_STATUS error = 0;
cdf_assert(dst && src);
@@ -520,7 +520,7 @@ static inline void __cdf_nbuf_trim_tail(struct sk_buff *skb, size_t size)
* prototypes. Implemented in cdf_nbuf.c
*/
cdf_nbuf_tx_cksum_t __cdf_nbuf_get_tx_cksum(struct sk_buff *skb);
CDF_STATUS __cdf_nbuf_set_rx_cksum(struct sk_buff *skb,
QDF_STATUS __cdf_nbuf_set_rx_cksum(struct sk_buff *skb,
cdf_nbuf_rx_cksum_t *cksum);
uint8_t __cdf_nbuf_get_tid(struct sk_buff *skb);
void __cdf_nbuf_set_tid(struct sk_buff *skb, uint8_t tid);
@@ -927,10 +927,10 @@ typedef struct __cdf_nbuf_qhead {
*
* Return: CDF status
*/
static inline CDF_STATUS __cdf_nbuf_queue_init(__cdf_nbuf_queue_t *qhead)
static inline QDF_STATUS __cdf_nbuf_queue_init(__cdf_nbuf_queue_t *qhead)
{
memset(qhead, 0, sizeof(struct __cdf_nbuf_qhead));
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

12
core/cdf/src/i_cdf_softirq_timer.h
Fájl megtekintése

@@ -56,7 +56,7 @@ typedef void (*cdf_dummy_timer_func_t)(unsigned long arg);
*
* Return: none
*/
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_softirq_timer_init(cdf_handle_t hdl,
struct timer_list *timer,
cdf_softirq_timer_func_t func, void *arg,
@@ -69,7 +69,7 @@ __cdf_softirq_timer_init(cdf_handle_t hdl,
timer->function = (cdf_dummy_timer_func_t) func;
timer->data = (unsigned long)arg;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -79,13 +79,13 @@ __cdf_softirq_timer_init(cdf_handle_t hdl,
*
* Return: none
*/
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_softirq_timer_start(struct timer_list *timer, uint32_t delay)
{
timer->expires = jiffies + msecs_to_jiffies(delay);
add_timer(timer);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -95,12 +95,12 @@ __cdf_softirq_timer_start(struct timer_list *timer, uint32_t delay)
*
* Return: none
*/
static inline CDF_STATUS
static inline QDF_STATUS
__cdf_softirq_timer_mod(struct timer_list *timer, uint32_t delay)
{
mod_timer(timer, jiffies + msecs_to_jiffies(delay));
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

31
core/cdf/src/i_cdf_util.h
Fájl megtekintése

@@ -36,7 +36,6 @@
#include <linux/random.h>
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <asm/byteorder.h>
/*
@@ -47,36 +46,36 @@
#define __cdf_likely(_expr) likely(_expr)
/**
* cdf_status_to_os_return(): translates cdf_status types to linux return types
* cdf_status_to_os_return(): translates qdf_status types to linux return types
* @status: status to translate
*
* Translates error types that linux may want to handle specially.
*
* return: 0 or the linux error code that most closely matches the CDF_STATUS.
* return: 0 or the linux error code that most closely matches the QDF_STATUS.
* defaults to -1 (EPERM)
*/
static inline int __cdf_status_to_os_return(CDF_STATUS status)
static inline int __cdf_status_to_os_return(QDF_STATUS status)
{
switch (status) {
case CDF_STATUS_SUCCESS:
case QDF_STATUS_SUCCESS:
return 0;
case CDF_STATUS_E_NULL_VALUE:
case CDF_STATUS_E_FAULT:
case QDF_STATUS_E_NULL_VALUE:
case QDF_STATUS_E_FAULT:
return -EFAULT;
case CDF_STATUS_E_TIMEOUT:
case CDF_STATUS_E_BUSY:
case QDF_STATUS_E_TIMEOUT:
case QDF_STATUS_E_BUSY:
return -EBUSY;
case CDF_STATUS_NOT_INITIALIZED:
case CDF_STATUS_E_AGAIN:
case QDF_STATUS_NOT_INITIALIZED:
case QDF_STATUS_E_AGAIN:
return -EAGAIN;
case CDF_STATUS_E_NOSUPPORT:
case QDF_STATUS_E_NOSUPPORT:
return -ENOSYS;
case CDF_STATUS_E_ALREADY:
case QDF_STATUS_E_ALREADY:
return -EALREADY;
case CDF_STATUS_E_NOMEM:
case QDF_STATUS_E_NOMEM:
return -ENOMEM;
case CDF_STATUS_E_FAILURE:
case CDF_STATUS_E_INVAL:
case QDF_STATUS_E_FAILURE:
case QDF_STATUS_E_INVAL:
return -EINVAL;
default:
return -EPERM;

25
core/cds/inc/cds_api.h
Fájl megtekintése

@@ -35,7 +35,6 @@
*/
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_memory.h>
#include <qdf_list.h>
@@ -186,17 +185,17 @@ static inline void cds_set_unload_in_progress(uint8_t value)
v_CONTEXT_t cds_init(void);
void cds_deinit(void);
CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context);
QDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context);
CDF_STATUS cds_open(void);
QDF_STATUS cds_open(void);
CDF_STATUS cds_enable(v_CONTEXT_t cds_context);
QDF_STATUS cds_enable(v_CONTEXT_t cds_context);
CDF_STATUS cds_disable(v_CONTEXT_t cds_context);
QDF_STATUS cds_disable(v_CONTEXT_t cds_context);
CDF_STATUS cds_close(v_CONTEXT_t cds_context);
QDF_STATUS cds_close(v_CONTEXT_t cds_context);
CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context);
QDF_STATUS cds_shutdown(v_CONTEXT_t cds_context);
void cds_core_return_msg(void *pVContext, p_cds_msg_wrapper pMsgWrapper);
@@ -204,15 +203,15 @@ void *cds_get_context(CDF_MODULE_ID moduleId);
v_CONTEXT_t cds_get_global_context(void);
CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
QDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
void **ppModuleContext, uint32_t size);
CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
QDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
void *pModuleContext);
CDF_STATUS cds_set_context(CDF_MODULE_ID moduleID, void *context);
QDF_STATUS cds_set_context(CDF_MODULE_ID moduleID, void *context);
CDF_STATUS cds_get_vdev_types(enum tCDF_ADAPTER_MODE mode, uint32_t *type,
QDF_STATUS cds_get_vdev_types(enum tCDF_ADAPTER_MODE mode, uint32_t *type,
uint32_t *subType);
void cds_flush_work(void *work);
@@ -230,7 +229,7 @@ void cds_set_ring_log_level(uint32_t ring_id, uint32_t log_level);
enum wifi_driver_log_level cds_get_ring_log_level(uint32_t ring_id);
void cds_set_multicast_logging(uint8_t value);
uint8_t cds_is_multicast_logging(void);
CDF_STATUS cds_set_log_completion(uint32_t is_fatal,
QDF_STATUS cds_set_log_completion(uint32_t is_fatal,
uint32_t type,
uint32_t sub_type);
void cds_get_log_completion(uint32_t *is_fatal,
@@ -239,7 +238,7 @@ void cds_get_log_completion(uint32_t *is_fatal,
bool cds_is_log_report_in_progress(void);
void cds_init_log_completion(void);
void cds_deinit_log_completion(void);
CDF_STATUS cds_flush_logs(uint32_t is_fatal,
QDF_STATUS cds_flush_logs(uint32_t is_fatal,
uint32_t indicator,
uint32_t reason_code);
void cds_logging_set_fw_flush_complete(void);

52
core/cds/inc/cds_concurrency.h
Fájl megtekintése

@@ -477,7 +477,7 @@ int cds_cfg80211_get_concurrency_matrix(struct wiphy *wiphy,
const void *data,
int data_len);
uint32_t cds_get_concurrency_mode(void);
CDF_STATUS cds_check_and_restart_sap(eCsrRoamResult roam_result,
QDF_STATUS cds_check_and_restart_sap(eCsrRoamResult roam_result,
hdd_station_ctx_t *hdd_sta_ctx);
void cds_handle_conc_rule1(hdd_adapter_t *adapter,
tCsrRoamProfile *roam_profile);
@@ -496,7 +496,7 @@ static inline bool cds_handle_conc_rule2(hdd_adapter_t *adapter,
uint8_t cds_search_and_check_for_session_conc(uint8_t session_id,
tCsrRoamProfile *roam_profile);
bool cds_check_for_session_conc(uint8_t session_id, uint8_t channel);
CDF_STATUS cds_handle_conc_multiport(uint8_t session_id, uint8_t channel);
QDF_STATUS cds_handle_conc_multiport(uint8_t session_id, uint8_t channel);
#ifdef FEATURE_WLAN_FORCE_SAP_SCC
void cds_force_sap_on_scc(eCsrRoamResult roam_result,
@@ -525,7 +525,7 @@ uint8_t cds_is_mcc_in_24G(void);
int32_t cds_set_mas(hdd_adapter_t *adapter, uint8_t mas_value);
int cds_set_mcc_p2p_quota(hdd_adapter_t *hostapd_adapter,
uint32_t set_value);
CDF_STATUS cds_change_mcc_go_beacon_interval(hdd_adapter_t *pHostapdAdapter);
QDF_STATUS cds_change_mcc_go_beacon_interval(hdd_adapter_t *pHostapdAdapter);
int cds_go_set_mcc_p2p_quota(hdd_adapter_t *hostapd_adapter,
uint32_t set_value);
void cds_set_mcc_latency(hdd_adapter_t *adapter, int set_value);
@@ -555,32 +555,32 @@ void cds_decr_active_session(enum tCDF_ADAPTER_MODE mode,
uint8_t sessionId);
void cds_decr_session_set_pcl(enum tCDF_ADAPTER_MODE mode,
uint8_t session_id);
CDF_STATUS cds_init_policy_mgr(void);
CDF_STATUS cds_deinit_policy_mgr(void);
CDF_STATUS cds_get_pcl(enum cds_con_mode mode,
QDF_STATUS cds_init_policy_mgr(void);
QDF_STATUS cds_deinit_policy_mgr(void);
QDF_STATUS cds_get_pcl(enum cds_con_mode mode,
uint8_t *pcl_Channels, uint32_t *len);
bool cds_allow_concurrency(enum cds_con_mode mode,
uint8_t channel, enum hw_mode_bandwidth bw);
enum cds_conc_priority_mode cds_get_first_connection_pcl_table_index(void);
enum cds_one_connection_mode cds_get_second_connection_pcl_table_index(void);
enum cds_two_connection_mode cds_get_third_connection_pcl_table_index(void);
CDF_STATUS cds_incr_connection_count(uint32_t vdev_id);
CDF_STATUS cds_update_connection_info(uint32_t vdev_id);
CDF_STATUS cds_decr_connection_count(uint32_t vdev_id);
CDF_STATUS cds_current_connections_update(uint32_t session_id,
QDF_STATUS cds_incr_connection_count(uint32_t vdev_id);
QDF_STATUS cds_update_connection_info(uint32_t vdev_id);
QDF_STATUS cds_decr_connection_count(uint32_t vdev_id);
QDF_STATUS cds_current_connections_update(uint32_t session_id,
uint8_t channel,
enum cds_conn_update_reason);
bool cds_is_ibss_conn_exist(uint8_t *ibss_channel);
#ifdef MPC_UT_FRAMEWORK
CDF_STATUS cds_incr_connection_count_utfw(
QDF_STATUS cds_incr_connection_count_utfw(
uint32_t vdev_id, uint32_t tx_streams, uint32_t rx_streams,
uint32_t chain_mask, uint32_t type, uint32_t sub_type,
uint32_t channelid, uint32_t mac_id);
CDF_STATUS cds_update_connection_info_utfw(
QDF_STATUS cds_update_connection_info_utfw(
uint32_t vdev_id, uint32_t tx_streams, uint32_t rx_streams,
uint32_t chain_mask, uint32_t type, uint32_t sub_type,
uint32_t channelid, uint32_t mac_id);
CDF_STATUS cds_decr_connection_count_utfw(
QDF_STATUS cds_decr_connection_count_utfw(
uint32_t del_all, uint32_t vdev_id);
struct cds_conc_connection_info *cds_get_conn_info(uint32_t *len);
enum cds_pcl_type get_pcl_from_first_conn_table(enum cds_con_mode type,
@@ -592,24 +592,24 @@ enum cds_pcl_type get_pcl_from_third_conn_table(
enum cds_two_connection_mode idx, enum cds_con_mode type,
enum cds_conc_priority_mode sys_pref, uint8_t dbs_capable);
#else
static inline CDF_STATUS cds_incr_connection_count_utfw(uint32_t vdev_id,
static inline QDF_STATUS cds_incr_connection_count_utfw(uint32_t vdev_id,
uint32_t tx_streams, uint32_t rx_streams,
uint32_t chain_mask, uint32_t type, uint32_t sub_type,
uint32_t channelid, uint32_t mac_id)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS cds_update_connection_info_utfw(uint32_t vdev_id,
static inline QDF_STATUS cds_update_connection_info_utfw(uint32_t vdev_id,
uint32_t tx_streams, uint32_t rx_streams,
uint32_t chain_mask, uint32_t type, uint32_t sub_type,
uint32_t channelid, uint32_t mac_id)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS cds_decr_connection_count_utfw(uint32_t del_all,
static inline QDF_STATUS cds_decr_connection_count_utfw(uint32_t del_all,
uint32_t vdev_id)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline struct cds_conc_connection_info *cds_get_conn_info(uint32_t *len)
{
@@ -618,7 +618,7 @@ static inline struct cds_conc_connection_info *cds_get_conn_info(uint32_t *len)
#endif
enum cds_con_mode cds_convert_device_mode_to_hdd_type(
device_mode_t device_mode);
CDF_STATUS cds_soc_set_hw_mode(uint32_t session_id,
QDF_STATUS cds_soc_set_hw_mode(uint32_t session_id,
enum hw_mode_ss_config mac0_ss,
enum hw_mode_bandwidth mac0_bw,
enum hw_mode_ss_config mac1_ss,
@@ -627,7 +627,7 @@ CDF_STATUS cds_soc_set_hw_mode(uint32_t session_id,
enum hw_mode_agile_dfs_capab dfs,
enum cds_conn_update_reason reason);
enum cds_conc_next_action cds_need_opportunistic_upgrade(void);
CDF_STATUS cds_next_actions(uint32_t session_id,
QDF_STATUS cds_next_actions(uint32_t session_id,
enum cds_conc_next_action action,
enum cds_conn_update_reason reason);
void cds_set_dual_mac_scan_config(uint8_t dbs_val,
@@ -640,7 +640,7 @@ void cds_soc_set_dual_mac_cfg_cb(enum set_hw_mode_status status,
uint32_t fw_mode_config);
bool cds_map_concurrency_mode(enum tCDF_ADAPTER_MODE *old_mode,
enum cds_con_mode *new_mode);
CDF_STATUS cds_get_channel_from_scan_result(hdd_adapter_t *adapter,
QDF_STATUS cds_get_channel_from_scan_result(hdd_adapter_t *adapter,
tCsrRoamProfile *roam_profile, uint8_t *channel);
enum tCDF_GLOBAL_CON_MODE cds_get_conparam(void);
@@ -650,8 +650,8 @@ void cds_clear_concurrent_session_count(void);
bool cds_is_multiple_active_sta_sessions(void);
bool cds_is_sta_active_connection_exists(void);
bool cds_concurrent_beaconing_sessions_running(void);
CDF_STATUS cdf_wait_for_connection_update(void);
CDF_STATUS cdf_reset_connection_update(void);
CDF_STATUS cdf_set_connection_update(void);
CDF_STATUS cdf_init_connection_update(void);
QDF_STATUS cdf_wait_for_connection_update(void);
QDF_STATUS cdf_reset_connection_update(void);
QDF_STATUS cdf_set_connection_update(void);
QDF_STATUS cdf_init_connection_update(void);
#endif /* __CDS_CONCURRENCY_H */

1
core/cds/inc/cds_crypto.h
Fájl megtekintése

@@ -35,7 +35,6 @@
*/
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <cdf_memory.h>
#include <qdf_list.h>

17
core/cds/inc/cds_mq.h
Fájl megtekintése

@@ -42,7 +42,6 @@
Include Files
------------------------------------------------------------------------*/
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
/*--------------------------------------------------------------------------
@@ -129,21 +128,21 @@ typedef enum {
message needs anything in this message, it needs to copy the contents
before returning from the message queue handler.
\return CDF_STATUS_SUCCESS - the message has been successfully posted
\return QDF_STATUS_SUCCESS - the message has been successfully posted
to the message queue.
CDF_STATUS_E_INVAL - The value specified by msgQueueId does not
QDF_STATUS_E_INVAL - The value specified by msgQueueId does not
refer to a valid Message Queue Id.
CDF_STATUS_E_FAULT - message is an invalid pointer.
QDF_STATUS_E_FAULT - message is an invalid pointer.
CDF_STATUS_E_FAILURE - the message queue handler has reported
QDF_STATUS_E_FAILURE - the message queue handler has reported
an unknown failure.
\sa
--------------------------------------------------------------------------*/
CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *message);
QDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *message);
/**---------------------------------------------------------------------------
@@ -152,15 +151,15 @@ CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *message);
\param pBuf is a buffer allocated by caller. The actual structure varies
base on message type
\return CDF_STATUS_SUCCESS - the message has been successfully posted
\return QDF_STATUS_SUCCESS - the message has been successfully posted
to the message queue.
CDF_STATUS_E_FAILURE - the message queue handler has reported
QDF_STATUS_E_FAILURE - the message queue handler has reported
an unknown failure.
\sa
--------------------------------------------------------------------------*/
CDF_STATUS cds_send_mb_message_to_mac(void *pBuf);
QDF_STATUS cds_send_mb_message_to_mac(void *pBuf);
#endif /* if !defined __CDS_MQ_H */

11
core/cds/inc/cds_packet.h
Fájl megtekintése

@@ -42,7 +42,6 @@
Include Files
------------------------------------------------------------------------*/
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
/*--------------------------------------------------------------------------
@@ -119,13 +118,13 @@ static inline void cds_pkt_proto_trace_close(void) {}
* cds_pkt_return_packet Free the cds Packet
* @ cds Packet
*/
CDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet);
QDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet);
/**
* cds_pkt_get_packet_length Returns the packet length
* @ cds Packet
*/
CDF_STATUS cds_pkt_get_packet_length(cds_pkt_t *pPacket,
QDF_STATUS cds_pkt_get_packet_length(cds_pkt_t *pPacket,
uint16_t *pPacketSize);
/*
@@ -175,15 +174,15 @@ typedef enum {
#define cds_packet_alloc(s, d, p) \
cds_packet_alloc_debug(s, d, p, __FILE__, __LINE__)
CDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
QDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
uint8_t *file_name, uint32_t line_num);
#else
CDF_STATUS cds_packet_alloc(uint16_t size, void **data, void **ppPacket);
QDF_STATUS cds_packet_alloc(uint16_t size, void **data, void **ppPacket);
#endif
void cds_packet_free(void *pPacket);
typedef CDF_STATUS (*cds_pkt_get_packet_callback)(cds_pkt_t *pPacket,
typedef QDF_STATUS (*cds_pkt_get_packet_callback)(cds_pkt_t *pPacket,
void *userData);
#endif /* !defined( __CDS_PKT_H ) */

16
core/cds/inc/cds_reg_service.h
Fájl megtekintése

@@ -36,7 +36,7 @@
========================================================================*/
#include "cdf_status.h"
#include "qdf_status.h"
#define CDS_COUNTRY_CODE_LEN 2
#define CDS_MAC_ADDRESS_LEN 6
@@ -318,26 +318,26 @@ enum channel_width {
extern struct regulatory_channel reg_channels[NUM_RF_CHANNELS];
extern const struct chan_map chan_mapping[NUM_RF_CHANNELS];
CDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *pRegDomain,
QDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *pRegDomain,
const uint8_t *country_alpha2,
enum country_src source);
CDF_STATUS cds_read_default_country(uint8_t *default_country);
QDF_STATUS cds_read_default_country(uint8_t *default_country);
CDF_STATUS cds_get_channel_list_with_power(struct channel_power
QDF_STATUS cds_get_channel_list_with_power(struct channel_power
*base_channels,
uint8_t *num_base_channels,
struct channel_power
*channel_40mhz,
uint8_t *num_channels_40mhz);
CDF_STATUS cds_set_reg_domain(void *client_ctxt, v_REGDOMAIN_t reg_domain);
QDF_STATUS cds_set_reg_domain(void *client_ctxt, v_REGDOMAIN_t reg_domain);
enum channel_state cds_get_channel_state(uint32_t chan_num);
CDF_STATUS cds_regulatory_init(void);
CDF_STATUS cds_get_dfs_region(uint8_t *dfs_region);
CDF_STATUS cds_set_dfs_region(uint8_t dfs_region);
QDF_STATUS cds_regulatory_init(void);
QDF_STATUS cds_get_dfs_region(uint8_t *dfs_region);
QDF_STATUS cds_set_dfs_region(uint8_t dfs_region);
bool cds_is_dsrc_channel(uint16_t);
enum channel_state cds_get_bonded_channel_state(uint32_t chan_num,
enum channel_width chan_width);

24
core/cds/inc/cds_sched.h
Fájl megtekintése

@@ -374,24 +374,24 @@ void cds_free_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext);
\param p_cds_sched_context - pointer to a previously allocated buffer big
enough to hold a scheduler context.
\return CDF_STATUS_SUCCESS - Scheduler was successfully initialized and
\return QDF_STATUS_SUCCESS - Scheduler was successfully initialized and
is ready to be used.
CDF_STATUS_E_RESOURCES - System resources (other than memory)
QDF_STATUS_E_RESOURCES - System resources (other than memory)
are unavailable to initilize the scheduler
CDF_STATUS_E_NOMEM - insufficient memory exists to initialize
QDF_STATUS_E_NOMEM - insufficient memory exists to initialize
the scheduler
CDF_STATUS_E_INVAL - Invalid parameter passed to the scheduler Open
QDF_STATUS_E_INVAL - Invalid parameter passed to the scheduler Open
function
CDF_STATUS_E_FAILURE - Failure to initialize the scheduler/
QDF_STATUS_E_FAILURE - Failure to initialize the scheduler/
\sa cds_sched_open()
-------------------------------------------------------------------------*/
CDF_STATUS cds_sched_open(void *p_cds_context,
QDF_STATUS cds_sched_open(void *p_cds_context,
p_cds_sched_context pSchedCxt, uint32_t SchedCtxSize);
/*---------------------------------------------------------------------------
@@ -409,27 +409,27 @@ CDF_STATUS cds_sched_open(void *p_cds_context,
\param p_cds_context - pointer to the global CDF Context
\return CDF_STATUS_SUCCESS - Scheduler was successfully initialized and
\return QDF_STATUS_SUCCESS - Scheduler was successfully initialized and
is ready to be used.
CDF_STATUS_E_INVAL - Invalid parameter passed to the scheduler Open
QDF_STATUS_E_INVAL - Invalid parameter passed to the scheduler Open
function
CDF_STATUS_E_FAILURE - Failure to initialize the scheduler/
QDF_STATUS_E_FAILURE - Failure to initialize the scheduler/
\sa cds_sched_close()
---------------------------------------------------------------------------*/
CDF_STATUS cds_sched_close(void *p_cds_context);
QDF_STATUS cds_sched_close(void *p_cds_context);
/* Helper routines provided to other CDS API's */
CDF_STATUS cds_mq_init(p_cds_mq_type pMq);
QDF_STATUS cds_mq_init(p_cds_mq_type pMq);
void cds_mq_deinit(p_cds_mq_type pMq);
void cds_mq_put(p_cds_mq_type pMq, p_cds_msg_wrapper pMsgWrapper);
p_cds_msg_wrapper cds_mq_get(p_cds_mq_type pMq);
bool cds_is_mq_empty(p_cds_mq_type pMq);
p_cds_sched_context get_cds_sched_ctxt(void);
CDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext);
QDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext);
void cds_sched_deinit_mqs(p_cds_sched_context pSchedContext);
void cds_sched_flush_mc_mqs(p_cds_sched_context pSchedContext);

23
core/cds/inc/cds_utils.h
Fájl megtekintése

@@ -42,7 +42,6 @@
Include Files
------------------------------------------------------------------------*/
#include <cdf_types.h>
#include <cdf_status.h>
#include <qdf_status.h>
#include <qdf_event.h>
#include "ani_global.h"
@@ -90,9 +89,9 @@
Function declarations and documenation
------------------------------------------------------------------------*/
CDF_STATUS cds_crypto_init(uint32_t *phCryptProv);
QDF_STATUS cds_crypto_init(uint32_t *phCryptProv);
CDF_STATUS cds_crypto_deinit(uint32_t hCryptProv);
QDF_STATUS cds_crypto_deinit(uint32_t hCryptProv);
/**
* cds_rand_get_bytes
@@ -105,9 +104,9 @@ CDF_STATUS cds_crypto_deinit(uint32_t hCryptProv);
* @param numBytes the number of bytes that should be generated and
* copied
*
* @return CDF_STATUS_SUCCSS if the operation succeeds
* @return QDF_STATUS_SUCCSS if the operation succeeds
*/
CDF_STATUS cds_rand_get_bytes(uint32_t handle, uint8_t *pbBuf,
QDF_STATUS cds_rand_get_bytes(uint32_t handle, uint8_t *pbBuf,
uint32_t numBytes);
/**
@@ -129,10 +128,10 @@ CDF_STATUS cds_rand_get_bytes(uint32_t handle, uint8_t *pbBuf,
* @param keyLen length of key
* @param digest holds resultant SHA1 HMAC (20B)
*
* @return CDF_STATUS_SUCCSS if the operation succeeds
* @return QDF_STATUS_SUCCSS if the operation succeeds
*
*/
CDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
uint8_t *text, /* pointer to data stream */
uint32_t textLen, /* length of data stream */
uint8_t *key, /* pointer to authentication key */
@@ -158,21 +157,21 @@ CDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
* @param keyLen length of key
* @param digest holds resultant MD5 HMAC (16B)
*
* @return CDF_STATUS_SUCCSS if the operation succeeds
* @return QDF_STATUS_SUCCSS if the operation succeeds
*
*/
CDF_STATUS cds_md5_hmac_str(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_md5_hmac_str(uint32_t cryptHandle, /* Handle */
uint8_t *text, /* pointer to data stream */
uint32_t textLen, /* length of data stream */
uint8_t *key, /* pointer to authentication key */
uint32_t keyLen, /* length of authentication key */
uint8_t digest[CDS_DIGEST_MD5_SIZE]); /* caller digest to be filled in */
CDF_STATUS cds_encrypt_aes(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_encrypt_aes(uint32_t cryptHandle, /* Handle */
uint8_t *pText, /* pointer to data stream */
uint8_t *Encrypted, uint8_t *pKey); /* pointer to authentication key */
CDF_STATUS cds_decrypt_aes(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_decrypt_aes(uint32_t cryptHandle, /* Handle */
uint8_t *pText, /* pointer to data stream */
uint8_t *pDecrypted, uint8_t *pKey); /* pointer to authentication key */
@@ -186,5 +185,5 @@ bool cds_attach_mmie(uint8_t *igtk, uint8_t *ipn, uint16_t key_id,
uint8_t *frm, uint8_t *efrm, uint16_t frmLen);
uint8_t cds_get_mmie_size(void);
#endif /* WLAN_FEATURE_11W */
CDF_STATUS sme_send_flush_logs_cmd_to_fw(tpAniSirGlobal pMac);
QDF_STATUS sme_send_flush_logs_cmd_to_fw(tpAniSirGlobal pMac);
#endif /* #if !defined __CDS_UTILS_H */

262
core/cds/src/cds_api.c
Fájl megtekintése

@@ -164,9 +164,9 @@ static void cds_set_nan_enable(tMacOpenParameters *param,
*
* Return: CDF status
*/
CDF_STATUS cds_open(void)
QDF_STATUS cds_open(void)
{
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
int iter = 0;
tSirRetStatus sirStatus = eSIR_SUCCESS;
tMacOpenParameters mac_openParms;
@@ -184,7 +184,7 @@ CDF_STATUS cds_open(void)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Trying to open CDS without a PreOpen", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Initialize the timer module */
@@ -198,7 +198,7 @@ CDF_STATUS cds_open(void)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Unable to init probeEvent", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (qdf_event_create(&(gp_cds_context->wmaCompleteEvent)) !=
QDF_STATUS_SUCCESS) {
@@ -209,8 +209,8 @@ CDF_STATUS cds_open(void)
}
/* Initialize the free message queue */
cdf_status = cds_mq_init(&gp_cds_context->freeVosMq);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cds_mq_init(&gp_cds_context->freeVosMq);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Failed to initialize CDS free message queue",
@@ -228,10 +228,10 @@ CDF_STATUS cds_open(void)
}
/* Now Open the CDS Scheduler */
cdf_status = cds_sched_open(gp_cds_context, &gp_cds_context->cdf_sched,
qdf_status = cds_sched_open(gp_cds_context, &gp_cds_context->cdf_sched,
sizeof(cds_sched_context));
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Failed to open CDS Scheduler", __func__);
@@ -259,10 +259,10 @@ CDF_STATUS cds_open(void)
ol_ctx = cds_get_context(CDF_MODULE_ID_BMI);
/* Initialize BMI and Download firmware */
cdf_status = bmi_download_firmware(ol_ctx);
if (cdf_status != CDF_STATUS_SUCCESS) {
qdf_status = bmi_download_firmware(ol_ctx);
if (qdf_status != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"BMI FIALED status:%d", cdf_status);
"BMI FIALED status:%d", qdf_status);
goto err_bmi_close;
}
@@ -367,11 +367,11 @@ CDF_STATUS cds_open(void)
mac_openParms.self_gen_frm_pwr = pHddCtx->config->self_gen_frm_pwr;
mac_openParms.maxStation = pHddCtx->config->maxNumberOfPeers;
cdf_status = wma_open(gp_cds_context,
qdf_status = wma_open(gp_cds_context,
hdd_update_tgt_cfg,
hdd_dfs_indicate_radar, &mac_openParms);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Failed to open WMA module", __func__);
@@ -417,8 +417,8 @@ CDF_STATUS cds_open(void)
}
/* Now proceed to open the SME */
cdf_status = sme_open(gp_cds_context->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sme_open(gp_cds_context->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Failed to open SME", __func__);
@@ -441,7 +441,7 @@ CDF_STATUS cds_open(void)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: CDS successfully Opened", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
err_sme_close:
sme_close(gp_cds_context->pMACContext);
@@ -475,7 +475,7 @@ err_wma_complete_event:
err_probe_event:
qdf_event_destroy(&gp_cds_context->ProbeEvent);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
} /* cds_open() */
/**
@@ -484,9 +484,9 @@ err_probe_event:
*
* Return: CDF status
*/
CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
QDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
p_cds_contextType p_cds_context = (p_cds_contextType) cds_context;
void *scn;
@@ -496,40 +496,40 @@ CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Context mismatch", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (p_cds_context->pMACContext == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: MAC NULL context", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (p_cds_context->pWMAContext == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: WMA NULL context", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
scn = cds_get_context(CDF_MODULE_ID_HIF);
if (!scn) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: scn is null!", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Reset wma wait event */
qdf_event_reset(&gp_cds_context->wmaCompleteEvent);
/*call WMA pre start */
cdf_status = wma_pre_start(gp_cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_pre_start(gp_cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_SYS, CDF_TRACE_LEVEL_FATAL,
"Failed to WMA prestart");
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Need to update time out of complete */
@@ -551,24 +551,24 @@ CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
wlan_sys_probe();
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_status = htc_start(gp_cds_context->htc_ctx);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = htc_start(gp_cds_context->htc_ctx);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_SYS, CDF_TRACE_LEVEL_FATAL,
"Failed to Start HTC");
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_status = wma_wait_for_ready_event(gp_cds_context->pWMAContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wait_for_ready_event(gp_cds_context->pWMAContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"Failed to get ready event from target firmware");
htc_set_target_to_sleep(scn);
htc_stop(gp_cds_context->htc_ctx);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (ol_txrx_pdev_attach(gp_cds_context->pdev_txrx_ctx)) {
@@ -577,12 +577,12 @@ CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
htc_set_target_to_sleep(scn);
htc_stop(gp_cds_context->htc_ctx);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
htc_set_target_to_sleep(scn);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -591,9 +591,9 @@ CDF_STATUS cds_pre_enable(v_CONTEXT_t cds_context)
*
* Return: CDF status
*/
CDF_STATUS cds_enable(v_CONTEXT_t cds_context)
QDF_STATUS cds_enable(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
tSirRetStatus sirStatus = eSIR_SUCCESS;
p_cds_contextType p_cds_context = (p_cds_contextType) cds_context;
@@ -606,7 +606,7 @@ CDF_STATUS cds_enable(v_CONTEXT_t cds_context)
if (gp_cds_context != p_cds_context) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: mismatch in context", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if ((p_cds_context->pWMAContext == NULL) ||
@@ -618,15 +618,15 @@ CDF_STATUS cds_enable(v_CONTEXT_t cds_context)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: MAC NULL context", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Start the wma */
cdf_status = wma_start(p_cds_context);
if (cdf_status != CDF_STATUS_SUCCESS) {
qdf_status = wma_start(p_cds_context);
if (qdf_status != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to start wma", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO,
"%s: wma correctly started", __func__);
@@ -649,9 +649,9 @@ CDF_STATUS cds_enable(v_CONTEXT_t cds_context)
"%s: MAC correctly started", __func__);
/* START SME */
cdf_status = sme_start(p_cds_context->pMACContext);
qdf_status = sme_start(p_cds_context->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"%s: Failed to start SME", __func__);
goto err_mac_stop;
@@ -672,7 +672,7 @@ CDF_STATUS cds_enable(v_CONTEXT_t cds_context)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO,
"%s: CDS Start is successful!!", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
err_sme_stop:
sme_stop(p_cds_context->pMACContext, HAL_STOP_TYPE_SYS_RESET);
@@ -682,11 +682,11 @@ err_mac_stop:
err_wma_stop:
qdf_event_reset(&(gp_cds_context->wmaCompleteEvent));
cdf_status = wma_stop(p_cds_context, HAL_STOP_TYPE_RF_KILL);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_stop(p_cds_context, HAL_STOP_TYPE_RF_KILL);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop wma", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
wma_setneedshutdown(cds_context);
} else {
qdf_status =
@@ -709,7 +709,7 @@ err_wma_stop:
}
}
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
} /* cds_enable() */
/**
@@ -718,9 +718,9 @@ err_wma_stop:
*
* Return: CDF status
*/
CDF_STATUS cds_disable(v_CONTEXT_t cds_context)
QDF_STATUS cds_disable(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
/* wma_stop is called before the SYS so that the processing of target
* pending responses will not be handled during uninitialization of
@@ -728,12 +728,12 @@ CDF_STATUS cds_disable(v_CONTEXT_t cds_context)
*/
qdf_event_reset(&(gp_cds_context->wmaCompleteEvent));
cdf_status = wma_stop(cds_context, HAL_STOP_TYPE_RF_KILL);
qdf_status = wma_stop(cds_context, HAL_STOP_TYPE_RF_KILL);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop wma", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
wma_setneedshutdown(cds_context);
}
@@ -741,14 +741,14 @@ CDF_STATUS cds_disable(v_CONTEXT_t cds_context)
hif_reset_soc(((cds_context_type *) cds_context)->pHIFContext);
/* SYS STOP will stop SME and MAC */
cdf_status = sys_stop(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sys_stop(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop SYS", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -757,13 +757,13 @@ CDF_STATUS cds_disable(v_CONTEXT_t cds_context)
*
* Return: CDF status
*/
CDF_STATUS cds_close(v_CONTEXT_t cds_context)
QDF_STATUS cds_close(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
QDF_STATUS qdf_status;
cdf_status = wma_wmi_work_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wmi_work_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma_wmi_work", __func__);
CDF_ASSERT(0);
@@ -779,18 +779,18 @@ CDF_STATUS cds_close(v_CONTEXT_t cds_context)
cds_free_context(cds_context, CDF_MODULE_ID_TXRX,
gp_cds_context->pdev_txrx_ctx);
cdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close SME", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
cdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close MAC", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
((p_cds_contextType) cds_context)->pMACContext = NULL;
@@ -799,19 +799,19 @@ CDF_STATUS cds_close(v_CONTEXT_t cds_context)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to shutdown wma", __func__);
} else {
cdf_status = wma_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
}
cdf_status = wma_wmi_service_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wmi_service_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma_wmi_service", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
cds_mq_deinit(&((p_cds_contextType) cds_context)->freeVosMq);
@@ -834,7 +834,7 @@ CDF_STATUS cds_close(v_CONTEXT_t cds_context)
gp_cds_context->pHDDContext = NULL;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1033,7 +1033,7 @@ void cds_clear_driver_state(enum cds_driver_state state)
* @moduleId: module ID who's context area is being allocated.
* @ppModuleContext: pointer to location where the pointer to the
* allocated context is returned. Note this output pointer
* is valid only if the API returns CDF_STATUS_SUCCESS
* is valid only if the API returns QDF_STATUS_SUCCESS
* @param size: size of the context area to be allocated.
*
* This API allows any user to allocate a user context area within the
@@ -1041,7 +1041,7 @@ void cds_clear_driver_state(enum cds_driver_state state)
*
* Return: CDF status
*/
CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
QDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
void **ppModuleContext, uint32_t size)
{
void **pGpModContext = NULL;
@@ -1049,14 +1049,14 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
if (p_cds_context == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: cds context is null", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if ((gp_cds_context != p_cds_context) || (ppModuleContext == NULL)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: context mismatch or null param passed",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
switch (moduleID) {
@@ -1090,7 +1090,7 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
"does not have its context allocated by CDS",
__func__, moduleID);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
}
@@ -1101,7 +1101,7 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Module ID %i context has already been allocated",
__func__, moduleID);
return CDF_STATUS_E_EXISTS;
return QDF_STATUS_E_EXISTS;
}
/* Dynamically allocate the context for module */
@@ -1113,7 +1113,7 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
"%s: Failed to " "allocate Context for module ID %i",
__func__, moduleID);
CDF_ASSERT(0);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
if (moduleID == CDF_MODULE_ID_TLSHIM)
@@ -1121,7 +1121,7 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
*pGpModContext = *ppModuleContext;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_alloc_context() */
/**
@@ -1131,16 +1131,16 @@ CDF_STATUS cds_alloc_context(void *p_cds_context, CDF_MODULE_ID moduleID,
*
* API to set a MODULE Context in gloabl CDS Context
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS cds_set_context(CDF_MODULE_ID module_id, void *context)
QDF_STATUS cds_set_context(CDF_MODULE_ID module_id, void *context)
{
p_cds_contextType p_cds_context = cds_get_global_context();
if (!p_cds_context) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"cds context is Invald");
return CDF_STATUS_NOT_INITIALIZED;
return QDF_STATUS_NOT_INITIALIZED;
}
switch (module_id) {
@@ -1152,10 +1152,10 @@ CDF_STATUS cds_set_context(CDF_MODULE_ID module_id, void *context)
"%s: Module ID %i does not have its context "
"allocated by CDS", __func__, module_id);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1170,7 +1170,7 @@ CDF_STATUS cds_set_context(CDF_MODULE_ID module_id, void *context)
*
* Return: CDF status
*/
CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
QDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
void *pModuleContext)
{
void **pGpModContext = NULL;
@@ -1179,7 +1179,7 @@ CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
(pModuleContext == NULL)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null params or context mismatch", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
switch (moduleID) {
@@ -1219,7 +1219,7 @@ CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
"does not have its context allocated by CDS",
__func__, moduleID);
CDF_ASSERT(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
}
@@ -1229,13 +1229,13 @@ CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
"%s: Module ID %i "
"context has not been allocated or freed already",
__func__, moduleID);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (*pGpModContext != pModuleContext) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: pGpModContext != pModuleContext", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (pModuleContext != NULL)
@@ -1243,7 +1243,7 @@ CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
*pGpModContext = NULL;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_free_context() */
/**
@@ -1258,7 +1258,7 @@ CDF_STATUS cds_free_context(void *p_cds_context, CDF_MODULE_ID moduleID,
*
* Return: CDF status
*/
CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
QDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
{
p_cds_mq_type pTargetMq = NULL;
p_cds_msg_wrapper pMsgWrapper = NULL;
@@ -1269,7 +1269,7 @@ CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
"%s: Null params or global cds context is null",
__func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
switch (msgQueueId) {
@@ -1306,14 +1306,14 @@ CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
("%s: Trying to queue msg into unknown MC Msg queue ID %d"),
__func__, msgQueueId);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
CDF_ASSERT(NULL != pTargetMq);
if (pTargetMq == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: pTargetMq == NULL", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Try and get a free Msg wrapper */
@@ -1329,7 +1329,7 @@ CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
if (CDS_WRAPPER_MAX_FAIL_COUNT == debug_count)
CDF_BUG(0);
return CDF_STATUS_E_RESOURCES;
return QDF_STATUS_E_RESOURCES;
}
atomic_set(&cds_wrapper_empty_count, 0);
@@ -1343,7 +1343,7 @@ CDF_STATUS cds_mq_post_message(CDS_MQ_ID msgQueueId, cds_msg_t *pMsg)
set_bit(MC_POST_EVENT_MASK, &gp_cds_context->cdf_sched.mcEventFlag);
wake_up_interruptible(&gp_cds_context->cdf_sched.mcWaitQueue);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_mq_post_message() */
/**
@@ -1430,9 +1430,9 @@ void cds_core_return_msg(void *pVContext, p_cds_msg_wrapper pMsgWrapper)
*
* Return: CDF status
*/
CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
QDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
QDF_STATUS qdf_status;
tpAniSirGlobal pmac = (((p_cds_contextType)cds_context)->pMACContext);
@@ -1440,11 +1440,11 @@ CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
cds_free_context(cds_context, CDF_MODULE_ID_TXRX,
gp_cds_context->pdev_txrx_ctx);
cdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close SME", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
/*
* CAC timer will be initiated and started only when SAP starts on
@@ -1458,27 +1458,27 @@ CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
cdf_mc_timer_destroy(&pmac->sap.SapDfsInfo.sap_dfs_cac_timer);
}
cdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close MAC", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
((p_cds_contextType) cds_context)->pMACContext = NULL;
if (false == wma_needshutdown(cds_context)) {
cdf_status = wma_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma!", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
}
cdf_status = wma_wmi_work_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wmi_work_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma_wmi_work!", __func__);
CDF_ASSERT(0);
@@ -1490,11 +1490,11 @@ CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
gp_cds_context->htc_ctx = NULL;
}
cdf_status = wma_wmi_service_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wmi_service_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma_wmi_service!", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
cds_mq_deinit(&((p_cds_contextType) cds_context)->freeVosMq);
@@ -1513,7 +1513,7 @@ CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1524,10 +1524,10 @@ CDF_STATUS cds_shutdown(v_CONTEXT_t cds_context)
*
* Return: WMI vdev type
*/
CDF_STATUS cds_get_vdev_types(enum tCDF_ADAPTER_MODE mode, uint32_t *type,
QDF_STATUS cds_get_vdev_types(enum tCDF_ADAPTER_MODE mode, uint32_t *type,
uint32_t *sub_type)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
*type = 0;
*sub_type = 0;
@@ -1556,7 +1556,7 @@ CDF_STATUS cds_get_vdev_types(enum tCDF_ADAPTER_MODE mode, uint32_t *type,
default:
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"Invalid device mode %d", mode);
status = CDF_STATUS_E_INVAL;
status = QDF_STATUS_E_INVAL;
break;
}
return status;
@@ -1891,7 +1891,7 @@ void cds_deinit_log_completion(void)
*
* Return: 0 if setting of params is successful
*/
CDF_STATUS cds_set_log_completion(uint32_t is_fatal,
QDF_STATUS cds_set_log_completion(uint32_t is_fatal,
uint32_t indicator,
uint32_t reason_code)
{
@@ -1901,7 +1901,7 @@ CDF_STATUS cds_set_log_completion(uint32_t is_fatal,
if (!p_cds_context) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: cds context is Invalid", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_spinlock_acquire(&p_cds_context->bug_report_lock);
@@ -1910,7 +1910,7 @@ CDF_STATUS cds_set_log_completion(uint32_t is_fatal,
p_cds_context->log_complete.reason_code = reason_code;
p_cds_context->log_complete.is_report_in_progress = true;
cdf_spinlock_release(&p_cds_context->bug_report_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1976,12 +1976,12 @@ bool cds_is_log_report_in_progress(void)
*
* Return: 0 on success
*/
CDF_STATUS cds_flush_logs(uint32_t is_fatal,
QDF_STATUS cds_flush_logs(uint32_t is_fatal,
uint32_t indicator,
uint32_t reason_code)
{
uint32_t ret;
CDF_STATUS status;
QDF_STATUS status;
p_cds_contextType p_cds_context;
@@ -1989,21 +1989,21 @@ CDF_STATUS cds_flush_logs(uint32_t is_fatal,
if (!p_cds_context) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: cds context is Invalid", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (cds_is_log_report_in_progress() == true) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Bug report already in progress - dropping! type:%d, indicator=%d reason_code=%d",
__func__, is_fatal, indicator, reason_code);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
status = cds_set_log_completion(is_fatal, indicator, reason_code);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to set log trigger params", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO,
@@ -2015,10 +2015,10 @@ CDF_STATUS cds_flush_logs(uint32_t is_fatal,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to send flush FW log", __func__);
cds_init_log_completion();
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

352
core/cds/src/cds_concurrency.c
Fájl megtekintése

A különbségek nem kerülnek megjelenítésre, mivel a fájl túl nagy Load Diff

16
core/cds/src/cds_mq.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -55,13 +55,13 @@ tSirRetStatus u_mac_post_ctrl_msg(void *pSirGlobal, void *pMb);
*
* Return: cdf status
*/
inline CDF_STATUS cds_mq_init(p_cds_mq_type pMq)
inline QDF_STATUS cds_mq_init(p_cds_mq_type pMq)
{
if (pMq == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Now initialize the lock */
@@ -70,7 +70,7 @@ inline CDF_STATUS cds_mq_init(p_cds_mq_type pMq)
/* Now initialize the List data structure */
INIT_LIST_HEAD(&pMq->mqList);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_mq_init() */
/**
@@ -170,7 +170,7 @@ inline bool cds_is_mq_empty(p_cds_mq_type pMq)
if (pMq == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: NULL pointer passed", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
spin_lock_irqsave(&pMq->mqLock, flags);
@@ -186,9 +186,9 @@ inline bool cds_is_mq_empty(p_cds_mq_type pMq)
*
* Return: cdf status
*/
CDF_STATUS cds_send_mb_message_to_mac(void *pBuf)
QDF_STATUS cds_send_mb_message_to_mac(void *pBuf)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
tSirRetStatus sirStatus;
v_CONTEXT_t cds_context;
void *hHal;
@@ -205,7 +205,7 @@ CDF_STATUS cds_send_mb_message_to_mac(void *pBuf)
} else {
sirStatus = u_mac_post_ctrl_msg(hHal, pBuf);
if (eSIR_SUCCESS == sirStatus)
cdf_ret_status = CDF_STATUS_SUCCESS;
cdf_ret_status = QDF_STATUS_SUCCESS;
}
}

26
core/cds/src/cds_packet.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -76,11 +76,11 @@ cdf_spinlock_t trace_buffer_lock;
* cds_pkt_return_packet Free the cds Packet
* @ cds Packet
*/
CDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet)
QDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet)
{
/* Validate the input parameter pointer */
if (unlikely(packet == NULL)) {
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* Free up the Adf nbuf */
@@ -91,7 +91,7 @@ CDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet)
/* Free up the Rx packet */
cdf_mem_free(packet);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**--------------------------------------------------------------------------
@@ -109,7 +109,7 @@ CDF_STATUS cds_pkt_return_packet(cds_pkt_t *packet)
\sa
---------------------------------------------------------------------------*/
CDF_STATUS
QDF_STATUS
cds_pkt_get_packet_length(cds_pkt_t *pPacket, uint16_t *pPacketSize)
{
/* Validate the parameter pointers */
@@ -117,11 +117,11 @@ cds_pkt_get_packet_length(cds_pkt_t *pPacket, uint16_t *pPacketSize)
(pPacket->pkt_buf == NULL)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_FATAL,
"VPKT [%d]: NULL pointer", __LINE__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* return the requested information */
*pPacketSize = cdf_nbuf_len(pPacket->pkt_buf);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/*---------------------------------------------------------------------------
@@ -289,10 +289,10 @@ void cds_pkt_proto_trace_close(void)
* @brief cds_packet_alloc_debug() -
Allocate a network buffer for TX
---------------------------------------------------------------------------*/
CDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
QDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
uint8_t *file_name, uint32_t line_num)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
cdf_nbuf_t nbuf;
nbuf =
@@ -305,7 +305,7 @@ CDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
cdf_nbuf_set_protocol(nbuf, ETH_P_CONTROL);
*ppPacket = nbuf;
*data = cdf_nbuf_data(nbuf);
cdf_ret_status = CDF_STATUS_SUCCESS;
cdf_ret_status = QDF_STATUS_SUCCESS;
}
return cdf_ret_status;
@@ -315,9 +315,9 @@ CDF_STATUS cds_packet_alloc_debug(uint16_t size, void **data, void **ppPacket,
* @brief cds_packet_alloc() -
Allocate a network buffer for TX
---------------------------------------------------------------------------*/
CDF_STATUS cds_packet_alloc(uint16_t size, void **data, void **ppPacket)
QDF_STATUS cds_packet_alloc(uint16_t size, void **data, void **ppPacket)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
cdf_nbuf_t nbuf;
nbuf = cdf_nbuf_alloc(NULL, roundup(size + TX_PKT_MIN_HEADROOM, 4),
@@ -328,7 +328,7 @@ CDF_STATUS cds_packet_alloc(uint16_t size, void **data, void **ppPacket)
cdf_nbuf_set_protocol(nbuf, ETH_P_CONTROL);
*ppPacket = nbuf;
*data = cdf_nbuf_data(nbuf);
cdf_ret_status = CDF_STATUS_SUCCESS;
cdf_ret_status = QDF_STATUS_SUCCESS;
}
return cdf_ret_status;

