samsung-sm8650/android_kernel_samsung_sm8650-modules
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android_kernel_samsung_sm86…/msm/dp/dp_pll_5nm.c
Tatenda Chipeperekwa 37412f5add disp: msm: dp: add support for PLL programming 
Add support for PLL programming in the DisplayPort driver.

Change-Id: I4f08a621dcae5d1f54d67bb5c34409249012cc7b
Signed-off-by: Tatenda Chipeperekwa <tatendac@codeaurora.org>
2020-03-13 20:26:39 -07:00

1039 rindas
27 KiB
C
Neapstrādāts Vainot Vēsture

// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (c) 2016-2020, The Linux Foundation. All rights reserved.
*/
/*
* Display Port PLL driver block diagram for branch clocks
*
* +------------------------------+
* | DP_VCO_CLK |
* | |
* | +-------------------+ |
* | | (DP PLL/VCO) | |
* | +---------+---------+ |
* | v |
* | +----------+-----------+ |
* | | hsclk_divsel_clk_src | |
* | +----------+-----------+ |
* +------------------------------+
* |
* +------------<---------v------------>----------+
* | |
* +-----v------------+ |
* | dp_link_clk_src | |
* | divsel_ten | |
* +---------+--------+ |
* | |
* | |
* v v
* Input to DISPCC block |
* for link clk, crypto clk |
* and interface clock |
* |
* |
* +--------<------------+-----------------+---<---+
* | | |
* +-------v------+ +--------v-----+ +--------v------+
* | vco_divided | | vco_divided | | vco_divided |
* | _clk_src | | _clk_src | | _clk_src |
* | | | | | |
* |divsel_six | | divsel_two | | divsel_four |
* +-------+------+ +-----+--------+ +--------+------+
* | | |
* v------->----------v-------------<------v
* |
* +----------+---------+
* | vco_divided_clk |
* | _src_mux |
* +---------+----------+
* |
* v
* Input to DISPCC block
* for DP pixel clock
*
*/
#include <dt-bindings/clock/mdss-5nm-pll-clk.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/err.h>
#include <linux/iopoll.h>
#include <linux/kernel.h>
#include <linux/regmap.h>
#include "clk-regmap-mux.h"
#include "dp_hpd.h"
#include "dp_debug.h"
#include "dp_pll.h"
#define DP_PHY_CFG 0x0010
#define DP_PHY_CFG_1 0x0014
#define DP_PHY_PD_CTL 0x0018
#define DP_PHY_MODE 0x001C
#define DP_PHY_AUX_CFG1 0x0024
#define DP_PHY_AUX_CFG2 0x0028
#define DP_PHY_VCO_DIV 0x0070
#define DP_PHY_TX0_TX1_LANE_CTL 0x0078
#define DP_PHY_TX2_TX3_LANE_CTL 0x009C
#define DP_PHY_SPARE0 0x00C8
#define DP_PHY_STATUS 0x00DC
/* Tx registers */
#define TXn_CLKBUF_ENABLE 0x0008
#define TXn_TX_EMP_POST1_LVL 0x000C
#define TXn_TX_DRV_LVL 0x0014
#define TXn_RESET_TSYNC_EN 0x001C
#define TXn_PRE_STALL_LDO_BOOST_EN 0x0020
#define TXn_TX_BAND 0x0024
#define TXn_INTERFACE_SELECT 0x002C