82
core/cds/src/cds_reg_service.c
Fájl megtekintése

@@ -333,7 +333,7 @@ static int cds_regulatory_wiphy_init(hdd_context_t *hdd_ctx,
* cds_update_regulatory_info() - update regulatory info
* @hdd_ctx: hdd context
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
static void cds_update_regulatory_info(hdd_context_t *hdd_ctx)
{
@@ -357,16 +357,16 @@ static void cds_update_regulatory_info(hdd_context_t *hdd_ctx)
* @channels_40mhz: 40 MHz channels
* @num_40mhz_channels: number of 40 Mhz channels
*
* Return: CDF_STATUS_SUCCESS
* Return: QDF_STATUS_SUCCESS
*/
CDF_STATUS cds_get_channel_list_with_power(struct channel_power
QDF_STATUS cds_get_channel_list_with_power(struct channel_power
*base_channels,
uint8_t *num_base_channels,
struct channel_power
*channels_40mhz,
uint8_t *num_40mhz_channels)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
int i, count;
if (base_channels && num_base_channels) {
@@ -420,9 +420,9 @@ CDF_STATUS cds_get_channel_list_with_power(struct channel_power
* cds_read_default_country() - set the default country
* @default_country: default country
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS cds_read_default_country(uint8_t *default_country)
QDF_STATUS cds_read_default_country(uint8_t *default_country)
{
hdd_context_t *hdd_ctx;
@@ -430,7 +430,7 @@ CDF_STATUS cds_read_default_country(uint8_t *default_country)
if (!hdd_ctx) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"invalid hdd_ctx pointer");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
memcpy(default_country,
@@ -442,7 +442,7 @@ CDF_STATUS cds_read_default_country(uint8_t *default_country)
default_country[0],
default_country[1]);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -580,9 +580,7 @@ static int cds_bw20_ch_index_to_bw40_ch_index(int k)
m = k - RF_CHAN_36 + RF_CHAN_BOND_38;
if (m > RF_CHAN_BOND_62)
m = RF_CHAN_BOND_62;
}
else if (k >= RF_CHAN_100 && k <= RF_CHAN_144)
{
} else if (k >= RF_CHAN_100 && k <= RF_CHAN_144) {
m = k - RF_CHAN_100 + RF_CHAN_BOND_102;
if (m > RF_CHAN_BOND_142)
m = RF_CHAN_BOND_142;
@@ -598,17 +596,17 @@ static int cds_bw20_ch_index_to_bw40_ch_index(int k)
* cds_set_dfs_region() - set the dfs_region
* @dfs_region: the dfs_region to set
*
* Return: CDF_STATUS_SUCCESS if dfs_region set correctly
* CDF_STATUS_E_EXISTS if hdd context not found
* Return: QDF_STATUS_SUCCESS if dfs_region set correctly
* QDF_STATUS_E_EXISTS if hdd context not found
*/
CDF_STATUS cds_set_dfs_region(uint8_t dfs_region)
QDF_STATUS cds_set_dfs_region(uint8_t dfs_region)
{
hdd_context_t *hdd_ctx;
hdd_ctx = cds_get_context(CDF_MODULE_ID_HDD);
if (NULL == hdd_ctx)
return CDF_STATUS_E_EXISTS;
return QDF_STATUS_E_EXISTS;
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 14, 0)) || defined(WITH_BACKPORTS)
hdd_ctx->reg.dfs_region = dfs_region;
@@ -631,39 +629,39 @@ CDF_STATUS cds_set_dfs_region(uint8_t dfs_region)
break;
}
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
* cds_get_dfs_region() - get the dfs_region
* @dfs_region: the dfs_region to return
*
* Return: CDF_STATUS_SUCCESS if dfs_region set correctly
* CDF_STATUS_E_EXISTS if hdd context not found
* Return: QDF_STATUS_SUCCESS if dfs_region set correctly
* QDF_STATUS_E_EXISTS if hdd context not found
*/
CDF_STATUS cds_get_dfs_region(uint8_t *dfs_region)
QDF_STATUS cds_get_dfs_region(uint8_t *dfs_region)
{
hdd_context_t *hdd_ctx;
hdd_ctx = cds_get_context(CDF_MODULE_ID_HDD);
if (NULL == hdd_ctx)
return CDF_STATUS_E_EXISTS;
return QDF_STATUS_E_EXISTS;
*dfs_region = hdd_ctx->reg.dfs_region;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
* cds_get_reg_domain_from_country_code() - get the regulatory domain
* @reg_domain_ptr: ptr to store regulatory domain
*
* Return: CDF_STATUS_SUCCESS on success
* CDF_STATUS_E_FAULT on error
* CDF_STATUS_E_EMPTY country table empty
* Return: QDF_STATUS_SUCCESS on success
* QDF_STATUS_E_FAULT on error
* QDF_STATUS_E_EMPTY country table empty
*/
CDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *reg_domain_ptr,
QDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *reg_domain_ptr,
const uint8_t *country_alpha2,
enum country_src source)
{
@@ -673,24 +671,24 @@ CDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *reg_domain_ptr,
if (NULL == reg_domain_ptr) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
("Invalid reg domain pointer"));
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
*reg_domain_ptr = 0;
if (SOURCE_QUERY == source)
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
if (NULL == country_alpha2) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
("Country code array is NULL"));
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (cds_is_driver_recovering()) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"SSR in progress, return");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
hdd_ctx = cds_get_context(CDF_MODULE_ID_HDD);
@@ -698,7 +696,7 @@ CDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *reg_domain_ptr,
if (NULL == hdd_ctx) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
("Invalid pHddCtx pointer"));
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
wiphy = hdd_ctx->wiphy;
@@ -716,7 +714,7 @@ CDF_STATUS cds_get_reg_domain_from_country_code(v_REGDOMAIN_t *reg_domain_ptr,
NL80211_USER_REG_HINT_USER);
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/*
@@ -757,7 +755,7 @@ static int cds_process_regulatory_data(struct wiphy *wiphy,
if (NULL == hdd_ctx) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"invalid hdd_ctx pointer");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
hdd_ctx->isVHT80Allowed = 0;
@@ -928,7 +926,7 @@ static int cds_process_regulatory_data(struct wiphy *wiphy,
if (k == 0)
return -1;
return 0;
return QDF_STATUS_SUCCESS;
}
#if (LINUX_VERSION_CODE < KERNEL_VERSION(3, 14, 0)) && !defined(WITH_BACKPORTS)
@@ -1098,9 +1096,9 @@ void hdd_reg_notifier(struct wiphy *wiphy,
/**
* cds_regulatory_init() - regulatory_init
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS cds_regulatory_init(void)
QDF_STATUS cds_regulatory_init(void)
{
hdd_context_t *hdd_ctx = NULL;
struct wiphy *wiphy = NULL;
@@ -1111,7 +1109,7 @@ CDF_STATUS cds_regulatory_init(void)
if (!hdd_ctx) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"invalid hdd_ctx pointer");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
wiphy = hdd_ctx->wiphy;
@@ -1125,7 +1123,7 @@ CDF_STATUS cds_regulatory_init(void)
nBandCapability, true) != 0) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
("Error while creating regulatory entry"));
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
reg_info->cc_src = SOURCE_DRIVER;
@@ -1143,7 +1141,7 @@ CDF_STATUS cds_regulatory_init(void)
cds_fill_and_send_ctl_to_fw(reg_info);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1151,18 +1149,18 @@ CDF_STATUS cds_regulatory_init(void)
* @client_ctxt: client context
* @reg_domain: regulatory domain
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS cds_set_reg_domain(void *client_ctxt, v_REGDOMAIN_t reg_domain)
QDF_STATUS cds_set_reg_domain(void *client_ctxt, v_REGDOMAIN_t reg_domain)
{
if (reg_domain >= REGDOMAIN_COUNT) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"CDS set reg domain, invalid REG domain ID %d",
reg_domain);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

54
core/cds/src/cds_sched.c
Fájl megtekintése

@@ -82,7 +82,7 @@ static int cds_mc_thread(void *Arg);
#ifdef QCA_CONFIG_SMP
static int cds_ol_rx_thread(void *arg);
static unsigned long affine_cpu;
static CDF_STATUS cds_alloc_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext);
static QDF_STATUS cds_alloc_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext);
#endif
#ifdef QCA_CONFIG_SMP
@@ -186,29 +186,29 @@ static struct notifier_block cds_cpu_hotplug_notifier = {
*
* Return: CDF status
*/
CDF_STATUS cds_sched_open(void *p_cds_context,
QDF_STATUS cds_sched_open(void *p_cds_context,
p_cds_sched_context pSchedContext,
uint32_t SchedCtxSize)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Opening the CDS Scheduler", __func__);
/* Sanity checks */
if ((p_cds_context == NULL) || (pSchedContext == NULL)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Null params being passed", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (sizeof(cds_sched_context) != SchedCtxSize) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Incorrect CDS Sched Context size passed",
__func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
cdf_mem_zero(pSchedContext, sizeof(cds_sched_context));
pSchedContext->pVContext = p_cds_context;
vStatus = cds_sched_init_mqs(pSchedContext);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to initialize CDS Scheduler MQs",
__func__);
@@ -240,8 +240,8 @@ CDF_STATUS cds_sched_open(void *p_cds_context,
spin_lock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
INIT_LIST_HEAD(&pSchedContext->cds_ol_rx_pkt_freeq);
spin_unlock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
if (cds_alloc_ol_rx_pkt_freeq(pSchedContext) != CDF_STATUS_SUCCESS) {
return CDF_STATUS_E_FAILURE;
if (cds_alloc_ol_rx_pkt_freeq(pSchedContext) != QDF_STATUS_SUCCESS) {
return QDF_STATUS_E_FAILURE;
}
register_hotcpu_notifier(&cds_cpu_hotplug_notifier);
pSchedContext->cpu_hot_plug_notifier = &cds_cpu_hotplug_notifier;
@@ -292,7 +292,7 @@ CDF_STATUS cds_sched_open(void *p_cds_context,
/* We're good now: Let's get the ball rolling!!! */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: CDS Scheduler successfully Opened", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
#ifdef QCA_CONFIG_SMP
OL_RX_THREAD_START_FAILURE:
@@ -313,7 +313,7 @@ MC_THREAD_START_FAILURE:
cds_free_ol_rx_pkt_freeq(gp_cds_sched_context);
#endif
return CDF_STATUS_E_RESOURCES;
return QDF_STATUS_E_RESOURCES;
} /* cds_sched_open() */
@@ -329,7 +329,7 @@ static int cds_mc_thread(void *Arg)
p_cds_msg_wrapper pMsgWrapper = NULL;
tpAniSirGlobal pMacContext = NULL;
tSirRetStatus macStatus = eSIR_SUCCESS;
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
int retWaitStatus = 0;
bool shutdown = false;
hdd_context_t *pHddCtx = NULL;
@@ -424,7 +424,7 @@ static int cds_mc_thread(void *Arg)
vStatus =
sys_mc_process_msg(pSchedContext->pVContext,
pMsgWrapper->pVosMsg);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF,
CDF_TRACE_LEVEL_ERROR,
"%s: Issue Processing SYS message",
@@ -455,7 +455,7 @@ static int cds_mc_thread(void *Arg)
vStatus =
wma_mc_process_msg(pSchedContext->pVContext,
pMsgWrapper->pVosMsg);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF,
CDF_TRACE_LEVEL_ERROR,
"%s: Issue Processing WMA message",
@@ -546,7 +546,7 @@ static int cds_mc_thread(void *Arg)
vStatus =
sme_process_msg((tHalHandle) pMacContext,
pMsgWrapper->pVosMsg);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF,
CDF_TRACE_LEVEL_ERROR,
"%s: Issue Processing SME message",
@@ -619,7 +619,7 @@ void cds_free_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext)
*
* Return: status of memory allocation
*/
static CDF_STATUS cds_alloc_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext)
static QDF_STATUS cds_alloc_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext)
{
struct cds_ol_rx_pkt *pkt, *tmp;
int i;
@@ -638,7 +638,7 @@ static CDF_STATUS cds_alloc_ol_rx_pkt_freeq(p_cds_sched_context pSchedContext)
spin_unlock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
free:
spin_lock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
@@ -650,7 +650,7 @@ free:
spin_lock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
}
spin_unlock_bh(&pSchedContext->cds_ol_rx_pkt_freeq_lock);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
/**
@@ -895,14 +895,14 @@ static int cds_ol_rx_thread(void *arg)
*
* Return: cdf status
*/
CDF_STATUS cds_sched_close(void *p_cds_context)
QDF_STATUS cds_sched_close(void *p_cds_context)
{
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: invoked", __func__);
if (gp_cds_sched_context == NULL) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: gp_cds_sched_context == NULL", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* shut down MC Thread */
set_bit(MC_SHUTDOWN_EVENT_MASK, &gp_cds_sched_context->mcEventFlag);
@@ -929,7 +929,7 @@ CDF_STATUS cds_sched_close(void *p_cds_context)
cds_free_ol_rx_pkt_freeq(gp_cds_sched_context);
unregister_hotcpu_notifier(&cds_cpu_hotplug_notifier);
#endif
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_sched_close() */
/**
@@ -940,14 +940,14 @@ CDF_STATUS cds_sched_close(void *p_cds_context)
*
* Return: CDF status
*/
CDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext)
QDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
/* Now intialize all the message queues */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Initializing the WMA MC Message queue", __func__);
vStatus = cds_mq_init(&pSchedContext->wmaMcMq);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to init WMA MC Message queue", __func__);
CDF_ASSERT(0);
@@ -956,7 +956,7 @@ CDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Initializing the PE MC Message queue", __func__);
vStatus = cds_mq_init(&pSchedContext->peMcMq);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to init PE MC Message queue", __func__);
CDF_ASSERT(0);
@@ -965,7 +965,7 @@ CDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Initializing the SME MC Message queue", __func__);
vStatus = cds_mq_init(&pSchedContext->smeMcMq);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to init SME MC Message queue", __func__);
CDF_ASSERT(0);
@@ -974,14 +974,14 @@ CDF_STATUS cds_sched_init_mqs(p_cds_sched_context pSchedContext)
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: Initializing the SYS MC Message queue", __func__);
vStatus = cds_mq_init(&pSchedContext->sysMcMq);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to init SYS MC Message queue", __func__);
CDF_ASSERT(0);
return vStatus;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} /* cds_sched_init_mqs() */
/**

94
core/cds/src/cds_utils.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -201,37 +201,37 @@ static void cds_cmac_calc_mic(struct crypto_cipher *tfm,
\param phCryptProv - pointer to the Crypt handle
\return CDF_STATUS_SUCCESS - Successfully generated random memory.
\return QDF_STATUS_SUCCESS - Successfully generated random memory.
CDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
QDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
CDF_STATUS_E_FAILURE - default return value if it fails due to
QDF_STATUS_E_FAILURE - default return value if it fails due to
unknown reasons
***CDF_STATUS_E_RESOURCES - System resources (other than memory)
***QDF_STATUS_E_RESOURCES - System resources (other than memory)
are unavailable
\sa
( *** return value not considered yet )
--------------------------------------------------------------------------*/
CDF_STATUS cds_crypto_init(uint32_t *phCryptProv)
QDF_STATUS cds_crypto_init(uint32_t *phCryptProv)
{
CDF_STATUS uResult = CDF_STATUS_E_FAILURE;
QDF_STATUS uResult = QDF_STATUS_E_FAILURE;
/* This implementation doesn't require a crypto context */
*phCryptProv = 0;
uResult = CDF_STATUS_SUCCESS;
return (uResult);
uResult = QDF_STATUS_SUCCESS;
return uResult;
}
CDF_STATUS cds_crypto_deinit(uint32_t hCryptProv)
QDF_STATUS cds_crypto_deinit(uint32_t hCryptProv)
{
CDF_STATUS uResult = CDF_STATUS_E_FAILURE;
QDF_STATUS uResult = QDF_STATUS_E_FAILURE;
/* CryptReleaseContext succeeded */
uResult = CDF_STATUS_SUCCESS;
uResult = QDF_STATUS_SUCCESS;
return (uResult);
return uResult;
}
/*--------------------------------------------------------------------------
@@ -247,38 +247,38 @@ CDF_STATUS cds_crypto_deinit(uint32_t hCryptProv)
\param lock - pointer to the opaque lock object to initialize
\return CDF_STATUS_SUCCESS - Successfully generated random memory.
\return QDF_STATUS_SUCCESS - Successfully generated random memory.
CDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
QDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
CDF_STATUS_E_FAILURE - default return value if it fails due to
QDF_STATUS_E_FAILURE - default return value if it fails due to
unknown reasons
***CDF_STATUS_E_RESOURCES - System resources (other than memory)
***QDF_STATUS_E_RESOURCES - System resources (other than memory)
are unavailable
\sa
( *** return value not considered yet )
--------------------------------------------------------------------------*/
CDF_STATUS
QDF_STATUS
cds_rand_get_bytes(uint32_t cryptHandle, uint8_t *pbBuf, uint32_t numBytes)
{
CDF_STATUS uResult = CDF_STATUS_E_FAILURE;
QDF_STATUS uResult = QDF_STATUS_E_FAILURE;
/* check for invalid pointer */
if (NULL == pbBuf) {
uResult = CDF_STATUS_E_FAULT;
return (uResult);
uResult = QDF_STATUS_E_FAULT;
return uResult;
}
get_random_bytes(pbBuf, numBytes);
/* "Random sequence generated." */
uResult = CDF_STATUS_SUCCESS;
return (uResult);
uResult = QDF_STATUS_SUCCESS;
return uResult;
}
#ifdef WLAN_FEATURE_11W
uint8_t cds_get_mmie_size()
uint8_t cds_get_mmie_size(void)
{
return sizeof(struct ieee80211_mmie);
}
@@ -420,7 +420,7 @@ cds_attach_mmie(uint8_t *igtk, uint8_t *ipn, uint16_t key_id,
if (NULL == input) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Memory allocation failed", __func__);
ret = CDF_STATUS_E_NOMEM;
ret = QDF_STATUS_E_NOMEM;
goto err_tfm;
}
@@ -530,7 +530,7 @@ cds_is_mmie_valid(uint8_t *igtk, uint8_t *ipn, uint8_t *frm, uint8_t *efrm)
if (NULL == input) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"Memory allocation failed");
ret = CDF_STATUS_E_NOMEM;
ret = QDF_STATUS_E_NOMEM;
goto err_tfm;
}
@@ -708,7 +708,7 @@ err_tfm:
return ret;
}
CDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
uint8_t *pText, /* pointer to data stream */
uint32_t textLen, /* length of data stream */
uint8_t *pKey, /* pointer to authentication key */
@@ -728,10 +728,10 @@ CDF_STATUS cds_sha1_hmac_str(uint32_t cryptHandle, /* Handle */
if (ret != 0) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"hmac_sha1() call failed");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -868,7 +868,7 @@ err_tfm:
return ret;
}
CDF_STATUS cds_md5_hmac_str(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_md5_hmac_str(uint32_t cryptHandle, /* Handle */
uint8_t *pText, /* pointer to data stream */
uint32_t textLen, /* length of data stream */
uint8_t *pKey, /* pointer to authentication key */
@@ -888,10 +888,10 @@ CDF_STATUS cds_md5_hmac_str(uint32_t cryptHandle, /* Handle */
if (ret != 0) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"hmac_md5() call failed");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
struct ecb_aes_result {
@@ -921,21 +921,21 @@ static void ecb_aes_complete(struct crypto_async_request *req, int err)
\param lock - pointer to the opaque lock object to initialize
\return CDF_STATUS_SUCCESS - Successfully generated random memory.
\return QDF_STATUS_SUCCESS - Successfully generated random memory.
CDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
QDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
CDF_STATUS_E_FAILURE - default return value if it fails due to
QDF_STATUS_E_FAILURE - default return value if it fails due to
unknown reasons
***CDF_STATUS_E_RESOURCES - System resources (other than memory)
***QDF_STATUS_E_RESOURCES - System resources (other than memory)
are unavailable
\sa
( *** return value not considered yet )
--------------------------------------------------------------------------*/
CDF_STATUS cds_encrypt_aes(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_encrypt_aes(uint32_t cryptHandle, /* Handle */
uint8_t *pPlainText, /* pointer to data stream */
uint8_t *pCiphertext, uint8_t *pKey)
{ /* pointer to authentication key */
@@ -997,10 +997,10 @@ err_tfm:
if (ret != 0) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s() call failed", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/*--------------------------------------------------------------------------
@@ -1016,25 +1016,25 @@ err_tfm:
\param lock - pointer to the opaque lock object to initialize
\return CDF_STATUS_SUCCESS - Successfully generated random memory.
\return QDF_STATUS_SUCCESS - Successfully generated random memory.
CDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
QDF_STATUS_E_FAULT - pbBuf is an invalid pointer.
CDF_STATUS_E_FAILURE - default return value if it fails due to
QDF_STATUS_E_FAILURE - default return value if it fails due to
unknown reasons
***CDF_STATUS_E_RESOURCES - System resources (other than memory)
***QDF_STATUS_E_RESOURCES - System resources (other than memory)
are unavailable
\sa
( *** return value not considered yet )
--------------------------------------------------------------------------*/
CDF_STATUS cds_decrypt_aes(uint32_t cryptHandle, /* Handle */
QDF_STATUS cds_decrypt_aes(uint32_t cryptHandle, /* Handle */
uint8_t *pText, /* pointer to data stream */
uint8_t *pDecrypted, uint8_t *pKey)
{ /* pointer to authentication key */
/* CDF_STATUS uResult = CDF_STATUS_E_FAILURE; */
/* QDF_STATUS uResult = QDF_STATUS_E_FAILURE; */
struct ecb_aes_result result;
struct ablkcipher_request *req;
struct crypto_ablkcipher *tfm;
@@ -1093,10 +1093,10 @@ err_tfm:
if (ret != 0) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s() call failed", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
uint32_t cds_chan_to_freq(uint8_t chan)

4
core/dp/htt/htt_rx.c
Fájl megtekintése

@@ -224,7 +224,7 @@ static void htt_rx_ring_refill_retry(void *arg)
void htt_rx_ring_fill_n(struct htt_pdev_t *pdev, int num)
{
int idx;
CDF_STATUS status;
QDF_STATUS status;
struct htt_host_rx_desc_base *rx_desc;
idx = *(pdev->rx_ring.alloc_idx.vaddr);
@@ -284,7 +284,7 @@ void htt_rx_ring_fill_n(struct htt_pdev_t *pdev, int num)
cdf_nbuf_map(pdev->osdev, rx_netbuf,
CDF_DMA_FROM_DEVICE);
#endif
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
cdf_nbuf_free(rx_netbuf);
goto fail;
}

14
core/dp/ol/inc/ol_txrx_ctrl_api.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2011-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2011-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -674,9 +674,9 @@ ol_txrx_set_monitor_mode_vap(ol_txrx_pdev_handle pdev,
*/
void ol_txrx_set_curchan(ol_txrx_pdev_handle pdev, uint32_t chan_mhz);
CDF_STATUS ol_txrx_bus_suspend(void);
CDF_STATUS ol_txrx_bus_resume(void);
CDF_STATUS ol_txrx_wait_for_pending_tx(int timeout);
QDF_STATUS ol_txrx_bus_suspend(void);
QDF_STATUS ol_txrx_bus_resume(void);
QDF_STATUS ol_txrx_wait_for_pending_tx(int timeout);
/**
* @brief Get the number of pending transmit frames that are awaiting completion.
@@ -764,7 +764,7 @@ enum ol_txrx_peer_state {
*
* Return: CDF Status
*/
CDF_STATUS
QDF_STATUS
ol_txrx_peer_state_update(ol_txrx_pdev_handle pdev, uint8_t *peer_addr,
enum ol_txrx_peer_state state);
@@ -900,7 +900,7 @@ struct txrx_pdev_cfg_param_t {
ol_pdev_handle ol_pdev_cfg_attach(cdf_device_t osdev,
struct txrx_pdev_cfg_param_t cfg_param);
CDF_STATUS ol_txrx_get_vdevid(struct ol_txrx_peer_t *peer, uint8_t *vdev_id);
QDF_STATUS ol_txrx_get_vdevid(struct ol_txrx_peer_t *peer, uint8_t *vdev_id);
void *ol_txrx_get_vdev_by_sta_id(uint8_t sta_id);
@@ -1252,7 +1252,7 @@ void ol_txrx_display_stats(uint16_t bitmap);
void ol_txrx_clear_stats(uint16_t bitmap);
int ol_txrx_stats(uint8_t vdev_id, char *buffer, unsigned buf_len);
CDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
QDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
uint8_t *peer_id);
void ol_txrx_set_ocb_peer(struct ol_txrx_pdev_t *pdev,

16
core/dp/ol/inc/ol_txrx_osif_api.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2012, 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2012, 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -110,7 +110,7 @@ struct ol_txrx_desc_type {
};
typedef CDF_STATUS (*ol_rx_callback_fp)(void *p_cds_gctx,
typedef QDF_STATUS (*ol_rx_callback_fp)(void *p_cds_gctx,
cdf_nbuf_t pDataBuff,
uint8_t ucSTAId);
@@ -119,12 +119,12 @@ typedef void (*ol_tx_pause_callback_fp)(uint8_t vdev_id,
enum netif_reason_type reason);
#ifdef QCA_LL_TX_FLOW_CONTROL_V2
CDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb);
QDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb);
#else
static inline
CDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb)
QDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -262,12 +262,12 @@ cdf_nbuf_t ol_tx_send_ipa_data_frame(void *vdev,
cdf_nbuf_t skb);
#endif
CDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
QDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
struct ol_txrx_desc_type *sta_desc);
CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id);
QDF_STATUS ol_txrx_clear_peer(uint8_t sta_id);
CDF_STATUS ol_txrx_change_peer_state(uint8_t sta_id,
QDF_STATUS ol_txrx_change_peer_state(uint8_t sta_id,
enum ol_txrx_peer_state sta_state,
bool roam_synch_in_progress);

4
core/dp/txrx/ol_tx.c
Fájl megtekintése

@@ -149,7 +149,7 @@ cdf_nbuf_t ol_tx_send_data_frame(uint8_t sta_id, cdf_nbuf_t skb,
struct ol_txrx_pdev_t *pdev = cds_get_context(CDF_MODULE_ID_TXRX);
struct ol_txrx_peer_t *peer;
cdf_nbuf_t ret;
CDF_STATUS status;
QDF_STATUS status;
if (cdf_unlikely(!pdev)) {
CDF_TRACE(CDF_MODULE_ID_TXRX, CDF_TRACE_LEVEL_WARN,
@@ -182,7 +182,7 @@ cdf_nbuf_t ol_tx_send_data_frame(uint8_t sta_id, cdf_nbuf_t skb,
}
status = cdf_nbuf_map_single(cdf_ctx, skb, CDF_DMA_TO_DEVICE);
if (cdf_unlikely(status != CDF_STATUS_SUCCESS)) {
if (cdf_unlikely(status != QDF_STATUS_SUCCESS)) {
CDF_TRACE(CDF_MODULE_ID_TXRX, CDF_TRACE_LEVEL_WARN,
"%s: nbuf map failed", __func__);
return skb;

86
core/dp/txrx/ol_txrx.c
Fájl megtekintése

@@ -130,16 +130,16 @@ ol_txrx_find_peer_by_addr_and_vdev(ol_txrx_pdev_handle pdev,
return peer;
}
CDF_STATUS ol_txrx_get_vdevid(struct ol_txrx_peer_t *peer, uint8_t *vdev_id)
QDF_STATUS ol_txrx_get_vdevid(struct ol_txrx_peer_t *peer, uint8_t *vdev_id)
{
if (!peer) {
CDF_TRACE(CDF_MODULE_ID_TXRX, CDF_TRACE_LEVEL_ERROR,
"peer argument is null!!");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
*vdev_id = peer->vdev->vdev_id;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
void *ol_txrx_get_vdev_by_sta_id(uint8_t sta_id)
@@ -1263,7 +1263,7 @@ void ol_txrx_flush_rx_frames(struct ol_txrx_peer_t *peer,
bool drop)
{
struct ol_rx_cached_buf *cache_buf;
CDF_STATUS ret;
QDF_STATUS ret;
ol_rx_callback_fp data_rx = NULL;
void *cds_ctx = cds_get_global_context();
@@ -1291,7 +1291,7 @@ void ol_txrx_flush_rx_frames(struct ol_txrx_peer_t *peer,
} else {
/* Flush the cached frames to HDD */
ret = data_rx(cds_ctx, cache_buf->buf, peer->local_id);
if (ret != CDF_STATUS_SUCCESS)
if (ret != QDF_STATUS_SUCCESS)
cdf_nbuf_free(cache_buf->buf);
}
cdf_mem_free(cache_buf);
@@ -1466,7 +1466,7 @@ static A_STATUS ol_tx_filter_pass_thru(struct ol_txrx_msdu_info_t *tx_msdu_info)
return A_OK;
}
CDF_STATUS
QDF_STATUS
ol_txrx_peer_state_update(struct ol_txrx_pdev_t *pdev, uint8_t *peer_mac,
enum ol_txrx_peer_state state)
{
@@ -1475,7 +1475,7 @@ ol_txrx_peer_state_update(struct ol_txrx_pdev_t *pdev, uint8_t *peer_mac,
if (cdf_unlikely(!pdev)) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "Pdev is NULL");
cdf_assert(0);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
peer = ol_txrx_peer_find_hash_find(pdev, peer_mac, 0, 1);
@@ -1484,7 +1484,7 @@ ol_txrx_peer_state_update(struct ol_txrx_pdev_t *pdev, uint8_t *peer_mac,
" 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x\n", __FUNCTION__,
peer_mac[0], peer_mac[1], peer_mac[2], peer_mac[3],
peer_mac[4], peer_mac[5]);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
/* TODO: Should we send WMI command of the connection state? */
@@ -1496,7 +1496,7 @@ ol_txrx_peer_state_update(struct ol_txrx_pdev_t *pdev, uint8_t *peer_mac,
__func__);
#endif
cdf_atomic_dec(&peer->ref_cnt);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
TXRX_PRINT(TXRX_PRINT_LEVEL_INFO2, "%s: change from %d to %d\n",
@@ -1530,7 +1530,7 @@ ol_txrx_peer_state_update(struct ol_txrx_pdev_t *pdev, uint8_t *peer_mac,
/* Set the state after the Pause to avoid the race condiction
with ADDBA check in tx path */
peer->state = state;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
void
@@ -1886,18 +1886,18 @@ static void ol_txrx_dump_tx_desc(ol_txrx_pdev_handle pdev_handle)
* queue doesn't empty before timeout occurs.
*
* Return:
* CDF_STATUS_SUCCESS if the queue empties,
* CDF_STATUS_E_TIMEOUT in case of timeout,
* CDF_STATUS_E_FAULT in case of missing handle
* QDF_STATUS_SUCCESS if the queue empties,
* QDF_STATUS_E_TIMEOUT in case of timeout,
* QDF_STATUS_E_FAULT in case of missing handle
*/
CDF_STATUS ol_txrx_wait_for_pending_tx(int timeout)
QDF_STATUS ol_txrx_wait_for_pending_tx(int timeout)
{
ol_txrx_pdev_handle txrx_pdev = cds_get_context(CDF_MODULE_ID_TXRX);
if (txrx_pdev == NULL) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR,
"%s: txrx context is null", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
while (ol_txrx_get_tx_pending(txrx_pdev)) {
@@ -1906,11 +1906,11 @@ CDF_STATUS ol_txrx_wait_for_pending_tx(int timeout)
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR,
"%s: tx frames are pending", __func__);
ol_txrx_dump_tx_desc(txrx_pdev);
return CDF_STATUS_E_TIMEOUT;
return QDF_STATUS_E_TIMEOUT;
}
timeout = timeout - OL_ATH_TX_DRAIN_WAIT_DELAY;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#ifndef QCA_WIFI_3_0_EMU
@@ -1924,9 +1924,9 @@ CDF_STATUS ol_txrx_wait_for_pending_tx(int timeout)
*
* Ensure that ol_txrx is ready for bus suspend
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS ol_txrx_bus_suspend(void)
QDF_STATUS ol_txrx_bus_suspend(void)
{
return ol_txrx_wait_for_pending_tx(SUSPEND_DRAIN_WAIT);
}
@@ -1936,11 +1936,11 @@ CDF_STATUS ol_txrx_bus_suspend(void)
*
* Dummy function for symetry
*
* Return: CDF_STATUS_SUCCESS
* Return: QDF_STATUS_SUCCESS
*/
CDF_STATUS ol_txrx_bus_resume(void)
QDF_STATUS ol_txrx_bus_resume(void)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
int ol_txrx_get_tx_pending(ol_txrx_pdev_handle pdev_handle)
@@ -2990,7 +2990,7 @@ static void ol_rx_data_cb(struct ol_txrx_peer_t *peer,
{
void *cds_ctx = cds_get_global_context();
cdf_nbuf_t buf, next_buf;
CDF_STATUS ret;
QDF_STATUS ret;
ol_rx_callback_fp data_rx = NULL;
if (cdf_unlikely(!cds_ctx))
@@ -3017,7 +3017,7 @@ static void ol_rx_data_cb(struct ol_txrx_peer_t *peer,
next_buf = cdf_nbuf_queue_next(buf);
cdf_nbuf_set_next(buf, NULL); /* Add NULL terminator */
ret = data_rx(cds_ctx, buf, peer->local_id);
if (ret != CDF_STATUS_SUCCESS) {
if (ret != QDF_STATUS_SUCCESS) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "Frame Rx to HDD failed");
cdf_nbuf_free(buf);
}
@@ -3141,7 +3141,7 @@ drop_rx_buf:
*
* Return: CDF Status
*/
CDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
QDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
struct ol_txrx_desc_type *sta_desc)
{
struct ol_txrx_peer_t *peer;
@@ -3151,18 +3151,18 @@ CDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
if (!pdev) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "Pdev is NULL");
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (sta_desc->sta_id >= WLAN_MAX_STA_COUNT) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "Invalid sta id :%d",
sta_desc->sta_id);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
peer = ol_txrx_peer_find_by_local_id(pdev, sta_desc->sta_id);
if (!peer)
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
cdf_spin_lock_bh(&peer->peer_info_lock);
peer->osif_rx = rxcb;
@@ -3182,7 +3182,7 @@ CDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
}
ol_txrx_flush_rx_frames(peer, 0);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -3191,7 +3191,7 @@ CDF_STATUS ol_txrx_register_peer(ol_rx_callback_fp rxcb,
*
* Return: CDF Status
*/
CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
QDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
{
struct ol_txrx_peer_t *peer;
struct ol_txrx_pdev_t *pdev = cds_get_context(CDF_MODULE_ID_TXRX);
@@ -3199,12 +3199,12 @@ CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
if (!pdev) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "%s: Unable to find pdev!",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (sta_id >= WLAN_MAX_STA_COUNT) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "Invalid sta id %d", sta_id);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
#ifdef QCA_CONFIG_SMP
@@ -3218,7 +3218,7 @@ CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
peer = ol_txrx_peer_find_by_local_id(pdev, sta_id);
if (!peer)
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
/* Purge the cached rx frame queue */
ol_txrx_flush_rx_frames(peer, 1);
@@ -3228,7 +3228,7 @@ CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
peer->state = ol_txrx_peer_state_disc;
cdf_spin_unlock_bh(&peer->peer_info_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -3237,9 +3237,9 @@ CDF_STATUS ol_txrx_clear_peer(uint8_t sta_id)
* @mac_addr: MAC address of the self peer
* @peer_id: Pointer to the peer ID
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_FAILURE on failure
* Return: QDF_STATUS_SUCCESS on success, QDF_STATUS_E_FAILURE on failure
*/
CDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
QDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
uint8_t *peer_id)
{
ol_txrx_pdev_handle pdev;
@@ -3248,21 +3248,21 @@ CDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
if (!cds_ctx) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "%s: Invalid context",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pdev = cds_get_context(CDF_MODULE_ID_TXRX);
if (!pdev) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "%s: Unable to find pdev!",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
peer = ol_txrx_find_peer_by_addr(pdev, mac_addr, peer_id);
if (!peer) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "%s: Unable to find OCB peer!",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
ol_txrx_set_ocb_peer(pdev, peer);
@@ -3271,7 +3271,7 @@ CDF_STATUS ol_txrx_register_ocb_peer(void *cds_ctx, uint8_t *mac_addr,
ol_txrx_peer_state_update(pdev, peer->mac_addr.raw,
ol_txrx_peer_state_auth);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -3324,15 +3324,15 @@ exit:
*
* Return: CDF status
*/
CDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb)
QDF_STATUS ol_txrx_register_pause_cb(ol_tx_pause_callback_fp pause_cb)
{
struct ol_txrx_pdev_t *pdev = cds_get_context(CDF_MODULE_ID_TXRX);
if (!pdev || !pause_cb) {
TXRX_PRINT(TXRX_PRINT_LEVEL_ERR, "pdev or pause_cb is NULL");
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
pdev->pause_cb = pause_cb;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif

8
core/dp/txrx/txrx.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2014 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -107,8 +107,8 @@ struct wlan_txrx_stats {
struct ol_txrx_vdev_t;
CDF_STATUS wlan_register_mgmt_client(void *pdev_txrx,
CDF_STATUS (*rx_mgmt)(void *g_cdsctx,
QDF_STATUS wlan_register_mgmt_client(void *pdev_txrx,
QDF_STATUS (*rx_mgmt)(void *g_cdsctx,
void *buf));
typedef void (*ol_txrx_vdev_delete_cb)(void *context);
@@ -124,7 +124,7 @@ typedef void
(*ol_txrx_mgmt_tx_cb)(void *ctxt, cdf_nbuf_t tx_mgmt_frm, int had_error);
/* If RSSI realm is changed, send notification to Clients, SME, HDD */
typedef CDF_STATUS (*wlan_txrx_rssi_cross_thresh)(void *adapter, u8 rssi,
typedef QDF_STATUS (*wlan_txrx_rssi_cross_thresh)(void *adapter, u8 rssi,
void *usr_ctx,
int8_t avg_rssi);

10
core/hdd/inc/wlan_hdd_assoc.h
Fájl megtekintése

@@ -168,9 +168,9 @@ eCsrBand hdd_conn_get_connected_band(hdd_station_ctx_t *pHddStaCtx);
* @roamStatus: roam status
* @roamResult: roam result
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo,
QDF_STATUS hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
eRoamCmdStatus roamStatus,
eCsrRoamResult roamResult);
@@ -214,9 +214,9 @@ int hdd_set_csr_auth_type(hdd_adapter_t *pAdapter, eCsrAuthType RSNAuthType);
* Construct the staDesc and register with TL the new STA.
* This is called as part of ADD_STA in the TDLS setup.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
const uint8_t *peerMac, uint16_t staId,
uint8_t ucastSig);
@@ -248,7 +248,7 @@ hdd_indicate_ese_bcn_report_no_results(const hdd_adapter_t *pAdapter,
const uint8_t numBss);
#endif /* FEATURE_WLAN_ESE && FEATURE_WLAN_ESE_UPLOAD */
CDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
uint8_t sta_id,
enum ol_txrx_peer_state sta_state,
bool roam_synch_in_progress);

20
core/hdd/inc/wlan_hdd_cfg.h
Fájl megtekintése

@@ -3569,32 +3569,32 @@ static __inline unsigned long util_min(unsigned long a, unsigned long b)
}
/* Function declarations and documenation */
CDF_STATUS hdd_parse_config_ini(hdd_context_t *pHddCtx);
CDF_STATUS hdd_update_mac_config(hdd_context_t *pHddCtx);
CDF_STATUS hdd_set_sme_config(hdd_context_t *pHddCtx);
CDF_STATUS hdd_set_sme_chan_list(hdd_context_t *hdd_ctx);
QDF_STATUS hdd_parse_config_ini(hdd_context_t *pHddCtx);
QDF_STATUS hdd_update_mac_config(hdd_context_t *pHddCtx);
QDF_STATUS hdd_set_sme_config(hdd_context_t *pHddCtx);
QDF_STATUS hdd_set_sme_chan_list(hdd_context_t *hdd_ctx);
bool hdd_update_config_dat(hdd_context_t *pHddCtx);
CDF_STATUS hdd_cfg_get_global_config(hdd_context_t *pHddCtx, char *pBuf,
QDF_STATUS hdd_cfg_get_global_config(hdd_context_t *pHddCtx, char *pBuf,
int buflen);
eCsrPhyMode hdd_cfg_xlate_to_csr_phy_mode(eHddDot11Mode dot11Mode);
CDF_STATUS hdd_execute_global_config_command(hdd_context_t *pHddCtx,
QDF_STATUS hdd_execute_global_config_command(hdd_context_t *pHddCtx,
char *command);
bool hdd_is_okc_mode_enabled(hdd_context_t *pHddCtx);
CDF_STATUS hdd_set_idle_ps_config(hdd_context_t *pHddCtx, uint32_t val);
QDF_STATUS hdd_set_idle_ps_config(hdd_context_t *pHddCtx, uint32_t val);
void hdd_update_tgt_cfg(void *context, void *param);
bool hdd_dfs_indicate_radar(void *context, void *param);
CDF_STATUS hdd_string_to_u8_array(char *str, uint8_t *intArray, uint8_t *len,
QDF_STATUS hdd_string_to_u8_array(char *str, uint8_t *intArray, uint8_t *len,
uint8_t intArrayMaxLen);
CDF_STATUS hdd_hex_string_to_u16_array(char *str, uint16_t *int_array,
QDF_STATUS hdd_hex_string_to_u16_array(char *str, uint16_t *int_array,
uint8_t *len, uint8_t int_array_max_len);
void hdd_cfg_print(hdd_context_t *pHddCtx);
CDF_STATUS hdd_update_nss(hdd_context_t *hdd_ctx, uint8_t nss);
QDF_STATUS hdd_update_nss(hdd_context_t *hdd_ctx, uint8_t nss);
#ifdef FEATURE_WLAN_SCAN_PNO
void hdd_set_pno_channel_prediction_config(
tpSmeConfigParams sme_config, hdd_context_t *hdd_ctx);

8
core/hdd/inc/wlan_hdd_debugfs.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2014 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -29,12 +29,12 @@
#define _WLAN_HDD_DEBUGFS_H
#ifdef WLAN_OPEN_SOURCE
CDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter);
void hdd_debugfs_exit(hdd_context_t *pHddCtx);
#else
inline CDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter)
inline QDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
inline void hdd_debugfs_exit(hdd_context_t *pHddCtx)

3
core/hdd/inc/wlan_hdd_ftm.h
Fájl megtekintése

@@ -34,7 +34,6 @@
* WLAN Host Device Driver Factory Test Mode header file
*/
#include "cdf_status.h"
#include "qdf_status.h"
#include "cds_mq.h"
#include "cds_api.h"
@@ -60,7 +59,7 @@ int wlan_hdd_ftm_open(hdd_context_t *hdd_ctx);
int wlan_hdd_ftm_close(hdd_context_t *hdd_ctx);
#if defined(QCA_WIFI_FTM)
CDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len);
QDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len);
int wlan_hdd_qcmbr_unified_ioctl(hdd_adapter_t *adapter, struct ifreq *ifr);
int hdd_ftm_start(hdd_context_t *hdd_ctx);
int hdd_ftm_stop(hdd_context_t *hdd_ctx);

18
core/hdd/inc/wlan_hdd_ipa.h
Fájl megtekintése

@@ -52,9 +52,9 @@ static inline hdd_ipa_nbuf_cb_fn wlan_hdd_stub_ipa_fn(void)
return hdd_ipa_nbuf_cb;
};
CDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx);
CDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx);
CDF_STATUS hdd_ipa_process_rxt(void *cds_context, cdf_nbuf_t rxBuf,
QDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx);
QDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx);
QDF_STATUS hdd_ipa_process_rxt(void *cds_context, cdf_nbuf_t rxBuf,
uint8_t sta_id);
int hdd_ipa_wlan_evt(hdd_adapter_t *adapter, uint8_t sta_id,
enum ipa_wlan_event type, uint8_t *mac_addr);
@@ -75,20 +75,20 @@ void hdd_ipa_uc_force_pipe_shutdown(hdd_context_t *hdd_ctx);
struct sk_buff *hdd_ipa_tx_packet_ipa(hdd_context_t *hdd_ctx,
struct sk_buff *skb, uint8_t session_id);
#else
static inline CDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx)
static inline QDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
static inline QDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline CDF_STATUS hdd_ipa_process_rxt(void *cds_context,
static inline QDF_STATUS hdd_ipa_process_rxt(void *cds_context,
cdf_nbuf_t rxBuf, uint8_t sta_id)
{
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static inline int hdd_ipa_wlan_evt(hdd_adapter_t *adapter, uint8_t sta_id,

42
core/hdd/inc/wlan_hdd_main.h
Fájl megtekintése

@@ -674,7 +674,7 @@ typedef struct hdd_hostapd_state_s {
int bssState;
qdf_event_t cdf_event;
qdf_event_t cdf_stop_bss_event;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
bool bCommit;
} hdd_hostapd_state_t;
@@ -899,7 +899,7 @@ struct hdd_adapter_s {
struct completion tdls_del_station_comp;
struct completion tdls_mgmt_comp;
struct completion tdls_link_establish_req_comp;
CDF_STATUS tdlsAddStaStatus;
QDF_STATUS tdlsAddStaStatus;
#endif
/* Track whether the linkup handling is needed */
@@ -1343,43 +1343,43 @@ void wlan_hdd_check_sta_ap_concurrent_ch_intf(void *sta_pAdapter);
const char *hdd_device_mode_to_string(uint8_t device_mode);
CDF_STATUS hdd_get_front_adapter(hdd_context_t *pHddCtx,
QDF_STATUS hdd_get_front_adapter(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t **ppAdapterNode);
CDF_STATUS hdd_get_next_adapter(hdd_context_t *pHddCtx,
QDF_STATUS hdd_get_next_adapter(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t *pAdapterNode,
hdd_adapter_list_node_t **pNextAdapterNode);
CDF_STATUS hdd_remove_adapter(hdd_context_t *pHddCtx,
QDF_STATUS hdd_remove_adapter(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t *pAdapterNode);
CDF_STATUS hdd_remove_front_adapter(hdd_context_t *pHddCtx,
QDF_STATUS hdd_remove_front_adapter(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t **ppAdapterNode);
CDF_STATUS hdd_add_adapter_back(hdd_context_t *pHddCtx,
QDF_STATUS hdd_add_adapter_back(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t *pAdapterNode);
CDF_STATUS hdd_add_adapter_front(hdd_context_t *pHddCtx,
QDF_STATUS hdd_add_adapter_front(hdd_context_t *pHddCtx,
hdd_adapter_list_node_t *pAdapterNode);
hdd_adapter_t *hdd_open_adapter(hdd_context_t *pHddCtx, uint8_t session_type,
const char *name, tSirMacAddr macAddr,
bool rtnl_held);
CDF_STATUS hdd_close_adapter(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter,
QDF_STATUS hdd_close_adapter(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter,
bool rtnl_held);
CDF_STATUS hdd_close_all_adapters(hdd_context_t *pHddCtx, bool rtnl_held);
CDF_STATUS hdd_stop_all_adapters(hdd_context_t *pHddCtx);
CDF_STATUS hdd_reset_all_adapters(hdd_context_t *pHddCtx);
CDF_STATUS hdd_start_all_adapters(hdd_context_t *pHddCtx);
QDF_STATUS hdd_close_all_adapters(hdd_context_t *pHddCtx, bool rtnl_held);
QDF_STATUS hdd_stop_all_adapters(hdd_context_t *pHddCtx);
QDF_STATUS hdd_reset_all_adapters(hdd_context_t *pHddCtx);
QDF_STATUS hdd_start_all_adapters(hdd_context_t *pHddCtx);
hdd_adapter_t *hdd_get_adapter_by_vdev(hdd_context_t *pHddCtx,
uint32_t vdev_id);
hdd_adapter_t *hdd_get_adapter_by_macaddr(hdd_context_t *pHddCtx,
tSirMacAddr macAddr);
CDF_STATUS hdd_init_station_mode(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_init_station_mode(hdd_adapter_t *pAdapter);
hdd_adapter_t *hdd_get_adapter(hdd_context_t *pHddCtx, device_mode_t mode);
void hdd_deinit_adapter(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter,
bool rtnl_held);
CDF_STATUS hdd_stop_adapter(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter,
QDF_STATUS hdd_stop_adapter(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter,
const bool bCloseSession);
void hdd_set_station_ops(struct net_device *pWlanDev);
uint8_t *wlan_hdd_get_intf_addr(hdd_context_t *pHddCtx);
@@ -1400,12 +1400,12 @@ void hdd_allow_suspend(uint32_t reason);
void hdd_prevent_suspend_timeout(uint32_t timeout, uint32_t reason);
void wlan_hdd_cfg80211_update_wiphy_caps(struct wiphy *wiphy);
CDF_STATUS hdd_set_ibss_power_save_params(hdd_adapter_t *pAdapter);
CDF_STATUS wlan_hdd_restart_driver(hdd_context_t *pHddCtx);
QDF_STATUS hdd_set_ibss_power_save_params(hdd_adapter_t *pAdapter);
QDF_STATUS wlan_hdd_restart_driver(hdd_context_t *pHddCtx);
void hdd_exchange_version_and_caps(hdd_context_t *pHddCtx);
int wlan_hdd_validate_context(hdd_context_t *pHddCtx);
bool hdd_is_valid_mac_address(const uint8_t *pMacAddr);
CDF_STATUS hdd_issta_p2p_clientconnected(hdd_context_t *pHddCtx);
QDF_STATUS hdd_issta_p2p_clientconnected(hdd_context_t *pHddCtx);
void hdd_checkandupdate_phymode(hdd_context_t *pHddCtx);
@@ -1484,11 +1484,11 @@ void hdd_update_macaddr(struct hdd_config *config,
void wlan_hdd_disable_roaming(hdd_adapter_t *pAdapter);
void wlan_hdd_enable_roaming(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_post_cds_enable_config(hdd_context_t *pHddCtx);
QDF_STATUS hdd_post_cds_enable_config(hdd_context_t *pHddCtx);
CDF_STATUS hdd_abort_mac_scan_all_adapters(hdd_context_t *hdd_ctx);
QDF_STATUS hdd_abort_mac_scan_all_adapters(hdd_context_t *hdd_ctx);
CDF_STATUS wlan_hdd_check_custom_con_channel_rules(hdd_adapter_t *sta_adapter,
QDF_STATUS wlan_hdd_check_custom_con_channel_rules(hdd_adapter_t *sta_adapter,
hdd_adapter_t *ap_adapter,
tCsrRoamProfile *roam_profile,
tScanResultHandle *scan_cache,

8
core/hdd/inc/wlan_hdd_power.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2012, 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2012, 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -128,11 +128,11 @@ struct pkt_filter_cfg {
/* SSR shutdown & re-init functions */
CDF_STATUS hdd_wlan_shutdown(void);
CDF_STATUS hdd_wlan_re_init(void *hif_sc);
QDF_STATUS hdd_wlan_shutdown(void);
QDF_STATUS hdd_wlan_re_init(void *hif_sc);
void hdd_conf_mcastbcast_filter(hdd_context_t *pHddCtx, bool setfilter);
CDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable);
QDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable);
void hdd_conf_hostoffload(hdd_adapter_t *pAdapter, bool fenable);
#ifdef WLAN_FEATURE_PACKET_FILTERING

28
core/hdd/inc/wlan_hdd_softap_tx_rx.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2014-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2014-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -39,24 +39,24 @@
int hdd_softap_hard_start_xmit(struct sk_buff *skb,
struct net_device *dev);
void hdd_softap_tx_timeout(struct net_device *dev);
CDF_STATUS hdd_softap_init_tx_rx(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_softap_deinit_tx_rx(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_init_tx_rx(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_softap_deinit_tx_rx(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter,
uint8_t STAId,
struct cdf_mac_addr *pmacAddrSTA);
CDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter,
uint8_t STAId);
CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
QDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
cdf_nbuf_t rxBufChain,
uint8_t staId);
#ifdef IPA_OFFLOAD
CDF_STATUS hdd_softap_rx_mul_packet_cbk(void *cds_context,
QDF_STATUS hdd_softap_rx_mul_packet_cbk(void *cds_context,
cdf_nbuf_t rx_buf_list, uint8_t staId);
#endif /* IPA_OFFLOAD */
CDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter,
uint8_t staId);
CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
bool fAuthRequired,
bool fPrivacyBit,
uint8_t staId,
@@ -64,14 +64,14 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
uint8_t bcastSig,
struct cdf_mac_addr *pPeerMacAddress,
bool fWmmEnabled);
CDF_STATUS hdd_softap_register_bc_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_register_bc_sta(hdd_adapter_t *pAdapter,
bool fPrivacyBit);
CDF_STATUS hdd_softap_deregister_bc_sta(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pHostapdAdapter);
CDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_deregister_bc_sta(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pHostapdAdapter);
QDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
struct cdf_mac_addr *pDestMacAddress,
enum ol_txrx_peer_state state);
CDF_STATUS hdd_softap_get_sta_id(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_get_sta_id(hdd_adapter_t *pAdapter,
struct cdf_mac_addr *pMacAddress,
uint8_t *staId);

12
core/hdd/inc/wlan_hdd_tx_rx.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -55,17 +55,17 @@
int hdd_hard_start_xmit(struct sk_buff *skb, struct net_device *dev);
void hdd_tx_timeout(struct net_device *dev);
CDF_STATUS hdd_init_tx_rx(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_deinit_tx_rx(hdd_adapter_t *pAdapter);
CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBufChain,
QDF_STATUS hdd_init_tx_rx(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_deinit_tx_rx(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBufChain,
uint8_t staId);
#ifdef IPA_OFFLOAD
CDF_STATUS hdd_rx_mul_packet_cbk(void *cds_context,
QDF_STATUS hdd_rx_mul_packet_cbk(void *cds_context,
cdf_nbuf_t rx_buf_list, uint8_t staId);
#endif /* IPA_OFFLOAD */
CDF_STATUS hdd_ibss_get_sta_id(hdd_station_ctx_t *pHddStaCtx,
QDF_STATUS hdd_ibss_get_sta_id(hdd_station_ctx_t *pHddStaCtx,
struct cdf_mac_addr *pMacAddress,
uint8_t *staId);

12
core/hdd/inc/wlan_hdd_wext.h
Fájl megtekintése

@@ -338,23 +338,23 @@ extern int hdd_priv_get_data(struct iw_point *p_priv_data,
extern void *mem_alloc_copy_from_user_helper(const void *wrqu_data, size_t len);
extern CDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
extern QDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
struct cdf_mac_addr mac_address);
void hdd_clear_roam_profile_ie(hdd_adapter_t *pAdapter);
uint8_t *wlan_hdd_get_vendor_oui_ie_ptr(uint8_t *oui, uint8_t oui_size,
uint8_t *ie, int ie_len);
CDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter);
QDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter);
CDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter);
QDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter);
CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value);
QDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value);
CDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr);
QDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr);
#ifdef FEATURE_WLAN_TDLS
CDF_STATUS iw_set_tdls_params(struct net_device *dev,
QDF_STATUS iw_set_tdls_params(struct net_device *dev,
struct iw_request_info *info,
union iwreq_data *wrqu, char *extra, int nOffset);
#endif

34
core/hdd/inc/wlan_hdd_wmm.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2011-2012,2014 The Linux Foundation. All rights reserved.
* Copyright (c) 2011-2012,2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -223,9 +223,9 @@ int hdd_wmmps_helper(hdd_adapter_t *pAdapter, uint8_t *ptr);
* adapter to an initial state. The configuration can later be
* overwritten via application APIs or via QoS Map sent OTA.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter);
/**
* hdd_wmm_adapter_init() - initialize the WMM configuration of an adapter
@@ -235,9 +235,9 @@ CDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter);
* adapter to an initial state. The configuration can later be
* overwritten via application APIs
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter);
/**
* hdd_wmm_close() - WMM close function
@@ -246,9 +246,9 @@ CDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter);
* Function which will perform any necessary work to to clean up the
* WMM functionality prior to the kernel module unload.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_close(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_wmm_adapter_close(hdd_adapter_t *pAdapter);
/**
* hdd_wmm_select_queue() - Function which will classify the packet
@@ -301,9 +301,9 @@ void hdd_wmm_acquire_access_required(hdd_adapter_t *pAdapter,
* @pGranted: [out] pointer to bool flag when indicates if access
* has been granted or not
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
sme_ac_enum_type acType, bool *pGranted);
/**
@@ -314,9 +314,9 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
* @pRoamInfo: [in] pointer to roam information
* @eBssType: [in] type of BSS
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo, eCsrRoamBssType eBssType);
/**
@@ -327,9 +327,9 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
* @pRoamInfo: [in] pointer to roam information
* @eBssType : [in] type of BSS
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo, eCsrRoamBssType eBssType);
/**
@@ -339,9 +339,9 @@ CDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
* @pAdapter : [in] pointer to adapter context
* @pUapsdMask: [out] pointer to where the UAPSD Mask is to be stored
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_get_uapsd_mask(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_get_uapsd_mask(hdd_adapter_t *pAdapter,
uint8_t *pUapsdMask);
/**
@@ -396,9 +396,9 @@ hdd_wlan_wmm_status_e hdd_wmm_checkts(hdd_adapter_t *pAdapter,
*
* @pAdapter: [in] pointer to Adapter context
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter);
void wlan_hdd_process_peer_unauthorised_pause(hdd_adapter_t *adapter);
#endif /* #ifndef _WLAN_HDD_WMM_H */

278
core/hdd/src/wlan_hdd_assoc.c
Fájl megtekintése

@@ -917,12 +917,12 @@ static void hdd_conn_remove_connect_info(hdd_station_ctx_t *pHddStaCtx)
* @pAdapter: pointer to adapter
* @staId: station identifier
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
hdd_roam_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
if (eConnectionState_IbssDisconnected ==
@@ -933,13 +933,13 @@ hdd_roam_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
*/
}
cdf_status = ol_txrx_clear_peer(staId);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = ol_txrx_clear_peer(staId);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE,
FL("ol_txrx_clear_peer() failed for staID %d. Status(%d) [0x%08X]"),
staId, cdf_status, cdf_status);
staId, qdf_status, qdf_status);
}
return cdf_status;
return qdf_status;
}
/**
@@ -955,16 +955,16 @@ hdd_roam_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
* 2. Clean up internal connection states and data structures;
* 3. Send disconnect indication to supplicant.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
static QDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
eRoamCmdStatus roamStatus,
eCsrRoamResult roamResult)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
CDF_STATUS vstatus;
QDF_STATUS status = QDF_STATUS_SUCCESS;
QDF_STATUS vstatus;
struct net_device *dev = pAdapter->dev;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
@@ -973,7 +973,7 @@ static CDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
if (dev == NULL) {
hddLog(LOGE, FL("net_dev is released return"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* notify apps that we can't pass traffic anymore */
hddLog(LOG1, FL("Disabling queues"));
@@ -1083,10 +1083,10 @@ static CDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
uint8_t i;
sta_id = pHddStaCtx->broadcast_ibss_staid;
vstatus = hdd_roam_deregister_sta(pAdapter, sta_id);
if (!CDF_IS_STATUS_SUCCESS(vstatus)) {
if (!QDF_IS_STATUS_SUCCESS(vstatus)) {
hdd_err("hdd_roam_deregister_sta() failed for staID %d Status=%d [0x%x]",
sta_id, status, status);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
}
pHddCtx->sta_to_adapter[sta_id] = NULL;
/* Clear all the peer sta register with TL. */
@@ -1096,11 +1096,11 @@ static CDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
sta_id = pHddStaCtx->conn_info.staId[i];
hddLog(LOG1, FL("Deregister StaID %d"), sta_id);
vstatus = hdd_roam_deregister_sta(pAdapter, sta_id);
if (!CDF_IS_STATUS_SUCCESS(vstatus)) {
if (!QDF_IS_STATUS_SUCCESS(vstatus)) {
hddLog(LOGE,
FL("hdd_roamDeregisterSTA() failed to for staID %d. Status= %d [0x%x]"),
sta_id, status, status);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
}
/* set the staid and peer mac as 0, all other
* reset are done in hdd_connRemoveConnectInfo.
@@ -1117,11 +1117,11 @@ static CDF_STATUS hdd_dis_connect_handler(hdd_adapter_t *pAdapter,
* for now, only one.
*/
vstatus = hdd_roam_deregister_sta(pAdapter, sta_id);
if (!CDF_IS_STATUS_SUCCESS(vstatus)) {
if (!QDF_IS_STATUS_SUCCESS(vstatus)) {
hddLog(LOGE,
FL("hdd_roam_deregister_sta() failed to for staID %d. Status= %d [0x%x]"),
sta_id, status, status);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
}
pHddCtx->sta_to_adapter[sta_id] = NULL;
}
@@ -1181,38 +1181,38 @@ void hdd_set_peer_authorized_event(uint32_t vdev_id)
*
* Return: CDF status
*/
CDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
uint8_t sta_id,
enum ol_txrx_peer_state sta_state,
bool roam_synch_in_progress)
{
struct ol_txrx_peer_t *peer;
CDF_STATUS err;
QDF_STATUS err;
struct ol_txrx_pdev_t *pdev = cds_get_context(CDF_MODULE_ID_TXRX);
if (!pdev) {
hdd_err("Failed to get txrx context");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (sta_id >= WLAN_MAX_STA_COUNT) {
hddLog(LOGE, "Invalid sta id :%d", sta_id);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
peer = ol_txrx_peer_find_by_local_id(pdev, sta_id);
if (!peer)
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
err = ol_txrx_peer_state_update(pdev,
(u_int8_t *) peer->mac_addr.raw, sta_state);
if (err != CDF_STATUS_SUCCESS) {
if (err != QDF_STATUS_SUCCESS) {
hddLog(LOGE, "peer state update failed");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
#ifdef WLAN_FEATURE_ROAM_OFFLOAD
if (roam_synch_in_progress)
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
#endif
if (sta_state == ol_txrx_peer_state_auth) {
@@ -1224,9 +1224,9 @@ CDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
err = sme_set_peer_authorized(peer->mac_addr.raw,
hdd_set_peer_authorized_event,
pAdapter->sessionId);
if (err != CDF_STATUS_SUCCESS) {
if (err != QDF_STATUS_SUCCESS) {
hddLog(LOGE, "Failed to set the peer state to authorized");
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (pAdapter->device_mode == WLAN_HDD_INFRA_STATION ||
@@ -1247,7 +1247,7 @@ CDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
#endif
}
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1258,20 +1258,20 @@ CDF_STATUS hdd_change_peer_state(hdd_adapter_t *pAdapter,
* @pPeerMacAddress: peer MAC address
* @pBssDesc: pointer to BSS description
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
static QDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint8_t staId,
struct cdf_mac_addr *pPeerMacAddress,
tSirBssDescription *pBssDesc)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
struct ol_txrx_desc_type staDesc = { 0 };
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
if (NULL == pBssDesc)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* Get the Station ID from the one saved during the association */
staDesc.sta_id = staId;
@@ -1291,13 +1291,13 @@ static CDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
staDesc.is_wapi_supported = 0;
#endif /* FEATURE_WLAN_WAPI */
cdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
qdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
&staDesc);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGW,
"ol_txrx_register_peer() failed to register. Status=%d [0x%08X]",
cdf_status, cdf_status);
return cdf_status;
qdf_status, qdf_status);
return qdf_status;
}
if (!pRoamInfo->fAuthRequired) {
@@ -1305,7 +1305,7 @@ static CDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
* Connections that do not need Upper layer auth, transition
* TLSHIM directly to 'Authenticated' state
*/
cdf_status =
qdf_status =
hdd_change_peer_state(pAdapter, staDesc.sta_id,
ol_txrx_peer_state_auth,
#ifdef WLAN_FEATURE_ROAM_OFFLOAD
@@ -1320,7 +1320,7 @@ static CDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
hddLog(LOG3,
"ULA auth StaId= %d. Changing TL state to CONNECTED at Join time",
pHddStaCtx->conn_info.staId[0]);
cdf_status =
qdf_status =
hdd_change_peer_state(pAdapter, staDesc.sta_id,
ol_txrx_peer_state_conn,
#ifdef WLAN_FEATURE_ROAM_OFFLOAD
@@ -1331,7 +1331,7 @@ static CDF_STATUS hdd_roam_register_sta(hdd_adapter_t *pAdapter,
);
hdd_conn_set_authenticated(pAdapter, false);
}
return cdf_status;
return qdf_status;
}
/**
@@ -1541,9 +1541,9 @@ static int hdd_change_sta_state_authenticated(hdd_adapter_t *adapter,
* @roamStatus: roam status
* @roamResult: roam result
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
static QDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
eRoamCmdStatus roamStatus,
@@ -1551,13 +1551,13 @@ static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
{
eCsrEncryptionType connectedCipherAlgo;
bool fConnected = false;
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
ENTER();
if (NULL == pRoamInfo) {
hddLog(LOG2, FL("pRoamInfo is NULL"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/*
* if (WPA), tell TL to go to 'authenticated' after the keys are set.
@@ -1579,11 +1579,11 @@ static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
pHddStaCtx->roam_info.roamingState =
HDD_ROAM_STATE_NONE;
} else {
cdf_status = hdd_ibss_get_sta_id(
qdf_status = hdd_ibss_get_sta_id(
pHddStaCtx,
&pRoamInfo->peerMac,
&staId);
if (CDF_STATUS_SUCCESS == cdf_status) {
if (QDF_STATUS_SUCCESS == qdf_status) {
hddLog(LOG2,
"WLAN TL STA Ptk Installed for STAID=%d",
staId);
@@ -1623,11 +1623,11 @@ static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
eCSR_ENCRYPT_TYPE_WEP104_STATICKEY)) {
if (pHddStaCtx->conn_info.gtk_installed &&
pHddStaCtx->conn_info.ptk_installed)
cdf_status =
qdf_status =
hdd_change_sta_state_authenticated(pAdapter,
pRoamInfo);
} else if (pHddStaCtx->conn_info.ptk_installed) {
cdf_status =
qdf_status =
hdd_change_sta_state_authenticated(pAdapter,
pRoamInfo);
}
@@ -1650,7 +1650,7 @@ static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
}
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1661,7 +1661,7 @@ static CDF_STATUS hdd_roam_set_key_complete_handler(hdd_adapter_t *pAdapter,
*/
void hdd_perform_roam_set_key_complete(hdd_adapter_t *pAdapter)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_SUCCESS;
QDF_STATUS cdf_ret_status = QDF_STATUS_SUCCESS;
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
tCsrRoamInfo roamInfo;
roamInfo.fAuthRequired = false;
@@ -1676,7 +1676,7 @@ void hdd_perform_roam_set_key_complete(hdd_adapter_t *pAdapter)
pHddStaCtx->roam_info.roamId,
pHddStaCtx->roam_info.roamStatus,
eCSR_ROAM_RESULT_AUTHENTICATED);
if (cdf_ret_status != CDF_STATUS_SUCCESS)
if (cdf_ret_status != QDF_STATUS_SUCCESS)
hddLog(LOGE, FL("Set Key complete failure"));
pHddStaCtx->roam_info.deferKeyComplete = false;
@@ -1690,9 +1690,9 @@ void hdd_perform_roam_set_key_complete(hdd_adapter_t *pAdapter)
* @roamStatus: roam status
* @roamResult: roam result
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
static QDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
eRoamCmdStatus roamStatus,
@@ -1701,7 +1701,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
struct net_device *dev = pAdapter->dev;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
uint8_t reqRsnIe[DOT11F_IE_RSN_MAX_LEN];
uint32_t reqRsnLength = DOT11F_IE_RSN_MAX_LEN;
int ft_carrier_on = false;
@@ -1710,7 +1710,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
if (!pHddCtx) {
hdd_err("HDD context is NULL");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* HDD has initiated disconnect, do not send connect result indication
@@ -1726,7 +1726,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
if (eCSR_ROAM_RESULT_ASSOCIATED == roamResult) {
if (NULL == pRoamInfo) {
hddLog(LOGE, FL("pRoamInfo is NULL"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (!hddDisconInProgress) {
hddLog(LOG1, FL("Set HDD connState to eConnectionState_Associated"));
@@ -1853,7 +1853,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
wlan_hdd_netif_queue_control(pAdapter,
WLAN_NETIF_CARRIER_OFF,
WLAN_CONTROL_PATH);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (pRoamInfo->u.pConnectedProfile->AuthType ==
eCSR_AUTH_TYPE_FT_RSN
@@ -2083,7 +2083,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
/*
* Register the Station with TL after associated
*/
cdf_status = hdd_roam_register_sta(pAdapter,
qdf_status = hdd_roam_register_sta(pAdapter,
pRoamInfo,
pHddStaCtx->
conn_info.
@@ -2107,7 +2107,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
reqRsnIe, reqRsnLength);
/* Reassoc successfully */
if (pRoamInfo->fAuthRequired) {
cdf_status =
qdf_status =
hdd_change_peer_state(pAdapter,
pHddStaCtx->conn_info.staId[0],
ol_txrx_peer_state_conn,
@@ -2122,7 +2122,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
hddLog(LOG2,
FL("staId: %d Changing TL state to AUTHENTICATED"),
pHddStaCtx->conn_info.staId[0]);
cdf_status =
qdf_status =
hdd_change_peer_state(pAdapter,
pHddStaCtx->conn_info.staId[0],
ol_txrx_peer_state_auth,
@@ -2135,7 +2135,7 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
hdd_conn_set_authenticated(pAdapter, true);
}
if (CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (QDF_IS_STATUS_SUCCESS(qdf_status)) {
/*
* Perform any WMM-related association
* processing
@@ -2155,10 +2155,10 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
WLAN_CONTROL_PATH);
}
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE,
"STA register with TL failed. status(=%d) [%08X]",
cdf_status, cdf_status);
qdf_status, qdf_status);
}
#ifdef WLAN_FEATURE_11W
cdf_mem_zero(&pAdapter->hdd_stats.hddPmfStats,
@@ -2293,19 +2293,19 @@ static CDF_STATUS hdd_association_completion_handler(hdd_adapter_t *pAdapter,
WLAN_CONTROL_PATH);
}
if (CDF_STATUS_SUCCESS != cds_check_and_restart_sap(
if (QDF_STATUS_SUCCESS != cds_check_and_restart_sap(
roamResult, pHddStaCtx))
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (NULL != pRoamInfo && NULL != pRoamInfo->pBssDesc) {
cds_force_sap_on_scc(roamResult,
pRoamInfo->pBssDesc->channelId);
} else {
hdd_err("pRoamInfo profile is not set properly");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -2561,9 +2561,9 @@ static bool roam_remove_ibss_station(hdd_adapter_t *pAdapter, uint8_t staId)
*
* We update the status of the IBSS to connected in this function.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS roam_ibss_connect_handler(hdd_adapter_t *pAdapter,
static QDF_STATUS roam_ibss_connect_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo)
{
struct cfg80211_bss *bss;
@@ -2585,13 +2585,13 @@ static CDF_STATUS roam_ibss_connect_handler(hdd_adapter_t *pAdapter,
hddLog(LOGE,
FL("%s: unable to create IBSS entry"),
pAdapter->dev->name);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cfg80211_put_bss(
WLAN_HDD_GET_CTX(pAdapter)->wiphy,
bss);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -2604,9 +2604,9 @@ static CDF_STATUS roam_ibss_connect_handler(hdd_adapter_t *pAdapter,
*
* This function indicates the Mic failure to the supplicant
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
hdd_roam_mic_error_indication_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
@@ -2652,7 +2652,7 @@ hdd_roam_mic_error_indication_handler(hdd_adapter_t *pAdapter,
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -2665,16 +2665,16 @@ hdd_roam_mic_error_indication_handler(hdd_adapter_t *pAdapter,
*
* The Ibss connection status is updated regularly here in this function.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
roam_roam_connect_status_update_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
eRoamCmdStatus roamStatus,
eCsrRoamResult roamResult)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
switch (roamResult) {
@@ -2702,15 +2702,15 @@ roam_roam_connect_status_update_handler(hdd_adapter_t *pAdapter,
pHddCtx->sta_to_adapter[pRoamInfo->staId] = pAdapter;
/* Register the Station with TL for the new peer. */
cdf_status = hdd_roam_register_sta(pAdapter,
qdf_status = hdd_roam_register_sta(pAdapter,
pRoamInfo,
pRoamInfo->staId,
&pRoamInfo->peerMac,
pRoamInfo->pBssDesc);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE,
"Cannot register STA with TL for IBSS. Failed with cdf_status = %d [%08X]",
cdf_status, cdf_status);
"Cannot register STA with TL for IBSS. Failed with qdf_status = %d [%08X]",
qdf_status, qdf_status);
}
pHddStaCtx->ibss_sta_generation++;
memset(&staInfo, 0, sizeof(staInfo));
@@ -2737,18 +2737,18 @@ roam_roam_connect_status_update_handler(hdd_adapter_t *pAdapter,
hddLog(LOG2, "New peer joined set PTK encType=%d",
pHddStaCtx->ibss_enc_key.encType);
cdf_status =
qdf_status =
sme_roam_set_key(WLAN_HDD_GET_HAL_CTX
(pAdapter),
pAdapter->sessionId,
&pHddStaCtx->ibss_enc_key,
&roamId);
if (CDF_STATUS_SUCCESS != cdf_status) {
if (QDF_STATUS_SUCCESS != qdf_status) {
hddLog(LOGE,
FL("sme_roam_set_key failed, status=%d"),
cdf_status);
return CDF_STATUS_E_FAILURE;
qdf_status);
return QDF_STATUS_E_FAILURE;
}
}
hddLog(LOG1, FL("Enabling queues"));
@@ -2814,7 +2814,7 @@ roam_roam_connect_status_update_handler(hdd_adapter_t *pAdapter,
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#ifdef FEATURE_WLAN_TDLS
@@ -2828,13 +2828,13 @@ roam_roam_connect_status_update_handler(hdd_adapter_t *pAdapter,
* Construct the staDesc and register with TL the new STA.
* This is called as part of ADD_STA in the TDLS setup.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
const uint8_t *peerMac, uint16_t staId,
uint8_t ucastSig)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
struct ol_txrx_desc_type staDesc = { 0 };
/*
@@ -2849,15 +2849,15 @@ CDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
/* Register the Station with TL... */
cdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
qdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
&staDesc);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE, FL("ol_txrx_register_peer() failed to register. Status=%d [0x%08X]"),
cdf_status, cdf_status);
return cdf_status;
qdf_status, qdf_status);
return qdf_status;
}
return cdf_status;
return qdf_status;
}
/**
@@ -2865,18 +2865,18 @@ CDF_STATUS hdd_roam_register_tdlssta(hdd_adapter_t *pAdapter,
* @pAdapter: pointer to adapter
* @staId: station identifier
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_roam_deregister_tdlssta(hdd_adapter_t *pAdapter,
static QDF_STATUS hdd_roam_deregister_tdlssta(hdd_adapter_t *pAdapter,
uint8_t staId)
{
CDF_STATUS cdf_status;
cdf_status = ol_txrx_clear_peer(staId);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
QDF_STATUS qdf_status;
qdf_status = ol_txrx_clear_peer(staId);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGW, FL("ol_txrx_clear_peer() failed for staID %d. Status=%d [0x%08X]"),
staId, cdf_status, cdf_status);
staId, qdf_status, qdf_status);
}
return cdf_status;
return qdf_status;
}
/**
@@ -2891,9 +2891,9 @@ static CDF_STATUS hdd_roam_deregister_tdlssta(hdd_adapter_t *pAdapter,
* TL in case of new TDLS client is added and deregistration at the time
* TDLS client is deleted.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
uint32_t roamId,
@@ -2903,7 +2903,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
tdlsCtx_t *pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
tSmeTdlsPeerStateParams smeTdlsPeerStateParams;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
uint8_t staIdx;
hddTdlsPeer_t *curr_peer;
uint32_t reason;
@@ -2978,7 +2978,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
peerMac,
&pRoamInfo->
peerMac);
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
break;
}
}
@@ -2991,7 +2991,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
staId)) {
hddLog(LOGE,
"wlan_hdd_tdls_set_sta_id() failed");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
(WLAN_HDD_GET_CTX(pAdapter))->
@@ -3008,7 +3008,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pRoamInfo->
ucastSig);
} else {
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
hddLog(LOGE,
FL("no available slot in conn_info. staId %d cannot be stored"),
pRoamInfo->staId);
@@ -3078,7 +3078,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
tdlsConnInfo[staIdx].
peerMac,
CDF_MAC_ADDR_SIZE);
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
break;
}
}
@@ -3096,7 +3096,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pRoamInfo->peerMac.bytes, true);
wlan_hdd_tdls_indicate_teardown(pAdapter, curr_peer,
pRoamInfo->reasonCode);
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
break;
}
case eCSR_ROAM_RESULT_DELETE_ALL_TDLS_PEER_IND:
@@ -3156,7 +3156,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
sme_update_tdls_peer_state(
pHddCtx->hHal,
&smeTdlsPeerStateParams);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE,
FL("sme_update_tdls_peer_state failed for "
MAC_ADDRESS_STR),
@@ -3176,7 +3176,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pHddCtx->tdlsConnInfo[staIdx].
sessionId = 255;
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
}
break;
@@ -3190,7 +3190,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
FL("concurrency detected. ignore SHOULD_DISCOVER concurrency_mode: 0x%x, active_sessions: %d"),
pHddCtx->concurrency_mode,
pHddCtx->no_of_active_sessions[CDF_STA_MODE]);
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
break;
}
@@ -3199,7 +3199,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pRoamInfo->peerMac.bytes);
if (!curr_peer) {
hddLog(LOGE, FL("curr_peer is null"));
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
} else {
if (eTDLS_LINK_CONNECTED ==
curr_peer->link_status) {
@@ -3218,7 +3218,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
hddLog(LOG2,
FL
("TDLS ExternalControl enabled but curr_peer is not forced, ignore SHOULD_DISCOVER"));
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
break;
} else {
hddLog(LOG2,
@@ -3232,7 +3232,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
wlan_hdd_tdls_pre_setup_init_work
(pHddTdlsCtx, curr_peer);
}
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
break;
}
@@ -3244,7 +3244,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pRoamInfo->peerMac.bytes, true);
if (!curr_peer) {
hddLog(LOGE, FL("curr_peer is null"));
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
} else {
if (eTDLS_LINK_CONNECTED ==
curr_peer->link_status) {
@@ -3281,7 +3281,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
("TDLS link is not connected, ignore SHOULD_TEARDOWN, reason: %d"),
pRoamInfo->reasonCode);
}
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
break;
}
@@ -3293,7 +3293,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
pRoamInfo->peerMac.bytes, true);
if (!curr_peer) {
hddLog(LOGE, FL("curr_peer is null"));
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
} else {
if (eTDLS_LINK_CONNECTED ==
curr_peer->link_status) {
@@ -3329,7 +3329,7 @@ hdd_roam_tdls_status_update_handler(hdd_adapter_t *pAdapter,
("TDLS link is not connected, ignore SHOULD_PEER_DISCONNECTED, reason: %d"),
pRoamInfo->reasonCode);
}
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
break;
}
@@ -3835,17 +3835,17 @@ static inline bool hdd_is_8021x_sha256_auth_type(hdd_station_ctx_t *pHddStaCtx)
* @roamStatus: roam status
* @roamResult: roam result
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS
QDF_STATUS
hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo, uint32_t roamId,
eRoamCmdStatus roamStatus, eCsrRoamResult roamResult)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_SUCCESS;
QDF_STATUS cdf_ret_status = QDF_STATUS_SUCCESS;
hdd_adapter_t *pAdapter = (hdd_adapter_t *) pContext;
hdd_wext_state_t *pWextState = NULL;
hdd_station_ctx_t *pHddStaCtx = NULL;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_context_t *pHddCtx = NULL;
hddLog(LOG2,
@@ -3855,7 +3855,7 @@ hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo, uint32_t roamId,
/* Sanity check */
if ((NULL == pAdapter) || (WLAN_HDD_ADAPTER_MAGIC != pAdapter->magic)) {
hddLog(LOGP, "invalid adapter or adapter has invalid magic");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pWextState = WLAN_HDD_GET_WEXT_STATE_PTR(pAdapter);
@@ -3916,8 +3916,8 @@ hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo, uint32_t roamId,
WLAN_CONTROL_PATH);
status = hdd_roam_deregister_sta(pAdapter,
pHddStaCtx->conn_info.staId[0]);
if (!CDF_IS_STATUS_SUCCESS(status))
cdf_ret_status = CDF_STATUS_E_FAILURE;
if (!QDF_IS_STATUS_SUCCESS(status))
cdf_ret_status = QDF_STATUS_E_FAILURE;
pHddStaCtx->ft_carrier_on = true;
pHddStaCtx->hdd_ReassocScenario = true;
hddLog(LOG1,
@@ -4075,39 +4075,39 @@ hdd_sme_roam_callback(void *pContext, tCsrRoamInfo *pRoamInfo, uint32_t roamId,
#ifdef FEATURE_WLAN_LFR_METRICS
case eCSR_ROAM_PREAUTH_INIT_NOTIFY:
/* This event is to notify pre-auth initiation */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_cfg80211_roam_metrics_preauth(pAdapter,
pRoamInfo)) {
cdf_ret_status = CDF_STATUS_E_FAILURE;
cdf_ret_status = QDF_STATUS_E_FAILURE;
}
break;
case eCSR_ROAM_PREAUTH_STATUS_SUCCESS:
/*
* This event will notify pre-auth completion in case of success
*/
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_cfg80211_roam_metrics_preauth_status(pAdapter,
pRoamInfo, 1)) {
cdf_ret_status = CDF_STATUS_E_FAILURE;
cdf_ret_status = QDF_STATUS_E_FAILURE;
}
break;
case eCSR_ROAM_PREAUTH_STATUS_FAILURE:
/*
* This event will notify pre-auth completion incase of failure.
*/
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_cfg80211_roam_metrics_preauth_status(pAdapter,
pRoamInfo, 0)) {
cdf_ret_status = CDF_STATUS_E_FAILURE;
cdf_ret_status = QDF_STATUS_E_FAILURE;
}
break;
case eCSR_ROAM_HANDOVER_SUCCESS:
/* This event is to notify handover success.
It will be only invoked on success */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_cfg80211_roam_metrics_handover(pAdapter,
pRoamInfo)) {
cdf_ret_status = CDF_STATUS_E_FAILURE;
cdf_ret_status = QDF_STATUS_E_FAILURE;
}
break;
#endif
@@ -4321,7 +4321,7 @@ static int32_t hdd_process_genie(hdd_adapter_t *pAdapter,
uint16_t gen_ie_len, uint8_t *gen_ie)
{
tHalHandle halHandle = WLAN_HDD_GET_HAL_CTX(pAdapter);
CDF_STATUS result;
QDF_STATUS result;
tDot11fIERSN dot11RSNIE;
tDot11fIEWPA dot11WPAIE;
uint32_t i;
@@ -4723,14 +4723,14 @@ static int __iw_set_essid(struct net_device *dev,
if (hdd_conn_get_connected_bss_type(pHddStaCtx, &connectedBssType) ||
(eMib_dot11DesiredBssType_independent ==
pHddStaCtx->conn_info.connDot11DesiredBssType)) {
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
/* Need to issue a disconnect to CSR. */
INIT_COMPLETION(pAdapter->disconnect_comp_var);
cdf_status = sme_roam_disconnect(hHal, pAdapter->sessionId,
qdf_status = sme_roam_disconnect(hHal, pAdapter->sessionId,
eCSR_DISCONNECT_REASON_UNSPECIFIED);
if (CDF_STATUS_SUCCESS == cdf_status) {
if (QDF_STATUS_SUCCESS == qdf_status) {
rc = wait_for_completion_timeout(&pAdapter->
disconnect_comp_var,
msecs_to_jiffies
@@ -4751,7 +4751,7 @@ static int __iw_set_essid(struct net_device *dev,
status = hdd_wmm_get_uapsd_mask(pAdapter,
&pWextState->roamProfile.uapsd_mask);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
pWextState->roamProfile.uapsd_mask = 0;
pWextState->roamProfile.SSIDs.numOfSSIDs = 1;