#define TXn_RES_CODE_LANE_OFFSET_TX 0x003C
#define TXn_RES_CODE_LANE_OFFSET_RX 0x0040
#define TXn_TRANSCEIVER_BIAS_EN 0x0054
#define TXn_HIGHZ_DRVR_EN 0x0058
#define TXn_TX_POL_INV 0x005C
#define TXn_PARRATE_REC_DETECT_IDLE_EN 0x0060
/* PLL register offset */
#define QSERDES_COM_BG_TIMER 0x000C
#define QSERDES_COM_SSC_EN_CENTER 0x0010
#define QSERDES_COM_SSC_ADJ_PER1 0x0014
#define QSERDES_COM_SSC_PER1 0x001C
#define QSERDES_COM_SSC_PER2 0x0020
#define QSERDES_COM_SSC_STEP_SIZE1_MODE0 0x0024
#define QSERDES_COM_SSC_STEP_SIZE2_MODE0 0X0028
#define QSERDES_COM_BIAS_EN_CLKBUFLR_EN 0x0044
#define QSERDES_COM_CLK_ENABLE1 0x0048
#define QSERDES_COM_SYS_CLK_CTRL 0x004C
#define QSERDES_COM_SYSCLK_BUF_ENABLE 0x0050
#define QSERDES_COM_PLL_IVCO 0x0058
#define QSERDES_COM_CP_CTRL_MODE0 0x0074
#define QSERDES_COM_PLL_RCTRL_MODE0 0x007C
#define QSERDES_COM_PLL_CCTRL_MODE0 0x0084
#define QSERDES_COM_SYSCLK_EN_SEL 0x0094
#define QSERDES_COM_RESETSM_CNTRL 0x009C
#define QSERDES_COM_LOCK_CMP_EN 0x00A4
#define QSERDES_COM_LOCK_CMP1_MODE0 0x00AC
#define QSERDES_COM_LOCK_CMP2_MODE0 0x00B0
#define QSERDES_COM_DEC_START_MODE0 0x00BC
#define QSERDES_COM_DIV_FRAC_START1_MODE0 0x00CC
#define QSERDES_COM_DIV_FRAC_START2_MODE0 0x00D0
#define QSERDES_COM_DIV_FRAC_START3_MODE0 0x00D4
#define QSERDES_COM_INTEGLOOP_GAIN0_MODE0 0x00EC
#define QSERDES_COM_INTEGLOOP_GAIN1_MODE0 0x00F0
#define QSERDES_COM_VCO_TUNE_CTRL 0x0108
#define QSERDES_COM_VCO_TUNE_MAP 0x010C
#define QSERDES_COM_CMN_STATUS 0x0140
#define QSERDES_COM_CLK_SEL 0x0154
#define QSERDES_COM_HSCLK_SEL 0x0158
#define QSERDES_COM_CORECLK_DIV_MODE0 0x0168
#define QSERDES_COM_CORE_CLK_EN 0x0174
#define QSERDES_COM_C_READY_STATUS 0x0178
#define QSERDES_COM_CMN_CONFIG 0x017C
#define QSERDES_COM_SVS_MODE_CLK_SEL 0x0184
/* Tx tran offsets */
#define DP_TRAN_DRVR_EMP_EN 0x00C0
#define DP_TX_INTERFACE_MODE 0x00C4
/* Tx VMODE offsets */
#define DP_VMODE_CTRL1 0x00C8
#define DP_PHY_PLL_POLL_SLEEP_US 500
#define DP_PHY_PLL_POLL_TIMEOUT_US 10000
#define DP_VCO_RATE_8100MHZDIV1000 8100000UL
#define DP_VCO_RATE_9720MHZDIV1000 9720000UL
#define DP_VCO_RATE_10800MHZDIV1000 10800000UL
#define DP_5NM_C_READY BIT(0)
#define DP_5NM_FREQ_DONE BIT(0)
#define DP_5NM_PLL_LOCKED BIT(1)
#define DP_5NM_PHY_READY BIT(1)
#define DP_5NM_TSYNC_DONE BIT(0)
static int dp_vco_pll_init_db_5nm(struct dp_pll_db *pdb,
unsigned long rate)
{
struct dp_pll *pll = pdb->pll;
u32 spare_value = 0;
spare_value = dp_pll_read(dp_phy, DP_PHY_SPARE0);
pdb->lane_cnt = spare_value & 0x0F;
pdb->orientation = (spare_value & 0xF0) >> 4;