344
core/hdd/src/wlan_hdd_cfg.c
Fájl megtekintése

A különbségek nem kerülnek megjelenítésre, mivel a fájl túl nagy Load Diff

213
core/hdd/src/wlan_hdd_cfg80211.c
Fájl megtekintése

@@ -1529,7 +1529,7 @@ static int __wlan_hdd_cfg80211_do_acs(struct wiphy *wiphy,
status = cds_get_pcl(CDS_SAP_MODE,
sap_config->acs_cfg.pcl_channels,
&sap_config->acs_cfg.pcl_ch_count);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
hddLog(LOGE, FL("Get PCL failed"));
wlan_hdd_set_acs_ch_range(sap_config, ht_enabled, vht_enabled);
@@ -1938,7 +1938,7 @@ __wlan_hdd_cfg80211_set_scanning_mac_oui(struct wiphy *wiphy,
tpSirScanMacOui pReqMsg = NULL;
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_SET_SCANNING_MAC_OUI_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
int ret;
ENTER();
@@ -1977,7 +1977,7 @@ __wlan_hdd_cfg80211_set_scanning_mac_oui(struct wiphy *wiphy,
hddLog(LOG1, FL("Oui (%02x:%02x:%02x)"), pReqMsg->oui[0],
pReqMsg->oui[1], pReqMsg->oui[2]);
status = sme_set_scanning_mac_oui(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("sme_set_scanning_mac_oui failed(err=%d)"), status);
goto fail;
@@ -2058,7 +2058,7 @@ __wlan_hdd_cfg80211_get_features(struct wiphy *wiphy,
struct sk_buff *skb = NULL;
uint32_t dbs_capability = 0;
bool one_by_one_dbs, two_by_two_dbs;
CDF_STATUS ret = CDF_STATUS_E_FAILURE;
QDF_STATUS ret = QDF_STATUS_E_FAILURE;
int ret_val;
uint8_t feature_flags[(NUM_QCA_WLAN_VENDOR_FEATURES + 7) / 8] = {0};
@@ -2097,7 +2097,7 @@ __wlan_hdd_cfg80211_get_features(struct wiphy *wiphy,
goto nla_put_failure;
ret = wma_get_dbs_hw_modes(&one_by_one_dbs, &two_by_two_dbs);
if (CDF_STATUS_SUCCESS == ret) {
if (QDF_STATUS_SUCCESS == ret) {
if (one_by_one_dbs)
dbs_capability = DRV_DBS_CAPABILITY_1X1;
@@ -2483,13 +2483,13 @@ static bool wlan_hdd_check_dfs_channel_for_adapter(hdd_context_t *hdd_ctx,
hdd_adapter_list_node_t *adapter_node = NULL, *next = NULL;
hdd_ap_ctx_t *ap_ctx;
hdd_station_ctx_t *sta_ctx;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
cdf_status = hdd_get_front_adapter(hdd_ctx,
qdf_status = hdd_get_front_adapter(hdd_ctx,
&adapter_node);
while ((NULL != adapter_node) &&
(CDF_STATUS_SUCCESS == cdf_status)) {
(QDF_STATUS_SUCCESS == qdf_status)) {
adapter = adapter_node->pAdapter;
if ((device_mode == adapter->device_mode) &&
@@ -2532,7 +2532,7 @@ static bool wlan_hdd_check_dfs_channel_for_adapter(hdd_context_t *hdd_ctx,
}
}
cdf_status = hdd_get_next_adapter(hdd_ctx,
qdf_status = hdd_get_next_adapter(hdd_ctx,
adapter_node,
&next);
adapter_node = next;
@@ -2559,7 +2559,7 @@ int wlan_hdd_disable_dfs_chan_scan(hdd_context_t *hdd_ctx,
uint32_t no_dfs_flag)
{
tHalHandle h_hal = WLAN_HDD_GET_HAL_CTX(adapter);
CDF_STATUS status;
QDF_STATUS status;
int ret_val = -EPERM;
if (no_dfs_flag == hdd_ctx->config->enableDFSChnlScan) {
@@ -2588,7 +2588,7 @@ int wlan_hdd_disable_dfs_chan_scan(hdd_context_t *hdd_ctx,
status = sme_handle_dfs_chan_scan(
h_hal, hdd_ctx->config->enableDFSChnlScan);
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
ret_val = 0;
/*
@@ -2598,7 +2598,7 @@ int wlan_hdd_disable_dfs_chan_scan(hdd_context_t *hdd_ctx,
* all sessions
*/
status = sme_scan_flush_result(h_hal);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
ret_val = -EPERM;
}
@@ -3135,7 +3135,7 @@ __wlan_hdd_cfg80211_wifi_configuration_set(struct wiphy *wiphy,
u32 modulated_dtim;
u16 stats_avg_factor;
u32 guard_time;
CDF_STATUS status;
QDF_STATUS status;
if (CDF_GLOBAL_FTM_MODE == hdd_get_conparam()) {
hdd_err("Command not allowed in FTM mode");
@@ -3163,7 +3163,7 @@ __wlan_hdd_cfg80211_wifi_configuration_set(struct wiphy *wiphy,
adapter->sessionId,
modulated_dtim);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
ret_val = -EPERM;
}
@@ -3174,7 +3174,7 @@ __wlan_hdd_cfg80211_wifi_configuration_set(struct wiphy *wiphy,
adapter->sessionId,
stats_avg_factor);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
ret_val = -EPERM;
}
@@ -3186,7 +3186,7 @@ __wlan_hdd_cfg80211_wifi_configuration_set(struct wiphy *wiphy,
adapter->sessionId,
guard_time);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
ret_val = -EPERM;
}
@@ -3251,7 +3251,7 @@ static int __wlan_hdd_cfg80211_wifi_logger_start(struct wiphy *wiphy,
const void *data,
int data_len)
{
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_WIFI_LOGGER_START_MAX + 1];
struct sir_wifi_start_log start_log;
@@ -3313,7 +3313,7 @@ static int __wlan_hdd_cfg80211_wifi_logger_start(struct wiphy *wiphy,
}
status = sme_wifi_start_logger(hdd_ctx->hHal, start_log);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("sme_wifi_start_logger failed(err=%d)"),
status);
return -EINVAL;
@@ -3374,7 +3374,7 @@ static int __wlan_hdd_cfg80211_wifi_logger_get_ring_data(struct wiphy *wiphy,
const void *data,
int data_len)
{
CDF_STATUS status;
QDF_STATUS status;
uint32_t ring_id;
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb
@@ -3417,7 +3417,7 @@ static int __wlan_hdd_cfg80211_wifi_logger_get_ring_data(struct wiphy *wiphy,
status = cds_flush_logs(WLAN_LOG_TYPE_NON_FATAL,
WLAN_LOG_INDICATOR_FRAMEWORK,
WLAN_LOG_REASON_CODE_UNUSED);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("Failed to trigger bug report"));
return -EINVAL;
}
@@ -3553,7 +3553,7 @@ wlan_hdd_add_tx_ptrn(hdd_adapter_t *adapter, hdd_context_t *hdd_ctx,
struct nlattr **tb)
{
struct sSirAddPeriodicTxPtrn *add_req;
CDF_STATUS status;
QDF_STATUS status;
uint32_t request_id, ret, len;
uint8_t pattern_id = 0;
struct cdf_mac_addr dst_addr;
@@ -3661,7 +3661,7 @@ wlan_hdd_add_tx_ptrn(hdd_adapter_t *adapter, hdd_context_t *hdd_ctx,
hddLog(LOG1, FL("pattern id: %d"), add_req->ucPtrnId);
status = sme_add_periodic_tx_ptrn(hdd_ctx->hHal, add_req);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_add_periodic_tx_ptrn failed (err=%d)"), status);
goto fail;
@@ -3691,7 +3691,7 @@ wlan_hdd_del_tx_ptrn(hdd_adapter_t *adapter, hdd_context_t *hdd_ctx,
struct nlattr **tb)
{
struct sSirDelPeriodicTxPtrn *del_req;
CDF_STATUS status;
QDF_STATUS status;
uint32_t request_id, ret;
uint8_t pattern_id = 0;
@@ -3725,7 +3725,7 @@ wlan_hdd_del_tx_ptrn(hdd_adapter_t *adapter, hdd_context_t *hdd_ctx,
request_id, del_req->ucPtrnId);
status = sme_del_periodic_tx_ptrn(hdd_ctx->hHal, del_req);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_del_periodic_tx_ptrn failed (err=%d)"), status);
goto fail;
@@ -3878,7 +3878,7 @@ __wlan_hdd_cfg80211_monitor_rssi(struct wiphy *wiphy,
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[PARAM_MAX + 1];
struct rssi_monitor_req req;
CDF_STATUS status;
QDF_STATUS status;
int ret;
uint32_t control;
static const struct nla_policy policy[PARAM_MAX + 1] = {
@@ -3951,7 +3951,7 @@ __wlan_hdd_cfg80211_monitor_rssi(struct wiphy *wiphy,
req.request_id, req.session_id, req.control);
status = sme_set_rssi_monitoring(hdd_ctx->hHal, &req);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_set_rssi_monitoring failed(err=%d)"), status);
return -EINVAL;
@@ -4069,7 +4069,7 @@ static int __wlan_hdd_cfg80211_get_preferred_freq_list(struct wiphy *wiphy,
{
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
int i, ret = 0;
CDF_STATUS status;
QDF_STATUS status;
uint8_t pcl[MAX_NUM_CHAN];
uint32_t pcl_len = 0;
uint32_t freq_list[MAX_NUM_CHAN];
@@ -4103,7 +4103,7 @@ static int __wlan_hdd_cfg80211_get_preferred_freq_list(struct wiphy *wiphy,
hdd_debug("Userspace requested pref freq list");
status = cds_get_pcl(intf_mode, pcl, &pcl_len);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hdd_err("Get pcl failed");
return -EINVAL;
}
@@ -4234,19 +4234,19 @@ static int __wlan_hdd_cfg80211_set_probable_oper_channel(struct wiphy *wiphy,
if (hdd_ctx->config->policy_manager_enabled) {
ret = cdf_reset_connection_update();
if (!CDF_IS_STATUS_SUCCESS(ret))
if (!QDF_IS_STATUS_SUCCESS(ret))
hdd_err("clearing event failed");
ret = cds_current_connections_update(adapter->sessionId,
channel_hint,
CDS_UPDATE_REASON_SET_OPER_CHAN);
if (CDF_STATUS_E_FAILURE == ret) {
if (QDF_STATUS_E_FAILURE == ret) {
/* return in the failure case */
hdd_err("ERROR: connections update failed!!");
return -EINVAL;
}
if (CDF_STATUS_SUCCESS == ret) {
if (QDF_STATUS_SUCCESS == ret) {
/*
* Success is the only case for which we expect hw mode
* change to take place, hence we need to wait.
@@ -4254,7 +4254,7 @@ static int __wlan_hdd_cfg80211_set_probable_oper_channel(struct wiphy *wiphy,
* through
*/
ret = cdf_wait_for_connection_update();
if (!CDF_IS_STATUS_SUCCESS(ret)) {
if (!QDF_IS_STATUS_SUCCESS(ret)) {
hdd_err("ERROR: cdf wait for event failed!!");
return -EINVAL;
}
@@ -4507,7 +4507,7 @@ static int __wlan_hdd_cfg80211_set_ota_test(struct wiphy *wiphy,
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_OTA_TEST_MAX + 1];
uint8_t ota_enable = 0;
CDF_STATUS status;
QDF_STATUS status;
uint32_t current_roam_state;
if (CDF_GLOBAL_FTM_MODE == hdd_get_conparam()) {
@@ -4543,14 +4543,14 @@ static int __wlan_hdd_cfg80211_set_ota_test(struct wiphy *wiphy,
sme_get_current_roam_state(hal, adapter->sessionId);
status = sme_stop_roaming(hal, adapter->sessionId,
eCsrHddIssued);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hdd_err("Enable/Disable roaming failed");
return -EINVAL;
}
status = sme_ps_enable_disable(hal, adapter->sessionId,
SME_PS_DISABLE);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hdd_err("Enable/Disable power save failed");
/* restore previous roaming setting */
if (current_roam_state == eCSR_ROAMING_STATE_JOINING ||
@@ -4562,7 +4562,7 @@ static int __wlan_hdd_cfg80211_set_ota_test(struct wiphy *wiphy,
status = sme_stop_roaming(hal, adapter->sessionId,
eCsrHddIssued);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
hdd_err("Restoring roaming state failed");
return -EINVAL;
@@ -5743,7 +5743,7 @@ uint8_t *wlan_hdd_cfg80211_get_ie_ptr(const uint8_t *ies_ptr, int length,
* This function validates whether given channel is part of valid
* channel list.
*/
CDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
int channel)
{
@@ -5767,7 +5767,7 @@ CDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
if (fValidChannel != true) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Invalid Channel [%d]", __func__, channel);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
} else {
if (0 != sme_cfg_get_str(hHal, WNI_CFG_VALID_CHANNEL_LIST,
@@ -5775,7 +5775,7 @@ CDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: failed to get valid channel list",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
for (indx = 0; indx < num_ch; indx++) {
if (channel == valid_ch[indx]) {
@@ -5786,10 +5786,10 @@ CDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
if (indx >= num_ch) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Invalid Channel [%d]", __func__, channel);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
@@ -5836,7 +5836,7 @@ static void wlan_hdd_set_dhcp_server_offload(hdd_adapter_t *pHostapdAdapter)
temp = srv_ip[num];
pDhcpSrvInfo->dhcpSrvIP |= (temp << (8 * num));
}
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_dhcp_srv_offload(pHddCtx->hHal, pDhcpSrvInfo)) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: sme_setDHCPSrvOffload fail!", __func__);
@@ -5857,7 +5857,7 @@ static int __wlan_hdd_cfg80211_change_bss(struct wiphy *wiphy,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
int ret = 0;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
ENTER();
@@ -5894,7 +5894,7 @@ static int __wlan_hdd_cfg80211_change_bss(struct wiphy *wiphy,
pAdapter->sessionCtx.
ap.
apDisableIntraBssFwd);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
ret = -EINVAL;
}
}
@@ -5929,7 +5929,7 @@ static int wlan_hdd_change_iface_to_sta_mode(struct net_device *ndev,
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
hdd_wext_state_t *wext;
struct wireless_dev *wdev;
CDF_STATUS status;
QDF_STATUS status;
ENTER();
@@ -6011,7 +6011,7 @@ static int __wlan_hdd_cfg80211_change_iface(struct wiphy *wiphy,
struct hdd_config *pConfig = NULL;
eMib_dot11DesiredBssType connectedBssType;
unsigned long rc;
CDF_STATUS vstatus;
QDF_STATUS vstatus;
int status;
ENTER();
@@ -6063,7 +6063,7 @@ static int __wlan_hdd_cfg80211_change_iface(struct wiphy *wiphy,
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_P2P_CLIENT:
vstatus = wlan_hdd_change_iface_to_sta_mode(ndev, type);
if (vstatus != CDF_STATUS_SUCCESS)
if (vstatus != QDF_STATUS_SUCCESS)
return -EINVAL;
hdd_register_tx_flow_control(pAdapter,
@@ -6129,7 +6129,7 @@ static int __wlan_hdd_cfg80211_change_iface(struct wiphy *wiphy,
hdd_set_ap_ops(pAdapter->dev);
vstatus = hdd_init_ap_mode(pAdapter);
if (vstatus != CDF_STATUS_SUCCESS) {
if (vstatus != QDF_STATUS_SUCCESS) {
hddLog(LOGP,
FL
("Error initializing the ap mode"));
@@ -6163,7 +6163,7 @@ static int __wlan_hdd_cfg80211_change_iface(struct wiphy *wiphy,
case NL80211_IFTYPE_P2P_CLIENT:
case NL80211_IFTYPE_ADHOC:
status = wlan_hdd_change_iface_to_sta_mode(ndev, type);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
return status;
if ((NL80211_IFTYPE_P2P_CLIENT == type) ||
@@ -6208,7 +6208,7 @@ static int __wlan_hdd_cfg80211_change_iface(struct wiphy *wiphy,
|| (eCSR_BSS_TYPE_START_IBSS == LastBSSType)) {
/* Need to issue a disconnect to CSR. */
INIT_COMPLETION(pAdapter->disconnect_comp_var);
if (CDF_STATUS_SUCCESS ==
if (QDF_STATUS_SUCCESS ==
sme_roam_disconnect(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId,
eCSR_DISCONNECT_REASON_UNSPECIFIED)) {
@@ -6297,7 +6297,7 @@ static int __wlan_hdd_change_station(struct wiphy *wiphy,
struct station_parameters *params)
#endif
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx;
hdd_station_ctx_t *pHddStaCtx;
@@ -6337,7 +6337,7 @@ static int __wlan_hdd_change_station(struct wiphy *wiphy,
&STAMacAddress,
ol_txrx_peer_state_auth);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_INFO,
FL
("Not able to change TL state to AUTHENTICATED"));
@@ -6514,7 +6514,7 @@ static int __wlan_hdd_change_station(struct wiphy *wiphy,
&StaParams,
isBufSta,
isOffChannelSupported);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL
("wlan_hdd_tdls_set_peer_caps failed!"));
@@ -6524,7 +6524,7 @@ static int __wlan_hdd_change_station(struct wiphy *wiphy,
status =
wlan_hdd_tdls_add_station(wiphy, dev, mac, 1,
&StaParams);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("wlan_hdd_tdls_add_station failed!"));
return -EINVAL;
@@ -6588,7 +6588,7 @@ static int __wlan_hdd_cfg80211_add_key(struct wiphy *wiphy,
v_CONTEXT_t p_cds_context = (WLAN_HDD_GET_CTX(pAdapter))->pcds_context;
#endif
hdd_hostapd_state_t *pHostapdState;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
hdd_context_t *pHddCtx;
hdd_ap_ctx_t *ap_ctx = WLAN_HDD_GET_AP_CTX_PTR(pAdapter);
@@ -6771,7 +6771,7 @@ static int __wlan_hdd_cfg80211_add_key(struct wiphy *wiphy,
#else
status = wlansap_set_key_sta(p_cds_context, &setKey);
#endif
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"[%4d] wlansap_set_key_sta returned ERROR status= %d",
@@ -6828,11 +6828,11 @@ static int __wlan_hdd_cfg80211_add_key(struct wiphy *wiphy,
request */
cdf_ret_status = sme_ft_update_key(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &setKey);
if (cdf_ret_status == CDF_STATUS_FT_PREAUTH_KEY_SUCCESS) {
if (cdf_ret_status == QDF_STATUS_FT_PREAUTH_KEY_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_INFO_MED,
"%s: Update PreAuth Key success", __func__);
return 0;
} else if (cdf_ret_status == CDF_STATUS_FT_PREAUTH_KEY_FAILED) {
} else if (cdf_ret_status == QDF_STATUS_FT_PREAUTH_KEY_FAILED) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Update PreAuth Key failed", __func__);
return -EINVAL;
@@ -7486,7 +7486,7 @@ int wlan_hdd_cfg80211_update_bss(struct wiphy *wiphy,
{
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
tCsrScanResultInfo *pScanResult;
CDF_STATUS status = 0;
QDF_STATUS status = 0;
tScanResultHandle pResult;
struct cfg80211_bss *bss_status = NULL;
hdd_context_t *pHddCtx;
@@ -7615,7 +7615,7 @@ int wlan_hdd_cfg80211_pmksa_candidate_notify(hdd_adapter_t *pAdapter,
* Return: CDF status
*/
#define MAX_LFR_METRICS_EVENT_LENGTH 100
CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo)
{
unsigned char metrics_notification[MAX_LFR_METRICS_EVENT_LENGTH + 1];
@@ -7625,7 +7625,7 @@ CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
if (NULL == pAdapter) {
hddLog(LOGE, FL("pAdapter is NULL!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* create the event */
@@ -7643,7 +7643,7 @@ CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -7656,7 +7656,7 @@ CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
*
* Return: CDF status
*/
CDF_STATUS
QDF_STATUS
wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo,
bool preauth_status)
@@ -7668,7 +7668,7 @@ wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *pAdapter,
if (NULL == pAdapter) {
hddLog(LOGE, FL("pAdapter is NULL!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* create the event */
@@ -7694,7 +7694,7 @@ wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *pAdapter,
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -7706,7 +7706,7 @@ wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *pAdapter,
*
* Return: CDF status
*/
CDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo)
{
unsigned char metrics_notification[MAX_LFR_METRICS_EVENT_LENGTH + 1];
@@ -7716,7 +7716,7 @@ CDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
if (NULL == pAdapter) {
hddLog(LOGE, FL("pAdapter is NULL!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* create the event */
@@ -7735,7 +7735,7 @@ CDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -7957,7 +7957,7 @@ int wlan_hdd_cfg80211_connect_start(hdd_adapter_t *pAdapter,
*/
status = hdd_set_ibss_power_save_params(pAdapter);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE,
FL("Set IBSS Power Save Params Failed"));
return -EINVAL;
@@ -8034,7 +8034,7 @@ int wlan_hdd_cfg80211_connect_start(hdd_adapter_t *pAdapter,
pAdapter->sessionId, pRoamProfile,
&roamId);
if ((CDF_STATUS_SUCCESS != status) &&
if ((QDF_STATUS_SUCCESS != status) &&
(WLAN_HDD_INFRA_STATION == pAdapter->device_mode ||
WLAN_HDD_P2P_CLIENT == pAdapter->device_mode)) {
hddLog(LOGE,
@@ -8757,7 +8757,7 @@ static int wlan_hdd_try_disconnect(hdd_adapter_t *pAdapter)
* ssid and the previous connect command in CSR. Else we might
* hit some race conditions leading to SME and HDD out of sync.
*/
if (CDF_STATUS_CMD_NOT_QUEUED == status) {
if (QDF_STATUS_CMD_NOT_QUEUED == status) {
hdd_info("Already disconnected or connect was in sme/roam pending list and removed by disconnect");
} else if (0 != status) {
hdd_err("csrRoamDisconnect failure, returned %d",
@@ -8770,7 +8770,7 @@ static int wlan_hdd_try_disconnect(hdd_adapter_t *pAdapter)
rc = wait_for_completion_timeout(
&pAdapter->disconnect_comp_var,
msecs_to_jiffies(WLAN_WAIT_TIME_DISCONNECT));
if (!rc && (CDF_STATUS_CMD_NOT_QUEUED != status)) {
if (!rc && (QDF_STATUS_CMD_NOT_QUEUED != status)) {
hdd_err("Sme disconnect event timed out session Id %d staDebugState %d",
pAdapter->sessionId, pHddStaCtx->staDebugState);
result = -ETIMEDOUT;
@@ -8958,7 +8958,7 @@ int wlan_hdd_disconnect(hdd_adapter_t *pAdapter, u16 reason)
* the previous connect command in CSR. Else we might hit some
* race conditions leading to SME and HDD out of sync.
*/
if (CDF_STATUS_CMD_NOT_QUEUED == status) {
if (QDF_STATUS_CMD_NOT_QUEUED == status) {
hdd_info("Already disconnected or connect was in sme/roam pending list and removed by disconnect");
} else if (0 != status) {
hddLog(LOGE,
@@ -8972,7 +8972,7 @@ int wlan_hdd_disconnect(hdd_adapter_t *pAdapter, u16 reason)
msecs_to_jiffies
(WLAN_WAIT_TIME_DISCONNECT));
if (!rc && (CDF_STATUS_CMD_NOT_QUEUED != status)) {
if (!rc && (QDF_STATUS_CMD_NOT_QUEUED != status)) {
hddLog(LOGE,
FL("Failed to disconnect, timed out"));
result = -ETIMEDOUT;
@@ -9370,20 +9370,20 @@ static int __wlan_hdd_cfg80211_join_ibss(struct wiphy *wiphy,
}
if (pHddCtx->config->policy_manager_enabled) {
status = cdf_reset_connection_update();
if (!CDF_IS_STATUS_SUCCESS(status))
if (!QDF_IS_STATUS_SUCCESS(status))
hdd_err("ERR: clear event failed");
status = cds_current_connections_update(pAdapter->sessionId,
channelNum,
CDS_UPDATE_REASON_JOIN_IBSS);
if (CDF_STATUS_E_FAILURE == status) {
if (QDF_STATUS_E_FAILURE == status) {
hdd_err("ERROR: connections update failed!!");
return -EINVAL;
}
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
status = cdf_wait_for_connection_update();
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hdd_err("ERROR: cdf wait for event failed!!");
return -EINVAL;
}
@@ -9409,7 +9409,7 @@ static int __wlan_hdd_cfg80211_join_ibss(struct wiphy *wiphy,
/* enable selected protection checks in IBSS mode */
pRoamProfile->cfg_protection = IBSS_CFG_PROTECTION_ENABLE_MASK;
if (CDF_STATUS_E_FAILURE == sme_cfg_set_int(pHddCtx->hHal,
if (QDF_STATUS_E_FAILURE == sme_cfg_set_int(pHddCtx->hHal,
WNI_CFG_IBSS_ATIM_WIN_SIZE,
pHddCtx->config->
ibssATIMWinSize)) {
@@ -9420,7 +9420,7 @@ static int __wlan_hdd_cfg80211_join_ibss(struct wiphy *wiphy,
/* BSSID is provided by upper layers hence no need to AUTO generate */
if (NULL != params->bssid) {
if (sme_cfg_set_int(pHddCtx->hHal, WNI_CFG_IBSS_AUTO_BSSID, 0)
== CDF_STATUS_E_FAILURE) {
== QDF_STATUS_E_FAILURE) {
hddLog(LOGE,
FL("ccmCfgStInt failed for WNI_CFG_IBSS_AUTO_BSSID"));
return -EIO;
@@ -9428,7 +9428,7 @@ static int __wlan_hdd_cfg80211_join_ibss(struct wiphy *wiphy,
cdf_mem_copy(bssid.bytes, params->bssid, CDF_MAC_ADDR_SIZE);
} else if (pHddCtx->config->isCoalesingInIBSSAllowed == 0) {
if (sme_cfg_set_int(pHddCtx->hHal, WNI_CFG_IBSS_AUTO_BSSID, 0)
== CDF_STATUS_E_FAILURE) {
== QDF_STATUS_E_FAILURE) {
hddLog(LOGE,
FL("ccmCfgStInt failed for WNI_CFG_IBSS_AUTO_BSSID"));
return -EIO;
@@ -9519,7 +9519,7 @@ static int __wlan_hdd_cfg80211_leave_ibss(struct wiphy *wiphy,
tCsrRoamProfile *pRoamProfile;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
int status;
CDF_STATUS hal_status;
QDF_STATUS hal_status;
unsigned long rc;
ENTER();
@@ -9559,7 +9559,7 @@ static int __wlan_hdd_cfg80211_leave_ibss(struct wiphy *wiphy,
hal_status = sme_roam_disconnect(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId,
eCSR_DISCONNECT_REASON_IBSS_LEAVE);
if (!CDF_IS_STATUS_SUCCESS(hal_status)) {
if (!QDF_IS_STATUS_SUCCESS(hal_status)) {
hddLog(LOGE,
FL("sme_roam_disconnect failed hal_status(%d)"),
hal_status);
@@ -9829,7 +9829,6 @@ int __wlan_hdd_cfg80211_del_station(struct wiphy *wiphy,
{
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx;
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
hdd_hostapd_state_t *hapd_state;
int status;
@@ -9895,10 +9894,10 @@ int __wlan_hdd_cfg80211_del_station(struct wiphy *wiphy,
qdf_event_reset(&hapd_state->cdf_event);
hdd_softap_sta_disassoc(pAdapter,
mac);
cdf_status =
qdf_status =
hdd_softap_sta_deauth(pAdapter,
pDelStaParams);
if (CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (QDF_IS_STATUS_SUCCESS(qdf_status)) {
pAdapter->aStaInfo[i].
isDeauthInProgress = true;
qdf_status =
@@ -9914,11 +9913,11 @@ int __wlan_hdd_cfg80211_del_station(struct wiphy *wiphy,
}
}
} else {
cdf_status =
qdf_status =
hdd_softap_get_sta_id(pAdapter,
(struct cdf_mac_addr *) mac,
&staId);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOG1,
FL("Skip DEL STA as this is not used::"
MAC_ADDRESS_STR),
@@ -9958,9 +9957,9 @@ int __wlan_hdd_cfg80211_del_station(struct wiphy *wiphy,
qdf_event_reset(&hapd_state->cdf_event);
hdd_softap_sta_disassoc(pAdapter, mac);
cdf_status = hdd_softap_sta_deauth(pAdapter,
qdf_status = hdd_softap_sta_deauth(pAdapter,
pDelStaParams);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
pAdapter->aStaInfo[staId].isDeauthInProgress =
false;
hddLog(LOG1,
@@ -10131,7 +10130,7 @@ static int __wlan_hdd_cfg80211_set_pmksa(struct wiphy *wiphy,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
tHalHandle halHandle;
CDF_STATUS result = CDF_STATUS_SUCCESS;
QDF_STATUS result = QDF_STATUS_SUCCESS;
int status;
tPmkidCacheInfo pmk_id;
@@ -10175,7 +10174,7 @@ static int __wlan_hdd_cfg80211_set_pmksa(struct wiphy *wiphy,
pAdapter->sessionId, result));
EXIT();
return CDF_IS_STATUS_SUCCESS(result) ? 0 : -EINVAL;
return QDF_IS_STATUS_SUCCESS(result) ? 0 : -EINVAL;
}
/**
@@ -10247,7 +10246,7 @@ static int __wlan_hdd_cfg80211_del_pmksa(struct wiphy *wiphy,
TRACE_CODE_HDD_CFG80211_DEL_PMKSA,
pAdapter->sessionId, 0));
/* Delete the PMKID CSR cache */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_roam_del_pmkid_from_cache(halHandle,
pAdapter->sessionId, pmksa->bssid,
false)) {
@@ -10315,7 +10314,7 @@ static int __wlan_hdd_cfg80211_flush_pmksa(struct wiphy *wiphy,
halHandle = WLAN_HDD_GET_HAL_CTX(pAdapter);
/* Flush the PMKID cache in CSR */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_roam_del_pmkid_from_cache(halHandle, pAdapter->sessionId, NULL,
true)) {
hddLog(LOGE, FL("Cannot flush PMKIDCache"));
@@ -10447,7 +10446,7 @@ void wlan_hdd_cfg80211_update_replay_counter_callback(void *callbackContext,
return;
}
if (CDF_STATUS_SUCCESS != pGtkOffloadGetInfoRsp->ulStatus) {
if (QDF_STATUS_SUCCESS != pGtkOffloadGetInfoRsp->ulStatus) {
hddLog(LOGE, FL("wlan Failed to get replay counter value"));
return;
}
@@ -10496,7 +10495,7 @@ int __wlan_hdd_cfg80211_set_rekey_data(struct wiphy *wiphy,
tHalHandle hHal;
int result;
tSirGtkOffloadParams hddGtkOffloadReqParams;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
ENTER();
@@ -10551,7 +10550,7 @@ int __wlan_hdd_cfg80211_set_rekey_data(struct wiphy *wiphy,
sme_set_gtk_offload(hHal, &hddGtkOffloadReqParams,
pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("sme_set_gtk_offload failed, status(%d)"),
status);
return -EINVAL;
@@ -10608,7 +10607,7 @@ static int __wlan_hdd_cfg80211_set_mac_acl(struct wiphy *wiphy,
v_CONTEXT_t p_cds_context = NULL;
hdd_context_t *pHddCtx;
int status;
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
ENTER();
@@ -10695,13 +10694,13 @@ static int __wlan_hdd_cfg80211_set_mac_acl(struct wiphy *wiphy,
}
}
#ifdef WLAN_FEATURE_MBSSID
cdf_status =
qdf_status =
wlansap_set_mac_acl(WLAN_HDD_GET_SAP_CTX_PTR(pAdapter),
pConfig);
#else
cdf_status = wlansap_set_mac_acl(p_cds_context, pConfig);
qdf_status = wlansap_set_mac_acl(p_cds_context, pConfig);
#endif
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE, FL("SAP Set Mac Acl fail"));
return -EINVAL;
}
@@ -10837,7 +10836,7 @@ static int __wlan_hdd_cfg80211_testmode(struct wiphy *wiphy,
void *buf;
tSirLPHBReq *hb_params = NULL;
tSirLPHBReq *hb_params_temp = NULL;
CDF_STATUS smeStatus;
QDF_STATUS smeStatus;
if (!tb[WLAN_HDD_TM_ATTR_DATA]) {
hddLog(LOGE, FL("Testmode INV DATA"));
@@ -10865,7 +10864,7 @@ static int __wlan_hdd_cfg80211_testmode(struct wiphy *wiphy,
sme_lphb_config_req((tHalHandle) (pHddCtx->hHal),
hb_params,
wlan_hdd_cfg80211_lphb_ind_handler);
if (CDF_STATUS_SUCCESS != smeStatus) {
if (QDF_STATUS_SUCCESS != smeStatus) {
hddLog(LOGE, "LPHB Config Fail, disable");
cdf_mem_free(hb_params);
}
@@ -10878,7 +10877,7 @@ static int __wlan_hdd_cfg80211_testmode(struct wiphy *wiphy,
{
int buf_len;
void *buf;
CDF_STATUS status;
QDF_STATUS status;
if (!tb[WLAN_HDD_TM_ATTR_DATA]) {
hddLog(LOGE,
FL
@@ -10893,7 +10892,7 @@ static int __wlan_hdd_cfg80211_testmode(struct wiphy *wiphy,
status = wlan_hdd_ftm_testmode_cmd(buf, buf_len);
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
err = -EBUSY;
break;
}
@@ -11000,7 +10999,7 @@ __wlan_hdd_cfg80211_set_ap_channel_width(struct wiphy *wiphy,
{
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx;
CDF_STATUS status;
QDF_STATUS status;
tSmeConfigParams sme_config;
bool cbModeChange;
@@ -11062,7 +11061,7 @@ __wlan_hdd_cfg80211_set_ap_channel_width(struct wiphy *wiphy,
/* Change SAP ht2040 mode */
status = hdd_set_sap_ht2040_mode(pAdapter,
cfg80211_get_chandef_type(chandef));
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error!!! Cannot set SAP HT20/40 mode!"));
return -EINVAL;
}

8
core/hdd/src/wlan_hdd_cfg80211.h
Fájl megtekintése

@@ -2266,16 +2266,16 @@ int wlan_hdd_cfg80211_pmksa_candidate_notify(hdd_adapter_t *pAdapter,
int index, bool preauth);
#ifdef FEATURE_WLAN_LFR_METRICS
CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo);
CDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *
QDF_STATUS wlan_hdd_cfg80211_roam_metrics_preauth_status(hdd_adapter_t *
pAdapter,
tCsrRoamInfo *
pRoamInfo,
bool preauth_status);
CDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_cfg80211_roam_metrics_handover(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo);
#endif
@@ -2304,7 +2304,7 @@ void hdd_reg_notifier(struct wiphy *wiphy,
extern void hdd_conn_set_connection_state(hdd_adapter_t *pAdapter,
eConnectionState connState);
CDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_validate_operation_channel(hdd_adapter_t *pAdapter,
int channel);
#ifdef FEATURE_WLAN_TDLS
int wlan_hdd_cfg80211_send_tdls_discover_req(struct wiphy *wiphy,

12
core/hdd/src/wlan_hdd_conc_ut.c
Fájl megtekintése

@@ -630,11 +630,11 @@ void wlan_hdd_one_connection_scenario(hdd_context_t *hdd_ctx)
bool status = false;
enum cds_pcl_type pcl_type;
char reason[20] = {0};
CDF_STATUS ret;
QDF_STATUS ret;
/* flush the entire table first */
ret = cds_init_policy_mgr();
if (!CDF_IS_STATUS_SUCCESS(ret)) {
if (!QDF_IS_STATUS_SUCCESS(ret)) {
hdd_err("Policy manager initialization failed");
return;
}
@@ -681,7 +681,7 @@ void wlan_hdd_two_connections_scenario(hdd_context_t *hdd_ctx,
enum cds_one_connection_mode second_index;
char reason[20] = {0};
bool status = false;
CDF_STATUS ret;
QDF_STATUS ret;
for (sub_type = CDS_STA_MODE;
sub_type < CDS_MAX_NUM_OF_MODE; sub_type++) {
@@ -689,7 +689,7 @@ void wlan_hdd_two_connections_scenario(hdd_context_t *hdd_ctx,
/* flush the entire table first */
ret = cds_init_policy_mgr();
if (!CDF_IS_STATUS_SUCCESS(ret)) {
if (!QDF_IS_STATUS_SUCCESS(ret)) {
hdd_err("Policy manager initialization failed");
return;
}
@@ -761,7 +761,7 @@ void wlan_hdd_three_connections_scenario(hdd_context_t *hdd_ctx,
enum cds_two_connection_mode third_index;
char reason[20] = {0};
bool status = false;
CDF_STATUS ret;
QDF_STATUS ret;
/* let's set the chain_mask, mac_ids*/
if (chain_mask == CDS_TWO_TWO) {
@@ -787,7 +787,7 @@ void wlan_hdd_three_connections_scenario(hdd_context_t *hdd_ctx,
type_1 = wlan_hdd_valid_type_of_persona(sub_type_1);
/* flush the entire table first */
ret = cds_init_policy_mgr();
if (!CDF_IS_STATUS_SUCCESS(ret)) {
if (!QDF_IS_STATUS_SUCCESS(ret)) {
hdd_err("Policy manager initialization failed");
return;
}

24
core/hdd/src/wlan_hdd_debugfs.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -321,7 +321,7 @@ static ssize_t __wcnss_patterngen_write(struct file *file,
char *pattern_buf;
uint16_t pattern_len = 0;
uint16_t i = 0;
CDF_STATUS status;
QDF_STATUS status;
int ret;
ENTER();
@@ -411,7 +411,7 @@ static ssize_t __wcnss_patterngen_write(struct file *file,
/* Delete pattern */
status = sme_del_periodic_tx_ptrn(pHddCtx->hHal,
delPeriodicTxPtrnParams);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: sme_del_periodic_tx_ptrn() failed!",
__func__);
@@ -489,7 +489,7 @@ static ssize_t __wcnss_patterngen_write(struct file *file,
/* Add pattern */
status = sme_add_periodic_tx_ptrn(pHddCtx->hHal,
addPeriodicTxPtrnParams);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: sme_add_periodic_tx_ptrn() failed!", __func__);
@@ -610,33 +610,33 @@ static const struct file_operations fops_patterngen = {
* NB: The current implementation only supports debugfs operations
* on the primary interface, i.e. wlan0
*
* Return: CDF_STATUS_SUCCESS if all files registered,
* CDF_STATUS_E_FAILURE on failure
* Return: QDF_STATUS_SUCCESS if all files registered,
* QDF_STATUS_E_FAILURE on failure
*/
CDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_debugfs_init(hdd_adapter_t *pAdapter)
{
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
pHddCtx->debugfs_phy = debugfs_create_dir("wlan_wcnss", 0);
if (NULL == pHddCtx->debugfs_phy)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (NULL == debugfs_create_file("wow_enable", S_IRUSR | S_IWUSR,
pHddCtx->debugfs_phy, pAdapter,
&fops_wowenable))
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (NULL == debugfs_create_file("wow_pattern", S_IRUSR | S_IWUSR,
pHddCtx->debugfs_phy, pAdapter,
&fops_wowpattern))
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (NULL == debugfs_create_file("pattern_gen", S_IRUSR | S_IWUSR,
pHddCtx->debugfs_phy, pAdapter,
&fops_patterngen))
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

17
core/hdd/src/wlan_hdd_driver_ops.c
Fájl megtekintése

@@ -38,7 +38,6 @@
#include <soc/qcom/icnss.h>
#endif /* HIF_PCI */
#include "cds_api.h"
#include "cdf_status.h"
#include "qdf_status.h"
#include "cdf_lock.h"
#include "cds_sched.h"
@@ -182,7 +181,7 @@ static void hdd_hif_init_cds_callbacks(void *data, struct hif_callbacks *cbk)
*/
static int hdd_init_cds_hif_context(void *hif)
{
CDF_STATUS status;
QDF_STATUS status;
status = cds_set_context(CDF_MODULE_ID_HIF, hif);
@@ -199,7 +198,7 @@ static int hdd_init_cds_hif_context(void *hif)
*/
static void hdd_deinit_cds_hif_context(void)
{
CDF_STATUS status;
QDF_STATUS status;
status = cds_set_context(CDF_MODULE_ID_HIF, NULL);
@@ -224,7 +223,7 @@ static void hdd_deinit_cds_hif_context(void)
static int hdd_hif_open(struct device *dev, void *bdev, const hif_bus_id *bid,
enum ath_hal_bus_type bus_type, bool reinit)
{
CDF_STATUS status;
QDF_STATUS status;
int ret = 0;
struct hif_opaque_softc *hif_ctx;
cdf_device_t cdf_ctx = cds_get_context(CDF_MODULE_ID_CDF_DEVICE);
@@ -259,7 +258,7 @@ static int hdd_hif_open(struct device *dev, void *bdev, const hif_bus_id *bid,
status = hif_enable(hif_ctx, dev, bdev, bid, bus_type,
(reinit == true) ? HIF_ENABLE_TYPE_REINIT :
HIF_ENABLE_TYPE_PROBE);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hdd_err("hif_enable error = %d, reinit = %d",
status, reinit);
ret = cdf_status_to_os_return(status);
@@ -328,7 +327,7 @@ static int wlan_hdd_probe(struct device *dev, void *bdev, const hif_bus_id *bid,
enum ath_hal_bus_type bus_type, bool reinit)
{
void *hif_ctx;
CDF_STATUS status;
QDF_STATUS status;
int ret = 0;
cdf_device_t cdf_dev;
uint32_t mode = cds_get_conparam();
@@ -358,7 +357,7 @@ static int wlan_hdd_probe(struct device *dev, void *bdev, const hif_bus_id *bid,
if (WLAN_IS_EPPING_ENABLED(mode)) {
status = epping_open();
if (status != CDF_STATUS_SUCCESS)
if (status != QDF_STATUS_SUCCESS)
goto err_hdd_deinit;
}
@@ -374,7 +373,7 @@ static int wlan_hdd_probe(struct device *dev, void *bdev, const hif_bus_id *bid,
status = ol_cds_init(cdf_dev, hif_ctx);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
pr_err("%s No Memory to Create BMI Context\n", __func__);
goto err_hif_close;
}
@@ -599,7 +598,7 @@ done:
*
* @state: state
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
int wlan_hdd_bus_suspend(pm_message_t state)
{

62
core/hdd/src/wlan_hdd_ext_scan.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2012-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2012-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -1714,7 +1714,7 @@ static int __wlan_hdd_cfg80211_extscan_get_capabilities(struct wiphy *wiphy,
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_EXTSCAN_SUBCMD_CONFIG_PARAM_MAX +
1];
CDF_STATUS status;
QDF_STATUS status;
ENTER();
@@ -1759,7 +1759,7 @@ static int __wlan_hdd_cfg80211_extscan_get_capabilities(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_ext_scan_get_capabilities(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("sme_ext_scan_get_capabilities failed(err=%d)"),
status);
goto fail;
@@ -1846,7 +1846,7 @@ static int __wlan_hdd_cfg80211_extscan_get_cached_results(struct wiphy *wiphy,
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_EXTSCAN_SUBCMD_CONFIG_PARAM_MAX +
1];
struct hdd_ext_scan_context *context;
CDF_STATUS status;
QDF_STATUS status;
int retval = 0;
unsigned long rc;
@@ -1900,7 +1900,7 @@ static int __wlan_hdd_cfg80211_extscan_get_cached_results(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_get_cached_results(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_get_cached_results failed(err=%d)"), status);
goto fail;
@@ -1993,7 +1993,7 @@ __wlan_hdd_cfg80211_extscan_set_bssid_hotlist(struct wiphy *wiphy,
struct nlattr *apTh;
struct hdd_ext_scan_context *context;
uint32_t request_id;
CDF_STATUS status;
QDF_STATUS status;
uint8_t i;
int rem, retval;
unsigned long rc;
@@ -2111,7 +2111,7 @@ __wlan_hdd_cfg80211_extscan_set_bssid_hotlist(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_set_bss_hotlist(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("sme_set_bss_hotlist failed(err=%d)"), status);
goto fail;
}
@@ -2190,7 +2190,7 @@ __wlan_hdd_cfg80211_extscan_set_significant_change(struct wiphy *wiphy,
struct nlattr *apTh;
struct hdd_ext_scan_context *context;
uint32_t request_id;
CDF_STATUS status;
QDF_STATUS status;
uint8_t i;
int rem, retval;
unsigned long rc;
@@ -2330,7 +2330,7 @@ __wlan_hdd_cfg80211_extscan_set_significant_change(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_set_significant_change(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_set_significant_change failed(err=%d)"), status);
cdf_mem_free(pReqMsg);
@@ -2472,7 +2472,7 @@ __wlan_hdd_cfg80211_extscan_get_valid_channels(struct wiphy *wiphy,
1];
uint32_t requestId, maxChannels;
tWifiBand wifiBand;
CDF_STATUS status;
QDF_STATUS status;
struct sk_buff *reply_skb;
uint8_t i;
int ret;
@@ -2527,7 +2527,7 @@ __wlan_hdd_cfg80211_extscan_get_valid_channels(struct wiphy *wiphy,
status = sme_get_valid_channels_by_band((tHalHandle) (pHddCtx->hHal),
wifiBand, chan_list,
&num_channels);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE,
FL("sme_get_valid_channels_by_band failed (err=%d)"),
status);
@@ -2693,7 +2693,7 @@ static int hdd_extscan_start_fill_bucket_channel_spec(
struct nlattr *buckets;
struct nlattr *channels;
int rem1, rem2;
CDF_STATUS status;
QDF_STATUS status;
uint8_t bkt_index, j, num_channels, total_channels = 0;
uint32_t chan_list[WNI_CFG_VALID_CHANNEL_LIST_LEN] = {0};
@@ -2821,7 +2821,7 @@ static int hdd_extscan_start_fill_bucket_channel_spec(
status = sme_get_valid_channels_by_band(hdd_ctx->hHal,
req_msg->buckets[bkt_index].band,
chan_list, &num_channels);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_GetValidChannelsByBand failed (err=%d)"),
status);
@@ -3138,7 +3138,7 @@ __wlan_hdd_cfg80211_extscan_start(struct wiphy *wiphy,
struct nlattr *tb[PARAM_MAX + 1];
struct hdd_ext_scan_context *context;
uint32_t request_id, num_buckets;
CDF_STATUS status;
QDF_STATUS status;
int retval;
unsigned long rc;
@@ -3250,7 +3250,7 @@ __wlan_hdd_cfg80211_extscan_start(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_ext_scan_start(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_ext_scan_start failed(err=%d)"), status);
goto fail;
@@ -3347,7 +3347,7 @@ __wlan_hdd_cfg80211_extscan_stop(struct wiphy *wiphy,
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[PARAM_MAX + 1];
struct hdd_ext_scan_context *context;
CDF_STATUS status;
QDF_STATUS status;
uint32_t request_id;
int retval;
unsigned long rc;
@@ -3393,7 +3393,7 @@ __wlan_hdd_cfg80211_extscan_stop(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_ext_scan_stop(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_ext_scan_stop failed(err=%d)"), status);
goto fail;
@@ -3475,7 +3475,7 @@ __wlan_hdd_cfg80211_extscan_reset_bssid_hotlist(struct wiphy *wiphy,
1];
struct hdd_ext_scan_context *context;
uint32_t request_id;
CDF_STATUS status;
QDF_STATUS status;
int retval;
unsigned long rc;
@@ -3522,7 +3522,7 @@ __wlan_hdd_cfg80211_extscan_reset_bssid_hotlist(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_reset_bss_hotlist(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_reset_bss_hotlist failed(err=%d)"), status);
goto fail;
@@ -3600,7 +3600,7 @@ __wlan_hdd_cfg80211_extscan_reset_significant_change(struct wiphy
1];
struct hdd_ext_scan_context *context;
uint32_t request_id;
CDF_STATUS status;
QDF_STATUS status;
int retval;
unsigned long rc;
@@ -3647,7 +3647,7 @@ __wlan_hdd_cfg80211_extscan_reset_significant_change(struct wiphy
spin_unlock(&context->context_lock);
status = sme_reset_significant_change(pHddCtx->hHal, pReqMsg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("sme_reset_significant_change failed(err=%d)"),
status);
cdf_mem_free(pReqMsg);
@@ -3812,7 +3812,7 @@ static int __wlan_hdd_cfg80211_set_epno_list(struct wiphy *wiphy,
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[
QCA_WLAN_VENDOR_ATTR_PNO_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
uint32_t num_networks, len;
int ret_val;
@@ -3869,7 +3869,7 @@ static int __wlan_hdd_cfg80211_set_epno_list(struct wiphy *wiphy,
goto fail;
status = sme_set_epno_list(hdd_ctx->hHal, req_msg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("sme_set_epno_list failed(err=%d)"), status);
goto fail;
}
@@ -4018,7 +4018,7 @@ static int __wlan_hdd_cfg80211_set_passpoint_list(struct wiphy *wiphy,
hdd_adapter_t *adapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_PNO_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
uint32_t num_networks = 0;
int ret;
@@ -4072,7 +4072,7 @@ static int __wlan_hdd_cfg80211_set_passpoint_list(struct wiphy *wiphy,
goto fail;
status = sme_set_passpoint_list(hdd_ctx->hHal, req_msg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_set_passpoint_list failed(err=%d)"), status);
goto fail;
@@ -4135,7 +4135,7 @@ static int __wlan_hdd_cfg80211_reset_passpoint_list(struct wiphy *wiphy,
hdd_adapter_t *adapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_PNO_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
int ret;
ENTER();
@@ -4174,7 +4174,7 @@ static int __wlan_hdd_cfg80211_reset_passpoint_list(struct wiphy *wiphy,
req_msg->request_id, req_msg->session_id);
status = sme_reset_passpoint_list(hdd_ctx->hHal, req_msg);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_reset_passpoint_list failed(err=%d)"), status);
goto fail;
@@ -4264,7 +4264,7 @@ __wlan_hdd_cfg80211_extscan_set_ssid_hotlist(struct wiphy *wiphy,
uint32_t request_id;
char ssid_string[SIR_MAC_MAX_SSID_LENGTH + 1];
int ssid_len, i, rem;
CDF_STATUS status;
QDF_STATUS status;
int retval;
unsigned long rc;
@@ -4384,7 +4384,7 @@ __wlan_hdd_cfg80211_extscan_set_ssid_hotlist(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_set_ssid_hotlist(hdd_ctx->hHal, request);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_set_ssid_hotlist failed(err=%d)"), status);
goto fail;
@@ -4484,7 +4484,7 @@ __wlan_hdd_cfg80211_extscan_reset_ssid_hotlist(struct wiphy *wiphy,
struct nlattr *tb[PARAM_MAX + 1];
struct hdd_ext_scan_context *context;
uint32_t request_id;
CDF_STATUS status;
QDF_STATUS status;
int retval;
unsigned long rc;
@@ -4534,7 +4534,7 @@ __wlan_hdd_cfg80211_extscan_reset_ssid_hotlist(struct wiphy *wiphy,
spin_unlock(&context->context_lock);
status = sme_set_ssid_hotlist(hdd_ctx->hHal, request);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE,
FL("sme_reset_ssid_hotlist failed(err=%d)"), status);
goto fail;

125
core/hdd/src/wlan_hdd_ftm.c
Fájl megtekintése

@@ -99,16 +99,16 @@ static uint32_t wlan_ftm_postmsg(uint8_t *cmd_ptr, uint16_t cmd_len)
ftmMsg.bodyptr = (uint8_t *) cmd_ptr;
ftmMsg.bodyval = 0;
if (CDF_STATUS_SUCCESS != cds_mq_post_message(CDF_MODULE_ID_WMA,
if (QDF_STATUS_SUCCESS != cds_mq_post_message(CDF_MODULE_ID_WMA,
&ftmMsg)) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: : Failed to post Msg to HAL",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -161,16 +161,16 @@ static inline void hdd_is_lpass_supported(tMacOpenParameters *mac_openParms,
* - All the WLAN SW components should have been opened. This includes MAC.
*
* Returns:
* CDF_STATUS_SUCCESS - Scheduler was successfully initialized and
* QDF_STATUS_SUCCESS - Scheduler was successfully initialized and
* is ready to be used.
* CDF_STATUS_E_RESOURCES - System resources (other than memory)
* QDF_STATUS_E_RESOURCES - System resources (other than memory)
* are unavailable to initialize the scheduler
* CDF_STATUS_E_FAILURE - Failure to initialize the scheduler
* QDF_STATUS_E_FAILURE - Failure to initialize the scheduler
*/
static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
static QDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
uint32_t hddContextSize)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
int iter = 0;
tSirRetStatus sirStatus = eSIR_SUCCESS;
tMacOpenParameters mac_openParms;
@@ -191,7 +191,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Trying to open CDS without a PreOpen", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Initialize the probe event */
@@ -199,7 +199,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Unable to init probeEvent", __func__);
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (qdf_event_create(&(gp_cds_context->wmaCompleteEvent)) !=
@@ -213,7 +213,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
/* Initialize the free message queue */
vStatus = cds_mq_init(&gp_cds_context->freeVosMq);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
@@ -235,7 +235,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
vStatus = cds_sched_open(gp_cds_context, &gp_cds_context->cdf_sched,
sizeof(cds_sched_context));
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to open CDS Scheduler %d", __func__,
@@ -300,7 +300,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
vStatus = wma_open(gp_cds_context,
wlan_hdd_ftm_update_tgt_cfg, NULL, &mac_openParms);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to open WMA module %d", __func__,
@@ -346,7 +346,7 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
#ifndef QCA_WIFI_FTM
/* Now proceed to open the SME */
vStatus = sme_open(gp_cds_context->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
/* Critical Error ... Cannot proceed further */
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to open SME %d", __func__, vStatus);
@@ -355,16 +355,16 @@ static CDF_STATUS wlan_ftm_cds_open(v_CONTEXT_t p_cds_context,
vStatus = sme_init_chan_list(gp_cds_context->pMACContext,
hdd_ctx->reg.alpha2, hdd_ctx->reg.cc_src);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to init sme channel list", __func__);
} else {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_INFO_HIGH,
"%s: CDS successfully Opened", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#else
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
#endif
#ifndef QCA_WIFI_FTM
@@ -397,7 +397,7 @@ err_wma_complete_event:
err_probe_event:
qdf_event_destroy(&gp_cds_context->ProbeEvent);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
} /* wlan_ftm_cds_open() */
@@ -407,38 +407,37 @@ err_probe_event:
*
* The wlan_ftm_cds_close() function closes the CDF Module
*
* Return: CDF_STATUS_SUCCESS - successfully closed
* Return: QDF_STATUS_SUCCESS - successfully closed
*/
static CDF_STATUS wlan_ftm_cds_close(v_CONTEXT_t cds_context)
static QDF_STATUS wlan_ftm_cds_close(v_CONTEXT_t cds_context)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
p_cds_contextType gp_cds_context = (p_cds_contextType) cds_context;
#ifndef QCA_WIFI_FTM
cdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sme_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close SME %d", __func__, cdf_status);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
"%s: Failed to close SME %d", __func__, qdf_status);
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
#endif
cdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = mac_close(((p_cds_contextType) cds_context)->pMACContext);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close MAC %d", __func__, cdf_status);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
"%s: Failed to close MAC %d", __func__, qdf_status);
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
((p_cds_contextType) cds_context)->pMACContext = NULL;
cdf_status = wma_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close WMA %d", __func__, cdf_status);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
"%s: Failed to close WMA %d", __func__, qdf_status);
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
#if defined(QCA_WIFI_FTM)
if (gp_cds_context->htc_ctx) {
@@ -446,11 +445,11 @@ static CDF_STATUS wlan_ftm_cds_close(v_CONTEXT_t cds_context)
htc_destroy(gp_cds_context->htc_ctx);
gp_cds_context->htc_ctx = NULL;
}
cdf_status = wma_wmi_service_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = wma_wmi_service_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close wma_wmi_service", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
hif_disable_isr(gp_cds_context->pHIFContext);
@@ -474,7 +473,7 @@ static CDF_STATUS wlan_ftm_cds_close(v_CONTEXT_t cds_context)
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -484,12 +483,12 @@ static CDF_STATUS wlan_ftm_cds_close(v_CONTEXT_t cds_context)
* The cds_ftm_pre_start() function performs all pre-start activities
* in FTM mode.
*
* Return: CDF_STATUS_SUCCESS if pre-start was successful, an
* Return: QDF_STATUS_SUCCESS if pre-start was successful, an
* appropriate CDF_STATUS_E_* error code otherwise
*/
static CDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
static QDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
p_cds_contextType p_cds_context = (p_cds_contextType) cds_context;
#if defined(QCA_WIFI_FTM)
@@ -502,7 +501,7 @@ static CDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
CDF_ASSERT(0);
CDF_TRACE(CDF_MODULE_ID_SYS, CDF_TRACE_LEVEL_ERROR,
"%s: WMA NULL context", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Reset WMA wait event */
@@ -510,11 +509,11 @@ static CDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
/*call WMA pre start */
vStatus = wma_pre_start(p_cds_context);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_SYS, CDF_TRACE_LEVEL_ERROR,
"Failed to WMA prestart ");
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Need to update time out of complete */
@@ -531,20 +530,20 @@ static CDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
__func__);
}
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
#if defined(QCA_WIFI_FTM)
vStatus = htc_start(gp_cds_context->htc_ctx);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
CDF_TRACE(CDF_MODULE_ID_SYS, CDF_TRACE_LEVEL_FATAL,
"Failed to Start HTC");
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
wma_wait_for_ready_event(gp_cds_context->pWMAContext);
#endif /* QCA_WIFI_FTM */
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -558,7 +557,7 @@ static CDF_STATUS cds_ftm_pre_start(v_CONTEXT_t cds_context)
*/
int wlan_hdd_ftm_open(hdd_context_t *hdd_ctx)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
p_cds_contextType p_cds_context = NULL;
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_INFO_HIGH,
@@ -575,7 +574,7 @@ int wlan_hdd_ftm_open(hdd_context_t *hdd_ctx)
vStatus = wlan_ftm_cds_open(p_cds_context, 0);
if (!CDF_IS_STATUS_SUCCESS(vStatus)) {
if (!QDF_IS_STATUS_SUCCESS(vStatus)) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: cds_open failed", __func__);
goto err_cdf_status_failure;
}
@@ -656,7 +655,7 @@ static int wlan_ftm_stop(hdd_context_t *hdd_ctx)
*/
int wlan_hdd_ftm_close(hdd_context_t *hdd_ctx)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
v_CONTEXT_t cds_context = hdd_ctx->pcds_context;
hdd_adapter_t *adapter = hdd_get_adapter(hdd_ctx, WLAN_HDD_FTM);
@@ -675,11 +674,11 @@ int wlan_hdd_ftm_close(hdd_context_t *hdd_ctx)
hdd_close_all_adapters(hdd_ctx, false);
cdf_status = cds_sched_close(cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cds_sched_close(cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to close CDS Scheduler", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
}
/* Close CDS */
wlan_ftm_cds_close(cds_context);
@@ -746,7 +745,7 @@ static void hdd_ftm_mc_process_msg(void *message)
*/
static int wlan_hdd_ftm_start(hdd_context_t *hdd_ctx)
{
CDF_STATUS vStatus = CDF_STATUS_SUCCESS;
QDF_STATUS vStatus = QDF_STATUS_SUCCESS;
p_cds_contextType p_cds_context =
(p_cds_contextType) (hdd_ctx->pcds_context);
@@ -771,7 +770,7 @@ static int wlan_hdd_ftm_start(hdd_context_t *hdd_ctx)
}
/* Vos preStart is calling */
if (!CDF_IS_STATUS_SUCCESS(cds_ftm_pre_start(hdd_ctx->pcds_context))) {
if (!QDF_IS_STATUS_SUCCESS(cds_ftm_pre_start(hdd_ctx->pcds_context))) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: cds_pre_enable failed",
__func__);
goto err_status_failure;
@@ -780,7 +779,7 @@ static int wlan_hdd_ftm_start(hdd_context_t *hdd_ctx)
sme_register_ftm_msg_processor(hdd_ctx->hHal, hdd_ftm_mc_process_msg);
vStatus = wma_start(p_cds_context);
if (vStatus != CDF_STATUS_SUCCESS) {
if (vStatus != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to start WMA", __func__);
goto err_status_failure;
@@ -856,7 +855,7 @@ static int wlan_hdd_qcmbr_command(hdd_adapter_t *adapter,
if (wlan_hdd_ftm_testmode_cmd(pqcmbr_data->buf,
pqcmbr_data->
length)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
ret = -EBUSY;
} else {
ret = 0;
@@ -1013,9 +1012,9 @@ static void wlanqcmbr_mc_process_msg(void *message)
* @data: FTM testmode command
* @len: length of @data
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len)
QDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len)
{
struct ar6k_testmode_cmd_data *cmd_data;
@@ -1025,7 +1024,7 @@ CDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len)
if (!cmd_data) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
("Failed to allocate FTM command data"));
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cmd_data->data = cdf_mem_malloc(len);
@@ -1034,7 +1033,7 @@ CDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len)
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
("Failed to allocate FTM command data buffer"));
cdf_mem_free(cmd_data);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cmd_data->len = len;
@@ -1043,9 +1042,9 @@ CDF_STATUS wlan_hdd_ftm_testmode_cmd(void *data, int len)
if (wlan_ftm_postmsg((uint8_t *) cmd_data, sizeof(*cmd_data))) {
cdf_mem_free(cmd_data->data);
cdf_mem_free(cmd_data);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif /*QCA_WIFI_FTM */

22
core/hdd/src/wlan_hdd_green_ap.c
Fájl megtekintése

@@ -302,19 +302,19 @@ static void hdd_wlan_green_ap_timer_fn(void *ctx)
* hdd_wlan_green_ap_attach() - Attach Green AP context to HDD context
* @hdd_ctx: Global HDD contect
*
* Return: CDF_STATUS_SUCCESS on success, otherwise CDF_STATUS_E_* error
* Return: QDF_STATUS_SUCCESS on success, otherwise CDF_STATUS_E_* error
*/
static CDF_STATUS hdd_wlan_green_ap_attach(struct hdd_context_s *hdd_ctx)
static QDF_STATUS hdd_wlan_green_ap_attach(struct hdd_context_s *hdd_ctx)
{
struct hdd_green_ap_ctx *green_ap;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
ENTER();
green_ap = cdf_mem_malloc(sizeof(*green_ap));
if (!green_ap) {
hdd_alert("Memory allocation for Green-AP failed!");
status = CDF_STATUS_E_NOMEM;
status = QDF_STATUS_E_NOMEM;
goto error;
}
@@ -340,18 +340,18 @@ error:
* hdd_wlan_green_ap_deattach() - Detach Green AP context from HDD context
* @hdd_ctx: Global HDD contect
*
* Return: CDF_STATUS_SUCCESS on success, otherwise CDF_STATUS_E_* error
* Return: QDF_STATUS_SUCCESS on success, otherwise CDF_STATUS_E_* error
*/
static CDF_STATUS hdd_wlan_green_ap_deattach(struct hdd_context_s *hdd_ctx)
static QDF_STATUS hdd_wlan_green_ap_deattach(struct hdd_context_s *hdd_ctx)
{
struct hdd_green_ap_ctx *green_ap = hdd_ctx->green_ap_ctx;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
ENTER();
if (green_ap == NULL) {
hdd_notice("Green-AP is not enabled");
status = CDF_STATUS_E_NOSUPPORT;
status = QDF_STATUS_E_NOSUPPORT;
goto done;
}
@@ -361,7 +361,7 @@ static CDF_STATUS hdd_wlan_green_ap_deattach(struct hdd_context_s *hdd_ctx)
cdf_mc_timer_stop(&green_ap->ps_timer);
/* Destroy the Green AP timer */
if (!CDF_IS_STATUS_SUCCESS(cdf_mc_timer_destroy(&green_ap->ps_timer)))
if (!QDF_IS_STATUS_SUCCESS(cdf_mc_timer_destroy(&green_ap->ps_timer)))
hdd_notice("Cannot deallocate Green-AP's timer");
/* release memory */
@@ -383,7 +383,7 @@ done:
*/
void hdd_wlan_green_ap_init(struct hdd_context_s *hdd_ctx)
{
if (!CDF_IS_STATUS_SUCCESS(hdd_wlan_green_ap_attach(hdd_ctx)))
if (!QDF_IS_STATUS_SUCCESS(hdd_wlan_green_ap_attach(hdd_ctx)))
hdd_err("Failed to allocate Green-AP resource");
}
@@ -395,7 +395,7 @@ void hdd_wlan_green_ap_init(struct hdd_context_s *hdd_ctx)
*/
void hdd_wlan_green_ap_deinit(struct hdd_context_s *hdd_ctx)
{
if (!CDF_IS_STATUS_SUCCESS(hdd_wlan_green_ap_deattach(hdd_ctx)))
if (!QDF_IS_STATUS_SUCCESS(hdd_wlan_green_ap_deattach(hdd_ctx)))
hdd_err("Cannot deallocate Green-AP resource");
}

387
core/hdd/src/wlan_hdd_hostapd.c
Fájl megtekintése

A különbségek nem kerülnek megjelenítésre, mivel a fájl túl nagy Load Diff

14
core/hdd/src/wlan_hdd_hostapd.h
Fájl megtekintése

@@ -50,9 +50,9 @@
hdd_adapter_t *hdd_wlan_create_ap_dev(hdd_context_t *pHddCtx,
tSirMacAddr macAddr, uint8_t *name);
CDF_STATUS hdd_register_hostapd(hdd_adapter_t *pAdapter, uint8_t rtnl_held);
QDF_STATUS hdd_register_hostapd(hdd_adapter_t *pAdapter, uint8_t rtnl_held);
CDF_STATUS hdd_unregister_hostapd(hdd_adapter_t *pAdapter, bool rtnl_held);
QDF_STATUS hdd_unregister_hostapd(hdd_adapter_t *pAdapter, bool rtnl_held);
eCsrAuthType
hdd_translate_rsn_to_csr_auth_type(uint8_t auth_suite[4]);
@@ -73,7 +73,7 @@ hdd_translate_wpa_to_csr_auth_type(uint8_t auth_suite[4]);
eCsrEncryptionType
hdd_translate_wpa_to_csr_encryption_type(uint8_t cipher_suite[4]);
CDF_STATUS hdd_softap_sta_deauth(hdd_adapter_t *,
QDF_STATUS hdd_softap_sta_deauth(hdd_adapter_t *,
struct tagCsrDelStaParams *);
void hdd_softap_sta_disassoc(hdd_adapter_t *, uint8_t *);
void hdd_softap_tkip_mic_fail_counter_measure(hdd_adapter_t *, bool);
@@ -85,9 +85,9 @@ int hdd_softap_unpack_ie(tHalHandle halHandle,
bool *pMFPRequired,
uint16_t gen_ie_len, uint8_t *gen_ie);
CDF_STATUS hdd_hostapd_sap_event_cb(tpSap_Event pSapEvent,
QDF_STATUS hdd_hostapd_sap_event_cb(tpSap_Event pSapEvent,
void *usrDataForCallback);
CDF_STATUS hdd_init_ap_mode(hdd_adapter_t *pAdapter);
QDF_STATUS hdd_init_ap_mode(hdd_adapter_t *pAdapter);
void hdd_set_ap_ops(struct net_device *pWlanHostapdDev);
int hdd_hostapd_stop(struct net_device *dev);
void hdd_hostapd_channel_wakelock_init(hdd_context_t *pHddCtx);
@@ -96,7 +96,7 @@ void hdd_hostapd_channel_wakelock_deinit(hdd_context_t *pHddCtx);
void hdd_restart_softap(hdd_context_t *pHddCtx, hdd_adapter_t *pAdapter);
#endif /* FEATURE_WLAN_FORCE_SAP_SCC */
#ifdef QCA_HT_2040_COEX
CDF_STATUS hdd_set_sap_ht2040_mode(hdd_adapter_t *pHostapdAdapter,
QDF_STATUS hdd_set_sap_ht2040_mode(hdd_adapter_t *pHostapdAdapter,
uint8_t channel_type);
#endif
@@ -112,5 +112,5 @@ int wlan_hdd_cfg80211_change_beacon(struct wiphy *wiphy,
struct net_device *dev,
struct cfg80211_beacon_data *params);
CDF_STATUS wlan_hdd_config_acs(hdd_context_t *hdd_ctx, hdd_adapter_t *adapter);
QDF_STATUS wlan_hdd_config_acs(hdd_context_t *hdd_ctx, hdd_adapter_t *adapter);
#endif /* end #if !defined(WLAN_HDD_HOSTAPD_H) */

186
core/hdd/src/wlan_hdd_ioctl.c
Fájl megtekintése

@@ -180,13 +180,13 @@ static void hdd_get_tsm_stats_cb(tAniTrafStrmMetrics tsm_metrics,
}
static
CDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
QDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
const uint8_t tid,
tAniTrafStrmMetrics *tsm_metrics)
{
hdd_station_ctx_t *hdd_sta_ctx = NULL;
CDF_STATUS hstatus;
CDF_STATUS vstatus = CDF_STATUS_SUCCESS;
QDF_STATUS hstatus;
QDF_STATUS vstatus = QDF_STATUS_SUCCESS;
unsigned long rc;
struct statsContext context;
hdd_context_t *hdd_ctx = NULL;
@@ -194,7 +194,7 @@ CDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
if (NULL == adapter) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: adapter is NULL", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
hdd_ctx = WLAN_HDD_GET_CTX(adapter);
@@ -210,10 +210,10 @@ CDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
hdd_sta_ctx->conn_info.staId[0],
hdd_sta_ctx->conn_info.bssId,
&context, hdd_ctx->pcds_context, tid);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve statistics", __func__);
vstatus = CDF_STATUS_E_FAULT;
vstatus = QDF_STATUS_E_FAULT;
} else {
/* request was sent -- wait for the response */
rc = wait_for_completion_timeout(&context.completion,
@@ -222,7 +222,7 @@ CDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: SME timed out while retrieving statistics",
__func__);
vstatus = CDF_STATUS_E_TIMEOUT;
vstatus = QDF_STATUS_E_TIMEOUT;
}
}
@@ -243,7 +243,7 @@ CDF_STATUS hdd_get_tsm_stats(hdd_adapter_t *adapter,
context.magic = 0;
spin_unlock(&hdd_context_lock);
if (CDF_STATUS_SUCCESS == vstatus) {
if (QDF_STATUS_SUCCESS == vstatus) {
tsm_metrics->UplinkPktQueueDly =
adapter->tsmStats.UplinkPktQueueDly;
cdf_mem_copy(tsm_metrics->UplinkPktQueueDlyHist,
@@ -566,7 +566,7 @@ hdd_reassoc(hdd_adapter_t *adapter, const uint8_t *bssid,
}
/* Check channel number is a valid channel number */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_validate_operation_channel(adapter, channel)) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: Invalid Channel %d",
__func__, channel);
@@ -1107,7 +1107,7 @@ hdd_parse_set_roam_scan_channels_v1(hdd_adapter_t *adapter,
{
uint8_t channel_list[WNI_CFG_VALID_CHANNEL_LIST_LEN] = { 0 };
uint8_t num_chan = 0;
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
int ret;
@@ -1135,7 +1135,7 @@ hdd_parse_set_roam_scan_channels_v1(hdd_adapter_t *adapter,
sme_change_roam_scan_channel_list(hdd_ctx->hHal,
adapter->sessionId,
channel_list, num_chan);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to update channel list information",
__func__);
@@ -1174,7 +1174,7 @@ hdd_parse_set_roam_scan_channels_v2(hdd_adapter_t *adapter,
uint8_t num_chan;
int i;
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
CDF_STATUS status;
QDF_STATUS status;
int ret = 0;
/* array of values begins after "SETROAMSCANCHANNELS " */
@@ -1208,7 +1208,7 @@ hdd_parse_set_roam_scan_channels_v2(hdd_adapter_t *adapter,
sme_change_roam_scan_channel_list(hdd_ctx->hHal,
adapter->sessionId,
channel_list, num_chan);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to update channel list information",
__func__);
@@ -1278,7 +1278,7 @@ hdd_parse_set_roam_scan_channels(hdd_adapter_t *adapter, const char *command)
*
* Return: 0 for success non-zero for failure
*/
CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
QDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
{
uint8_t *cmdPtr = NULL;
int count, content = 0, ret = 0;
@@ -1287,11 +1287,11 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* move to argument list */
cmdPtr = strnchr(pValue, strlen(pValue), SPACE_ASCII_VALUE);
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* no space after the command */
if (SPACE_ASCII_VALUE != *cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1300,17 +1300,17 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* START/STOP PLM req */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->enable = content;
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1319,11 +1319,11 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* Dialog token of radio meas req containing meas reqIE */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->diag_token = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "diag token %d",
@@ -1331,7 +1331,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1340,11 +1340,11 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* measurement token of meas req IE */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->meas_token = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "meas token %d",
@@ -1357,7 +1357,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1366,14 +1366,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* total number of bursts after which STA stops sending */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->numBursts = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "num burst %d",
@@ -1381,7 +1381,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1390,14 +1390,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* burst interval in seconds */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content <= 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->burstInt = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "burst Int %d",
@@ -1405,7 +1405,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1414,14 +1414,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* Meas dur in TU's,STA goes off-ch and transmit PLM bursts */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content <= 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->measDuration = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "measDur %d",
@@ -1429,7 +1429,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1438,14 +1438,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* burst length of PLM bursts */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content <= 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->burstLen = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "burstLen %d",
@@ -1453,7 +1453,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1462,14 +1462,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* desired tx power for transmission of PLM bursts */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content <= 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->desiredTxPwr = content;
hddLog(CDF_TRACE_LEVEL_DEBUG,
@@ -1479,7 +1479,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr)
@@ -1488,11 +1488,11 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 16, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->mac_addr.bytes[count] = content;
}
@@ -1503,7 +1503,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr) && ('\0' != *cmdPtr))
@@ -1512,14 +1512,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
/* number of channels */
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->plmNumCh = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, "numch %d",
@@ -1530,7 +1530,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
cmdPtr = strpbrk(cmdPtr, " ");
if (NULL == cmdPtr)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
/* remove empty spaces */
while ((SPACE_ASCII_VALUE == *cmdPtr)
@@ -1539,14 +1539,14 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
ret = sscanf(cmdPtr, "%31s ", buf);
if (1 != ret)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
ret = kstrtos32(buf, 10, &content);
if (ret < 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
if (content <= 0)
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
pPlmRequest->plmChList[count] = content;
hddLog(CDF_TRACE_LEVEL_DEBUG, " ch- %d",
@@ -1554,7 +1554,7 @@ CDF_STATUS hdd_parse_plm_cmd(uint8_t *pValue, tSirPlmReq *pPlmRequest)
}
}
/* If PLM START */
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -1577,7 +1577,7 @@ static int hdd_enable_ext_wow(hdd_adapter_t *adapter,
tpSirExtWoWParams arg_params)
{
tSirExtWoWParams params;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(adapter);
int rc;
@@ -1589,7 +1589,7 @@ static int hdd_enable_ext_wow(hdd_adapter_t *adapter,
cdf_ret_status = sme_configure_ext_wow(hHal, &params,
&wlan_hdd_ready_to_extwow,
hdd_ctx);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("sme_configure_ext_wow returned failure %d"),
cdf_ret_status);
@@ -1621,7 +1621,7 @@ static int hdd_enable_ext_wow(hdd_adapter_t *adapter,
return rc;
}
cdf_ret_status = wlan_hdd_bus_suspend(state);
if (cdf_ret_status != CDF_STATUS_SUCCESS) {
if (cdf_ret_status != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: wlan_hdd_suspend failed, status = %d",
__func__, cdf_ret_status);
@@ -1685,12 +1685,12 @@ static int hdd_set_app_type1_params(tHalHandle hHal,
tpSirAppType1Params arg_params)
{
tSirAppType1Params params;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
cdf_mem_copy(&params, arg_params, sizeof(params));
cdf_ret_status = sme_configure_app_type1_params(hHal, &params);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("sme_configure_app_type1_params returned failure %d"),
cdf_ret_status);
@@ -1743,12 +1743,12 @@ static int hdd_set_app_type2_params(tHalHandle hHal,
tpSirAppType2Params arg_params)
{
tSirAppType2Params params;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
cdf_mem_copy(&params, arg_params, sizeof(params));
cdf_ret_status = sme_configure_app_type2_params(hHal, &params);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("sme_configure_app_type2_params returned failure %d"),
cdf_ret_status);
@@ -2105,7 +2105,7 @@ static int wlan_hdd_get_link_status(hdd_adapter_t *adapter)
hdd_station_ctx_t *pHddStaCtx =
WLAN_HDD_GET_STATION_CTX_PTR(adapter);
struct statsContext context;
CDF_STATUS hstatus;
QDF_STATUS hstatus;
unsigned long rc;
if (cds_is_driver_recovering()) {
@@ -2137,7 +2137,7 @@ static int wlan_hdd_get_link_status(hdd_adapter_t *adapter)
hstatus = sme_get_link_status(WLAN_HDD_GET_HAL_CTX(adapter),
hdd_get_link_status_cb,
&context, adapter->sessionId);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve link status", __func__);
/* return a cached value */
@@ -2399,7 +2399,7 @@ static int hdd_parse_get_cckm_ie(uint8_t *pValue, uint8_t **pCckmIe,
int wlan_hdd_set_mc_rate(hdd_adapter_t *pAdapter, int targetRate)
{
tSirRateUpdateInd rateUpdate = {0};
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
struct hdd_config *pConfig = NULL;
@@ -2433,7 +2433,7 @@ int wlan_hdd_set_mc_rate(hdd_adapter_t *pAdapter, int targetRate)
hdd_device_mode_to_string(pAdapter->device_mode),
pAdapter->device_mode);
status = sme_send_rate_update_ind(pHddCtx->hHal, &rateUpdate);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: SETMCRATE failed",
__func__);
return -EFAULT;
@@ -2557,7 +2557,7 @@ static int drv_cmd_country(hdd_adapter_t *adapter,
hdd_priv_data_t *priv_data)
{
int ret = 0;
CDF_STATUS status;
QDF_STATUS status;
unsigned long rc;
char *country_code;
@@ -2572,7 +2572,7 @@ static int drv_cmd_country(hdd_adapter_t *adapter,
hdd_ctx->pcds_context,
eSIR_TRUE,
eSIR_TRUE);
if (status == CDF_STATUS_SUCCESS) {
if (status == QDF_STATUS_SUCCESS) {
rc = wait_for_completion_timeout(
&adapter->change_country_code,
msecs_to_jiffies(WLAN_WAIT_TIME_COUNTRY));
@@ -2600,7 +2600,7 @@ static int drv_cmd_set_roam_trigger(hdd_adapter_t *adapter,
uint8_t *value = command;
int8_t rssi = 0;
uint8_t lookUpThreshold = CFG_NEIGHBOR_LOOKUP_RSSI_THRESHOLD_DEFAULT;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
/* Move pointer to ahead of SETROAMTRIGGER<delimiter> */
value = value + command_len + 1;
@@ -2648,7 +2648,7 @@ static int drv_cmd_set_roam_trigger(hdd_adapter_t *adapter,
status = sme_set_neighbor_lookup_rssi_threshold(hdd_ctx->hHal,
adapter->sessionId,
lookUpThreshold);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: Failed to set roam trigger, try again",
@@ -3131,7 +3131,7 @@ static int drv_cmd_get_roam_scan_channels(hdd_adapter_t *adapter,
char extra[128] = { 0 };
int len;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_get_roam_scan_channel_list(hdd_ctx->hHal,
ChannelList,
&numChannels,
@@ -4160,7 +4160,7 @@ static void hdd_wma_send_fastreassoc_cmd(int sessionId, tSirMacAddr bssid,
msg.type = SIR_HAL_ROAM_INVOKE;
msg.reserved = 0;
msg.bodyptr = fastreassoc;
if (CDF_STATUS_SUCCESS != cds_mq_post_message(CDF_MODULE_ID_WMA,
if (QDF_STATUS_SUCCESS != cds_mq_post_message(CDF_MODULE_ID_WMA,
&msg)) {
cdf_mem_free(fastreassoc);
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
@@ -4237,7 +4237,7 @@ static int drv_cmd_fast_reassoc(hdd_adapter_t *adapter,
}
/* Check channel number is a valid channel number */
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_validate_operation_channel(adapter, channel)) {
hddLog(LOGE, FL("Invalid Channel [%d]"), channel);
return -EINVAL;
@@ -4272,7 +4272,7 @@ static int drv_cmd_ccx_plm_req(hdd_adapter_t *adapter,
{
int ret = 0;
uint8_t *value = command;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
tpSirPlmReq pPlmRequest = NULL;
pPlmRequest = cdf_mem_malloc(sizeof(tSirPlmReq));
@@ -4282,7 +4282,7 @@ static int drv_cmd_ccx_plm_req(hdd_adapter_t *adapter,
}
status = hdd_parse_plm_cmd(value, pPlmRequest);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
cdf_mem_free(pPlmRequest);
pPlmRequest = NULL;
ret = -EINVAL;
@@ -4291,7 +4291,7 @@ static int drv_cmd_ccx_plm_req(hdd_adapter_t *adapter,
pPlmRequest->sessionId = adapter->sessionId;
status = sme_set_plm_request(hdd_ctx->hHal, pPlmRequest);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
cdf_mem_free(pPlmRequest);
pPlmRequest = NULL;
ret = -EINVAL;
@@ -4600,7 +4600,7 @@ static int drv_cmd_miracast(hdd_adapter_t *adapter,
uint8_t command_len,
hdd_priv_data_t *priv_data)
{
CDF_STATUS ret_status;
QDF_STATUS ret_status;
int ret = 0;
tHalHandle hHal;
uint8_t filterType = 0;
@@ -4646,7 +4646,7 @@ static int drv_cmd_miracast(hdd_adapter_t *adapter,
pHddCtx->miracast_value = filterType;
ret_status = sme_set_miracast(hHal, filterType);
if (CDF_STATUS_SUCCESS != ret_status) {
if (QDF_STATUS_SUCCESS != ret_status) {
hddLog(LOGE, "Failed to set miracast");
return -EBUSY;
}
@@ -4669,7 +4669,7 @@ static int drv_cmd_set_ccx_roam_scan_channels(hdd_adapter_t *adapter,
uint8_t *value = command;
uint8_t ChannelList[WNI_CFG_VALID_CHANNEL_LIST_LEN] = { 0 };
uint8_t numChannels = 0;
CDF_STATUS status;
QDF_STATUS status;
ret = hdd_parse_channellist(value, ChannelList, &numChannels);
if (ret) {
@@ -4693,7 +4693,7 @@ static int drv_cmd_set_ccx_roam_scan_channels(hdd_adapter_t *adapter,
adapter->sessionId,
ChannelList,
numChannels);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: Failed to update channel list information",
@@ -4769,7 +4769,7 @@ static int drv_cmd_get_tsm_stats(hdd_adapter_t *adapter,
CDF_TRACE_LEVEL_INFO,
"%s: Received Command to get tsm stats tid = %d",
__func__, tid);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hdd_get_tsm_stats(adapter, tid, &tsm_metrics)) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
@@ -4878,7 +4878,7 @@ static int drv_cmd_ccx_beacon_req(hdd_adapter_t *adapter,
int ret;
uint8_t *value = command;
tCsrEseBeaconReq eseBcnReq;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (WLAN_HDD_INFRA_STATION != adapter->device_mode) {
hdd_warn("Unsupported in mode %s(%d)",
@@ -4909,13 +4909,13 @@ static int drv_cmd_ccx_beacon_req(hdd_adapter_t *adapter,
adapter->sessionId,
&eseBcnReq);
if (CDF_STATUS_E_RESOURCES == status) {
if (QDF_STATUS_E_RESOURCES == status) {
hddLog(CDF_TRACE_LEVEL_INFO,
FL("sme_set_ese_beacon_request failed (%d), a request already in progress"),
status);
ret = -EBUSY;
goto exit;
} else if (CDF_STATUS_SUCCESS != status) {
} else if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: sme_set_ese_beacon_request failed (%d)",
@@ -4960,8 +4960,8 @@ static int drv_cmd_max_tx_power(hdd_adapter_t *adapter,
int ret = 0;
int status;
int txPower;
CDF_STATUS cdf_status;
CDF_STATUS smeStatus;
QDF_STATUS qdf_status;
QDF_STATUS smeStatus;
uint8_t *value = command;
struct cdf_mac_addr bssid = CDF_MAC_ADDR_BROADCAST_INITIALIZER;
struct cdf_mac_addr selfMac = CDF_MAC_ADDR_BROADCAST_INITIALIZER;
@@ -4977,9 +4977,9 @@ static int drv_cmd_max_tx_power(hdd_adapter_t *adapter,
goto exit;
}
cdf_status = hdd_get_front_adapter(hdd_ctx, &pAdapterNode);
qdf_status = hdd_get_front_adapter(hdd_ctx, &pAdapterNode);
while (NULL != pAdapterNode
&& CDF_STATUS_SUCCESS == cdf_status) {
&& QDF_STATUS_SUCCESS == qdf_status) {
adapter = pAdapterNode->pAdapter;
/* Assign correct self MAC address */
cdf_copy_macaddr(&bssid,
@@ -4995,7 +4995,7 @@ static int drv_cmd_max_tx_power(hdd_adapter_t *adapter,
smeStatus = sme_set_max_tx_power(hdd_ctx->hHal,
bssid, selfMac, txPower);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s:Set max tx power failed",
__func__);
@@ -5005,7 +5005,7 @@ static int drv_cmd_max_tx_power(hdd_adapter_t *adapter,
hddLog(CDF_TRACE_LEVEL_INFO,
"%s: Set max tx power success",
__func__);
cdf_status = hdd_get_next_adapter(hdd_ctx, pAdapterNode,
qdf_status = hdd_get_next_adapter(hdd_ctx, pAdapterNode,
&pNext);
pAdapterNode = pNext;
}
@@ -5910,7 +5910,7 @@ static int drv_cmd_set_fcc_channel(hdd_adapter_t *adapter,
{
uint8_t *value;
uint8_t fcc_constraint;
CDF_STATUS status;
QDF_STATUS status;
int ret = 0;
/*
@@ -5936,7 +5936,7 @@ static int drv_cmd_set_fcc_channel(hdd_adapter_t *adapter,
}
status = sme_disable_non_fcc_channel(hdd_ctx->hHal, !fcc_constraint);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hdd_err("sme disable fn. returned err");
ret = -EPERM;
}

38
core/hdd/src/wlan_hdd_ipa.c
Fájl megtekintése

@@ -1234,7 +1234,7 @@ static void
hdd_ipa_uc_rm_notify_handler(void *context, enum ipa_rm_event event)
{
struct hdd_ipa_priv *hdd_ipa = context;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
/*
* When SSR is going on or driver is unloading, just return.
@@ -1354,7 +1354,7 @@ static void hdd_ipa_uc_op_cb(struct op_msg_type *op_msg, void *usr_ctxt)
struct IpaHwStatsWDIInfoData_t ipa_stat;
struct hdd_ipa_priv *hdd_ipa;
hdd_context_t *hdd_ctx;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (!op_msg || !usr_ctxt) {
HDD_IPA_LOG(CDF_TRACE_LEVEL_ERROR, "%s, INVALID ARG", __func__);
@@ -1664,7 +1664,7 @@ static void hdd_ipa_uc_offload_enable_disable(hdd_adapter_t *adapter,
ipa_offload_enable_disable.vdev_id,
ipa_offload_enable_disable.enable);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_ipa_offload_enable_disable(WLAN_HDD_GET_HAL_CTX(adapter),
adapter->sessionId, &ipa_offload_enable_disable)) {
HDD_IPA_LOG(CDF_TRACE_LEVEL_ERROR,
@@ -1716,7 +1716,7 @@ static void hdd_ipa_uc_op_event_handler(uint8_t *op_msg, void *hdd_ctx)
struct hdd_ipa_priv *hdd_ipa;
struct op_msg_type *msg;
struct uc_op_work_struct *uc_op_work;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
status = wlan_hdd_validate_context(hdd_ctx);
if (0 != status) {
@@ -1775,9 +1775,9 @@ static void hdd_ipa_init_uc_op_work(struct work_struct *work,
* hdd_ipa_uc_ol_init() - Initialize IPA uC offload
* @hdd_ctx: Global HDD context
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
static CDF_STATUS hdd_ipa_uc_ol_init(hdd_context_t *hdd_ctx)
static QDF_STATUS hdd_ipa_uc_ol_init(hdd_context_t *hdd_ctx)
{
struct ipa_wdi_in_params pipe_in;
struct ipa_wdi_out_params pipe_out;
@@ -1879,7 +1879,7 @@ static CDF_STATUS hdd_ipa_uc_ol_init(hdd_context_t *hdd_ctx)
ipa_ctxt->uc_op_work[i].msg = NULL;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -2827,7 +2827,7 @@ static void hdd_ipa_i2w_cb(void *priv, enum ipa_dp_evt_type evt,
struct hdd_ipa_iface_context *iface_context;
cdf_nbuf_t skb;
struct hdd_ipa_pm_tx_cb *pm_tx_cb = NULL;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
iface_context = (struct hdd_ipa_iface_context *)priv;
if (evt != IPA_RECEIVE) {
@@ -3511,7 +3511,7 @@ static void hdd_ipa_msg_free_fn(void *buff, uint32_t len, uint32_t type)
int hdd_ipa_send_mcc_scc_msg(hdd_context_t *pHddCtx, bool mcc_mode)
{
hdd_adapter_list_node_t *adapter_node = NULL, *next = NULL;
CDF_STATUS status;
QDF_STATUS status;
hdd_adapter_t *pAdapter;
struct ipa_msg_meta meta;
struct ipa_wlan_msg *msg;
@@ -3523,7 +3523,7 @@ int hdd_ipa_send_mcc_scc_msg(hdd_context_t *pHddCtx, bool mcc_mode)
if (!pHddCtx->mcc_mode) {
/* Flush TxRx queue for each adapter before switch to SCC */
status = hdd_get_front_adapter(pHddCtx, &adapter_node);
while (NULL != adapter_node && CDF_STATUS_SUCCESS == status) {
while (NULL != adapter_node && QDF_STATUS_SUCCESS == status) {
pAdapter = adapter_node->pAdapter;
if (pAdapter->device_mode == WLAN_HDD_INFRA_STATION ||
pAdapter->device_mode == WLAN_HDD_SOFTAP) {
@@ -4002,16 +4002,16 @@ static inline char *hdd_ipa_rm_state_to_str(enum hdd_ipa_rm_state state)
* Allocate hdd_ipa resources, ipa pipe resource and register
* wlan interface with IPA module.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx)
QDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx)
{
struct hdd_ipa_priv *hdd_ipa = NULL;
int ret, i;
struct hdd_ipa_iface_context *iface_context = NULL;
if (!hdd_ipa_is_enabled(hdd_ctx))
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
hdd_ipa = cdf_mem_malloc(sizeof(*hdd_ipa));
if (!hdd_ipa) {
@@ -4097,7 +4097,7 @@ CDF_STATUS hdd_ipa_init(hdd_context_t *hdd_ctx)
goto fail_create_sys_pipe;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
fail_create_sys_pipe:
hdd_ipa_destroy_rm_resource(hdd_ipa);
@@ -4108,7 +4108,7 @@ fail_get_resource:
hdd_ctx->hdd_ipa = NULL;
ghdd_ipa = NULL;
fail_return:
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/**
@@ -4133,9 +4133,9 @@ void hdd_ipa_cleanup_pending_event(struct hdd_ipa_priv *hdd_ipa)
* hdd_ipa_cleanup - IPA cleanup function
* @hdd_ctx: HDD global context
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
QDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
{
struct hdd_ipa_priv *hdd_ipa = hdd_ctx->hdd_ipa;
int i;
@@ -4144,7 +4144,7 @@ CDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
struct hdd_ipa_pm_tx_cb *pm_tx_cb = NULL;
if (!hdd_ipa_is_enabled(hdd_ctx))
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
if (!hdd_ipa_uc_is_enabled(hdd_ctx)) {
unregister_inetaddr_notifier(&hdd_ipa->ipv4_notifier);
@@ -4222,6 +4222,6 @@ CDF_STATUS hdd_ipa_cleanup(hdd_context_t *hdd_ctx)
cdf_mem_free(hdd_ipa);
hdd_ctx->hdd_ipa = NULL;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif /* IPA_OFFLOAD */

508
core/hdd/src/wlan_hdd_main.c
Fájl megtekintése

A különbségek nem kerülnek megjelenítésre, mivel a fájl túl nagy Load Diff

22
core/hdd/src/wlan_hdd_memdump.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -197,7 +197,7 @@ static int __wlan_hdd_cfg80211_get_fw_mem_dump(struct wiphy *wiphy,
const void *data, int data_len)
{
int status;
CDF_STATUS sme_status;
QDF_STATUS sme_status;
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
struct fw_dump_req fw_mem_dump_req;
struct fw_dump_seg_req *seg_req;
@@ -296,7 +296,7 @@ static int __wlan_hdd_cfg80211_get_fw_mem_dump(struct wiphy *wiphy,
spin_unlock(&hdd_context_lock);
sme_status = sme_fw_mem_dump(hdd_ctx->hHal, &fw_mem_dump_req);
if (CDF_STATUS_SUCCESS != sme_status) {
if (QDF_STATUS_SUCCESS != sme_status) {
hddLog(LOGE, FL("sme_fw_mem_dump Failed"));
mutex_lock(&hdd_ctx->memdump_lock);
cdf_os_mem_free_consistent(cdf_ctx,
@@ -539,8 +539,8 @@ int memdump_init(void)
{
hdd_context_t *hdd_ctx;
int status = 0;
CDF_STATUS cb_status;
CDF_STATUS cdf_status;
QDF_STATUS cb_status;
QDF_STATUS qdf_status;
hdd_ctx = cds_get_context(CDF_MODULE_ID_HDD);
if (!hdd_ctx) {
@@ -555,7 +555,7 @@ int memdump_init(void)
cb_status = sme_fw_mem_dump_register_cb(hdd_ctx->hHal,
wlan_hdd_cfg80211_fw_mem_dump_cb);
if (CDF_STATUS_SUCCESS != cb_status) {
if (QDF_STATUS_SUCCESS != cb_status) {
hddLog(LOGE , FL("Failed to register the callback"));
return -EINVAL;
}
@@ -568,10 +568,10 @@ int memdump_init(void)
init_completion(&fw_dump_context.response_event);
cdf_status = cdf_mc_timer_init(&hdd_ctx->memdump_cleanup_timer,
qdf_status = cdf_mc_timer_init(&hdd_ctx->memdump_cleanup_timer,
CDF_TIMER_TYPE_SW, memdump_cleanup_timer_cb,
(void *)hdd_ctx);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE, FL("Failed to init memdump cleanup timer"));
return -EINVAL;
}
@@ -594,7 +594,7 @@ void memdump_deinit(void)
cdf_dma_addr_t paddr;
cdf_dma_addr_t dma_ctx = 0;
cdf_device_t cdf_ctx;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
hdd_ctx = cds_get_context(CDF_MODULE_ID_HDD);
if (!hdd_ctx) {
@@ -631,7 +631,7 @@ void memdump_deinit(void)
cdf_mc_timer_stop(&hdd_ctx->memdump_cleanup_timer);
}
cdf_status = cdf_mc_timer_destroy(&hdd_ctx->memdump_cleanup_timer);
if (!CDF_IS_STATUS_SUCCESS(cdf_status))
qdf_status = cdf_mc_timer_destroy(&hdd_ctx->memdump_cleanup_timer);
if (!QDF_IS_STATUS_SUCCESS(qdf_status))
hddLog(LOGE, FL("Failed to deallocate timer"));
}

4
core/hdd/src/wlan_hdd_nan.c
Fájl megtekintése

@@ -58,7 +58,7 @@ static int __wlan_hdd_cfg80211_nan_request(struct wiphy *wiphy,
int data_len)
{
tNanRequestReq nan_req;
CDF_STATUS status;
QDF_STATUS status;
int ret_val;
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
@@ -82,7 +82,7 @@ static int __wlan_hdd_cfg80211_nan_request(struct wiphy *wiphy,
nan_req.request_data = data;
status = sme_nan_request(&nan_req);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
ret_val = -EINVAL;
}
return ret_val;

2
core/hdd/src/wlan_hdd_napi.c
Fájl megtekintése

@@ -121,7 +121,7 @@ int hdd_napi_create(void)
* services/calls.
* For Rome, there is only one service, hence a single call
*/
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hif_map_service_to_pipe(hif_ctx, HTT_DATA_MSG_SVC,
&ul, &dl, &ul_polled, &dl_polled)) {
hdd_err("cannot map service to pipe");

30
core/hdd/src/wlan_hdd_ocb.c
Fájl megtekintése

@@ -241,16 +241,16 @@ static int hdd_ocb_validate_config(hdd_adapter_t *adapter,
*/
static int hdd_ocb_register_sta(hdd_adapter_t *adapter)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
struct ol_txrx_desc_type sta_desc = {0};
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(adapter);
uint8_t peer_id;
cdf_status = ol_txrx_register_ocb_peer(hdd_ctx->pcds_context,
qdf_status = ol_txrx_register_ocb_peer(hdd_ctx->pcds_context,
adapter->macAddressCurrent.bytes,
&peer_id);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE, FL("Error registering OCB Self Peer!"));
return -EINVAL;
}
@@ -260,11 +260,11 @@ static int hdd_ocb_register_sta(hdd_adapter_t *adapter)
sta_desc.sta_id = peer_id;
sta_desc.is_qos_enabled = 1;
cdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
qdf_status = ol_txrx_register_peer(hdd_rx_packet_cbk,
&sta_desc);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOGE, FL("Failed to register. Status= %d [0x%08X]"),
cdf_status, cdf_status);
qdf_status, qdf_status);
return -EINVAL;
}
@@ -400,7 +400,7 @@ static int hdd_ocb_set_config_req(hdd_adapter_t *adapter,
struct sir_ocb_config *config)
{
int rc;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
struct hdd_ocb_ctxt context = {0};
if (hdd_ocb_validate_config(adapter, config)) {
@@ -417,10 +417,10 @@ static int hdd_ocb_set_config_req(hdd_adapter_t *adapter,
netif_carrier_off(adapter->dev);
/* Call the SME API to set the config */
cdf_status = sme_ocb_set_config(
qdf_status = sme_ocb_set_config(
((hdd_context_t *)adapter->pHddCtx)->hHal, &context,
hdd_ocb_set_config_callback, config);
if (cdf_status != CDF_STATUS_SUCCESS) {
if (qdf_status != QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error calling SME function."));
/* Convert from ecdf_status to errno */
return -EINVAL;
@@ -1036,7 +1036,7 @@ static int __wlan_hdd_cfg80211_ocb_set_utc_time(struct wiphy *wiphy,
cdf_mem_copy(utc->time_error, nla_data(time_error_attr),
SIZE_UTC_TIME_ERROR);
if (sme_ocb_set_utc_time(hdd_ctx->hHal, utc) != CDF_STATUS_SUCCESS) {
if (sme_ocb_set_utc_time(hdd_ctx->hHal, utc) != QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error while setting UTC time"));
rc = -EINVAL;
} else {
@@ -1152,7 +1152,7 @@ __wlan_hdd_cfg80211_ocb_start_timing_advert(struct wiphy *wiphy,
}
if (sme_ocb_start_timing_advert(hdd_ctx->hHal, timing_advert) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error while starting timing advert"));
rc = -EINVAL;
} else {
@@ -1254,7 +1254,7 @@ __wlan_hdd_cfg80211_ocb_stop_timing_advert(struct wiphy *wiphy,
tb[QCA_WLAN_VENDOR_ATTR_OCB_STOP_TIMING_ADVERT_CHANNEL_FREQ]);
if (sme_ocb_stop_timing_advert(hdd_ctx->hHal, timing_advert) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error while stopping timing advert"));
rc = -EINVAL;
} else {
@@ -1586,7 +1586,7 @@ static int __wlan_hdd_cfg80211_dcc_get_stats(struct wiphy *wiphy,
&request);
if (rc) {
hddLog(LOGE, FL("Error calling SME function"));
/* Need to convert from cdf_status to errno. */
/* Need to convert from qdf_status to errno. */
return -EINVAL;
}
@@ -1733,7 +1733,7 @@ static int __wlan_hdd_cfg80211_dcc_clear_stats(struct wiphy *wiphy,
if (sme_dcc_clear_stats(hdd_ctx->hHal, adapter->sessionId,
nla_get_u32(
tb[QCA_WLAN_VENDOR_ATTR_DCC_CLEAR_STATS_BITMAP])) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Error calling SME function."));
return -EINVAL;
}
@@ -1882,7 +1882,7 @@ static int __wlan_hdd_cfg80211_dcc_update_ndl(struct wiphy *wiphy,
&request);
if (rc) {
hddLog(LOGE, FL("Error calling SME function."));
/* Convert from cdf_status to errno */
/* Convert from qdf_status to errno */
return -EINVAL;
}

28
core/hdd/src/wlan_hdd_oemdata.c
Fájl megtekintése

@@ -58,7 +58,7 @@ static struct hdd_context_s *p_hdd_ctx;
static int populate_oem_data_cap(hdd_adapter_t *adapter,
t_iw_oem_data_cap *data_cap)
{
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
struct hdd_config *config;
uint32_t num_chan;
uint8_t *chan_list;
@@ -97,7 +97,7 @@ static int populate_oem_data_cap(hdd_adapter_t *adapter,
num_chan = WNI_CFG_VALID_CHANNEL_LIST_LEN;
status = sme_get_cfg_valid_channels(hdd_ctx->hHal,
&chan_list[0], &num_chan);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hdd_err("failed to get valid channel list, status: %d", status);
cdf_mem_free(chan_list);
return -EINVAL;
@@ -179,7 +179,7 @@ static void send_oem_reg_rsp_nlink_msg(void)
hdd_adapter_list_node_t *pAdapterNode = NULL;
hdd_adapter_list_node_t *pNext = NULL;
hdd_adapter_t *pAdapter = NULL;
CDF_STATUS status = 0;
QDF_STATUS status = 0;
/* OEM message is always to a specific process and cannot be a broadcast */
if (p_hdd_ctx->oem_pid == 0) {
@@ -215,7 +215,7 @@ static void send_oem_reg_rsp_nlink_msg(void)
/* Iterate through each of the adapters and fill device mode and vdev id */
status = hdd_get_front_adapter(p_hdd_ctx, &pAdapterNode);
while ((CDF_STATUS_SUCCESS == status) && pAdapterNode) {
while ((QDF_STATUS_SUCCESS == status) && pAdapterNode) {
pAdapter = pAdapterNode->pAdapter;
if (pAdapter) {
deviceMode = buf++;
@@ -364,27 +364,27 @@ void hdd_send_oem_data_rsp_msg(int length, uint8_t *oemDataRsp)
*
* This function sends oem message to SME
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS oem_process_data_req_msg(int oemDataLen, char *oemData)
static QDF_STATUS oem_process_data_req_msg(int oemDataLen, char *oemData)
{
hdd_adapter_t *pAdapter = NULL;
tOemDataReqConfig oemDataReqConfig;
uint32_t oemDataReqID = 0;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
/* for now, STA interface only */
pAdapter = hdd_get_adapter(p_hdd_ctx, WLAN_HDD_INFRA_STATION);
if (!pAdapter) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: No adapter for STA mode", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (!oemData) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: oemData is null", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_zero(&oemDataReqConfig, sizeof(tOemDataReqConfig));
@@ -392,7 +392,7 @@ static CDF_STATUS oem_process_data_req_msg(int oemDataLen, char *oemData)
oemDataReqConfig.data = cdf_mem_malloc(oemDataLen);
if (!oemDataReqConfig.data) {
hddLog(LOGE, FL("malloc failed for data req buffer"));
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
oemDataReqConfig.data_len = oemDataLen;
@@ -431,7 +431,7 @@ static int oem_process_channel_info_req_msg(int numOfChannels, char *chanList)
uint8_t chanId;
uint32_t reg_info_1;
uint32_t reg_info_2;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
int i;
uint8_t *buf;
@@ -479,7 +479,7 @@ static int oem_process_channel_info_req_msg(int numOfChannels, char *chanList)
chanId = chanList[i];
status = sme_get_reg_info(p_hdd_ctx->hHal, chanId,
&reg_info_1, &reg_info_2);
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
/* copy into hdd chan info struct */
hddChanInfo.chan_id = chanId;
hddChanInfo.reserved0 = 0;
@@ -538,7 +538,7 @@ static int oem_process_channel_info_req_msg(int numOfChannels, char *chanList)
static int oem_process_set_cap_req_msg(int oem_cap_len,
char *oem_cap, int32_t app_pid)
{
CDF_STATUS status;
QDF_STATUS status;
int error_code;
struct sk_buff *skb;
struct nlmsghdr *nlh;
@@ -552,7 +552,7 @@ static int oem_process_set_cap_req_msg(int oem_cap_len,
status = sme_oem_update_capability(p_hdd_ctx->hHal,
(struct sme_oem_capability *)oem_cap);
if (!CDF_IS_STATUS_SUCCESS(status))
if (!QDF_IS_STATUS_SUCCESS(status))
hdd_err("error updating rm capability, status: %d", status);
error_code = cdf_status_to_os_return(status);

46
core/hdd/src/wlan_hdd_p2p.c
Fájl megtekintése

@@ -160,8 +160,8 @@ static bool hdd_p2p_is_action_type_rsp(const u8 *buf)
}
static
CDF_STATUS wlan_hdd_remain_on_channel_callback(tHalHandle hHal, void *pCtx,
CDF_STATUS status, uint32_t scan_id)
QDF_STATUS wlan_hdd_remain_on_channel_callback(tHalHandle hHal, void *pCtx,
QDF_STATUS status, uint32_t scan_id)
{
hdd_adapter_t *pAdapter = (hdd_adapter_t *) pCtx;
hdd_cfg80211_state_t *cfgState = WLAN_HDD_GET_CFG_STATE_PTR(pAdapter);
@@ -170,7 +170,7 @@ CDF_STATUS wlan_hdd_remain_on_channel_callback(tHalHandle hHal, void *pCtx,
if (!hdd_ctx) {
hdd_err("Invalid HDD context");
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
mutex_lock(&cfgState->remain_on_chan_ctx_lock);
@@ -181,7 +181,7 @@ CDF_STATUS wlan_hdd_remain_on_channel_callback(tHalHandle hHal, void *pCtx,
hddLog(LOGW,
"%s: No Rem on channel pending for which Rsp is received",
__func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
hddLog(LOG1, "Received remain on channel rsp");
@@ -266,9 +266,9 @@ CDF_STATUS wlan_hdd_remain_on_channel_callback(tHalHandle hHal, void *pCtx,
}
cdf_mem_free(pRemainChanCtx);
complete(&pAdapter->cancel_rem_on_chan_var);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
complete(&pAdapter->rem_on_chan_ready_event);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
void wlan_hdd_cancel_existing_remain_on_channel(hdd_adapter_t *pAdapter)
@@ -542,11 +542,11 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
hdd_remain_on_chan_ctx_t *pRemainChanCtx)
{
hdd_cfg80211_state_t *cfgState = WLAN_HDD_GET_CFG_STATE_PTR(pAdapter);
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
hdd_adapter_t *pAdapter_temp;
CDF_STATUS status;
QDF_STATUS status;
bool isGoPresent = false;
unsigned int duration;
@@ -565,11 +565,11 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
mutex_unlock(&cfgState->remain_on_chan_ctx_lock);
/* Initialize Remain on chan timer */
cdf_status =
qdf_status =
cdf_mc_timer_init(&pRemainChanCtx->hdd_remain_on_chan_timer,
CDF_TIMER_TYPE_SW,
wlan_hdd_remain_on_chan_timeout, pAdapter);
if (cdf_status != CDF_STATUS_SUCCESS) {
if (qdf_status != QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("Not able to initialize remain_on_chan timer"));
mutex_lock(&cfgState->remain_on_chan_ctx_lock);
@@ -581,7 +581,7 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
}
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter_temp = pAdapterNode->pAdapter;
if (pAdapter_temp->device_mode == WLAN_HDD_P2P_GO) {
isGoPresent = true;
@@ -608,7 +608,7 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
uint8_t sessionId = pAdapter->sessionId;
/* call sme API to start remain on channel. */
if (CDF_STATUS_SUCCESS != sme_remain_on_channel(
if (QDF_STATUS_SUCCESS != sme_remain_on_channel(
WLAN_HDD_GET_HAL_CTX(pAdapter),
sessionId,
pRemainChanCtx->chan.hw_value, duration,
@@ -631,7 +631,7 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
if (REMAIN_ON_CHANNEL_REQUEST ==
pRemainChanCtx->rem_on_chan_request) {
if (CDF_STATUS_SUCCESS != sme_register_mgmt_frame(
if (QDF_STATUS_SUCCESS != sme_register_mgmt_frame(
WLAN_HDD_GET_HAL_CTX(pAdapter),
sessionId,
(SIR_MAC_MGMT_FRAME << 2) |
@@ -644,7 +644,7 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
} else if ((WLAN_HDD_SOFTAP == pAdapter->device_mode) ||
(WLAN_HDD_P2P_GO == pAdapter->device_mode)) {
/* call sme API to start remain on channel. */
if (CDF_STATUS_SUCCESS != wlansap_remain_on_channel(
if (QDF_STATUS_SUCCESS != wlansap_remain_on_channel(
#ifdef WLAN_FEATURE_MBSSID
WLAN_HDD_GET_SAP_CTX_PTR(pAdapter),
#else
@@ -665,7 +665,7 @@ static int wlan_hdd_execute_remain_on_channel(hdd_adapter_t *pAdapter,
return -EINVAL;
}
if (CDF_STATUS_SUCCESS != wlansap_register_mgmt_frame(
if (QDF_STATUS_SUCCESS != wlansap_register_mgmt_frame(
#ifdef WLAN_FEATURE_MBSSID
WLAN_HDD_GET_SAP_CTX_PTR(pAdapter),
#else
@@ -987,7 +987,7 @@ void hdd_remain_chan_ready_handler(hdd_adapter_t *pAdapter,
{
hdd_cfg80211_state_t *cfgState = NULL;
hdd_remain_on_chan_ctx_t *pRemainChanCtx = NULL;
CDF_STATUS status;
QDF_STATUS status;
if (NULL == pAdapter) {
hddLog(LOGE, FL("pAdapter is NULL"));
@@ -1017,7 +1017,7 @@ void hdd_remain_chan_ready_handler(hdd_adapter_t *pAdapter,
hdd_remain_on_chan_timer,
(pRemainChanCtx->duration +
COMPLETE_EVENT_PROPOGATE_TIME));
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hddLog(LOGE, "%s: Remain on Channel timer start failed",
__func__);
}
@@ -1430,7 +1430,7 @@ int __wlan_hdd_mgmt_tx(struct wiphy *wiphy, struct wireless_dev *wdev,
remain_on_chan_ctx->
hdd_remain_on_chan_timer,
wait);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hddLog(LOGE,
"%s: Remain on Channel timer start failed",
__func__);
@@ -1572,7 +1572,7 @@ send_frame:
}
}
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_send_action(WLAN_HDD_GET_HAL_CTX(pAdapter),
sessionId, buf, len, extendedWait, noack,
current_freq)) {
@@ -1582,7 +1582,7 @@ send_frame:
}
} else if (WLAN_HDD_SOFTAP == pAdapter->device_mode ||
WLAN_HDD_P2P_GO == pAdapter->device_mode) {
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
#ifdef WLAN_FEATURE_MBSSID
wlansap_send_action(WLAN_HDD_GET_SAP_CTX_PTR(pAdapter),
#else
@@ -1896,7 +1896,7 @@ int hdd_set_p2p_ps(struct net_device *dev, void *msgData)
{
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
tP2pPsConfig NoA;
p2p_app_setP2pPs_t *pappNoA = (p2p_app_setP2pPs_t *) msgData;
@@ -2096,7 +2096,7 @@ void __hdd_indicate_mgmt_frame(hdd_adapter_t *pAdapter,
uint8_t subType = 0;
tActionFrmType actionFrmType;
hdd_cfg80211_state_t *cfgState = NULL;
CDF_STATUS status;
QDF_STATUS status;
hdd_remain_on_chan_ctx_t *pRemainChanCtx = NULL;
hdd_context_t *pHddCtx;
@@ -2270,7 +2270,7 @@ void __hdd_indicate_mgmt_frame(hdd_adapter_t *pAdapter,
hdd_remain_on_chan_timer,
extend_time);
if (status !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog
(LOGE,
"%s: Remain on Channel timer start failed",