DP_DEBUG("spare_value=0x%x, ln_cnt=0x%x, orientation=0x%x\n",
spare_value, pdb->lane_cnt, pdb->orientation);
pdb->div_frac_start1_mode0 = 0x00;
pdb->integloop_gain0_mode0 = 0x3f;
pdb->integloop_gain1_mode0 = 0x00;
switch (rate) {
case DP_VCO_HSCLK_RATE_1620MHZDIV1000:
DP_DEBUG("VCO rate: %ld\n", DP_VCO_RATE_9720MHZDIV1000);
pdb->hsclk_sel = 0x05;
pdb->dec_start_mode0 = 0x69;
pdb->div_frac_start2_mode0 = 0x80;
pdb->div_frac_start3_mode0 = 0x07;
pdb->lock_cmp1_mode0 = 0x6f;
pdb->lock_cmp2_mode0 = 0x08;
pdb->phy_vco_div = 0x1;
pdb->lock_cmp_en = 0x04;
pdb->ssc_step_size1_mode0 = 0x45;
pdb->ssc_step_size2_mode0 = 0x06;
break;
case DP_VCO_HSCLK_RATE_2700MHZDIV1000:
DP_DEBUG("VCO rate: %ld\n", DP_VCO_RATE_10800MHZDIV1000);
pdb->hsclk_sel = 0x03;
pdb->dec_start_mode0 = 0x69;
pdb->div_frac_start2_mode0 = 0x80;
pdb->div_frac_start3_mode0 = 0x07;
pdb->lock_cmp1_mode0 = 0x0f;
pdb->lock_cmp2_mode0 = 0x0e;
pdb->phy_vco_div = 0x1;
pdb->lock_cmp_en = 0x08;
pdb->ssc_step_size1_mode0 = 0x45;
pdb->ssc_step_size2_mode0 = 0x06;
break;
case DP_VCO_HSCLK_RATE_5400MHZDIV1000:
DP_DEBUG("VCO rate: %ld\n", DP_VCO_RATE_10800MHZDIV1000);
pdb->hsclk_sel = 0x01;
pdb->dec_start_mode0 = 0x8c;
pdb->div_frac_start2_mode0 = 0x00;
pdb->div_frac_start3_mode0 = 0x0a;
pdb->lock_cmp1_mode0 = 0x1f;
pdb->lock_cmp2_mode0 = 0x1c;
pdb->phy_vco_div = 0x2;
pdb->lock_cmp_en = 0x08;
pdb->ssc_step_size1_mode0 = 0x5c;
pdb->ssc_step_size2_mode0 = 0x08;
break;
case DP_VCO_HSCLK_RATE_8100MHZDIV1000:
DP_DEBUG("VCO rate: %ld\n", DP_VCO_RATE_8100MHZDIV1000);
pdb->hsclk_sel = 0x00;
pdb->dec_start_mode0 = 0x69;
pdb->div_frac_start2_mode0 = 0x80;
pdb->div_frac_start3_mode0 = 0x07;
pdb->lock_cmp1_mode0 = 0x2f;
pdb->lock_cmp2_mode0 = 0x2a;
pdb->phy_vco_div = 0x0;
pdb->lock_cmp_en = 0x08;
pdb->ssc_step_size1_mode0 = 0x45;
pdb->ssc_step_size2_mode0 = 0x06;
break;
default:
DP_ERR("unsupported rate %ld\n", rate);
return -EINVAL;
}
return 0;
}
static int dp_config_vco_rate_5nm(struct dp_pll_vco_clk *vco,
unsigned long rate)
{
int res = 0;
struct dp_pll *pll = vco->priv;
struct dp_pll_db *pdb = (struct dp_pll_db *)pll->priv;
res = dp_vco_pll_init_db_5nm(pdb, rate);
if (res) {
DP_ERR("VCO Init DB failed\n");
return res;
}
dp_pll_write(dp_phy, DP_PHY_CFG_1, 0x0F);
if (pdb->lane_cnt != 4) {
if (pdb->orientation == ORIENTATION_CC2)
dp_pll_write(dp_phy, DP_PHY_PD_CTL, 0x6d);
else
dp_pll_write(dp_phy, DP_PHY_PD_CTL, 0x75);
} else {
dp_pll_write(dp_phy, DP_PHY_PD_CTL, 0x7d);
}
/* Make sure the PHY register writes are done */
wmb();
dp_pll_write(dp_pll, QSERDES_COM_SVS_MODE_CLK_SEL, 0x05);
dp_pll_write(dp_pll, QSERDES_COM_SYSCLK_EN_SEL, 0x3b);
dp_pll_write(dp_pll, QSERDES_COM_SYS_CLK_CTRL, 0x02);
dp_pll_write(dp_pll, QSERDES_COM_CLK_ENABLE1, 0x0c);
dp_pll_write(dp_pll, QSERDES_COM_SYSCLK_BUF_ENABLE, 0x06);
dp_pll_write(dp_pll, QSERDES_COM_CLK_SEL, 0x30);
/* Make sure the PHY register writes are done */
wmb();
/* PLL Optimization */
dp_pll_write(dp_pll, QSERDES_COM_PLL_IVCO, 0x0f);
dp_pll_write(dp_pll, QSERDES_COM_PLL_CCTRL_MODE0, 0x36);
dp_pll_write(dp_pll, QSERDES_COM_PLL_RCTRL_MODE0, 0x16);
dp_pll_write(dp_pll, QSERDES_COM_CP_CTRL_MODE0, 0x06);
/* Make sure the PLL register writes are done */
wmb();
/* link rate dependent params */
dp_pll_write(dp_pll, QSERDES_COM_HSCLK_SEL, pdb->hsclk_sel);
dp_pll_write(dp_pll, QSERDES_COM_DEC_START_MODE0, pdb->dec_start_mode0);
dp_pll_write(dp_pll,
QSERDES_COM_DIV_FRAC_START1_MODE0, pdb->div_frac_start1_mode0);
dp_pll_write(dp_pll,
QSERDES_COM_DIV_FRAC_START2_MODE0, pdb->div_frac_start2_mode0);
dp_pll_write(dp_pll,
QSERDES_COM_DIV_FRAC_START3_MODE0, pdb->div_frac_start3_mode0);
dp_pll_write(dp_pll, QSERDES_COM_LOCK_CMP1_MODE0, pdb->lock_cmp1_mode0);
dp_pll_write(dp_pll, QSERDES_COM_LOCK_CMP2_MODE0, pdb->lock_cmp2_mode0);
dp_pll_write(dp_pll, QSERDES_COM_LOCK_CMP_EN, pdb->lock_cmp_en);
dp_pll_write(dp_phy, DP_PHY_VCO_DIV, pdb->phy_vco_div);
/* Make sure the PLL register writes are done */
wmb();
dp_pll_write(dp_pll, QSERDES_COM_CMN_CONFIG, 0x02);
dp_pll_write(dp_pll, QSERDES_COM_INTEGLOOP_GAIN0_MODE0, 0x3f);
dp_pll_write(dp_pll, QSERDES_COM_INTEGLOOP_GAIN1_MODE0, 0x00);
dp_pll_write(dp_pll, QSERDES_COM_VCO_TUNE_MAP, 0x00);
/* Make sure the PHY register writes are done */
wmb();
dp_pll_write(dp_pll, QSERDES_COM_BG_TIMER, 0x0a);
dp_pll_write(dp_pll, QSERDES_COM_CORECLK_DIV_MODE0, 0x0a);
dp_pll_write(dp_pll, QSERDES_COM_VCO_TUNE_CTRL, 0x00);
if (pll->bonding_en)
dp_pll_write(dp_pll, QSERDES_COM_BIAS_EN_CLKBUFLR_EN, 0x1f);
else
dp_pll_write(dp_pll, QSERDES_COM_BIAS_EN_CLKBUFLR_EN, 0x17);
dp_pll_write(dp_pll, QSERDES_COM_CORE_CLK_EN, 0x1f);
/* Make sure the PHY register writes are done */
wmb();
if (pll->ssc_en) {
dp_pll_write(dp_pll, QSERDES_COM_SSC_EN_CENTER, 0x01);
dp_pll_write(dp_pll, QSERDES_COM_SSC_ADJ_PER1, 0x00);
dp_pll_write(dp_pll, QSERDES_COM_SSC_PER1, 0x36);
dp_pll_write(dp_pll, QSERDES_COM_SSC_PER2, 0x01);
dp_pll_write(dp_pll, QSERDES_COM_SSC_STEP_SIZE1_MODE0,
pdb->ssc_step_size1_mode0);
dp_pll_write(dp_pll, QSERDES_COM_SSC_STEP_SIZE2_MODE0,
pdb->ssc_step_size2_mode0);
}
if (pdb->orientation == ORIENTATION_CC2)
dp_pll_write(dp_phy, DP_PHY_MODE, 0x4c);
else
dp_pll_write(dp_phy, DP_PHY_MODE, 0x5c);
dp_pll_write(dp_phy, DP_PHY_AUX_CFG1, 0x13);