146
core/hdd/src/wlan_hdd_power.c
Fájl megtekintése

@@ -103,7 +103,7 @@ static bool ssr_timer_started;
#ifdef WLAN_FEATURE_GTK_OFFLOAD
static void hdd_conf_gtk_offload(hdd_adapter_t *pAdapter, bool fenable)
{
CDF_STATUS ret;
QDF_STATUS ret;
tSirGtkOffloadParams hddGtkOffloadReqParams;
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
@@ -119,7 +119,7 @@ static void hdd_conf_gtk_offload(hdd_adapter_t *pAdapter, bool fenable)
ret = sme_set_gtk_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
&hddGtkOffloadReqParams,
pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: sme_set_gtk_offload failed, returned %d",
@@ -145,7 +145,7 @@ static void hdd_conf_gtk_offload(hdd_adapter_t *pAdapter, bool fenable)
(WLAN_HDD_GET_HAL_CTX(pAdapter),
wlan_hdd_cfg80211_update_replay_counter_callback,
pAdapter, pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: sme_get_gtk_offload failed, returned %d",
@@ -168,7 +168,7 @@ static void hdd_conf_gtk_offload(hdd_adapter_t *pAdapter, bool fenable)
(pAdapter),
&hddGtkOffloadReqParams,
pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: failed to dissable GTK offload, returned %d",
@@ -280,7 +280,7 @@ static void hdd_conf_ns_offload(hdd_adapter_t *pAdapter, bool fenable)
hdd_context_t *pHddCtx;
int i = 0;
CDF_STATUS returnStatus;
QDF_STATUS returnStatus;
uint32_t count = 0, scope;
ENTER();
@@ -394,7 +394,7 @@ static void hdd_conf_ns_offload(hdd_adapter_t *pAdapter, bool fenable)
/* Configure the Firmware with this */
returnStatus = sme_set_host_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &offLoadRequest);
if (CDF_STATUS_SUCCESS != returnStatus) {
if (QDF_STATUS_SUCCESS != returnStatus) {
hdd_err("Failed to enable HostOffload feature with status: %d",
returnStatus);
}
@@ -408,7 +408,7 @@ static void hdd_conf_ns_offload(hdd_adapter_t *pAdapter, bool fenable)
offLoadRequest.enableOrDisable = SIR_OFFLOAD_DISABLE;
offLoadRequest.offloadType = SIR_IPV6_NS_OFFLOAD;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_host_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &offLoadRequest))
hdd_err("Failed to disable NS Offload");
@@ -679,10 +679,10 @@ int wlan_hdd_ipv4_changed(struct notifier_block *nb,
* @fenable: true : enable ARP offload false : disable arp offload
*
* Return:
* CDF_STATUS_SUCCESS - on successful operation,
* CDF_STATUS_E_FAILURE - on failure of operation
* QDF_STATUS_SUCCESS - on successful operation,
* QDF_STATUS_E_FAILURE - on failure of operation
*/
CDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable)
QDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable)
{
struct in_ifaddr **ifap = NULL;
struct in_ifaddr *ifa = NULL;
@@ -701,7 +701,7 @@ CDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable)
!pHddCtx->ap_arpns_support) {
hddLog(LOG1,
FL("ARP Offload is not supported in SAP/P2PGO mode"));
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
if (fenable) {
@@ -749,36 +749,36 @@ CDF_STATUS hdd_conf_arp_offload(hdd_adapter_t *pAdapter, bool fenable)
offLoadRequest.params.hostIpv4Addr[2],
offLoadRequest.params.hostIpv4Addr[3]);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_host_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId,
&offLoadRequest)) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Failed to enable HostOffload feature",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
} else {
hddLog(CDF_TRACE_LEVEL_INFO,
FL("IP Address is not assigned"));
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
} else {
cdf_mem_zero((void *)&offLoadRequest,
sizeof(tSirHostOffloadReq));
offLoadRequest.enableOrDisable = SIR_OFFLOAD_DISABLE;
offLoadRequest.offloadType = SIR_IPV4_ARP_REPLY_OFFLOAD;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_host_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &offLoadRequest)) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Failure to disable host " "offload feature",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
}
@@ -832,7 +832,7 @@ static void hdd_mcbc_filter_modification(hdd_context_t *pHddCtx,
*/
void hdd_conf_mcastbcast_filter(hdd_context_t *pHddCtx, bool setfilter)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
tpSirWlanSetRxpFilters wlanRxpFilterParam =
cdf_mem_malloc(sizeof(tSirWlanSetRxpFilters));
if (NULL == wlanRxpFilterParam) {
@@ -857,17 +857,17 @@ void hdd_conf_mcastbcast_filter(hdd_context_t *pHddCtx, bool setfilter)
cdf_ret_status =
sme_configure_rxp_filter(pHddCtx->hHal, wlanRxpFilterParam);
if (setfilter && (CDF_STATUS_SUCCESS == cdf_ret_status))
if (setfilter && (QDF_STATUS_SUCCESS == cdf_ret_status))
pHddCtx->hdd_mcastbcast_filter_set = true;
hddLog(LOG1,
FL("%s to post set/reset filter to lower mac with status %d configuredMcstBcstFilterSetting = %d setMcstBcstFilter = %d"),
(CDF_STATUS_SUCCESS != cdf_ret_status) ? "Failed" : "Success",
(QDF_STATUS_SUCCESS != cdf_ret_status) ? "Failed" : "Success",
cdf_ret_status,
wlanRxpFilterParam->configuredMcstBcstFilterSetting,
wlanRxpFilterParam->setMcstBcstFilter);
if (CDF_STATUS_SUCCESS != cdf_ret_status)
if (QDF_STATUS_SUCCESS != cdf_ret_status)
cdf_mem_free(wlanRxpFilterParam);
}
@@ -1001,7 +1001,7 @@ static void hdd_send_suspend_ind(hdd_context_t *pHddCtx,
bool suspended),
void *callbackContext)
{
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
hdd_info("%s: send wlan suspend indication", __func__);
@@ -1009,7 +1009,7 @@ static void hdd_send_suspend_ind(hdd_context_t *pHddCtx,
sme_configure_suspend_ind(pHddCtx->hHal, conn_state_mask,
callback, callbackContext);
if (CDF_STATUS_SUCCESS == cdf_ret_status) {
if (QDF_STATUS_SUCCESS == cdf_ret_status) {
pHddCtx->hdd_mcastbcast_filter_set = true;
} else {
hddLog(CDF_TRACE_LEVEL_ERROR,
@@ -1027,11 +1027,11 @@ static void hdd_send_suspend_ind(hdd_context_t *pHddCtx,
static void hdd_conf_resume_ind(hdd_adapter_t *pAdapter)
{
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
cdf_ret_status = sme_configure_resume_req(pHddCtx->hHal, NULL);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: sme_configure_resume_req return failure %d",
__func__, cdf_ret_status);
@@ -1090,7 +1090,7 @@ hdd_suspend_wlan(void (*callback)(void *callbackContext, bool suspended),
{
hdd_context_t *pHddCtx;
CDF_STATUS status;
QDF_STATUS status;
hdd_adapter_t *pAdapter = NULL;
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
uint32_t conn_state_mask = 0;
@@ -1113,7 +1113,7 @@ hdd_suspend_wlan(void (*callback)(void *callbackContext, bool suspended),
hdd_update_mcastbcast_filter(pHddCtx);
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
/* stop all TX queues before suspend */
@@ -1149,7 +1149,7 @@ static void hdd_resume_wlan(void)
hdd_context_t *pHddCtx;
hdd_adapter_t *pAdapter = NULL;
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
CDF_STATUS status;
QDF_STATUS status;
hddLog(CDF_TRACE_LEVEL_INFO, "%s: WLAN being resumed by OS",
__func__);
@@ -1172,7 +1172,7 @@ static void hdd_resume_wlan(void)
/*loop through all adapters. Concurrency */
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
/* wake the tx queues */
@@ -1258,12 +1258,12 @@ static void hdd_ssr_timer_start(int msec)
*
* This function is called by the HIF to shutdown the driver during SSR.
*
* Return: CDF_STATUS_SUCCESS if the driver was shut down,
* Return: QDF_STATUS_SUCCESS if the driver was shut down,
* or an error status otherwise
*/
CDF_STATUS hdd_wlan_shutdown(void)
QDF_STATUS hdd_wlan_shutdown(void)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
v_CONTEXT_t p_cds_context = NULL;
hdd_context_t *pHddCtx;
p_cds_sched_context cds_sched_context = NULL;
@@ -1284,7 +1284,7 @@ CDF_STATUS hdd_wlan_shutdown(void)
if (!p_cds_context) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: Global CDS context is Null",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Get the HDD context. */
@@ -1292,7 +1292,7 @@ CDF_STATUS hdd_wlan_shutdown(void)
if (!pHddCtx) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: HDD context is Null",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cds_set_recovery_in_progress(true);
@@ -1343,12 +1343,12 @@ CDF_STATUS hdd_wlan_shutdown(void)
#endif
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: Doing WMA STOP", __func__);
cdf_status = wma_stop(p_cds_context, HAL_STOP_TYPE_RF_KILL);
qdf_status = wma_stop(p_cds_context, HAL_STOP_TYPE_RF_KILL);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop WMA", __func__);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(cdf_status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(qdf_status));
wma_setneedshutdown(p_cds_context);
}
@@ -1356,19 +1356,19 @@ CDF_STATUS hdd_wlan_shutdown(void)
/* Stop SME - Cannot invoke cds_disable as cds_disable relies
* on threads being running to process the SYS Stop
*/
cdf_status = sme_stop(pHddCtx->hHal, HAL_STOP_TYPE_SYS_RESET);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = sme_stop(pHddCtx->hHal, HAL_STOP_TYPE_SYS_RESET);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop sme %d", __func__, cdf_status);
"%s: Failed to stop sme %d", __func__, qdf_status);
CDF_ASSERT(0);
}
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: Doing MAC STOP", __func__);
/* Stop MAC (PE and HAL) */
cdf_status = mac_stop(pHddCtx->hHal, HAL_STOP_TYPE_SYS_RESET);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = mac_stop(pHddCtx->hHal, HAL_STOP_TYPE_SYS_RESET);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_CDF, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to stop mac %d", __func__, cdf_status);
"%s: Failed to stop mac %d", __func__, qdf_status);
CDF_ASSERT(0);
}
@@ -1389,7 +1389,7 @@ CDF_STATUS hdd_wlan_shutdown(void)
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: WLAN driver shutdown complete",
__func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1397,15 +1397,15 @@ CDF_STATUS hdd_wlan_shutdown(void)
*
* This function is called by the HIF to re-initialize the driver after SSR.
*
* Return: CDF_STATUS_SUCCESS if the driver was re-initialized,
* Return: QDF_STATUS_SUCCESS if the driver was re-initialized,
* or an error status otherwise
*/
CDF_STATUS hdd_wlan_re_init(void *hif_sc)
QDF_STATUS hdd_wlan_re_init(void *hif_sc)
{
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
v_CONTEXT_t p_cds_context = NULL;
hdd_context_t *pHddCtx = NULL;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
hdd_adapter_t *pAdapter;
int i;
@@ -1438,8 +1438,8 @@ CDF_STATUS hdd_wlan_re_init(void *hif_sc)
hdd_set_conparam(0);
/* Re-open CDS, it is a re-open b'se control transport was never closed. */
cdf_status = cds_open();
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cds_open();
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: cds_open failed", __func__);
goto err_re_init;
}
@@ -1452,8 +1452,8 @@ CDF_STATUS hdd_wlan_re_init(void *hif_sc)
goto err_cds_close;
}
cdf_status = cds_pre_enable(pHddCtx->pcds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cds_pre_enable(pHddCtx->pcds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hdd_alert("cds_pre_enable failed");
goto err_cds_close;
}
@@ -1464,16 +1464,16 @@ CDF_STATUS hdd_wlan_re_init(void *hif_sc)
* since the SME config operation must access the cfg database.
* Set the SME configuration parameters.
*/
cdf_status = hdd_set_sme_config(pHddCtx);
if (CDF_STATUS_SUCCESS != cdf_status) {
qdf_status = hdd_set_sme_config(pHddCtx);
if (QDF_STATUS_SUCCESS != qdf_status) {
hdd_alert("Failed hdd_set_sme_config");
goto err_cds_close;
}
ol_txrx_register_pause_cb(wlan_hdd_txrx_pause_cb);
cdf_status = hdd_set_sme_chan_list(pHddCtx);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = hdd_set_sme_chan_list(pHddCtx);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(CDF_TRACE_LEVEL_FATAL,
"%s: Failed to init channel list", __func__);
goto err_cds_close;
@@ -1492,7 +1492,7 @@ CDF_STATUS hdd_wlan_re_init(void *hif_sc)
(uint8_t *) &pHddCtx->config->
intfMacAddr[0],
sizeof(pHddCtx->config->intfMacAddr[0]));
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: Failed to set MAC Address. "
"HALStatus is %08d [x%08x]", __func__, cdf_ret_status,
cdf_ret_status);
@@ -1501,14 +1501,14 @@ CDF_STATUS hdd_wlan_re_init(void *hif_sc)
/* Start CDS which starts up the SME/MAC/HAL modules and everything else
Note: Firmware image will be read and downloaded inside cds_enable API */
cdf_status = cds_enable(p_cds_context);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cds_enable(p_cds_context);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(CDF_TRACE_LEVEL_FATAL, "%s: cds_enable failed", __func__);
goto err_cds_close;
}
cdf_status = hdd_post_cds_enable_config(pHddCtx);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = hdd_post_cds_enable_config(pHddCtx);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(CDF_TRACE_LEVEL_FATAL,
"%s: hdd_post_cds_enable_config failed", __func__);
goto err_cds_disable;
@@ -1628,7 +1628,7 @@ err_cds_close:
wiphy_unregister(pHddCtx->wiphy);
wiphy_free(pHddCtx->wiphy);
if (!CDF_IS_STATUS_SUCCESS(cds_deinit_policy_mgr())) {
if (!QDF_IS_STATUS_SUCCESS(cds_deinit_policy_mgr())) {
hdd_err("Failed to deinit policy manager");
/* Proceed and complete the clean up */
}
@@ -1641,7 +1641,7 @@ err_re_init:
return -EPERM;
success:
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1720,7 +1720,7 @@ static int __wlan_hdd_cfg80211_resume_wlan(struct wiphy *wiphy)
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
hdd_adapter_t *pAdapter;
hdd_adapter_list_node_t *pAdapterNode, *pNext;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
int result;
p_cds_sched_context cds_sched_context = get_cds_sched_ctxt();
@@ -1768,7 +1768,7 @@ static int __wlan_hdd_cfg80211_resume_wlan(struct wiphy *wiphy)
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
if ((NULL != pAdapter) &&
(WLAN_HDD_INFRA_STATION == pAdapter->device_mode)) {
@@ -1857,7 +1857,7 @@ static int __wlan_hdd_cfg80211_suspend_wlan(struct wiphy *wiphy,
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
hdd_adapter_t *pAdapter;
hdd_scaninfo_t *pScanInfo;
CDF_STATUS status;
QDF_STATUS status;
int rc;
ENTER();
@@ -1876,7 +1876,7 @@ static int __wlan_hdd_cfg80211_suspend_wlan(struct wiphy *wiphy,
* until CAC is done for a SoftAP which is in started state.
*/
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
if (WLAN_HDD_SOFTAP == pAdapter->device_mode) {
if (BSS_START ==
@@ -1911,7 +1911,7 @@ static int __wlan_hdd_cfg80211_suspend_wlan(struct wiphy *wiphy,
/* Stop ongoing scan on each interface */
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
pScanInfo = &pAdapter->scan_info;
@@ -2077,7 +2077,7 @@ static int __wlan_hdd_cfg80211_set_power_mgmt(struct wiphy *wiphy,
{
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
int status;
ENTER();
@@ -2105,11 +2105,11 @@ static int __wlan_hdd_cfg80211_set_power_mgmt(struct wiphy *wiphy,
hddLog(LOG1,
FL("offload: in cfg80211_set_power_mgmt, calling arp offload"));
cdf_status = hdd_conf_arp_offload(pAdapter, true);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = hdd_conf_arp_offload(pAdapter, true);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hddLog(LOG1,
FL("Failed to enable ARPOFFLOAD Feature %d"),
cdf_status);
qdf_status);
}
}
@@ -2204,7 +2204,7 @@ static int __wlan_hdd_cfg80211_set_txpower(struct wiphy *wiphy,
/* Fall through */
case NL80211_TX_POWER_LIMITED: /* Limit TX power by the mBm parameter */
if (sme_set_max_tx_power(hHal, bssid, selfMac, dbm) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(LOGE, FL("Setting maximum tx power failed"));
return -EIO;
}

42
core/hdd/src/wlan_hdd_scan.c
Fájl megtekintése

@@ -560,9 +560,9 @@ static int wlan_hdd_scan_request_enqueue(hdd_adapter_t *adapter,
* @source : returns source of the scan request
* @timestamp: scan request timestamp
*
* Return: CDF_STATUS
* Return: QDF_STATUS
*/
CDF_STATUS wlan_hdd_scan_request_dequeue(hdd_context_t *hdd_ctx,
QDF_STATUS wlan_hdd_scan_request_dequeue(hdd_context_t *hdd_ctx,
uint32_t scan_id, struct cfg80211_scan_request **req, uint8_t *source,
uint32_t *timestamp)
{
@@ -633,7 +633,7 @@ CDF_STATUS wlan_hdd_scan_request_dequeue(hdd_context_t *hdd_ctx,
* Return: 0 for success, non zero for failure
*/
static CDF_STATUS
static QDF_STATUS
hdd_scan_request_callback(tHalHandle halHandle, void *pContext,
uint8_t sessionId, uint32_t scanId,
eCsrScanStatus status)
@@ -663,7 +663,7 @@ hdd_scan_request_callback(tHalHandle halHandle, void *pContext,
if (pAdapter->dev != dev) {
hddLog(LOGW, "%s: device mismatch %p vs %p",
__func__, pAdapter->dev, dev);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
wlan_hdd_scan_request_dequeue(hddctx, scanId, &req, &source,
@@ -687,7 +687,7 @@ hdd_scan_request_callback(tHalHandle halHandle, void *pContext,
wireless_send_event(dev, we_event, &wrqu, msg);
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -710,7 +710,7 @@ static int __iw_set_scan(struct net_device *dev, struct iw_request_info *info,
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(pAdapter);
hdd_wext_state_t *pwextBuf = WLAN_HDD_GET_WEXT_STATE_PTR(pAdapter);
tCsrScanRequest scanRequest;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
struct iw_scan_req *scanReq = (struct iw_scan_req *)extra;
hdd_adapter_t *con_sap_adapter;
uint16_t con_dfs_ch;
@@ -832,7 +832,7 @@ static int __iw_set_scan(struct net_device *dev, struct iw_request_info *info,
status = sme_scan_request((WLAN_HDD_GET_CTX(pAdapter))->hHal,
pAdapter->sessionId, &scanRequest,
&hdd_scan_request_callback, dev);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_FATAL,
"%s:sme_scan_request fail %d!!!", __func__, status);
goto error;
@@ -891,7 +891,7 @@ static int __iw_get_scan(struct net_device *dev,
hdd_context_t *hdd_ctx;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
tCsrScanResultInfo *pScanResult;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_scan_info_t scanInfo;
tScanResultHandle pResult;
int i = 0;
@@ -1089,7 +1089,7 @@ nla_put_failure:
*
* Return: CDF status
*/
static CDF_STATUS hdd_cfg80211_scan_done_callback(tHalHandle halHandle,
static QDF_STATUS hdd_cfg80211_scan_done_callback(tHalHandle halHandle,
void *pContext,
uint8_t sessionId,
uint32_t scanId,
@@ -1108,7 +1108,7 @@ static CDF_STATUS hdd_cfg80211_scan_done_callback(tHalHandle halHandle,
ret = wlan_hdd_validate_context(hddctx);
if (0 != ret)
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
hddLog(CDF_TRACE_LEVEL_INFO,
"%s called with hal = %p, pContext = %p, ID = %d, status = %d",
@@ -1121,7 +1121,7 @@ static CDF_STATUS hdd_cfg80211_scan_done_callback(tHalHandle halHandle,
goto allow_suspend;
}
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
wlan_hdd_scan_request_dequeue(hddctx, scanId, &req, &source,
&scan_time)) {
hdd_err("Dequeue of scan request failed ID: %d", scanId);
@@ -1554,9 +1554,9 @@ static int __wlan_hdd_cfg80211_scan(struct wiphy *wiphy,
pAdapter->sessionId, &scan_req,
&hdd_cfg80211_scan_done_callback, dev);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("sme_scan_request returned error %d"), status);
if (CDF_STATUS_E_RESOURCES == status) {
if (QDF_STATUS_E_RESOURCES == status) {
hddLog(LOGE,
FL("HO is in progress.So defer the scan by informing busy"));
status = -EBUSY;
@@ -1985,7 +1985,7 @@ hdd_sched_scan_callback(void *callbackContext,
*
* Return: Success if PNO is allowed, Failure otherwise.
*/
static CDF_STATUS wlan_hdd_is_pno_allowed(hdd_adapter_t *adapter)
static QDF_STATUS wlan_hdd_is_pno_allowed(hdd_adapter_t *adapter)
{
hddLog(LOG1,
FL("dev_mode=%d, conn_state=%d, session ID=%d"),
@@ -1995,9 +1995,9 @@ static CDF_STATUS wlan_hdd_is_pno_allowed(hdd_adapter_t *adapter)
if ((adapter->device_mode == WLAN_HDD_INFRA_STATION) &&
(eConnectionState_NotConnected ==
adapter->sessionCtx.station.conn_info.connState))
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
else
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
@@ -2023,7 +2023,7 @@ static int __wlan_hdd_cfg80211_sched_scan_start(struct wiphy *wiphy,
u8 valid_ch[WNI_CFG_VALID_CHANNEL_LIST_LEN] = { 0 };
u8 channels_allowed[WNI_CFG_VALID_CHANNEL_LIST_LEN] = { 0 };
uint32_t num_channels_allowed = WNI_CFG_VALID_CHANNEL_LIST_LEN;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
int ret = 0;
hdd_scaninfo_t *pScanInfo = &pAdapter->scan_info;
struct hdd_config *config = NULL;
@@ -2079,7 +2079,7 @@ static int __wlan_hdd_cfg80211_sched_scan_start(struct wiphy *wiphy,
}
}
if (CDF_STATUS_E_FAILURE == wlan_hdd_is_pno_allowed(pAdapter)) {
if (QDF_STATUS_E_FAILURE == wlan_hdd_is_pno_allowed(pAdapter)) {
hddLog(LOGE, FL("pno is not allowed"));
return -ENOTSUPP;
}
@@ -2251,7 +2251,7 @@ static int __wlan_hdd_cfg80211_sched_scan_start(struct wiphy *wiphy,
pAdapter->sessionId,
hdd_sched_scan_callback,
pAdapter);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("Failed to enable PNO"));
ret = -EINVAL;
goto error;
@@ -2297,7 +2297,7 @@ int wlan_hdd_cfg80211_sched_scan_start(struct wiphy *wiphy,
static int __wlan_hdd_cfg80211_sched_scan_stop(struct wiphy *wiphy,
struct net_device *dev)
{
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx;
tHalHandle hHal;
@@ -2361,7 +2361,7 @@ static int __wlan_hdd_cfg80211_sched_scan_stop(struct wiphy *wiphy,
status = sme_set_preferred_network_list(hHal, pPnoRequest,
pAdapter->sessionId,
NULL, pAdapter);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("Failed to disabled PNO"));
ret = -EINVAL;
}

154
core/hdd/src/wlan_hdd_softap_tx_rx.c
Fájl megtekintése

@@ -208,7 +208,7 @@ int hdd_softap_hard_start_xmit(struct sk_buff *skb, struct net_device *dev)
*/
STAId = pHddApCtx->uBCStaId;
} else {
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hdd_softap_get_sta_id(pAdapter,
pDestMacAddress, &STAId)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA,
@@ -391,12 +391,12 @@ void hdd_softap_tx_timeout(struct net_device *dev)
* @hdd_softap_init_tx_rx() - Initialize Tx/RX module
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_softap_init_tx_rx(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_softap_init_tx_rx(hdd_adapter_t *pAdapter)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
uint8_t STAId = 0;
@@ -416,12 +416,12 @@ CDF_STATUS hdd_softap_init_tx_rx(hdd_adapter_t *pAdapter)
* @hdd_softap_deinit_tx_rx() - Deinitialize Tx/RX module
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_softap_deinit_tx_rx(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_softap_deinit_tx_rx(hdd_adapter_t *pAdapter)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
return status;
}
@@ -432,10 +432,10 @@ CDF_STATUS hdd_softap_deinit_tx_rx(hdd_adapter_t *pAdapter)
* @STAId: Station ID to initialize
* @pmacAddrSTA: pointer to the MAC address of the station
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId,
QDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId,
struct cdf_mac_addr *pmacAddrSTA)
{
spin_lock_bh(&pAdapter->staInfo_lock);
@@ -443,7 +443,7 @@ CDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId,
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Reinit station %d", __func__, STAId);
spin_unlock_bh(&pAdapter->staInfo_lock);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_mem_zero(&pAdapter->aStaInfo[STAId], sizeof(hdd_station_info_t));
@@ -453,7 +453,7 @@ CDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId,
cdf_copy_macaddr(&pAdapter->aStaInfo[STAId].macAddrSTA, pmacAddrSTA);
spin_unlock_bh(&pAdapter->staInfo_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -461,12 +461,12 @@ CDF_STATUS hdd_softap_init_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId,
* @pAdapter: pointer to adapter context
* @STAId: Station ID to deinitialize
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId)
QDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_hostapd_state_t *pHostapdState;
pHostapdState = WLAN_HDD_GET_HOSTAP_STATE_PTR(pAdapter);
@@ -477,7 +477,7 @@ CDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId)
spin_unlock_bh(&pAdapter->staInfo_lock);
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Deinit station not inited %d", __func__, STAId);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pAdapter->aStaInfo[STAId].isUsed = false;
@@ -497,10 +497,10 @@ CDF_STATUS hdd_softap_deinit_tx_rx_sta(hdd_adapter_t *pAdapter, uint8_t STAId)
* the HDD when one or more packets were received for a registered
* STA.
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
QDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
cdf_nbuf_t rxBuf, uint8_t staId)
{
hdd_adapter_t *pAdapter = NULL;
@@ -516,14 +516,14 @@ CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
if ((NULL == cds_context) || (NULL == rxBuf)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Null params being passed", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pHddCtx = cds_get_context(CDF_MODULE_ID_HDD);
if (NULL == pHddCtx) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: HDD context is Null", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pAdapter = pHddCtx->sta_to_adapter[staId];
@@ -531,7 +531,7 @@ CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
hddLog(LOGE,
FL("invalid adapter %p or adapter has invalid magic"),
pAdapter);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* walk the chain until all are processed */
@@ -545,7 +545,7 @@ CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: ERROR!!Invalid netdevice", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cpu_index = wlan_hdd_get_cpu();
++pAdapter->hdd_stats.hddTxRxStats.rxPackets[cpu_index];
@@ -592,7 +592,7 @@ CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
pAdapter->dev->last_rx = jiffies;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -600,23 +600,23 @@ CDF_STATUS hdd_softap_rx_packet_cbk(void *cds_context,
* @pAdapter: pointer to adapter context
* @staId: Station ID to deregister
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
QDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
{
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
hdd_context_t *pHddCtx;
if (NULL == pAdapter) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: pAdapter is NULL", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
if (WLAN_HDD_ADAPTER_MAGIC != pAdapter->magic) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Invalid pAdapter magic", __func__);
return CDF_STATUS_E_INVAL;
return QDF_STATUS_E_INVAL;
}
pHddCtx = (hdd_context_t *) (pAdapter->pHddCtx);
@@ -624,11 +624,11 @@ CDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
* structures. This helps to block RX frames from other
* station to this station.
*/
cdf_status = ol_txrx_clear_peer(staId);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = ol_txrx_clear_peer(staId);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"ol_txrx_clear_peer() failed to for staID %d. "
"Status= %d [0x%08X]", staId, cdf_status, cdf_status);
"Status= %d [0x%08X]", staId, qdf_status, qdf_status);
}
if (pAdapter->aStaInfo[staId].isUsed) {
@@ -639,7 +639,7 @@ CDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
}
pHddCtx->sta_to_adapter[staId] = NULL;
return cdf_status;
return qdf_status;
}
/**
@@ -653,9 +653,9 @@ CDF_STATUS hdd_softap_deregister_sta(hdd_adapter_t *pAdapter, uint8_t staId)
* @pPeerMacAddress: station MAC address
* @fWmmEnabled: is WMM enabled for this STA?
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
bool fAuthRequired,
bool fPrivacyBit,
uint8_t staId,
@@ -664,7 +664,7 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
struct cdf_mac_addr *pPeerMacAddress,
bool fWmmEnabled)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
struct ol_txrx_desc_type staDesc = { 0 };
hdd_context_t *pHddCtx = pAdapter->pHddCtx;
@@ -683,7 +683,7 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
/*Save the pAdapter Pointer for this staId */
pHddCtx->sta_to_adapter[staId] = pAdapter;
cdf_status =
qdf_status =
hdd_softap_init_tx_rx_sta(pAdapter, staId,
pPeerMacAddress);
@@ -693,14 +693,14 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
staDesc.is_qos_enabled);
cdf_status =
qdf_status =
ol_txrx_register_peer(hdd_softap_rx_packet_cbk,
&staDesc);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"SOFTAP ol_txrx_register_peer() failed to register. Status= %d [0x%08X]",
cdf_status, cdf_status);
return cdf_status;
qdf_status, qdf_status);
return qdf_status;
}
/* if ( WPA ), tell TL to go to 'connected' and after keys come to the
@@ -720,7 +720,7 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
/* Connections that do not need Upper layer auth,
* transition TL directly to 'Authenticated' state.
*/
cdf_status = hdd_change_peer_state(pAdapter, staDesc.sta_id,
qdf_status = hdd_change_peer_state(pAdapter, staDesc.sta_id,
ol_txrx_peer_state_auth, false);
pAdapter->aStaInfo[staId].tlSTAState = ol_txrx_peer_state_auth;
@@ -731,7 +731,7 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
"ULA auth StaId= %d. Changing TL state to CONNECTED at Join time",
pAdapter->aStaInfo[staId].ucSTAId);
cdf_status = hdd_change_peer_state(pAdapter, staDesc.sta_id,
qdf_status = hdd_change_peer_state(pAdapter, staDesc.sta_id,
ol_txrx_peer_state_conn, false);
pAdapter->aStaInfo[staId].tlSTAState = ol_txrx_peer_state_conn;
@@ -745,7 +745,7 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
WLAN_START_ALL_NETIF_QUEUE_N_CARRIER,
WLAN_CONTROL_PATH);
return cdf_status;
return qdf_status;
}
/**
@@ -753,12 +753,12 @@ CDF_STATUS hdd_softap_register_sta(hdd_adapter_t *pAdapter,
* @pAdapter: pointer to adapter context
* @fPrivacyBit: should 802.11 privacy bit be set?
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_register_bc_sta(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_register_bc_sta(hdd_adapter_t *pAdapter,
bool fPrivacyBit)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
struct cdf_mac_addr broadcastMacAddr =
CDF_MAC_ADDR_BROADCAST_INITIALIZER;
@@ -772,21 +772,21 @@ CDF_STATUS hdd_softap_register_bc_sta(hdd_adapter_t *pAdapter,
#else
pHddCtx->sta_to_adapter[WLAN_RX_SAP_SELF_STA_ID] = pAdapter;
#endif
cdf_status =
qdf_status =
hdd_softap_register_sta(pAdapter, false, fPrivacyBit,
(WLAN_HDD_GET_AP_CTX_PTR(pAdapter))->
uBCStaId, 0, 1, &broadcastMacAddr, 0);
return cdf_status;
return qdf_status;
}
/**
* hdd_softap_deregister_bc_sta() - Deregister the SoftAP broadcast STA
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_deregister_bc_sta(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_softap_deregister_bc_sta(hdd_adapter_t *pAdapter)
{
return hdd_softap_deregister_sta(pAdapter,
(WLAN_HDD_GET_AP_CTX_PTR(pAdapter))->
@@ -797,11 +797,11 @@ CDF_STATUS hdd_softap_deregister_bc_sta(hdd_adapter_t *pAdapter)
* hdd_softap_stop_bss() - Stop the BSS
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
uint8_t staId = 0;
hdd_context_t *pHddCtx;
pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
@@ -813,12 +813,12 @@ CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Loading_unloading in Progress, state: 0x%x. Ignore!!!",
__func__, cds_get_driver_state());
return CDF_STATUS_E_PERM;
return QDF_STATUS_E_PERM;
}
cdf_status = hdd_softap_deregister_bc_sta(pAdapter);
qdf_status = hdd_softap_deregister_bc_sta(pAdapter);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to deregister BC sta Id %d", __func__,
(WLAN_HDD_GET_AP_CTX_PTR(pAdapter))->uBCStaId);
@@ -827,8 +827,8 @@ CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
for (staId = 0; staId < WLAN_MAX_STA_COUNT; staId++) {
/* This excludes BC sta as it is already deregistered */
if (pAdapter->aStaInfo[staId].isUsed) {
cdf_status = hdd_softap_deregister_sta(pAdapter, staId);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = hdd_softap_deregister_sta(pAdapter, staId);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA,
CDF_TRACE_LEVEL_ERROR,
"%s: Failed to deregister sta Id %d",
@@ -836,7 +836,7 @@ CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
}
}
}
return cdf_status;
return qdf_status;
}
/**
@@ -845,24 +845,24 @@ CDF_STATUS hdd_softap_stop_bss(hdd_adapter_t *pAdapter)
* @pDestMacAddress: MAC address of the station
* @state: new state of the station
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
struct cdf_mac_addr *pDestMacAddress,
enum ol_txrx_peer_state state)
{
uint8_t ucSTAId = WLAN_MAX_STA_COUNT;
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_INFO,
"%s: enter", __func__);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hdd_softap_get_sta_id(pAdapter,
pDestMacAddress, &ucSTAId)) {
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Failed to find right station", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (false ==
@@ -871,15 +871,15 @@ CDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Station MAC address does not matching",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_status =
qdf_status =
hdd_change_peer_state(pAdapter, ucSTAId, state, false);
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_INFO,
"%s: change station to state %d succeed", __func__, state);
if (CDF_STATUS_SUCCESS == cdf_status) {
if (QDF_STATUS_SUCCESS == qdf_status) {
pAdapter->aStaInfo[ucSTAId].tlSTAState =
ol_txrx_peer_state_auth;
}
@@ -887,7 +887,7 @@ CDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
CDF_TRACE(CDF_MODULE_ID_HDD_SAP_DATA, CDF_TRACE_LEVEL_INFO,
"%s exit", __func__);
return cdf_status;
return qdf_status;
}
/*
@@ -896,11 +896,11 @@ CDF_STATUS hdd_softap_change_sta_state(hdd_adapter_t *pAdapter,
* @pDestMacAddress: MAC address of the destination
* @staId: Station ID associated with the MAC address
*
* Return: CDF_STATUS_SUCCESS if a match was found, in which case
* staId is populated, CDF_STATUS_E_FAILURE if a match is
* Return: QDF_STATUS_SUCCESS if a match was found, in which case
* staId is populated, QDF_STATUS_E_FAILURE if a match is
* not found
*/
CDF_STATUS hdd_softap_get_sta_id(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_softap_get_sta_id(hdd_adapter_t *pAdapter,
struct cdf_mac_addr *pMacAddress,
uint8_t *staId)
{
@@ -911,9 +911,9 @@ CDF_STATUS hdd_softap_get_sta_id(hdd_adapter_t *pAdapter,
(&pAdapter->aStaInfo[i].macAddrSTA, pMacAddress,
CDF_MAC_ADDR_SIZE) && pAdapter->aStaInfo[i].isUsed) {
*staId = i;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
}
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}

10
core/hdd/src/wlan_hdd_stats.c
Fájl megtekintése

@@ -1193,7 +1193,7 @@ __wlan_hdd_cfg80211_ll_stats_set(struct wiphy *wiphy,
LinkLayerStatsSetReq.mpduSizeThreshold,
LinkLayerStatsSetReq.aggressiveStatisticsGathering);
if (CDF_STATUS_SUCCESS != sme_ll_stats_set_req(pHddCtx->hHal,
if (QDF_STATUS_SUCCESS != sme_ll_stats_set_req(pHddCtx->hHal,
&LinkLayerStatsSetReq)) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s:"
"sme_ll_stats_set_req Failed", __func__);
@@ -1323,7 +1323,7 @@ __wlan_hdd_cfg80211_ll_stats_get(struct wiphy *wiphy,
INIT_COMPLETION(context->response_event);
spin_unlock(&context->context_lock);
if (CDF_STATUS_SUCCESS != sme_ll_stats_get_req(pHddCtx->hHal,
if (QDF_STATUS_SUCCESS != sme_ll_stats_get_req(pHddCtx->hHal,
&LinkLayerStatsGetReq)) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s:"
"sme_ll_stats_get_req Failed", __func__);
@@ -1454,7 +1454,7 @@ __wlan_hdd_cfg80211_ll_stats_clear(struct wiphy *wiphy,
LinkLayerStatsClearReq.statsClearReqMask,
LinkLayerStatsClearReq.stopReq);
if (CDF_STATUS_SUCCESS == sme_ll_stats_clear_req(pHddCtx->hHal,
if (QDF_STATUS_SUCCESS == sme_ll_stats_clear_req(pHddCtx->hHal,
&LinkLayerStatsClearReq)) {
temp_skbuff = cfg80211_vendor_cmd_alloc_reply_skb(wiphy,
2 *
@@ -1537,7 +1537,7 @@ static int __wlan_hdd_cfg80211_stats_ext_request(struct wiphy *wiphy,
struct net_device *dev = wdev->netdev;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
int ret_val;
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *hdd_ctx = wiphy_priv(wiphy);
ENTER();
@@ -1556,7 +1556,7 @@ static int __wlan_hdd_cfg80211_stats_ext_request(struct wiphy *wiphy,
status = sme_stats_ext_request(pAdapter->sessionId, &stats_ext_req);
if (CDF_STATUS_SUCCESS != status)
if (QDF_STATUS_SUCCESS != status)
ret_val = -EINVAL;
return ret_val;

6
core/hdd/src/wlan_hdd_subnet_detect.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2015-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -78,7 +78,7 @@ static int __wlan_hdd_cfg80211_set_gateway_params(struct wiphy *wiphy,
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_GW_PARAM_CONFIG_MAX + 1];
struct gateway_param_update_req req = { 0 };
int ret;
CDF_STATUS status;
QDF_STATUS status;
ENTER();
@@ -156,7 +156,7 @@ static int __wlan_hdd_cfg80211_set_gateway_params(struct wiphy *wiphy,
hdd_info("ipv6 addr: %pI6c", req.ipv6_addr);
status = sme_gateway_param_update(hdd_ctx->hHal, &req);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hdd_err("sme_gateway_param_update failed(err=%d)", status);
ret = -EINVAL;
}

62
core/hdd/src/wlan_hdd_tdls.c
Fájl megtekintése

@@ -234,11 +234,11 @@ static uint32_t wlan_hdd_tdls_discovery_sent_cnt(hdd_context_t *pHddCtx)
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
hdd_adapter_t *pAdapter = NULL;
tdlsCtx_t *pHddTdlsCtx = NULL;
CDF_STATUS status = 0;
QDF_STATUS status = 0;
uint32_t count = 0;
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
@@ -535,7 +535,7 @@ int wlan_hdd_tdls_init(hdd_adapter_t *pAdapter)
int i;
uint8_t staIdx;
tdlsInfo_t *tInfo;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
if (NULL == pHddCtx)
return -EINVAL;
@@ -723,7 +723,7 @@ int wlan_hdd_tdls_init(hdd_adapter_t *pAdapter)
dump_tdls_state_param_setting(tInfo);
cdf_ret_status = sme_update_fw_tdls_state(pHddCtx->hHal, tInfo, true);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
cdf_mem_free(tInfo);
cdf_mc_timer_destroy(&pHddTdlsCtx->peerDiscoveryTimeoutTimer);
cdf_mem_free(pHddTdlsCtx);
@@ -744,7 +744,7 @@ void wlan_hdd_tdls_exit(hdd_adapter_t *pAdapter)
tdlsCtx_t *pHddTdlsCtx;
hdd_context_t *pHddCtx;
tdlsInfo_t *tInfo;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
if (!pHddCtx) {
@@ -826,7 +826,7 @@ void wlan_hdd_tdls_exit(hdd_adapter_t *pAdapter)
cdf_ret_status =
sme_update_fw_tdls_state(pHddCtx->hHal, tInfo, false);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
cdf_mem_free(tInfo);
}
} else {
@@ -1530,7 +1530,7 @@ void wlan_hdd_tdls_set_mode(hdd_context_t *pHddCtx,
eTDLSSupportMode tdls_mode, bool bUpdateLast)
{
hdd_adapter_list_node_t *pAdapterNode = NULL, *pNext = NULL;
CDF_STATUS status;
QDF_STATUS status;
hdd_adapter_t *pAdapter;
tdlsCtx_t *pHddTdlsCtx;
@@ -1551,7 +1551,7 @@ void wlan_hdd_tdls_set_mode(hdd_context_t *pHddCtx,
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
if (NULL != pHddTdlsCtx) {
@@ -1591,7 +1591,7 @@ int wlan_hdd_tdls_set_params(struct net_device *dev,
tdlsCtx_t *pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
eTDLSSupportMode req_tdls_mode;
tdlsInfo_t *tdlsParams;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
if (NULL == pHddTdlsCtx) {
hddLog(LOGE, FL("TDLS not enabled!"));
@@ -1666,7 +1666,7 @@ int wlan_hdd_tdls_set_params(struct net_device *dev,
dump_tdls_state_param_setting(tdlsParams);
cdf_ret_status = sme_update_fw_tdls_state(pHddCtx->hHal, tdlsParams, true);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
cdf_mem_free(tdlsParams);
return -EINVAL;
}
@@ -1697,7 +1697,7 @@ void wlan_hdd_update_tdls_info(hdd_adapter_t *adapter, bool tdls_prohibited,
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
tdlsCtx_t *hdd_tdls_ctx = WLAN_HDD_GET_TDLS_CTX_PTR(adapter);
tdlsInfo_t *tdls_param;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
if (!hdd_tdls_ctx) {
/* may be TDLS is not applicable for this adapter */
@@ -1777,7 +1777,7 @@ void wlan_hdd_update_tdls_info(hdd_adapter_t *adapter, bool tdls_prohibited,
cdf_ret_status = sme_update_fw_tdls_state(hdd_ctx->hHal,
tdls_param,
true);
if (CDF_STATUS_SUCCESS != cdf_ret_status) {
if (QDF_STATUS_SUCCESS != cdf_ret_status) {
cdf_mem_free(tdls_param);
return;
}
@@ -1855,7 +1855,7 @@ int wlan_hdd_tdls_update_peer_mac(hdd_adapter_t *adapter, const uint8_t *mac,
uint32_t peer_state)
{
tSmeTdlsPeerStateParams sme_tdls_peer_state_params = {0};
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
sme_tdls_peer_state_params.vdevId = adapter->sessionId;
@@ -1864,7 +1864,7 @@ int wlan_hdd_tdls_update_peer_mac(hdd_adapter_t *adapter, const uint8_t *mac,
sme_tdls_peer_state_params.peerState = peer_state;
status = sme_update_tdls_peer_state(hdd_ctx->hHal,
&sme_tdls_peer_state_params);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(LOGE, FL("sme_UpdateTdlsPeerState failed for "MAC_ADDRESS_STR),
MAC_ADDR_ARRAY(mac));
return -EPERM;
@@ -1971,12 +1971,12 @@ hddTdlsPeer_t *wlan_hdd_tdls_find_all_peer(hdd_context_t *pHddCtx,
hdd_adapter_t *pAdapter = NULL;
tdlsCtx_t *pHddTdlsCtx = NULL;
hddTdlsPeer_t *curr_peer = NULL;
CDF_STATUS status = 0;
QDF_STATUS status = 0;
mutex_lock(&pHddCtx->tdls_lock);
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
@@ -2366,12 +2366,12 @@ hddTdlsPeer_t *wlan_hdd_tdls_is_progress(hdd_context_t *pHddCtx,
hdd_adapter_t *pAdapter = NULL;
tdlsCtx_t *pHddTdlsCtx = NULL;
hddTdlsPeer_t *curr_peer = NULL;
CDF_STATUS status = 0;
QDF_STATUS status = 0;
mutex_lock(&pHddCtx->tdls_lock);
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
pHddTdlsCtx = WLAN_HDD_GET_TDLS_CTX_PTR(pAdapter);
@@ -3055,7 +3055,7 @@ __wlan_hdd_cfg80211_exttdls_get_status(struct wiphy *wiphy,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_TDLS_GET_STATUS_MAX + 1];
CDF_STATUS ret;
QDF_STATUS ret;
uint32_t state;
int32_t reason;
uint32_t global_operating_class = 0;
@@ -3237,7 +3237,7 @@ __wlan_hdd_cfg80211_exttdls_enable(struct wiphy *wiphy,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_TDLS_ENABLE_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
tdls_req_params_t pReqMsg = { 0 };
int ret;
@@ -3360,7 +3360,7 @@ static int __wlan_hdd_cfg80211_exttdls_disable(struct wiphy *wiphy,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
struct nlattr *tb[QCA_WLAN_VENDOR_ATTR_TDLS_DISABLE_MAX + 1];
CDF_STATUS status;
QDF_STATUS status;
if (CDF_GLOBAL_FTM_MODE == hdd_get_conparam()) {
hdd_err("Command not allowed in FTM mode");
@@ -3429,7 +3429,7 @@ int wlan_hdd_tdls_add_station(struct wiphy *wiphy,
{
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
CDF_STATUS status;
QDF_STATUS status;
hddTdlsPeer_t *pTdlsPeer;
uint16_t numCurrTdlsPeers;
unsigned long rc;
@@ -3588,7 +3588,7 @@ int wlan_hdd_tdls_add_station(struct wiphy *wiphy,
return -EPERM;
}
if (CDF_STATUS_SUCCESS != pAdapter->tdlsAddStaStatus) {
if (QDF_STATUS_SUCCESS != pAdapter->tdlsAddStaStatus) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: Add Station is unsuccessful", __func__);
return -EPERM;
@@ -3671,7 +3671,7 @@ static int __wlan_hdd_cfg80211_tdls_mgmt(struct wiphy *wiphy,
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
hdd_station_ctx_t *hdd_sta_ctx;
u8 peerMac[CDF_MAC_ADDR_SIZE];
CDF_STATUS status;
QDF_STATUS status;
int max_sta_failed = 0;
int responder;
unsigned long rc;
@@ -3859,7 +3859,7 @@ static int __wlan_hdd_cfg80211_tdls_mgmt(struct wiphy *wiphy,
peer_capability, (uint8_t *) buf, len,
!responder);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: sme_send_tdls_mgmt_frame failed!", __func__);
pAdapter->mgmtTxCompletionStatus = false;
@@ -4157,7 +4157,7 @@ static int __wlan_hdd_cfg80211_tdls_oper(struct wiphy *wiphy,
hdd_context_t *pHddCtx = wiphy_priv(wiphy);
int status;
tSmeTdlsPeerStateParams smeTdlsPeerStateParams;
CDF_STATUS cdf_ret_status = CDF_STATUS_E_FAILURE;
QDF_STATUS cdf_ret_status = QDF_STATUS_E_FAILURE;
hddTdlsPeer_t *pTdlsPeer;
ENTER();
@@ -4194,7 +4194,7 @@ static int __wlan_hdd_cfg80211_tdls_oper(struct wiphy *wiphy,
switch (oper) {
case NL80211_TDLS_ENABLE_LINK:
{
CDF_STATUS status;
QDF_STATUS status;
unsigned long rc;
tCsrTdlsLinkEstablishParams tdlsLinkEstablishParams;
@@ -4269,7 +4269,7 @@ static int __wlan_hdd_cfg80211_tdls_oper(struct wiphy *wiphy,
pTdlsPeer->staId,
pTdlsPeer->
signature);
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
uint8_t i;
cdf_mem_zero(&smeTdlsPeerStateParams,
@@ -4388,7 +4388,7 @@ static int __wlan_hdd_cfg80211_tdls_oper(struct wiphy *wiphy,
sme_update_tdls_peer_state(pHddCtx->
hHal,
&smeTdlsPeerStateParams);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
cdf_ret_status) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
@@ -4741,7 +4741,7 @@ int hdd_set_tdls_offchannelmode(hdd_adapter_t *adapter, int offchanmode)
hdd_station_ctx_t *hdd_sta_ctx = WLAN_HDD_GET_STATION_CTX_PTR(adapter);
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(adapter);
sme_tdls_chan_switch_params chan_switch_params;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
if (offchanmode < ENABLE_CHANSWITCH ||
offchanmode > DISABLE_CHANSWITCH) {
@@ -4834,7 +4834,7 @@ int hdd_set_tdls_offchannelmode(hdd_adapter_t *adapter, int offchanmode)
status = sme_send_tdls_chan_switch_req(WLAN_HDD_GET_HAL_CTX(adapter),
&chan_switch_params);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hdd_log(LOG1,
FL("Failed to send channel switch request to sme"));
return -EINVAL;