dp_pll_write(dp_phy, DP_PHY_AUX_CFG2, 0xA4);
/* Make sure the PLL register writes are done */
wmb();
/* TX-0 register configuration */
dp_pll_write(dp_phy, DP_PHY_TX0_TX1_LANE_CTL, 0x05);
dp_pll_write(dp_ln_tx0, DP_VMODE_CTRL1, 0x40);
dp_pll_write(dp_ln_tx0, TXn_PRE_STALL_LDO_BOOST_EN, 0x30);
dp_pll_write(dp_ln_tx0, TXn_INTERFACE_SELECT, 0x3b);
dp_pll_write(dp_ln_tx0, TXn_CLKBUF_ENABLE, 0x0f);
dp_pll_write(dp_ln_tx0, TXn_RESET_TSYNC_EN, 0x03);
dp_pll_write(dp_ln_tx0, DP_TRAN_DRVR_EMP_EN, 0xf);
dp_pll_write(dp_ln_tx0, TXn_PARRATE_REC_DETECT_IDLE_EN, 0x00);
dp_pll_write(dp_ln_tx0, DP_TX_INTERFACE_MODE, 0x00);
dp_pll_write(dp_ln_tx0, TXn_RES_CODE_LANE_OFFSET_TX, 0x11);
dp_pll_write(dp_ln_tx0, TXn_RES_CODE_LANE_OFFSET_RX, 0x11);
dp_pll_write(dp_ln_tx0, TXn_TX_BAND, 0x04);
/* Make sure the PLL register writes are done */
wmb();
/* TX-1 register configuration */
dp_pll_write(dp_phy, DP_PHY_TX2_TX3_LANE_CTL, 0x05);
dp_pll_write(dp_ln_tx1, DP_VMODE_CTRL1, 0x40);
dp_pll_write(dp_ln_tx1, TXn_PRE_STALL_LDO_BOOST_EN, 0x30);
dp_pll_write(dp_ln_tx1, TXn_INTERFACE_SELECT, 0x3b);
dp_pll_write(dp_ln_tx1, TXn_CLKBUF_ENABLE, 0x0f);
dp_pll_write(dp_ln_tx1, TXn_RESET_TSYNC_EN, 0x03);
dp_pll_write(dp_ln_tx1, DP_TRAN_DRVR_EMP_EN, 0xf);
dp_pll_write(dp_ln_tx1, TXn_PARRATE_REC_DETECT_IDLE_EN, 0x00);
dp_pll_write(dp_ln_tx1, DP_TX_INTERFACE_MODE, 0x00);
dp_pll_write(dp_ln_tx1, TXn_RES_CODE_LANE_OFFSET_TX, 0x11);
dp_pll_write(dp_ln_tx1, TXn_RES_CODE_LANE_OFFSET_RX, 0x11);
dp_pll_write(dp_ln_tx1, TXn_TX_BAND, 0x04);
/* Make sure the PHY register writes are done */
wmb();
return res;
}
enum dp_5nm_pll_status {
C_READY,
FREQ_DONE,
PLL_LOCKED,
PHY_READY,
TSYNC_DONE,
};
char *dp_5nm_pll_get_status_name(enum dp_5nm_pll_status status)
{
switch (status) {
case C_READY:
return "C_READY";
case FREQ_DONE:
return "FREQ_DONE";
case PLL_LOCKED:
return "PLL_LOCKED";
case PHY_READY:
return "PHY_READY";
case TSYNC_DONE:
return "TSYNC_DONE";
default:
return "unknown";
}
}
static bool dp_5nm_pll_get_status(struct dp_pll *pll,
enum dp_5nm_pll_status status)
{
u32 reg, state, bit;
void __iomem *base;
bool success = true;
switch (status) {
case C_READY:
base = dp_pll_get_base(dp_pll);
reg = QSERDES_COM_C_READY_STATUS;
bit = DP_5NM_C_READY;
break;
case FREQ_DONE:
base = dp_pll_get_base(dp_pll);
reg = QSERDES_COM_CMN_STATUS;
bit = DP_5NM_FREQ_DONE;
break;
case PLL_LOCKED:
base = dp_pll_get_base(dp_pll);
reg = QSERDES_COM_CMN_STATUS;
bit = DP_5NM_PLL_LOCKED;
break;
case PHY_READY:
base = dp_pll_get_base(dp_phy);
reg = DP_PHY_STATUS;
bit = DP_5NM_PHY_READY;
break;
case TSYNC_DONE:
base = dp_pll_get_base(dp_phy);
reg = DP_PHY_STATUS;
bit = DP_5NM_TSYNC_DONE;
break;
default:
return false;
}
if (readl_poll_timeout_atomic((base + reg), state,
((state & bit) > 0),
DP_PHY_PLL_POLL_SLEEP_US,
DP_PHY_PLL_POLL_TIMEOUT_US)) {
DP_ERR("%s failed, status=%x\n",
dp_5nm_pll_get_status_name(status), state);
success = false;
}
return success;
}
static int dp_pll_enable_5nm(struct clk_hw *hw)
{
int rc = 0;
struct dp_pll_vco_clk *vco = to_dp_vco_hw(hw);
struct dp_pll *pll = vco->priv;
pll->aux->state &= ~DP_STATE_PLL_LOCKED;
dp_pll_write(dp_phy, DP_PHY_CFG, 0x01);
dp_pll_write(dp_phy, DP_PHY_CFG, 0x05);
dp_pll_write(dp_phy, DP_PHY_CFG, 0x01);
dp_pll_write(dp_phy, DP_PHY_CFG, 0x09);
dp_pll_write(dp_pll, QSERDES_COM_RESETSM_CNTRL, 0x20);
wmb(); /* Make sure the PLL register writes are done */
if (!dp_5nm_pll_get_status(pll, C_READY)) {
rc = -EINVAL;
goto lock_err;
}
if (!dp_5nm_pll_get_status(pll, FREQ_DONE)) {
rc = -EINVAL;
goto lock_err;
}
if (!dp_5nm_pll_get_status(pll, PLL_LOCKED)) {
rc = -EINVAL;
goto lock_err;
}
dp_pll_write(dp_phy, DP_PHY_CFG, 0x19);
/* Make sure the PHY register writes are done */
wmb();
if (!dp_5nm_pll_get_status(pll, TSYNC_DONE)) {
rc = -EINVAL;
goto lock_err;
}
if (!dp_5nm_pll_get_status(pll, PHY_READY)) {
rc = -EINVAL;
goto lock_err;
}
pll->aux->state |= DP_STATE_PLL_LOCKED;
DP_DEBUG("PLL is locked\n");
lock_err:
return rc;
}
static int dp_pll_disable_5nm(struct clk_hw *hw)
{
struct dp_pll_vco_clk *vco = to_dp_vco_hw(hw);
struct dp_pll *pll = vco->priv;
/* Assert DP PHY power down */
dp_pll_write(dp_phy, DP_PHY_PD_CTL, 0x2);
/*
* Make sure all the register writes to disable PLL are
* completed before doing any other operation
*/
wmb();
return 0;
}
static struct clk_ops mux_clk_ops;
static struct regmap_config dp_pll_5nm_cfg = {
.reg_bits = 32,
.reg_stride = 4,
.val_bits = 32,
.max_register = 0x910,
};
int dp_mux_set_parent_5nm(void *context, unsigned int reg, unsigned int val)
{
struct dp_pll *pll = context;
u32 auxclk_div;
if (!context) {
DP_ERR("invalid input parameters\n");
return -EINVAL;
}
auxclk_div = dp_pll_read(dp_phy, DP_PHY_VCO_DIV);
auxclk_div &= ~0x03;
if (val == 0)
auxclk_div |= 1;
else if (val == 1)
auxclk_div |= 2;
else if (val == 2)
auxclk_div |= 0;
dp_pll_write(dp_phy, DP_PHY_VCO_DIV, auxclk_div);
/* Make sure the PHY registers writes are done */
wmb();
DP_DEBUG("mux=%d auxclk_div=%x\n", val, auxclk_div);
return 0;
}
int dp_mux_get_parent_5nm(void *context, unsigned int reg, unsigned int *val)
{
u32 auxclk_div = 0;
struct dp_pll *pll = context;
if (!context || !val) {
DP_ERR("invalid input parameters\n");