50
core/hdd/src/wlan_hdd_tx_rx.c
Fájl megtekintése

@@ -292,7 +292,7 @@ static bool wlan_hdd_is_eapol_or_wai(struct sk_buff *skb)
*/
int hdd_hard_start_xmit(struct sk_buff *skb, struct net_device *dev)
{
CDF_STATUS status;
QDF_STATUS status;
sme_ac_enum_type ac;
sme_QosWmmUpType up;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
@@ -325,7 +325,7 @@ int hdd_hard_start_xmit(struct sk_buff *skb, struct net_device *dev)
struct cdf_mac_addr *pDestMacAddress =
(struct cdf_mac_addr *) skb->data;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hdd_ibss_get_sta_id(&pAdapter->sessionCtx.station,
pDestMacAddress, &STAId))
STAId = HDD_WLAN_INVALID_STA_ID;
@@ -522,10 +522,10 @@ drop_pkt:
* @pMacAddress: pointer to Peer Mac address
* @staID: pointer to returned Station Index
*
* Return: CDF_STATUS_SUCCESS/CDF_STATUS_E_FAILURE
* Return: QDF_STATUS_SUCCESS/QDF_STATUS_E_FAILURE
*/
CDF_STATUS hdd_ibss_get_sta_id(hdd_station_ctx_t *pHddStaCtx,
QDF_STATUS hdd_ibss_get_sta_id(hdd_station_ctx_t *pHddStaCtx,
struct cdf_mac_addr *pMacAddress, uint8_t *staId)
{
uint8_t idx;
@@ -534,11 +534,11 @@ CDF_STATUS hdd_ibss_get_sta_id(hdd_station_ctx_t *pHddStaCtx,
if (cdf_mem_compare(&pHddStaCtx->conn_info.peerMacAddress[idx],
pMacAddress, CDF_MAC_ADDR_SIZE)) {
*staId = pHddStaCtx->conn_info.staId[idx];
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
}
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/**
@@ -601,18 +601,18 @@ void hdd_tx_timeout(struct net_device *dev)
* @hdd_init_tx_rx() - Initialize Tx/RX module
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_init_tx_rx(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_init_tx_rx(hdd_adapter_t *pAdapter)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (NULL == pAdapter) {
CDF_TRACE(CDF_MODULE_ID_HDD_DATA, CDF_TRACE_LEVEL_ERROR,
FL("pAdapter is NULL"));
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return status;
@@ -622,18 +622,18 @@ CDF_STATUS hdd_init_tx_rx(hdd_adapter_t *pAdapter)
* @hdd_deinit_tx_rx() - Deinitialize Tx/RX module
* @pAdapter: pointer to adapter context
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_deinit_tx_rx(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_deinit_tx_rx(hdd_adapter_t *pAdapter)
{
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
if (NULL == pAdapter) {
CDF_TRACE(CDF_MODULE_ID_HDD_DATA, CDF_TRACE_LEVEL_ERROR,
FL("pAdapter is NULL"));
CDF_ASSERT(0);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return status;
@@ -649,10 +649,10 @@ CDF_STATUS hdd_deinit_tx_rx(hdd_adapter_t *pAdapter)
* the HDD when one or more packets were received for a registered
* STA.
*
* Return: CDF_STATUS_E_FAILURE if any errors encountered,
* CDF_STATUS_SUCCESS otherwise
* Return: QDF_STATUS_E_FAILURE if any errors encountered,
* QDF_STATUS_SUCCESS otherwise
*/
CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
QDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
{
hdd_adapter_t *pAdapter = NULL;
hdd_context_t *pHddCtx = NULL;
@@ -668,14 +668,14 @@ CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
if ((NULL == cds_context) || (NULL == rxBuf)) {
CDF_TRACE(CDF_MODULE_ID_HDD_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: Null params being passed", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pHddCtx = cds_get_context(CDF_MODULE_ID_HDD);
if (NULL == pHddCtx) {
CDF_TRACE(CDF_MODULE_ID_HDD_DATA, CDF_TRACE_LEVEL_ERROR,
"%s: HDD context is Null", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pAdapter = pHddCtx->sta_to_adapter[staId];
@@ -683,7 +683,7 @@ CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
hddLog(LOGE,
FL("invalid adapter %p or adapter has invalid magic"),
pAdapter);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cpu_index = wlan_hdd_get_cpu();
@@ -693,7 +693,7 @@ CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
CDF_TRACE(CDF_MODULE_ID_HDD_DATA, CDF_TRACE_LEVEL_FATAL,
"Magic cookie(%x) for adapter sanity verification is invalid",
pAdapter->magic);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
@@ -707,7 +707,7 @@ CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
* it to stack
*/
cdf_nbuf_free(skb);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
wlan_hdd_log_eapol(skb, WIFI_EVENT_DRIVER_EAPOL_FRAME_RECEIVED);
@@ -764,7 +764,7 @@ CDF_STATUS hdd_rx_packet_cbk(void *cds_context, cdf_nbuf_t rxBuf, uint8_t staId)
pAdapter->dev->last_rx = jiffies;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#ifdef FEATURE_WLAN_DIAG_SUPPORT

239
core/hdd/src/wlan_hdd_wext.c
Fájl megtekintése

@@ -799,7 +799,7 @@ int hdd_wlan_get_rts_threshold(hdd_adapter_t *pAdapter, union iwreq_data *wrqu)
if (0 != ret)
return ret;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_cfg_get_int(hHal, WNI_CFG_RTS_THRESHOLD, &threshold)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN,
FL
@@ -847,7 +847,7 @@ int hdd_wlan_get_frag_threshold(hdd_adapter_t *pAdapter,
return status;
if (sme_cfg_get_int(hHal, WNI_CFG_FRAGMENTATION_THRESHOLD, &threshold)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN,
FL
("failed to get ini parameter, WNI_CFG_FRAGMENTATION_THRESHOLD"));
@@ -1088,27 +1088,27 @@ static void hdd_get_snr_cb(int8_t snr, uint32_t staId, void *pContext)
* @pAdapter: adapter upon which the measurement is requested
* @rssi_value: pointer to where the RSSI should be returned
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
QDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
{
struct statsContext context;
hdd_context_t *pHddCtx;
hdd_station_ctx_t *pHddStaCtx;
CDF_STATUS hstatus;
QDF_STATUS hstatus;
unsigned long rc;
if (NULL == pAdapter) {
hddLog(CDF_TRACE_LEVEL_WARN,
"%s: Invalid context, pAdapter", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (cds_is_driver_recovering()) {
hdd_err("Recovery in Progress. State: 0x%x Ignore!!!",
cds_get_driver_state());
/* return a cached value */
*rssi_value = pAdapter->rssi;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
@@ -1117,13 +1117,13 @@ CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
if (eConnectionState_Associated != pHddStaCtx->conn_info.connState) {
hdd_err("Not associated!, return last connected AP rssi!");
*rssi_value = pAdapter->rssi;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
if (pHddStaCtx->hdd_ReassocScenario) {
hdd_info("Roaming in progress, return cached RSSI");
*rssi_value = pAdapter->rssi;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
init_completion(&context.completion);
@@ -1134,7 +1134,7 @@ CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
pHddStaCtx->conn_info.staId[0],
pHddStaCtx->conn_info.bssId, pAdapter->rssi,
&context, pHddCtx->pcds_context);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: Unable to retrieve RSSI",
__func__);
/* we'll returned a cached value below */
@@ -1169,7 +1169,7 @@ CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
*rssi_value = pAdapter->rssi;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1177,14 +1177,14 @@ CDF_STATUS wlan_hdd_get_rssi(hdd_adapter_t *pAdapter, int8_t *rssi_value)
* @pAdapter: adapter upon which the measurement is requested
* @snr: pointer to where the SNR should be returned
*
* Return: CDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
* Return: QDF_STATUS_SUCCESS on success, CDF_STATUS_E_* on error
*/
CDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr)
QDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr)
{
struct statsContext context;
hdd_context_t *pHddCtx;
hdd_station_ctx_t *pHddStaCtx;
CDF_STATUS hstatus;
QDF_STATUS hstatus;
unsigned long rc;
int valid;
@@ -1193,14 +1193,14 @@ CDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr)
if (NULL == pAdapter) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Invalid context, pAdapter", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
valid = wlan_hdd_validate_context(pHddCtx);
if (0 != valid)
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
@@ -1211,7 +1211,7 @@ CDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr)
hstatus = sme_get_snr(pHddCtx->hHal, hdd_get_snr_cb,
pHddStaCtx->conn_info.staId[0],
pHddStaCtx->conn_info.bssId, &context);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: Unable to retrieve RSSI",
__func__);
/* we'll returned a cached value below */
@@ -1246,7 +1246,7 @@ CDF_STATUS wlan_hdd_get_snr(hdd_adapter_t *pAdapter, int8_t *snr)
*snr = pAdapter->snr;
EXIT();
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1326,25 +1326,25 @@ hdd_get_link_speed_cb(tSirLinkSpeedInfo *pLinkSpeed, void *pContext)
* This function will send a query to SME for the linkspeed of the
* given peer, and then wait for the callback to be invoked.
*
* Return: CDF_STATUS_SUCCESS if linkspeed data is available,
* Return: QDF_STATUS_SUCCESS if linkspeed data is available,
* otherwise a CDF_STATUS_E_* error.
*/
CDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
QDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
struct cdf_mac_addr macAddress) {
CDF_STATUS status;
QDF_STATUS status;
unsigned long rc;
struct linkspeedContext context;
tSirLinkSpeedInfo *linkspeed_req;
if (NULL == pAdapter) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: pAdapter is NULL", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
linkspeed_req = cdf_mem_malloc(sizeof(*linkspeed_req));
if (NULL == linkspeed_req) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s Request Buffer Alloc Fail", __func__);
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
init_completion(&context.completion);
context.pAdapter = pAdapter;
@@ -1354,7 +1354,7 @@ CDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
status = sme_get_link_speed(WLAN_HDD_GET_HAL_CTX(pAdapter),
linkspeed_req,
&context, hdd_get_link_speed_cb);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve statistics for link speed",
__func__);
@@ -1386,7 +1386,7 @@ CDF_STATUS wlan_hdd_get_linkspeed_for_peermac(hdd_adapter_t *pAdapter,
spin_lock(&hdd_context_lock);
context.magic = 0;
spin_unlock(&hdd_context_lock);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1418,13 +1418,13 @@ int wlan_hdd_get_link_speed(hdd_adapter_t *sta_adapter, uint32_t *link_speed)
/* we are not connected so we don't have a classAstats */
*link_speed = 0;
} else {
CDF_STATUS status;
QDF_STATUS status;
struct cdf_mac_addr bssid;
cdf_copy_macaddr(&bssid, &hdd_stactx->conn_info.bssId);
status = wlan_hdd_get_linkspeed_for_peermac(sta_adapter, bssid);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("Unable to retrieve SME linkspeed"));
return -EINVAL;
}
@@ -1772,14 +1772,14 @@ static int __iw_set_mode(struct net_device *dev,
if (hdd_conn_get_connected_bss_type
(WLAN_HDD_GET_STATION_CTX_PTR(pAdapter), &connectedBssType)
|| (eCSR_BSS_TYPE_START_IBSS == LastBSSType)) {
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
/* need to issue a disconnect to CSR. */
INIT_COMPLETION(pAdapter->disconnect_comp_var);
cdf_status =
qdf_status =
sme_roam_disconnect(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId,
eCSR_DISCONNECT_REASON_IBSS_LEAVE);
if (CDF_STATUS_SUCCESS == cdf_status) {
if (QDF_STATUS_SUCCESS == qdf_status) {
unsigned long rc;
rc = wait_for_completion_timeout(&pAdapter->
disconnect_comp_var,
@@ -1961,7 +1961,7 @@ static int __iw_set_freq(struct net_device *dev, struct iw_request_info *info,
if (sme_cfg_get_str(hHal, WNI_CFG_VALID_CHANNEL_LIST,
validChan, &numChans) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN, FL
("failed to get ini parameter, WNI_CFG_VALID_CHANNEL_LIST"));
return -EIO;
@@ -2050,7 +2050,7 @@ static int __iw_get_freq(struct net_device *dev, struct iw_request_info *info,
if (pHddStaCtx->conn_info.connState == eConnectionState_Associated) {
if (sme_get_operation_channel(hHal, &channel, pAdapter->sessionId)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
FL("failed to get operating channel %u"),
pAdapter->sessionId);
@@ -2181,7 +2181,7 @@ static int __iw_set_tx_power(struct net_device *dev,
return ret;
if (sme_cfg_set_int(hHal, WNI_CFG_CURRENT_TX_POWER_LEVEL,
wrqu->txpower.value) != CDF_STATUS_SUCCESS) {
wrqu->txpower.value) != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_CURRENT_TX_POWER_LEVEL"));
return -EIO;
@@ -2227,9 +2227,8 @@ static int __iw_get_bitrate(struct net_device *dev,
struct iw_request_info *info,
union iwreq_data *wrqu, char *extra)
{
CDF_STATUS cdf_status = CDF_STATUS_SUCCESS;
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_wext_state_t *pWextState;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
@@ -2266,7 +2265,7 @@ static int __iw_get_bitrate(struct net_device *dev,
pHddStaCtx->conn_info.staId[0],
pAdapter, pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve statistics", __func__);
return status;
@@ -2282,7 +2281,7 @@ static int __iw_get_bitrate(struct net_device *dev,
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: SME timeout while retrieving statistics",
__func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
wrqu->bitrate.value =
@@ -2291,7 +2290,7 @@ static int __iw_get_bitrate(struct net_device *dev,
EXIT();
return cdf_status;
return qdf_status;
}
/**
@@ -2360,17 +2359,17 @@ static int __iw_set_bitrate(struct net_device *dev,
valid_rate = true;
} else if (sme_cfg_get_int(WLAN_HDD_GET_HAL_CTX(pAdapter),
WNI_CFG_DOT11_MODE,
&active_phy_mode) == CDF_STATUS_SUCCESS) {
&active_phy_mode) == QDF_STATUS_SUCCESS) {
if (active_phy_mode == WNI_CFG_DOT11_MODE_11A
|| active_phy_mode == WNI_CFG_DOT11_MODE_11G
|| active_phy_mode == WNI_CFG_DOT11_MODE_11B) {
if ((sme_cfg_get_str(WLAN_HDD_GET_HAL_CTX(pAdapter),
WNI_CFG_SUPPORTED_RATES_11A, supp_rates,
&a_len) == CDF_STATUS_SUCCESS)
&a_len) == QDF_STATUS_SUCCESS)
&&
(sme_cfg_get_str(WLAN_HDD_GET_HAL_CTX(pAdapter),
WNI_CFG_SUPPORTED_RATES_11B, supp_rates,
&b_len) == CDF_STATUS_SUCCESS)) {
&b_len) == QDF_STATUS_SUCCESS)) {
for (i = 0; i < (b_len + a_len); ++i) {
/* supported rates returned is double
* the actual rate so we divide it by 2
@@ -2390,7 +2389,7 @@ static int __iw_set_bitrate(struct net_device *dev,
return -EINVAL;
}
if (sme_cfg_set_int(WLAN_HDD_GET_HAL_CTX(pAdapter),
WNI_CFG_FIXED_RATE, rate) != CDF_STATUS_SUCCESS) {
WNI_CFG_FIXED_RATE, rate) != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_FIXED_RATE"));
return -EIO;
@@ -2606,7 +2605,7 @@ static int __iw_get_genie(struct net_device *dev,
hdd_wext_state_t *pWextState;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
CDF_STATUS status;
QDF_STATUS status;
uint32_t length = DOT11F_IE_RSN_MAX_LEN;
uint8_t genIeBytes[DOT11F_IE_RSN_MAX_LEN];
hdd_context_t *hdd_ctx;
@@ -2825,7 +2824,7 @@ static int __iw_set_rts_threshold(struct net_device *dev,
}
if (sme_cfg_set_int(hHal, WNI_CFG_RTS_THRESHOLD, wrqu->rts.value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_RTS_THRESHOLD"));
return -EIO;
@@ -2955,7 +2954,7 @@ static int __iw_set_frag_threshold(struct net_device *dev,
if (sme_cfg_set_int
(hHal, WNI_CFG_FRAGMENTATION_THRESHOLD, wrqu->frag.value)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_FRAGMENTATION_THRESHOLD"));
return -EIO;
@@ -3129,7 +3128,7 @@ static int __iw_get_range(struct net_device *dev, struct iw_request_info *info,
/*Get the phy mode */
if (sme_cfg_get_int(hHal,
WNI_CFG_DOT11_MODE,
&active_phy_mode) == CDF_STATUS_SUCCESS) {
&active_phy_mode) == QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_INFO,
"active_phy_mode = %d", active_phy_mode);
@@ -3140,7 +3139,7 @@ static int __iw_get_range(struct net_device *dev, struct iw_request_info *info,
if (sme_cfg_get_str(hHal,
WNI_CFG_SUPPORTED_RATES_11A,
supp_rates,
&a_len) == CDF_STATUS_SUCCESS) {
&a_len) == QDF_STATUS_SUCCESS) {
if (a_len > WNI_CFG_SUPPORTED_RATES_11A_LEN) {
a_len = WNI_CFG_SUPPORTED_RATES_11A_LEN;
}
@@ -3159,7 +3158,7 @@ static int __iw_get_range(struct net_device *dev, struct iw_request_info *info,
if (sme_cfg_get_str(hHal,
WNI_CFG_SUPPORTED_RATES_11B,
supp_rates,
&b_len) == CDF_STATUS_SUCCESS) {
&b_len) == QDF_STATUS_SUCCESS) {
if (b_len > WNI_CFG_SUPPORTED_RATES_11B_LEN) {
b_len = WNI_CFG_SUPPORTED_RATES_11B_LEN;
}
@@ -3191,7 +3190,7 @@ static int __iw_get_range(struct net_device *dev, struct iw_request_info *info,
/*Supported Channels and Frequencies */
if (sme_cfg_get_str
((hHal), WNI_CFG_VALID_CHANNEL_LIST, channels,
&num_channels) != CDF_STATUS_SUCCESS) {
&num_channels) != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN,
FL
("failed to get ini parameter, WNI_CFG_VALID_CHANNEL_LIST"));
@@ -3334,23 +3333,23 @@ static void hdd_get_class_a_statistics_cb(void *pStats, void *pContext)
* wlan_hdd_get_class_astats() - Get Class A statistics
* @pAdapter: adapter for which statistics are desired
*
* Return: CDF_STATUS_SUCCESS if adapter's Class A statistics were updated
* Return: QDF_STATUS_SUCCESS if adapter's Class A statistics were updated
*/
CDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter)
QDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter)
{
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
CDF_STATUS hstatus;
QDF_STATUS hstatus;
unsigned long rc;
struct statsContext context;
if (NULL == pAdapter) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: pAdapter is NULL", __func__);
return CDF_STATUS_E_FAULT;
return QDF_STATUS_E_FAULT;
}
if (cds_is_driver_recovering()) {
hdd_err("Recovery in Progress. State: 0x%x Ignore!!!",
cds_get_driver_state());
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* we are connected so prepare our callback context */
@@ -3365,7 +3364,7 @@ CDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter)
false, /* non-cached results */
pHddStaCtx->conn_info.staId[0],
&context, pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve Class A statistics", __func__);
/* we'll returned a cached value below */
@@ -3398,7 +3397,7 @@ CDF_STATUS wlan_hdd_get_class_astats(hdd_adapter_t *pAdapter)
spin_unlock(&hdd_context_lock);
/* either callback updated pAdapter stats or it has cached data */
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -3474,18 +3473,18 @@ static void hdd_get_station_statistics_cb(void *pStats, void *pContext)
* wlan_hdd_get_station_stats() - Get station statistics
* @pAdapter: adapter for which statistics are desired
*
* Return: CDF_STATUS_SUCCESS if adapter's statistics were updated
* Return: QDF_STATUS_SUCCESS if adapter's statistics were updated
*/
CDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter)
QDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter)
{
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
CDF_STATUS hstatus;
QDF_STATUS hstatus;
unsigned long rc;
struct statsContext context;
if (NULL == pAdapter) {
hddLog(CDF_TRACE_LEVEL_ERROR, "%s: pAdapter is NULL", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* we are connected so prepare our callback context */
@@ -3503,7 +3502,7 @@ CDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter)
false, /* non-cached results */
pHddStaCtx->conn_info.staId[0],
&context, pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != hstatus) {
if (QDF_STATUS_SUCCESS != hstatus) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve statistics", __func__);
/* we'll return with cached values */
@@ -3537,7 +3536,7 @@ CDF_STATUS wlan_hdd_get_station_stats(hdd_adapter_t *pAdapter)
spin_unlock(&hdd_context_lock);
/* either callback updated pAdapter stats or it has cached data */
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -3748,7 +3747,7 @@ static int __iw_set_encode(struct net_device *dev, struct iw_request_info *info,
eCsrEncryptionType encryptionType = eCSR_ENCRYPT_TYPE_NONE;
bool fKeyPresent = 0;
int i;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
int ret;
ENTER();
@@ -3800,7 +3799,7 @@ static int __iw_set_encode(struct net_device *dev, struct iw_request_info *info,
sme_roam_disconnect(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId,
eCSR_DISCONNECT_REASON_UNSPECIFIED);
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
unsigned long rc;
rc = wait_for_completion_timeout(&pAdapter->
disconnect_comp_var,
@@ -4037,7 +4036,7 @@ static int __iw_set_encodeext(struct net_device *dev,
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
hdd_wext_state_t *pWextState = WLAN_HDD_GET_WEXT_STATE_PTR(pAdapter);
hdd_context_t *hdd_ctx;
CDF_STATUS cdf_ret_status = CDF_STATUS_SUCCESS;
QDF_STATUS cdf_ret_status = QDF_STATUS_SUCCESS;
tCsrRoamProfile *pRoamProfile = &pWextState->roamProfile;
int ret;
struct iw_encode_ext *ext = (struct iw_encode_ext *)extra;
@@ -4190,11 +4189,11 @@ static int __iw_set_encodeext(struct net_device *dev,
*/
cdf_ret_status = sme_ft_update_key(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &setKey);
if (cdf_ret_status == CDF_STATUS_FT_PREAUTH_KEY_SUCCESS) {
if (cdf_ret_status == QDF_STATUS_FT_PREAUTH_KEY_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_INFO_MED,
"%s: Update PreAuth Key success", __func__);
return 0;
} else if (cdf_ret_status == CDF_STATUS_FT_PREAUTH_KEY_FAILED) {
} else if (cdf_ret_status == QDF_STATUS_FT_PREAUTH_KEY_FAILED) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Update PreAuth Key failed", __func__);
return -EINVAL;
@@ -4206,7 +4205,7 @@ static int __iw_set_encodeext(struct net_device *dev,
pAdapter->sessionId,
&setKey, &roamId);
if (cdf_ret_status != CDF_STATUS_SUCCESS) {
if (cdf_ret_status != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"[%4d] sme_roam_set_key returned ERROR status= %d",
__LINE__, cdf_ret_status);
@@ -4277,7 +4276,7 @@ static int __iw_set_retry(struct net_device *dev, struct iw_request_info *info,
if ((wrqu->retry.flags & IW_RETRY_LONG)) {
if (sme_cfg_set_int (hHal, WNI_CFG_LONG_RETRY_LIMIT,
wrqu->retry.value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_LONG_RETRY_LIMIT"));
@@ -4286,7 +4285,7 @@ static int __iw_set_retry(struct net_device *dev, struct iw_request_info *info,
} else if ((wrqu->retry.flags & IW_RETRY_SHORT)) {
if (sme_cfg_set_int (hHal, WNI_CFG_SHORT_RETRY_LIMIT,
wrqu->retry.value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_LONG_RETRY_LIMIT"));
@@ -4356,7 +4355,7 @@ static int __iw_get_retry(struct net_device *dev, struct iw_request_info *info,
wrqu->retry.flags = IW_RETRY_LIMIT | IW_RETRY_LONG;
if (sme_cfg_get_int(hHal, WNI_CFG_LONG_RETRY_LIMIT, &retry) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN,
FL
("failed to get ini parameter, WNI_CFG_LONG_RETRY_LIMIT"));
@@ -4368,7 +4367,7 @@ static int __iw_get_retry(struct net_device *dev, struct iw_request_info *info,
wrqu->retry.flags = IW_RETRY_LIMIT | IW_RETRY_SHORT;
if (sme_cfg_get_int(hHal, WNI_CFG_SHORT_RETRY_LIMIT, &retry) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_WARN,
FL
("failed to get ini parameter, WNI_CFG_LONG_RETRY_LIMIT"));
@@ -4425,7 +4424,7 @@ static int __iw_set_mlme(struct net_device *dev,
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_station_ctx_t *pHddStaCtx = WLAN_HDD_GET_STATION_CTX_PTR(pAdapter);
struct iw_mlme *mlme = (struct iw_mlme *)extra;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_context_t *hdd_ctx;
int ret;
@@ -4456,7 +4455,7 @@ static int __iw_set_mlme(struct net_device *dev,
sme_roam_disconnect(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, reason);
if (CDF_STATUS_SUCCESS == status) {
if (QDF_STATUS_SUCCESS == status) {
unsigned long rc;
rc = wait_for_completion_timeout(&pAdapter->
disconnect_comp_var,
@@ -4540,7 +4539,7 @@ int wlan_hdd_update_phymode(struct net_device *net, tHalHandle hal,
{
#ifdef QCA_HT_2040_COEX
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(net);
CDF_STATUS halStatus = CDF_STATUS_E_FAILURE;
QDF_STATUS halStatus = QDF_STATUS_E_FAILURE;
#endif
bool band_24 = false, band_5g = false;
bool ch_bond24 = false, ch_bond5g = false;
@@ -4765,7 +4764,7 @@ int wlan_hdd_update_phymode(struct net_device *net, tHalHandle hal,
halStatus = sme_set_ht2040_mode(hal,
pAdapter->sessionId,
eHT_CHAN_HT20, false);
if (halStatus == CDF_STATUS_E_FAILURE) {
if (halStatus == QDF_STATUS_E_FAILURE) {
hddLog(LOGE, FL("Failed to disable OBSS"));
return -EIO;
}
@@ -4775,7 +4774,7 @@ int wlan_hdd_update_phymode(struct net_device *net, tHalHandle hal,
halStatus = sme_set_ht2040_mode(hal,
pAdapter->sessionId,
eHT_CHAN_HT20, true);
if (halStatus == CDF_STATUS_E_FAILURE) {
if (halStatus == QDF_STATUS_E_FAILURE) {
hddLog(LOGE, FL("Failed to enable OBSS"));
return -EIO;
}
@@ -4877,7 +4876,7 @@ static void hdd_get_temperature_cb(int temperature, void *pContext)
*/
int wlan_hdd_get_temperature(hdd_adapter_t *pAdapter, int *temperature)
{
CDF_STATUS status;
QDF_STATUS status;
struct statsContext tempContext;
unsigned long rc;
@@ -4891,7 +4890,7 @@ int wlan_hdd_get_temperature(hdd_adapter_t *pAdapter, int *temperature)
tempContext.magic = TEMP_CONTEXT_MAGIC;
status = sme_get_temperature(WLAN_HDD_GET_HAL_CTX(pAdapter),
&tempContext, hdd_get_temperature_cb);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
FL("Unable to retrieve temperature"));
} else {
@@ -4936,7 +4935,7 @@ static int __iw_setint_getnone(struct net_device *dev,
int set_value = value[1];
int ret;
int enable_pbm, enable_mp;
CDF_STATUS status;
QDF_STATUS status;
ENTER();
@@ -5033,7 +5032,7 @@ static int __iw_setint_getnone(struct net_device *dev,
ret = -EINVAL;
} else if (sme_cfg_set_int(hHal, WNI_CFG_ASSOC_STA_LIMIT,
set_value)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR, FL
("failed to set ini parameter, WNI_CFG_ASSOC_STA_LIMIT"));
@@ -5056,7 +5055,7 @@ static int __iw_setint_getnone(struct net_device *dev,
(set_value > CFG_DATA_INACTIVITY_TIMEOUT_MAX) ||
(sme_cfg_set_int((WLAN_HDD_GET_CTX(pAdapter))->hHal,
WNI_CFG_PS_DATA_INACTIVITY_TIMEOUT,
set_value) == CDF_STATUS_E_FAILURE)) {
set_value) == QDF_STATUS_E_FAILURE)) {
hddLog(LOGE, "Failure: Could not pass on "
"WNI_CFG_PS_DATA_INACTIVITY_TIMEOUT configuration info "
"to CCM");
@@ -5077,7 +5076,7 @@ static int __iw_setint_getnone(struct net_device *dev,
if (sme_set_tx_power
(hHal, pAdapter->sessionId, bssid,
pAdapter->device_mode,
set_value) != CDF_STATUS_SUCCESS) {
set_value) != QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Setting tx power failed", __func__);
return -EIO;
@@ -5096,7 +5095,7 @@ static int __iw_setint_getnone(struct net_device *dev,
cdf_copy_macaddr(&selfMac, &pHddStaCtx->conn_info.bssId);
if (sme_set_max_tx_power(hHal, bssid, selfMac, set_value)
!= CDF_STATUS_SUCCESS) {
!= QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Setting maximum tx power failed",
__func__);
@@ -5111,7 +5110,7 @@ static int __iw_setint_getnone(struct net_device *dev,
"%s: Setting maximum tx power %d dBm for 2.4 GHz band",
__func__, set_value);
if (sme_set_max_tx_power_per_band(eCSR_BAND_24, set_value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Setting maximum tx power failed for 2.4 GHz band",
__func__);
@@ -5126,7 +5125,7 @@ static int __iw_setint_getnone(struct net_device *dev,
"%s: Setting maximum tx power %d dBm for 5.0 GHz band",
__func__, set_value);
if (sme_set_max_tx_power_per_band(eCSR_BAND_5G, set_value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Setting maximum tx power failed for 5.0 GHz band",
__func__);
@@ -5180,7 +5179,7 @@ static int __iw_setint_getnone(struct net_device *dev,
hddLog(LOGE, "NSS greater than 2 not supported");
ret = -EINVAL;
} else {
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
hdd_update_nss(WLAN_HDD_GET_CTX(pAdapter),
set_value))
ret = -EINVAL;
@@ -5273,7 +5272,7 @@ static int __iw_setint_getnone(struct net_device *dev,
hddLog(LOG1, "LDPC val %d", set_value);
/* get the HT capability info */
ret = sme_cfg_get_int(hHal, WNI_CFG_HT_CAP_INFO, &value);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: could not get HT capability info",
@@ -5311,7 +5310,7 @@ static int __iw_setint_getnone(struct net_device *dev,
hddLog(LOG1, "TX_STBC val %d", set_value);
/* get the HT capability info */
ret = sme_cfg_get_int(hHal, WNI_CFG_HT_CAP_INFO, &value);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
"%s: could not get HT capability info",
@@ -5349,7 +5348,7 @@ static int __iw_setint_getnone(struct net_device *dev,
set_value);
/* get the HT capability info */
ret = sme_cfg_get_int(hHal, WNI_CFG_HT_CAP_INFO, &value);
if (CDF_STATUS_SUCCESS != ret) {
if (QDF_STATUS_SUCCESS != ret) {
CDF_TRACE(CDF_MODULE_ID_CDF,
CDF_TRACE_LEVEL_ERROR,
"%s: could not get HT capability info",
@@ -5414,7 +5413,7 @@ static int __iw_setint_getnone(struct net_device *dev,
if (!ret) {
if (sme_cfg_set_int
(hHal, WNI_CFG_RTS_THRESHOLD, value) !=
CDF_STATUS_SUCCESS) {
QDF_STATUS_SUCCESS) {
hddLog(LOGE, "FAILED TO SET RTSCTS");
return -EIO;
}
@@ -6120,7 +6119,7 @@ static int __iw_setint_getnone(struct net_device *dev,
status = sme_ext_change_channel(hHal,
set_value, pAdapter->sessionId);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
hddLog(LOGE,
FL("Error in change channel status %d"),
status);
@@ -6174,7 +6173,7 @@ static int __iw_setchar_getnone(struct net_device *dev,
struct iw_request_info *info,
union iwreq_data *wrqu, char *extra)
{
CDF_STATUS vstatus;
QDF_STATUS vstatus;
int sub_cmd;
int ret;
char *pBuffer = NULL;
@@ -6277,7 +6276,7 @@ static int __iw_setchar_getnone(struct net_device *dev,
break;
case WE_SET_CONFIG:
vstatus = hdd_execute_global_config_command(hdd_ctx, pBuffer);
if (CDF_STATUS_SUCCESS != vstatus) {
if (QDF_STATUS_SUCCESS != vstatus) {
ret = -EINVAL;
}
break;
@@ -6362,7 +6361,7 @@ static int __iw_setnone_getint(struct net_device *dev,
{
if (sme_cfg_get_int
(hHal, WNI_CFG_ASSOC_STA_LIMIT,
(uint32_t *) value) != CDF_STATUS_SUCCESS) {
(uint32_t *) value) != QDF_STATUS_SUCCESS) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_WARN, FL
("failed to get ini parameter, WNI_CFG_ASSOC_STA_LIMIT"));
@@ -6638,7 +6637,7 @@ static int __iw_setnone_getint(struct net_device *dev,
*value = wma_cli_get_command(pAdapter->sessionId,
WMI_PDEV_PARAM_TXPOWER_LIMIT2G,
PDEV_CMD);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_cfg_get_int(hHal, WNI_CFG_CURRENT_TX_POWER_LEVEL,
&txpow2g)) {
return -EIO;
@@ -6655,7 +6654,7 @@ static int __iw_setnone_getint(struct net_device *dev,
*value = wma_cli_get_command(pAdapter->sessionId,
WMI_PDEV_PARAM_TXPOWER_LIMIT5G,
PDEV_CMD);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_cfg_get_int(hHal, WNI_CFG_CURRENT_TX_POWER_LEVEL,
&txpow5g)) {
return -EIO;
@@ -6852,9 +6851,9 @@ static int __iw_set_three_ints_getnone(struct net_device *dev,
*/
case WE_SET_SAP_CHANNELS:
if (wlan_hdd_validate_operation_channel(pAdapter, value[1]) !=
CDF_STATUS_SUCCESS ||
QDF_STATUS_SUCCESS ||
wlan_hdd_validate_operation_channel(pAdapter,
value[2]) != CDF_STATUS_SUCCESS) {
value[2]) != QDF_STATUS_SUCCESS) {
ret = -EINVAL;
} else {
hdd_ctx->config->force_sap_acs_st_ch = value[1];
@@ -7189,7 +7188,7 @@ static int __iw_get_char_setnone(struct net_device *dev,
}
case WE_GET_CHANNEL_LIST:
{
CDF_STATUS status;
QDF_STATUS status;
uint8_t i, len;
char *buf;
uint8_t ubuf[WNI_CFG_COUNTRY_CODE_LEN];
@@ -7202,7 +7201,7 @@ static int __iw_get_char_setnone(struct net_device *dev,
status =
iw_softap_get_channel_list(dev, info, wrqu,
(char *)&channel_list);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hddLog(LOGE, FL("GetChannelList Failed!!!"));
return -EINVAL;
}
@@ -7221,7 +7220,7 @@ static int __iw_get_char_setnone(struct net_device *dev,
}
len = scnprintf(buf, WE_MAX_STR_LEN, "%u ",
channel_list.num_channels);
if (CDF_STATUS_SUCCESS == sme_get_country_code(hdd_ctx->hHal,
if (QDF_STATUS_SUCCESS == sme_get_country_code(hdd_ctx->hHal,
ubuf, &ubuf_len)) {
/* Printing Country code in getChannelList */
for (i = 0; i < (ubuf_len - 1); i++)
@@ -7292,7 +7291,7 @@ static int __iw_get_char_setnone(struct net_device *dev,
ch_bond5g = true;
phymode = sme_get_phy_mode(hal);
if ((CDF_STATUS_SUCCESS !=
if ((QDF_STATUS_SUCCESS !=
sme_get_freq_band(hal, &currBand))) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_INFO,
@@ -7919,7 +7918,7 @@ static int __iw_set_var_ints_getnone(struct net_device *dev,
msg.type = SIR_HAL_UNIT_TEST_CMD;
msg.reserved = 0;
msg.bodyptr = unitTestArgs;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
cds_mq_post_message(CDF_MODULE_ID_WMA, &msg)) {
cdf_mem_free(unitTestArgs);
CDF_TRACE(CDF_MODULE_ID_HDD,
@@ -8491,7 +8490,7 @@ static int __iw_set_host_offload(struct net_device *dev,
* copied individually.
*/
memcpy(&offloadRequest, pRequest, wrqu->data.length);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_host_offload(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, &offloadRequest)) {
hddLog(CDF_TRACE_LEVEL_ERROR,
@@ -8579,7 +8578,7 @@ static int __iw_set_keepalive_params(struct net_device *dev,
hdd_info("Keep alive period %d", request->timePeriod);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_keep_alive(WLAN_HDD_GET_HAL_CTX(pAdapter),
pAdapter->sessionId, request)) {
hdd_err("Failure to execute Keep Alive");
@@ -8694,7 +8693,7 @@ static int wlan_hdd_set_filter(hdd_context_t *hdd_ctx,
request->params_data[i].data_mask[5]);
}
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_receive_filter_set_filter(hdd_ctx->hHal,
&packetFilterSetReq,
sessionId)) {
@@ -8709,7 +8708,7 @@ static int wlan_hdd_set_filter(hdd_context_t *hdd_ctx,
hdd_info("Clear Packet Filter Request for Id: %d",
request->filter_id);
packetFilterClrReq.filterId = request->filter_id;
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_receive_filter_clear_filter(hdd_ctx->hHal,
&packetFilterClrReq,
sessionId)) {
@@ -8814,7 +8813,7 @@ static int __iw_get_statistics(struct net_device *dev,
{
QDF_STATUS qdf_status = QDF_STATUS_SUCCESS;
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
hdd_wext_state_t *pWextState;
hdd_adapter_t *pAdapter = WLAN_HDD_GET_PRIV_PTR(dev);
hdd_context_t *hdd_ctx = WLAN_HDD_GET_CTX(pAdapter);
@@ -8848,7 +8847,7 @@ static int __iw_get_statistics(struct net_device *dev,
(pAdapter))->conn_info.staId[0],
pAdapter, pAdapter->sessionId);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s: Unable to retrieve SME statistics",
__func__);
@@ -9259,7 +9258,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
eCsrBand band;
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *pHddCtx;
hdd_adapter_list_node_t *pAdapterNode, *pNext;
eCsrBand currBand = eCSR_BAND_MAX;
@@ -9308,7 +9307,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
band = pHddCtx->config->nBandCapability;
}
if (CDF_STATUS_SUCCESS != sme_get_freq_band(hHal, &currBand)) {
if (QDF_STATUS_SUCCESS != sme_get_freq_band(hHal, &currBand)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_INFO,
"%s: Failed to get current band config", __func__);
return -EIO;
@@ -9324,7 +9323,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
__func__, currBand, band);
status = hdd_get_front_adapter(pHddCtx, &pAdapterNode);
while (NULL != pAdapterNode && CDF_STATUS_SUCCESS == status) {
while (NULL != pAdapterNode && QDF_STATUS_SUCCESS == status) {
pAdapter = pAdapterNode->pAdapter;
hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
hdd_abort_mac_scan(pHddCtx, pAdapter->sessionId,
@@ -9341,7 +9340,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
(hdd_conn_is_connected
(WLAN_HDD_GET_STATION_CTX_PTR(pAdapter)))
&& (connectedBand != band)) {
CDF_STATUS status = CDF_STATUS_SUCCESS;
QDF_STATUS status = QDF_STATUS_SUCCESS;
long lrc;
/* STA already connected on current band, So issue disconnect
@@ -9359,7 +9358,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
pAdapter->sessionId,
eCSR_DISCONNECT_REASON_UNSPECIFIED);
if (CDF_STATUS_SUCCESS != status) {
if (QDF_STATUS_SUCCESS != status) {
hddLog(CDF_TRACE_LEVEL_ERROR,
"%s csr_roam_disconnect failure, returned %d",
__func__, (int)status);
@@ -9387,7 +9386,7 @@ int hdd_set_band(struct net_device *dev, u8 ui_band)
pAdapterNode = pNext;
}
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
sme_set_freq_band(hHal, pAdapter->sessionId, band)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_FATAL,
FL("Failed to set the band value to %u"),
@@ -10744,7 +10743,7 @@ int hdd_set_wext(hdd_adapter_t *pAdapter)
hdd_clear_roam_profile_ie(pAdapter);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
@@ -10768,19 +10767,19 @@ int hdd_register_wext(struct net_device *dev)
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
("ERROR: hdd_set_wext failed!!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (!QDF_IS_STATUS_SUCCESS(qdf_event_create(&pwextBuf->hdd_cdf_event))) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
("ERROR: HDD cdf event init failed!!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
if (!QDF_IS_STATUS_SUCCESS(qdf_event_create(&pwextBuf->scanevent))) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
("ERROR: HDD scan event init failed!!"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/* Register as a wireless device */
dev->wireless_handlers = (struct iw_handler_def *)&we_handler_def;

136
core/hdd/src/wlan_hdd_wmm.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -158,7 +158,7 @@ static void hdd_wmm_enable_tl_uapsd(hdd_wmm_qos_context_t *pQosContext)
sme_ac_enum_type acType = pQosContext->acType;
hdd_wmm_ac_status_t *pAc = &pAdapter->hddWmmStatus.wmmAcStatus[acType];
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
CDF_STATUS status;
QDF_STATUS status;
uint32_t service_interval;
uint32_t suspension_interval;
sme_QosWmmDirType direction;
@@ -209,7 +209,7 @@ static void hdd_wmm_enable_tl_uapsd(hdd_wmm_qos_context_t *pQosContext)
direction, psb, pAdapter->sessionId,
pHddCtx->config->DelayedTriggerFrmInt);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_ERROR,
"%s: Failed to enable U-APSD for AC=%d",
__func__, acType);
@@ -243,7 +243,7 @@ static void hdd_wmm_disable_tl_uapsd(hdd_wmm_qos_context_t *pQosContext)
hdd_adapter_t *pAdapter = pQosContext->pAdapter;
sme_ac_enum_type acType = pQosContext->acType;
hdd_wmm_ac_status_t *pAc = &pAdapter->hddWmmStatus.wmmAcStatus[acType];
CDF_STATUS status;
QDF_STATUS status;
/* have we previously enabled UAPSD? */
if (pAc->wmmAcUapsdInfoValid == true) {
@@ -254,7 +254,7 @@ static void hdd_wmm_disable_tl_uapsd(hdd_wmm_qos_context_t *pQosContext)
(pAdapter))->conn_info.staId[0],
acType, pAdapter->sessionId);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_ERROR,
"%s: Failed to disable U-APSD for AC=%d",
__func__, acType);
@@ -376,7 +376,7 @@ static void hdd_wmm_inactivity_timer_cb(void *user_data)
hdd_adapter_t *pAdapter;
hdd_wmm_ac_status_t *pAc;
hdd_wlan_wmm_status_e status;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
uint32_t currentTrafficCnt = 0;
sme_ac_enum_type acType = pQosContext->acType;
@@ -405,10 +405,10 @@ static void hdd_wmm_inactivity_timer_cb(void *user_data)
pAc->wmmPrevTrafficCnt = currentTrafficCnt;
if (pAc->wmmInactivityTimer.state == CDF_TIMER_STATE_STOPPED) {
/* Restart the timer */
cdf_status =
qdf_status =
cdf_mc_timer_start(&pAc->wmmInactivityTimer,
pAc->wmmInactivityTime);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD,
CDF_TRACE_LEVEL_ERROR,
FL(
@@ -437,13 +437,13 @@ static void hdd_wmm_inactivity_timer_cb(void *user_data)
* time specified in the AddTS parameters is non-zero, this function
* is invoked to start a traffic inactivity timer for the given AC.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
hdd_wmm_enable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext,
uint32_t inactivityTime)
{
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
hdd_adapter_t *pAdapter = pQosContext->pAdapter;
sme_ac_enum_type acType = pQosContext->acType;
hdd_wmm_ac_status_t *pAc;
@@ -451,28 +451,28 @@ hdd_wmm_enable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext,
pAdapter = pQosContext->pAdapter;
pAc = &pAdapter->hddWmmStatus.wmmAcStatus[acType];
cdf_status = cdf_mc_timer_init(&pAc->wmmInactivityTimer,
qdf_status = cdf_mc_timer_init(&pAc->wmmInactivityTimer,
CDF_TIMER_TYPE_SW,
hdd_wmm_inactivity_timer_cb,
pQosContext);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
FL("Initializing inactivity timer failed on AC %d"),
acType);
return cdf_status;
return qdf_status;
}
/* Start the inactivity timer */
cdf_status = cdf_mc_timer_start(&pAc->wmmInactivityTimer,
qdf_status = cdf_mc_timer_start(&pAc->wmmInactivityTimer,
inactivityTime);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
FL("Starting inactivity timer failed on AC %d"),
acType);
cdf_status = cdf_mc_timer_destroy(&pAc->wmmInactivityTimer);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cdf_mc_timer_destroy(&pAc->wmmInactivityTimer);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hdd_err("Failed to destroy inactivity timer");
}
return cdf_status;
return qdf_status;
}
pAc->wmmInactivityTime = inactivityTime;
/* Initialize the current tx traffic count on this AC */
@@ -480,7 +480,7 @@ hdd_wmm_enable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext,
pAdapter->hdd_stats.hddTxRxStats.txXmitClassifiedAC[pQosContext->
acType];
pQosContext->is_inactivity_timer_running = true;
return cdf_status;
return qdf_status;
}
/**
@@ -492,15 +492,15 @@ hdd_wmm_enable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext,
* This function is invoked to disable the traffic inactivity timer
* for the given AC. This is normally done when the TS is deleted.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS
static QDF_STATUS
hdd_wmm_disable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext)
{
hdd_adapter_t *pAdapter = pQosContext->pAdapter;
sme_ac_enum_type acType = pQosContext->acType;
hdd_wmm_ac_status_t *pAc = &pAdapter->hddWmmStatus.wmmAcStatus[acType];
CDF_STATUS cdf_status = CDF_STATUS_E_FAILURE;
QDF_STATUS qdf_status = QDF_STATUS_E_FAILURE;
/* Clear the timer and the counter */
pAc->wmmInactivityTime = 0;
@@ -508,17 +508,17 @@ hdd_wmm_disable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext)
if (pQosContext->is_inactivity_timer_running == true) {
pQosContext->is_inactivity_timer_running = false;
cdf_status = cdf_mc_timer_stop(&pAc->wmmInactivityTimer);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
qdf_status = cdf_mc_timer_stop(&pAc->wmmInactivityTimer);
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
hdd_err("Failed to stop inactivity timer");
return cdf_status;
return qdf_status;
}
cdf_status = cdf_mc_timer_destroy(&pAc->wmmInactivityTimer);
if (!CDF_IS_STATUS_SUCCESS(cdf_status))
qdf_status = cdf_mc_timer_destroy(&pAc->wmmInactivityTimer);
if (!QDF_IS_STATUS_SUCCESS(qdf_status))
hdd_err("Failed to destroy inactivity timer:Timer started");
}
return cdf_status;
return qdf_status;
}
#endif /* FEATURE_WLAN_ESE */
@@ -536,9 +536,9 @@ hdd_wmm_disable_inactivity_timer(hdd_wmm_qos_context_t *pQosContext)
* gets called externally through some function pointer magic (so
* there is a need for rigorous parameter checking).
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
static CDF_STATUS hdd_wmm_sme_callback(tHalHandle hHal,
static QDF_STATUS hdd_wmm_sme_callback(tHalHandle hHal,
void *hddCtx,
sme_QosWmmTspecInfo *pCurrentQosInfo,
sme_QosStatusType smeStatus,
@@ -556,7 +556,7 @@ static CDF_STATUS hdd_wmm_sme_callback(tHalHandle hHal,
(HDD_WMM_CTX_MAGIC != pQosContext->magic))) {
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_ERROR,
"%s: Invalid QoS Context", __func__);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pAdapter = pQosContext->pAdapter;
@@ -1059,7 +1059,7 @@ static CDF_STATUS hdd_wmm_sme_callback(tHalHandle hHal,
"%s: complete, access for TL AC %d is%sallowed",
__func__, acType, pAc->wmmAcAccessAllowed ? " " : " not ");
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -1371,9 +1371,9 @@ static void hdd_wmm_do_implicit_qos(struct work_struct *work)
* adapter to an initial state. The configuration can later be
* overwritten via application APIs or via QoS Map sent OTA.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter)
{
sme_QosWmmUpType *hddWmmDscpToUpMap = pAdapter->hddWmmDscpToUpMap;
uint8_t dscp;
@@ -1391,7 +1391,7 @@ CDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter)
/* Special case for Expedited Forwarding (DSCP 46) */
hddWmmDscpToUpMap[46] = SME_QOS_WMM_UP_VO;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1402,9 +1402,9 @@ CDF_STATUS hdd_wmm_init(hdd_adapter_t *pAdapter)
* adapter to an initial state. The configuration can later be
* overwritten via application APIs
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter)
{
hdd_wmm_ac_status_t *pAcStatus;
sme_ac_enum_type acType;
@@ -1432,7 +1432,7 @@ CDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter)
*/
pAdapter->configuredPsb = HDD_PSB_CFG_INVALID;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1441,9 +1441,9 @@ CDF_STATUS hdd_wmm_adapter_init(hdd_adapter_t *pAdapter)
*
* @pAdapter: [in] pointer to Adapter context
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter)
{
hdd_wmm_ac_status_t *pAcStatus;
sme_ac_enum_type acType;
@@ -1460,7 +1460,7 @@ CDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter)
pAcStatus->wmmAcTspecValid = false;
pAcStatus->wmmAcUapsdInfoValid = false;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1470,9 +1470,9 @@ CDF_STATUS hdd_wmm_adapter_clear(hdd_adapter_t *pAdapter)
* Function which will perform any necessary work to to clean up the
* WMM functionality prior to the kernel module unload.
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_adapter_close(hdd_adapter_t *pAdapter)
QDF_STATUS hdd_wmm_adapter_close(hdd_adapter_t *pAdapter)
{
hdd_wmm_qos_context_t *pQosContext;
@@ -1494,7 +1494,7 @@ CDF_STATUS hdd_wmm_adapter_close(hdd_adapter_t *pAdapter)
hdd_wmm_free_context(pQosContext);
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1792,9 +1792,9 @@ void hdd_wmm_acquire_access_required(hdd_adapter_t *pAdapter,
* @pGranted: [out] pointer to bool flag when indicates if access
* has been granted or not
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
sme_ac_enum_type acType, bool *pGranted)
{
hdd_wmm_qos_context_t *pQosContext;
@@ -1815,7 +1815,7 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
pAdapter->hddWmmStatus.wmmAcStatus[acType].
wmmAcAccessAllowed;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* do we already have an implicit QoS request pending for this AC? */
if ((pAdapter->hddWmmStatus.wmmAcStatus[acType].wmmAcAccessNeeded) ||
@@ -1828,7 +1828,7 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
__func__, acType);
*pGranted = false;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* did we already fail to establish implicit QoS for this AC?
* (if so, access should have been granted when the failure
@@ -1853,7 +1853,7 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
*pGranted = false;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* we need to establish implicit QoS */
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_INFO,
@@ -1872,7 +1872,7 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
pAdapter->hddWmmStatus.wmmAcStatus[acType].wmmAcAccessAllowed =
true;
*pGranted = true;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
pQosContext->acType = acType;
@@ -1899,7 +1899,7 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
* TSPEC negotiation completes
*/
*pGranted = false;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1910,13 +1910,13 @@ CDF_STATUS hdd_wmm_acquire_access(hdd_adapter_t *pAdapter,
* @pRoamInfo: [in] pointer to roam information
* @eBssType: [in] type of BSS
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo, eCsrRoamBssType eBssType)
{
uint8_t uapsdMask;
CDF_STATUS status;
QDF_STATUS status;
hdd_context_t *pHddCtx = WLAN_HDD_GET_CTX(pAdapter);
/* when we associate we need to notify TL if it needs to
@@ -1939,7 +1939,7 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_INFO_LOW,
"%s: Reassoc so no work, Exiting", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/* get the negotiated UAPSD Mask */
uapsdMask =
@@ -1961,7 +1961,7 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
pAdapter->sessionId,
pHddCtx->config->DelayedTriggerFrmInt);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(status));
}
if (uapsdMask & HDD_AC_VI) {
@@ -1977,7 +1977,7 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
pAdapter->sessionId,
pHddCtx->config->DelayedTriggerFrmInt);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(status));
}
if (uapsdMask & HDD_AC_BK) {
@@ -1993,7 +1993,7 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
pAdapter->sessionId,
pHddCtx->config->DelayedTriggerFrmInt);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(status));
}
if (uapsdMask & HDD_AC_BE) {
@@ -2009,21 +2009,21 @@ CDF_STATUS hdd_wmm_assoc(hdd_adapter_t *pAdapter,
pAdapter->sessionId,
pHddCtx->config->DelayedTriggerFrmInt);
CDF_ASSERT(CDF_IS_STATUS_SUCCESS(status));
CDF_ASSERT(QDF_IS_STATUS_SUCCESS(status));
}
status = sme_update_dsc_pto_up_mapping(pHddCtx->hHal,
pAdapter->hddWmmDscpToUpMap,
pAdapter->sessionId);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
hdd_wmm_init(pAdapter);
}
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_INFO_LOW,
"%s: Exiting", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
static const uint8_t acm_mask_bit[WLAN_MAX_AC] = {
@@ -2041,9 +2041,9 @@ static const uint8_t acm_mask_bit[WLAN_MAX_AC] = {
* @pRoamInfo: [in] pointer to roam information
* @eBssType : [in] type of BSS
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
tCsrRoamInfo *pRoamInfo, eCsrRoamBssType eBssType)
{
int ac;
@@ -2108,7 +2108,7 @@ CDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
CDF_TRACE(CDF_MODULE_ID_HDD, WMM_TRACE_LEVEL_INFO_LOW,
"%s: Exiting", __func__);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -2118,9 +2118,9 @@ CDF_STATUS hdd_wmm_connect(hdd_adapter_t *pAdapter,
* @pAdapter : [in] pointer to adapter context
* @pUapsdMask: [out] pointer to where the UAPSD Mask is to be stored
*
* Return: CDF_STATUS enumeration
* Return: QDF_STATUS enumeration
*/
CDF_STATUS hdd_wmm_get_uapsd_mask(hdd_adapter_t *pAdapter,
QDF_STATUS hdd_wmm_get_uapsd_mask(hdd_adapter_t *pAdapter,
uint8_t *pUapsdMask)
{
uint8_t uapsdMask;
@@ -2157,7 +2157,7 @@ CDF_STATUS hdd_wmm_get_uapsd_mask(hdd_adapter_t *pAdapter,
/* return calculated mask */
*pUapsdMask = uapsdMask;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**

30
core/hdd/src/wlan_hdd_wowl.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -57,7 +57,7 @@ static inline int find_ptrn_len(const char *ptrn)
return len;
}
static void hdd_wowl_callback(void *pContext, CDF_STATUS cdf_ret_status)
static void hdd_wowl_callback(void *pContext, QDF_STATUS cdf_ret_status)
{
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_INFO,
"%s: Return code = (%d)", __func__, cdf_ret_status);
@@ -117,7 +117,7 @@ bool hdd_add_wowl_ptrn(hdd_adapter_t *pAdapter, const char *ptrn)
{
struct wow_add_pattern localPattern;
int i, first_empty_slot, len, offset;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
const char *temp;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
uint8_t sessionId = pAdapter->sessionId;
@@ -256,7 +256,7 @@ bool hdd_add_wowl_ptrn(hdd_adapter_t *pAdapter, const char *ptrn)
cdf_ret_status =
sme_wow_add_pattern(hHal, &localPattern,
sessionId);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
/* Add failed, so invalidate the local storage */
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"sme_wowl_add_bcast_pattern failed with error code (%d)",
@@ -293,7 +293,7 @@ bool hdd_del_wowl_ptrn(hdd_adapter_t *pAdapter, const char *ptrn)
unsigned char id;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
bool patternFound = false;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
uint8_t sessionId = pAdapter->sessionId;
hdd_context_t *pHddCtx = pAdapter->pHddCtx;
@@ -314,7 +314,7 @@ bool hdd_del_wowl_ptrn(hdd_adapter_t *pAdapter, const char *ptrn)
cdf_ret_status =
sme_wow_delete_pattern(hHal, &delPattern,
sessionId);
if (CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
/* Remove from local storage as well */
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"Deleted pattern with id %d [%s]", id,
@@ -344,7 +344,7 @@ bool hdd_add_wowl_ptrn_debugfs(hdd_adapter_t *pAdapter, uint8_t pattern_idx,
char *pattern_mask)
{
struct wow_add_pattern localPattern;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
uint8_t session_id = pAdapter->sessionId;
uint16_t pattern_len, mask_len, i;
@@ -432,7 +432,7 @@ bool hdd_add_wowl_ptrn_debugfs(hdd_adapter_t *pAdapter, uint8_t pattern_idx,
cdf_ret_status =
sme_wow_add_pattern(hHal, &localPattern, session_id);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: sme_wowl_add_bcast_pattern failed with error code (%d).",
__func__, cdf_ret_status);
@@ -463,7 +463,7 @@ bool hdd_del_wowl_ptrn_debugfs(hdd_adapter_t *pAdapter, uint8_t pattern_idx)
{
struct wow_delete_pattern delPattern;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
uint8_t sessionId = pAdapter->sessionId;
if (pattern_idx > (WOWL_MAX_PTRNS_ALLOWED - 1)) {
@@ -487,7 +487,7 @@ bool hdd_del_wowl_ptrn_debugfs(hdd_adapter_t *pAdapter, uint8_t pattern_idx)
cdf_ret_status = sme_wow_delete_pattern(hHal, &delPattern,
sessionId);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"%s: sme_wowl_del_bcast_pattern failed with error code (%d).",
__func__, cdf_ret_status);
@@ -513,7 +513,7 @@ bool hdd_del_wowl_ptrn_debugfs(hdd_adapter_t *pAdapter, uint8_t pattern_idx)
bool hdd_enter_wowl(hdd_adapter_t *pAdapter, bool enable_mp, bool enable_pbm)
{
tSirSmeWowlEnterParams wowParams;
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
cdf_mem_zero(&wowParams, sizeof(tSirSmeWowlEnterParams));
@@ -541,8 +541,8 @@ bool hdd_enter_wowl(hdd_adapter_t *pAdapter, bool enable_mp, bool enable_pbm)
#endif /* WLAN_WAKEUP_EVENTS */
&wowParams, pAdapter->sessionId);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (CDF_STATUS_PMC_PENDING != cdf_ret_status) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (QDF_STATUS_PMC_PENDING != cdf_ret_status) {
/* We failed to enter WoWL */
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"sme_enter_wowl failed with error code (%d)",
@@ -563,12 +563,12 @@ bool hdd_exit_wowl(hdd_adapter_t *pAdapter)
{
tSirSmeWowlExitParams wowParams;
tHalHandle hHal = WLAN_HDD_GET_HAL_CTX(pAdapter);
CDF_STATUS cdf_ret_status;
QDF_STATUS cdf_ret_status;
wowParams.sessionId = pAdapter->sessionId;
cdf_ret_status = sme_exit_wowl(hHal, &wowParams);
if (!CDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
if (!QDF_IS_STATUS_SUCCESS(cdf_ret_status)) {
CDF_TRACE(CDF_MODULE_ID_HDD, CDF_TRACE_LEVEL_ERROR,
"sme_exit_wowl failed with error code (%d)",
cdf_ret_status);

4
core/mac/inc/ani_global.h
Fájl megtekintése

@@ -247,7 +247,7 @@ enum wifi_logging_ring_id {
/* ------------------------------------------------------------------- */
/* Change channel generic scheme */
typedef void (*CHANGE_CHANNEL_CALLBACK)(tpAniSirGlobal pMac, CDF_STATUS status,
typedef void (*CHANGE_CHANNEL_CALLBACK)(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data,
tpPESession psessionEntry);
@@ -842,7 +842,7 @@ typedef struct sAniSirLim {
uint8_t gLimDfsTargetChanNum;
uint8_t probeCounter;
uint8_t maxProbe;
CDF_STATUS(*add_bssdescr_callback)
QDF_STATUS(*add_bssdescr_callback)
(tpAniSirGlobal pMac, tpSirBssDescription buf,
uint32_t scan_id, uint32_t flags);
uint8_t retry_packet_cnt;

6
core/mac/inc/mac_trace.h
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2013-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2013-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -57,8 +57,8 @@ uint8_t *mac_trace_get_lim_msg_string(uint16_t limMsg);
uint8_t *mac_trace_get_wma_msg_string(uint16_t wmaMsg);
uint8_t *mac_trace_get_sme_msg_string(uint16_t smeMsg);
uint8_t *mac_trace_get_info_log_string(uint16_t infoLog);
CDF_STATUS pe_acquire_global_lock(tAniSirLim *psPe);
CDF_STATUS pe_release_global_lock(tAniSirLim *psPe);
QDF_STATUS pe_acquire_global_lock(tAniSirLim *psPe);
QDF_STATUS pe_release_global_lock(tAniSirLim *psPe);
uint8_t *mac_trace_get_neighbour_roam_state(uint16_t neighbourRoamState);
uint8_t *mac_trace_getcsr_roam_state(uint16_t csr_roamState);

4
core/mac/inc/sir_api.h
Fájl megtekintése

@@ -2322,7 +2322,7 @@ typedef struct sSirHalWowlEnterParams {
/* Status code to be filled by HAL when it sends
* SIR_HAL_WOWL_ENTER_RSP to PE.
*/
CDF_STATUS status;
QDF_STATUS status;
/*BSSID to find the current session
*/
@@ -2342,7 +2342,7 @@ typedef struct sSirHalWowlExitParams {
/* Status code to be filled by HAL when it sends
* SIR_HAL_WOWL_EXIT_RSP to PE.
*/
CDF_STATUS status;
QDF_STATUS status;
/*BSSIDX to find the current session
*/

4
core/mac/src/pe/include/lim_api.h
Fájl megtekintése

@@ -167,7 +167,7 @@ bool lim_is_deauth_diassoc_for_drop(tpAniSirGlobal mac, uint8_t *rx_pkt_info);
bool lim_is_assoc_req_for_drop(tpAniSirGlobal mac, uint8_t *rx_pkt_info);
#endif
#ifdef WLAN_FEATURE_ROAM_OFFLOAD
CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
QDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
struct sSirSmeRoamOffloadSynchInd *roam_sync_ind_ptr,
tpSirBssDescription bss_desc_ptr);
#endif
@@ -229,7 +229,7 @@ void pe_free_msg(tpAniSirGlobal pMac, tSirMsgQ *pMsg);
\return void
--------------------------------------------------------------------------*/
void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, CDF_STATUS status, uint32_t *data);
void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, QDF_STATUS status, uint32_t *data);
void lim_process_abort_scan_ind(tpAniSirGlobal pMac, uint8_t sessionId,
uint32_t scan_id, uint32_t scan_requestor_id);

8
core/mac/src/pe/include/lim_ft.h
Fájl megtekintése

@@ -48,11 +48,11 @@ void lim_ft_open(tpAniSirGlobal pMac, tpPESession psessionEntry);
void lim_ft_cleanup(tpAniSirGlobal pMac, tpPESession psessionEntry);
void lim_ft_cleanup_pre_auth_info(tpAniSirGlobal pMac, tpPESession psessionEntry);
int lim_process_ft_pre_auth_req(tpAniSirGlobal pMac, tpSirMsgQ pMsg);
void lim_perform_ft_pre_auth(tpAniSirGlobal pMac, CDF_STATUS status,
void lim_perform_ft_pre_auth(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data, tpPESession psessionEntry);
void limPerformPostFTPreAuth(tpAniSirGlobal pMac, CDF_STATUS status,
void limPerformPostFTPreAuth(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data, tpPESession psessionEntry);
void limFTResumeLinkCb(tpAniSirGlobal pMac, CDF_STATUS status, uint32_t *data);
void limFTResumeLinkCb(tpAniSirGlobal pMac, QDF_STATUS status, uint32_t *data);
void lim_post_ft_pre_auth_rsp(tpAniSirGlobal pMac, tSirRetStatus status,
uint8_t *auth_rsp, uint16_t auth_rsp_length,
tpPESession psessionEntry);
@@ -81,7 +81,7 @@ tSirRetStatus lim_ft_prepare_add_bss_req(tpAniSirGlobal pMac,
uint8_t updateEntry,
tpPESession pftSessionEntry,
tpSirBssDescription bssDescription);
CDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
QDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
uint8_t session_id, tSirFTPreAuthReq *ft_preauth_req);
#endif /* __LIMFT_H__ */

2
core/mac/src/pe/include/lim_global.h
Fájl megtekintése

@@ -209,7 +209,7 @@ typedef enum eLimDot11hChanSwStates {
/* WLAN_SUSPEND_LINK Related */
typedef void (*SUSPEND_RESUME_LINK_CALLBACK)(tpAniSirGlobal pMac,
CDF_STATUS status,
QDF_STATUS status,
uint32_t *data);
/* LIM to HAL SCAN Management Message Interface states */

4
core/mac/src/pe/lim/lim_admit_control.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2011-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2011-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -1087,7 +1087,7 @@ void lim_process_hal_add_ts_rsp(tpAniSirGlobal pMac, tpSirMsgQ limMsg)
goto end;
}
if (pAddTsRspMsg->status == CDF_STATUS_SUCCESS) {
if (pAddTsRspMsg->status == QDF_STATUS_SUCCESS) {
PELOG1(lim_log
(pMac, LOG1,
FL("Received successful ADDTS response from HAL "));

68
core/mac/src/pe/lim/lim_api.c
Fájl megtekintése

@@ -766,7 +766,7 @@ tSirRetStatus pe_open(tpAniSirGlobal pMac, tMacOpenParameters *pMacOpenParam)
pMac->lim.mgmtFrameSessionId = 0xff;
pMac->lim.deferredMsgCnt = 0;
if (!CDF_IS_STATUS_SUCCESS(cdf_mutex_init(&pMac->lim.lkPeGlobalLock))) {
if (!QDF_IS_STATUS_SUCCESS(cdf_mutex_init(&pMac->lim.lkPeGlobalLock))) {
PELOGE(lim_log(pMac, LOGE, FL("pe lock init failed!"));)
status = eSIR_FAILURE;
goto pe_open_lock_fail;
@@ -829,7 +829,7 @@ tSirRetStatus pe_close(tpAniSirGlobal pMac)
cdf_mem_free(pMac->lim.gpSession);
pMac->lim.gpSession = NULL;
if (!CDF_IS_STATUS_SUCCESS
if (!QDF_IS_STATUS_SUCCESS
(cdf_mutex_destroy(&pMac->lim.lkPeGlobalLock))) {
return eSIR_FAILURE;
}
@@ -987,18 +987,18 @@ tSirRetStatus pe_process_messages(tpAniSirGlobal pMac, tSirMsgQ *pMsg)
* @return None
*/
CDF_STATUS pe_handle_mgmt_frame(void *p_cds_gctx, void *cds_buff)
QDF_STATUS pe_handle_mgmt_frame(void *p_cds_gctx, void *cds_buff)
{
tpAniSirGlobal pMac;
tpSirMacMgmtHdr mHdr;
tSirMsgQ msg;
cds_pkt_t *pVosPkt;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
uint8_t *pRxPacketInfo;
pVosPkt = (cds_pkt_t *) cds_buff;
if (NULL == pVosPkt) {
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
pMac = cds_get_context(CDF_MODULE_ID_PE);
@@ -1006,16 +1006,16 @@ CDF_STATUS pe_handle_mgmt_frame(void *p_cds_gctx, void *cds_buff)
/* cannot log a failure without a valid pMac */
cds_pkt_return_packet(pVosPkt);
pVosPkt = NULL;
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
cdf_status =
qdf_status =
wma_ds_peek_rx_packet_info(pVosPkt, (void *)&pRxPacketInfo, false);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
cds_pkt_return_packet(pVosPkt);
pVosPkt = NULL;
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
/*
@@ -1065,10 +1065,10 @@ CDF_STATUS pe_handle_mgmt_frame(void *p_cds_gctx, void *cds_buff)
lim_log(pMac, LOGW,
FL
("sys_bbt_process_message_core failed to process SIR_BB_XPORT_MGMT_MSG"));
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -1081,20 +1081,20 @@ CDF_STATUS pe_handle_mgmt_frame(void *p_cds_gctx, void *cds_buff)
void pe_register_wma_handle(tpAniSirGlobal pMac, tSirSmeReadyReq *ready_req)
{
void *p_cds_gctx;
CDF_STATUS retStatus;
QDF_STATUS retStatus;
p_cds_gctx = cds_get_global_context();
retStatus = wma_register_mgmt_frm_client(p_cds_gctx,
pe_handle_mgmt_frame);
if (retStatus != CDF_STATUS_SUCCESS)
if (retStatus != QDF_STATUS_SUCCESS)
lim_log(pMac, LOGP,
FL("Registering the PE Handle with WMA has failed"));
retStatus = wma_register_roaming_callbacks(p_cds_gctx,
ready_req->csr_roam_synch_cb,
ready_req->pe_roam_synch_cb);
if (retStatus != CDF_STATUS_SUCCESS)
if (retStatus != QDF_STATUS_SUCCESS)
lim_log(pMac, LOGP,
FL("Registering roaming callbacks with WMA failed"));
}
@@ -1836,7 +1836,7 @@ void lim_fill_join_rsp_ht_caps(tpPESession session, tpSirSmeJoinRsp join_rsp)
#endif
#ifdef WLAN_FEATURE_ROAM_OFFLOAD
CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
QDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
roam_offload_synch_ind *roam_offload_synch_ind_ptr,
tpSirBssDescription bss_desc_ptr)
{
@@ -1852,7 +1852,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
(tpSirProbeRespBeacon) cdf_mem_malloc(sizeof(tSirProbeRespBeacon));
if (NULL == parsed_frm_ptr) {
lim_log(pMac, LOGE, "fail to allocate memory for frame");
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
if (roam_offload_synch_ind_ptr->beaconProbeRespLength <=
@@ -1861,7 +1861,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
"few bytes in synchInd beacon / probe resp frame! length=%d",
__func__, roam_offload_synch_ind_ptr->beaconProbeRespLength);
cdf_mem_free(parsed_frm_ptr);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
CDF_TRACE(CDF_MODULE_ID_PE, CDF_TRACE_LEVEL_INFO,
@@ -1879,7 +1879,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
"Parse error Beacon, length=%d",
roam_offload_synch_ind_ptr->beaconProbeRespLength);
cdf_mem_free(parsed_frm_ptr);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
} else {
if (sir_convert_probe_frame2_struct(pMac,
@@ -1891,7 +1891,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
"Parse error ProbeResponse, length=%d",
roam_offload_synch_ind_ptr->beaconProbeRespLength);
cdf_mem_free(parsed_frm_ptr);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
}
/* 24 byte MAC header and 12 byte to ssid IE */
@@ -1983,7 +1983,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
ie_len);
}
cdf_mem_free(parsed_frm_ptr);
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
* pe_roam_synch_callback() - PE level callback for roam synch propagation
@@ -1997,7 +1997,7 @@ CDF_STATUS lim_roam_fill_bss_descr(tpAniSirGlobal pMac,
*
* Return: Success or Failure status
*/
CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
QDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
roam_offload_synch_ind *roam_sync_ind_ptr,
tpSirBssDescription bss_desc)
{
@@ -2008,7 +2008,7 @@ CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
uint16_t aid;
tpAddBssParams add_bss_params;
uint8_t local_nss;
CDF_STATUS status = CDF_STATUS_E_FAILURE;
QDF_STATUS status = QDF_STATUS_E_FAILURE;
if (!roam_sync_ind_ptr) {
lim_log(mac_ctx, LOGE, FL("LFR3:roam_sync_ind_ptr is NULL"));
@@ -2030,11 +2030,11 @@ CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
return status;
}
status = lim_roam_fill_bss_descr(mac_ctx, roam_sync_ind_ptr, bss_desc);
if (!CDF_IS_STATUS_SUCCESS(status)) {
if (!QDF_IS_STATUS_SUCCESS(status)) {
lim_log(mac_ctx, LOGE, FL("LFR3:Failed to fill Bss Descr"));
return status;
}
status = CDF_STATUS_E_FAILURE;
status = QDF_STATUS_E_FAILURE;
ft_session_ptr = pe_create_session(mac_ctx, bss_desc->bssId,
&session_id, mac_ctx->lim.maxStation,
eSIR_INFRASTRUCTURE_MODE);
@@ -2096,7 +2096,7 @@ CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
if (NULL == mac_ctx->roam.pReassocResp) {
lim_log(mac_ctx, LOGE, FL("LFR3:assoc resp mem alloc failed"));
ft_session_ptr->bRoamSynchInProgress = false;
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cdf_mem_copy(mac_ctx->roam.pReassocResp,
(uint8_t *)roam_sync_ind_ptr +
@@ -2137,7 +2137,7 @@ CDF_STATUS pe_roam_synch_callback(tpAniSirGlobal mac_ctx,
if (mac_ctx->roam.pReassocResp)
cdf_mem_free(mac_ctx->roam.pReassocResp);
mac_ctx->roam.pReassocResp = NULL;
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
#endif
@@ -2259,26 +2259,26 @@ tMgmtFrmDropReason lim_is_pkt_candidate_for_drop(tpAniSirGlobal pMac,
return eMGMT_DROP_NO_DROP;
}
CDF_STATUS pe_acquire_global_lock(tAniSirLim *psPe)
QDF_STATUS pe_acquire_global_lock(tAniSirLim *psPe)
{
CDF_STATUS status = CDF_STATUS_E_INVAL;
QDF_STATUS status = QDF_STATUS_E_INVAL;
if (psPe) {
if (CDF_IS_STATUS_SUCCESS
if (QDF_IS_STATUS_SUCCESS
(cdf_mutex_acquire(&psPe->lkPeGlobalLock))) {
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
}
return status;
}
CDF_STATUS pe_release_global_lock(tAniSirLim *psPe)
QDF_STATUS pe_release_global_lock(tAniSirLim *psPe)
{
CDF_STATUS status = CDF_STATUS_E_INVAL;
QDF_STATUS status = QDF_STATUS_E_INVAL;
if (psPe) {
if (CDF_IS_STATUS_SUCCESS
if (QDF_IS_STATUS_SUCCESS
(cdf_mutex_release(&psPe->lkPeGlobalLock))) {
status = CDF_STATUS_SUCCESS;
status = QDF_STATUS_SUCCESS;
}
}
return status;

12
core/mac/src/pe/lim/lim_assoc_utils.c
Fájl megtekintése

@@ -2348,7 +2348,7 @@ lim_add_sta(tpAniSirGlobal mac_ctx,
add_sta_params->updateSta = update_entry;
add_sta_params->status = CDF_STATUS_SUCCESS;
add_sta_params->status = QDF_STATUS_SUCCESS;
add_sta_params->respReqd = 1;
/* Update HT Capability */
@@ -2757,7 +2757,7 @@ lim_del_sta(tpAniSirGlobal pMac,
cdf_mem_copy((uint8_t *) pDelStaParams->staMac,
(uint8_t *) pStaDs->staAddr, sizeof(tSirMacAddr));
pDelStaParams->status = CDF_STATUS_SUCCESS;
pDelStaParams->status = QDF_STATUS_SUCCESS;
msgQ.type = WMA_DELETE_STA_REQ;
msgQ.reserved = 0;
msgQ.bodyptr = pDelStaParams;
@@ -2908,7 +2908,7 @@ lim_add_sta_self(tpAniSirGlobal pMac, uint16_t staIdx, uint8_t updateSta,
pAddStaParams->assocId = psessionEntry->limAID;
pAddStaParams->staType = STA_ENTRY_SELF;
pAddStaParams->status = CDF_STATUS_SUCCESS;
pAddStaParams->status = QDF_STATUS_SUCCESS;
pAddStaParams->respReqd = 1;
/* Update PE session ID */
@@ -3586,7 +3586,7 @@ lim_del_bss(tpAniSirGlobal pMac, tpDphHashNode pStaDs, uint16_t bssIdx,
lim_deactivate_and_change_timer(pMac, eLIM_JOIN_FAIL_TIMER);
}
pDelBssParams->status = CDF_STATUS_SUCCESS;
pDelBssParams->status = QDF_STATUS_SUCCESS;
pDelBssParams->respReqd = 1;
cdf_mem_copy(pDelBssParams->bssid, psessionEntry->bssId,
sizeof(tSirMacAddr));
@@ -4213,7 +4213,7 @@ tSirRetStatus lim_sta_send_add_bss(tpAniSirGlobal pMac, tpSirAssocRsp pAssocRsp,
lim_log(pMac, LOG2, FL("maxTxPower: %d"), pAddBssParams->maxTxPower);
#endif
/* FIXME_GEN4 - Any other value that can be used for initialization? */
pAddBssParams->status = CDF_STATUS_SUCCESS;
pAddBssParams->status = QDF_STATUS_SUCCESS;
pAddBssParams->respReqd = true;
/* update persona */
pAddBssParams->halPersona = (uint8_t) psessionEntry->pePersona;
@@ -4744,7 +4744,7 @@ tSirRetStatus lim_sta_send_add_bss_pre_assoc(tpAniSirGlobal pMac, uint8_t update
lim_log(pMac, LOG2, FL("maxTxPower: %d"), pAddBssParams->maxTxPower);
#endif
pAddBssParams->status = CDF_STATUS_SUCCESS;
pAddBssParams->status = QDF_STATUS_SUCCESS;
pAddBssParams->respReqd = true;
pAddBssParams->staContext.smesessionId = psessionEntry->smeSessionId;

31
core/mac/src/pe/lim/lim_ft.c
Fájl megtekintése

@@ -283,7 +283,7 @@ int lim_process_ft_pre_auth_req(tpAniSirGlobal mac_ctx, tpSirMsgQ msg)
FL("Performing pre-auth on same channel (session %p)"),
session);
/* We are in the same channel. Perform pre-auth */
lim_perform_ft_pre_auth(mac_ctx, CDF_STATUS_SUCCESS, NULL,
lim_perform_ft_pre_auth(mac_ctx, QDF_STATUS_SUCCESS, NULL,
session);
}
@@ -294,7 +294,7 @@ int lim_process_ft_pre_auth_req(tpAniSirGlobal mac_ctx, tpSirMsgQ msg)
* Send the Auth1
* Receive back Auth2
*------------------------------------------------------------------*/
void lim_perform_ft_pre_auth(tpAniSirGlobal pMac, CDF_STATUS status,
void lim_perform_ft_pre_auth(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data, tpPESession psessionEntry)
{
tSirMacAuthFrameBody authFrame;
@@ -314,7 +314,7 @@ void lim_perform_ft_pre_auth(tpAniSirGlobal pMac, CDF_STATUS status,
}
}
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
lim_log(pMac, LOGE,
FL(" Change channel not successful for FT pre-auth"));
goto preauth_fail;
@@ -404,7 +404,7 @@ tSirRetStatus lim_ft_prepare_add_bss_req(tpAniSirGlobal pMac,
cdf_mem_free(pBeaconStruct);
lim_log(pMac, LOGP,
FL("Unable to allocate memory for creating ADD_BSS"));
return (eSIR_MEM_ALLOC_FAILED);
return eSIR_MEM_ALLOC_FAILED;
}
cdf_mem_set((uint8_t *) pAddBssParams, sizeof(tAddBssParams), 0);
@@ -726,7 +726,7 @@ tSirRetStatus lim_ft_prepare_add_bss_req(tpAniSirGlobal pMac,
}
#endif
pAddBssParams->status = CDF_STATUS_SUCCESS;
pAddBssParams->status = QDF_STATUS_SUCCESS;
pAddBssParams->respReqd = true;
pAddBssParams->staContext.sessionId = pftSessionEntry->peSessionId;
@@ -1012,7 +1012,7 @@ tSirRetStatus lim_ft_setup_auth_session(tpAniSirGlobal pMac,
/*------------------------------------------------------------------
* Resume Link Call Back
*------------------------------------------------------------------*/
void lim_ft_process_pre_auth_result(tpAniSirGlobal pMac, CDF_STATUS status,
void lim_ft_process_pre_auth_result(tpAniSirGlobal pMac, QDF_STATUS status,
tpPESession psessionEntry)
{
if (NULL == psessionEntry ||
@@ -1172,10 +1172,11 @@ void lim_handle_ft_pre_auth_rsp(tpAniSirGlobal pMac, tSirRetStatus status,
pbssDescription =
psessionEntry->ftPEContext.pFTPreAuthReq->pbssDescription;
lim_print_mac_addr(pMac, pbssDescription->bssId, LOG1);
if ((pftSessionEntry =
pftSessionEntry =
pe_create_session(pMac, pbssDescription->bssId,
&sessionId, pMac->lim.maxStation,
psessionEntry->bssType)) == NULL) {
psessionEntry->bssType);
if (pftSessionEntry == NULL) {
lim_log(pMac, LOGE, FL(
"Session not created for pre-auth 11R AP"));
status = eSIR_FAILURE;
@@ -1655,7 +1656,7 @@ void lim_process_ft_aggr_qo_s_rsp(tpAniSirGlobal pMac, tpSirMsgQ limMsg)
}
for (i = 0; i < HAL_QOS_NUM_AC_MAX; i++) {
if ((((1 << i) & pAggrQosRspMsg->tspecIdx)) &&
(pAggrQosRspMsg->status[i] != CDF_STATUS_SUCCESS)) {
(pAggrQosRspMsg->status[i] != QDF_STATUS_SUCCESS)) {
sir_copy_mac_addr(peerMacAddr, psessionEntry->bssId);
addTsParam.staIdx = pAggrQosRspMsg->staIdx;
addTsParam.sessionId = pAggrQosRspMsg->sessionId;
@@ -1878,7 +1879,7 @@ tSirRetStatus lim_process_ft_aggr_qos_req(tpAniSirGlobal pMac, uint32_t *pMsgBuf
*
* Return: Status of sending message to WMA.
*/
CDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
QDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
uint8_t session_id,
tSirFTPreAuthReq *ft_preauth_req)
{
@@ -1890,7 +1891,7 @@ CDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
if (NULL == scan_offload_req) {
lim_log(mac_ctx, LOGE,
FL("Memory allocation failed for pScanOffloadReq"));
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cdf_mem_zero(scan_offload_req, sizeof(tSirScanOffloadReq));
@@ -1932,10 +1933,10 @@ CDF_STATUS lim_send_preauth_scan_offload(tpAniSirGlobal mac_ctx,
if (rc != eSIR_SUCCESS) {
lim_log(mac_ctx, LOGE, FL("START_SCAN_OFFLOAD failed %u"), rc);
cdf_mem_free(scan_offload_req);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
@@ -1982,13 +1983,13 @@ void lim_preauth_scan_event_handler(tpAniSirGlobal mac_ctx,
* after successful auth, or timed out. Either way, STA
* is back to home channel. Data traffic can continue.
*/
lim_ft_process_pre_auth_result(mac_ctx, CDF_STATUS_SUCCESS,
lim_ft_process_pre_auth_result(mac_ctx, QDF_STATUS_SUCCESS,
session_entry);
break;
case SCAN_EVENT_FOREIGN_CHANNEL:
/* Sta is on candidate channel. Send auth */
lim_perform_ft_pre_auth(mac_ctx, CDF_STATUS_SUCCESS, NULL,
lim_perform_ft_pre_auth(mac_ctx, QDF_STATUS_SUCCESS, NULL,
session_entry);
break;
default:

8
core/mac/src/pe/lim/lim_ibss_peer_mgmt.c
Fájl megtekintése

@@ -1,5 +1,5 @@
/*
* Copyright (c) 2012-2015 The Linux Foundation. All rights reserved.
* Copyright (c) 2012-2016 The Linux Foundation. All rights reserved.
*
* Previously licensed under the ISC license by Qualcomm Atheros, Inc.
*
@@ -1088,7 +1088,7 @@ lim_ibss_add_sta_rsp(tpAniSirGlobal pMac, void *msg, tpPESession psessionEntry)
return eSIR_FAILURE;
}
if (pAddStaParams->status != CDF_STATUS_SUCCESS) {
if (pAddStaParams->status != QDF_STATUS_SUCCESS) {
PELOGE(lim_log
(pMac, LOGE, FL("IBSS: ADD_STA_RSP error (%x) "),
pAddStaParams->status);
@@ -1137,7 +1137,7 @@ void lim_ibss_del_bss_rsp_when_coalescing(tpAniSirGlobal pMac, void *msg,
goto end;
}
if (pDelBss->status != CDF_STATUS_SUCCESS) {
if (pDelBss->status != QDF_STATUS_SUCCESS) {
lim_log(pMac, LOGE,
FL("IBSS: DEL_BSS_RSP(coalesce) error (%x) Bss %d "),
pDelBss->status, pDelBss->bssIdx);
@@ -1234,7 +1234,7 @@ void lim_ibss_del_bss_rsp(tpAniSirGlobal pMac, void *msg, tpPESession psessionEn
return;
}
if (pDelBss->status != CDF_STATUS_SUCCESS) {
if (pDelBss->status != QDF_STATUS_SUCCESS) {
PELOGE(lim_log
(pMac, LOGE, FL("IBSS: DEL_BSS_RSP error (%x) Bss %d "),
pDelBss->status, pDelBss->bssIdx);

70
core/mac/src/pe/lim/lim_p2p.c
Fájl megtekintése

@@ -63,21 +63,21 @@
received Beacon/Prpbe Resp. */
#define MAX_TIME_TO_BE_ACTIVE_CHANNEL 9000
void lim_exit_remain_on_channel(tpAniSirGlobal pMac, CDF_STATUS status,
void lim_exit_remain_on_channel(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data, tpPESession psessionEntry);
extern tSirRetStatus lim_set_link_state(tpAniSirGlobal pMac, tSirLinkState state,
tSirMacAddr bssId, tSirMacAddr selfMacAddr,
tpSetLinkStateCallback callback,
void *callbackArg);
CDF_STATUS lim_p2p_action_cnf(tpAniSirGlobal pMac, uint32_t txCompleteSuccess);
QDF_STATUS lim_p2p_action_cnf(tpAniSirGlobal pMac, uint32_t txCompleteSuccess);
/*------------------------------------------------------------------
*
* Below function is called if hdd requests a remain on channel.
*
*------------------------------------------------------------------*/
static CDF_STATUS lim_send_hal_req_remain_on_chan_offload(tpAniSirGlobal pMac,
static QDF_STATUS lim_send_hal_req_remain_on_chan_offload(tpAniSirGlobal pMac,
tSirRemainOnChnReq *
pRemOnChnReq)
{
@@ -89,7 +89,7 @@ static CDF_STATUS lim_send_hal_req_remain_on_chan_offload(tpAniSirGlobal pMac,
if (NULL == pScanOffloadReq) {
lim_log(pMac, LOGE,
FL("Memory allocation failed for pScanOffloadReq"));
return CDF_STATUS_E_NOMEM;
return QDF_STATUS_E_NOMEM;
}
cdf_mem_zero(pScanOffloadReq, sizeof(tSirScanOffloadReq));
@@ -122,10 +122,10 @@ static CDF_STATUS lim_send_hal_req_remain_on_chan_offload(tpAniSirGlobal pMac,
lim_log(pMac, LOGE, FL("wma_post_ctrl_msg() return failure %u"),
rc);
cdf_mem_free(pScanOffloadReq);
return CDF_STATUS_E_FAILURE;
return QDF_STATUS_E_FAILURE;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/*------------------------------------------------------------------
@@ -137,11 +137,11 @@ static CDF_STATUS lim_send_hal_req_remain_on_chan_offload(tpAniSirGlobal pMac,
int lim_process_remain_on_chnl_req(tpAniSirGlobal pMac, uint32_t *pMsg)
{
tSirRemainOnChnReq *msgbuff = (tSirRemainOnChnReq *) pMsg;
CDF_STATUS status;
QDF_STATUS status;
pMac->lim.gpLimRemainOnChanReq = msgbuff;
status = lim_send_hal_req_remain_on_chan_offload(pMac, msgbuff);
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
/* Post the meessage to Sme */
lim_send_sme_rsp(pMac, eWNI_SME_REMAIN_ON_CHN_RSP,
status, msgbuff->sessionId, msgbuff->scan_id);
@@ -250,14 +250,13 @@ void lim_process_remain_on_chn_timeout(tpAniSirGlobal mac_ctx)
/* get the previous valid LINK state */
if (lim_set_link_state(mac_ctx, eSIR_LINK_IDLE_STATE, null_bssid,
mac_ctx->lim.gSelfMacAddr, NULL, NULL) != eSIR_SUCCESS)
{
mac_ctx->lim.gSelfMacAddr, NULL, NULL) != eSIR_SUCCESS) {
lim_log(mac_ctx, LOGE, FL("Unable to change link state"));
return;
}
if (mac_ctx->lim.gLimMlmState != eLIM_MLM_P2P_LISTEN_STATE) {
lim_remain_on_chn_rsp(mac_ctx, CDF_STATUS_SUCCESS, NULL);
lim_remain_on_chn_rsp(mac_ctx, QDF_STATUS_SUCCESS, NULL);
} else {
session = pe_find_session_by_session_id(mac_ctx,
roc_timer->sessionId);
@@ -269,11 +268,11 @@ void lim_process_remain_on_chn_timeout(tpAniSirGlobal mac_ctx)
goto error;
}
lim_exit_remain_on_channel(mac_ctx, CDF_STATUS_SUCCESS, NULL,
lim_exit_remain_on_channel(mac_ctx, QDF_STATUS_SUCCESS, NULL,
session);
return;
error:
lim_remain_on_chn_rsp(mac_ctx, CDF_STATUS_E_FAILURE, NULL);
lim_remain_on_chn_rsp(mac_ctx, QDF_STATUS_E_FAILURE, NULL);
}
return;
}
@@ -285,21 +284,21 @@ error:
*
*------------------------------------------------------------------*/
void lim_exit_remain_on_channel(tpAniSirGlobal pMac, CDF_STATUS status,
void lim_exit_remain_on_channel(tpAniSirGlobal pMac, QDF_STATUS status,
uint32_t *data, tpPESession psessionEntry)
{
if (status != CDF_STATUS_SUCCESS) {
if (status != QDF_STATUS_SUCCESS) {
PELOGE(lim_log(pMac, LOGE, "Remain on Channel Failed");)
goto error;
}
/* Set the resume channel to Any valid channel (invalid). */
/* This will instruct HAL to set it to any previous valid channel. */
pe_set_resume_channel(pMac, 0, 0);
lim_remain_on_chn_rsp(pMac, CDF_STATUS_SUCCESS, NULL);
lim_remain_on_chn_rsp(pMac, QDF_STATUS_SUCCESS, NULL);
return;
error:
lim_remain_on_chn_rsp(pMac, CDF_STATUS_E_FAILURE, NULL);
lim_remain_on_chn_rsp(pMac, QDF_STATUS_E_FAILURE, NULL);
return;
}
@@ -308,7 +307,7 @@ error:
* Send remain on channel respone: Success/ Failure
*
*------------------------------------------------------------------*/
void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, CDF_STATUS status, uint32_t *data)
void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, QDF_STATUS status, uint32_t *data)
{
tpPESession psessionEntry;
uint8_t sessionId;
@@ -324,7 +323,7 @@ void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, CDF_STATUS status, uint32_t *dat
}
/* Incase of the Remain on Channel Failure Case */
/* Cleanup Everything */
if (CDF_STATUS_E_FAILURE == status) {
if (QDF_STATUS_E_FAILURE == status) {
/* Deactivate Remain on Channel Timer */
lim_deactivate_and_change_timer(pMac, eLIM_REMAIN_CHN_TIMER);
@@ -342,10 +341,11 @@ void lim_remain_on_chn_rsp(tpAniSirGlobal pMac, CDF_STATUS status, uint32_t *dat
}
/* delete the session */
if ((psessionEntry = pe_find_session_by_bssid(pMac,
psessionEntry = pe_find_session_by_bssid(pMac,
MsgRemainonChannel->
selfMacAddr.bytes,
&sessionId)) != NULL) {
&sessionId);
if (psessionEntry != NULL) {
if (LIM_IS_P2P_DEVICE_ROLE(psessionEntry)) {
pe_delete_session(pMac, psessionEntry);
}
@@ -412,7 +412,7 @@ void lim_send_sme_mgmt_frame_ind(tpAniSirGlobal pMac, uint8_t frameType,
return;
}
CDF_STATUS lim_p2p_action_cnf(tpAniSirGlobal pMac, uint32_t txCompleteSuccess)
QDF_STATUS lim_p2p_action_cnf(tpAniSirGlobal pMac, uint32_t txCompleteSuccess)
{
if (pMac->lim.mgmtFrameSessionId != 0xff) {
/* The session entry might be invalid(0xff) action confirmation received after
@@ -424,7 +424,7 @@ CDF_STATUS lim_p2p_action_cnf(tpAniSirGlobal pMac, uint32_t txCompleteSuccess)
pMac->lim.mgmtFrameSessionId = 0xff;
}
return CDF_STATUS_SUCCESS;
return QDF_STATUS_SUCCESS;
}
/**
@@ -445,7 +445,7 @@ static void lim_tx_action_frame(tpAniSirGlobal mac_ctx,
{
uint8_t tx_flag = 0;
tpSirMacFrameCtl fc = (tpSirMacFrameCtl) mb_msg->data;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
uint8_t sme_session_id = 0;
uint16_t channel_freq;
@@ -459,7 +459,7 @@ static void lim_tx_action_frame(tpAniSirGlobal mac_ctx,
if ((SIR_MAC_MGMT_PROBE_RSP == fc->subType) ||
(mb_msg->noack)) {
cdf_status = wma_tx_frame(mac_ctx, packet, (uint16_t) msg_len,
qdf_status = wma_tx_frame(mac_ctx, packet, (uint16_t) msg_len,
TXRX_FRM_802_11_MGMT,
ANI_TXDIR_TODS, 7, lim_tx_complete,
frame, tx_flag, sme_session_id,
@@ -468,11 +468,11 @@ static void lim_tx_action_frame(tpAniSirGlobal mac_ctx,
if (!mb_msg->noack)
lim_send_sme_rsp(mac_ctx,
eWNI_SME_ACTION_FRAME_SEND_CNF,
cdf_status, mb_msg->sessionId, 0);
qdf_status, mb_msg->sessionId, 0);
mac_ctx->lim.mgmtFrameSessionId = 0xff;
} else {
mac_ctx->lim.mgmtFrameSessionId = mb_msg->sessionId;
cdf_status =
qdf_status =
wma_tx_frameWithTxComplete(mac_ctx, packet,
(uint16_t) msg_len,
TXRX_FRM_802_11_MGMT,
@@ -481,12 +481,12 @@ static void lim_tx_action_frame(tpAniSirGlobal mac_ctx,
sme_session_id, false,
channel_freq);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
lim_log(mac_ctx, LOGE,
FL("couldn't send action frame"));
lim_send_sme_rsp(mac_ctx,
eWNI_SME_ACTION_FRAME_SEND_CNF,
cdf_status, mb_msg->sessionId, 0);
qdf_status, mb_msg->sessionId, 0);
mac_ctx->lim.mgmtFrameSessionId = 0xff;
} else {
mac_ctx->lim.mgmtFrameSessionId = mb_msg->sessionId;
@@ -516,7 +516,7 @@ void lim_send_p2p_action_frame(tpAniSirGlobal mac_ctx,
uint32_t msg_len;
uint8_t *frame;
void *packet;
CDF_STATUS cdf_status;
QDF_STATUS qdf_status;
tpSirMacFrameCtl fc = (tpSirMacFrameCtl) mb_msg->data;
uint8_t noa_len = 0;
uint8_t noa_stream[SIR_MAX_NOA_ATTR_LEN + (2 * SIR_P2P_IE_HEADER_LEN)];
@@ -541,7 +541,7 @@ void lim_send_p2p_action_frame(tpAniSirGlobal mac_ctx,
lim_log(mac_ctx, LOGE,
FL("RemainOnChannel is not running\n"));
lim_send_sme_rsp(mac_ctx, eWNI_SME_ACTION_FRAME_SEND_CNF,
CDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
QDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
return;
}
sme_session_id = mb_msg->sessionId;
@@ -654,9 +654,9 @@ void lim_send_p2p_action_frame(tpAniSirGlobal mac_ctx,
msg_len - PROBE_RSP_IE_OFFSET);
/* Ok-- try to allocate some memory: */
cdf_status = cds_packet_alloc((uint16_t) msg_len, (void **)&frame,
qdf_status = cds_packet_alloc((uint16_t) msg_len, (void **)&frame,
(void **)&packet);
if (!CDF_IS_STATUS_SUCCESS(cdf_status)) {
if (!QDF_IS_STATUS_SUCCESS(qdf_status)) {
lim_log(mac_ctx, LOGE,
FL("Failed to allocate %d bytes for a Probe Request."),
msg_len);
@@ -720,7 +720,7 @@ void lim_send_p2p_action_frame(tpAniSirGlobal mac_ctx,
FL("Dropping SA Query - PE Session not found"));
lim_send_sme_rsp(mac_ctx,
eWNI_SME_ACTION_FRAME_SEND_CNF,
CDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
QDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
cds_packet_free((void *)packet);
return;
}
@@ -734,7 +734,7 @@ void lim_send_p2p_action_frame(tpAniSirGlobal mac_ctx,
FL("Dropping SA Query due to non PMF conne."));
lim_send_sme_rsp(mac_ctx,
eWNI_SME_ACTION_FRAME_SEND_CNF,
CDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
QDF_STATUS_E_FAILURE, mb_msg->sessionId, 0);
cds_packet_free((void *)packet);
return;
}

5
core/mac/src/pe/lim/lim_process_assoc_rsp_frame.c
Fájl megtekintése

@@ -811,8 +811,7 @@ lim_process_assoc_rsp_frame(tpAniSirGlobal mac_ctx,
/* Stop Association failure timer */
if (subtype == LIM_ASSOC)
lim_deactivate_and_change_timer(mac_ctx, eLIM_ASSOC_FAIL_TIMER);
else
{
else {
/* Stop Reassociation failure timer */
mac_ctx->lim.reAssocRetryAttempt = 0;
if ((NULL != mac_ctx->lim.pSessionEntry)
@@ -893,7 +892,7 @@ lim_process_assoc_rsp_frame(tpAniSirGlobal mac_ctx,
FL("ASSOC res with eSIR_MAC_TRY_AGAIN_LATER "
" recvd.Starting timer to wait timeout=%d."),
timeout_value);
if (CDF_STATUS_SUCCESS !=
if (QDF_STATUS_SUCCESS !=
cdf_mc_timer_start(
&session_entry->pmfComebackTimer,
timeout_value)) {

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