return -EINVAL;
}
if (is_gdsc_disabled(pll))
return 0;
auxclk_div = dp_pll_read(dp_phy, DP_PHY_VCO_DIV);
auxclk_div &= 0x03;
if (auxclk_div == 1) /* Default divider */
*val = 0;
else if (auxclk_div == 2)
*val = 1;
else if (auxclk_div == 0)
*val = 2;
DP_DEBUG("auxclk_div=%d, val=%d\n", auxclk_div, *val);
return 0;
}
static struct regmap_bus dp_pixel_mux_regmap_ops = {
.reg_write = dp_mux_set_parent_5nm,
.reg_read = dp_mux_get_parent_5nm,
};
static int dp_vco_set_rate_5nm(struct clk_hw *hw, unsigned long rate,
unsigned long parent_rate)
{
struct dp_pll_vco_clk *vco;
int rc;
struct dp_pll *pll;
if (!hw) {
DP_ERR("invalid input parameters\n");
return -EINVAL;
}
vco = to_dp_vco_hw(hw);
pll = vco->priv;
DP_DEBUG("DP lane CLK rate=%ld\n", rate);
rc = dp_config_vco_rate_5nm(vco, rate);
if (rc)
DP_ERR("Failed to set clk rate\n");
vco->rate = rate;
return 0;
}
static int dp_regulator_enable_5nm(struct dp_parser *parser,
enum dp_pm_type pm_type, bool enable)
{
int rc = 0;
struct dss_module_power mp;
if (pm_type < DP_CORE_PM || pm_type >= DP_MAX_PM) {
DP_ERR("invalid resource: %d %s\n", pm_type,
dp_parser_pm_name(pm_type));
return -EINVAL;
}
mp = parser->mp[pm_type];
rc = msm_dss_enable_vreg(mp.vreg_config, mp.num_vreg, enable);
if (rc) {
DP_ERR("failed to '%s' vregs for %s\n",
enable ? "enable" : "disable",
dp_parser_pm_name(pm_type));
return rc;
}
DP_DEBUG("success: '%s' vregs for %s\n", enable ? "enable" : "disable",
dp_parser_pm_name(pm_type));
return rc;
}
static int dp_vco_prepare_5nm(struct clk_hw *hw)
{
int rc = 0;
struct dp_pll_vco_clk *vco;
struct dp_pll *pll;
if (!hw) {
DP_ERR("invalid input parameters\n");
return -EINVAL;
}
vco = to_dp_vco_hw(hw);
pll = vco->priv;
DP_DEBUG("rate=%ld\n", vco->rate);
/*
* Enable DP_PM_PLL regulator if the PLL revision is 5nm-V1 and the
* link rate is 8.1Gbps. This will result in voting to place Mx rail in
* turbo as required for V1 hardware PLL functionality.
*/
if (pll->revision == DP_PLL_5NM_V1 &&
vco->rate == DP_VCO_HSCLK_RATE_8100MHZDIV1000)
dp_regulator_enable_5nm(pll->parser, DP_PLL_PM, true);
if ((pll->vco_cached_rate != 0)
&& (pll->vco_cached_rate == vco->rate)) {
rc = dp_vco_set_rate_5nm(hw, pll->vco_cached_rate,
pll->vco_cached_rate);
if (rc) {
DP_ERR("index=%d vco_set_rate failed. rc=%d\n",
rc, pll->index);
goto error;
}
}
rc = dp_pll_enable_5nm(hw);
if (rc) {
DP_ERR("ndx=%d failed to enable dp pll\n", pll->index);
goto error;
}
error:
return rc;
}
static void dp_vco_unprepare_5nm(struct clk_hw *hw)
{
struct dp_pll_vco_clk *vco;
struct dp_pll *pll;
if (!hw) {
DP_ERR("invalid input parameters\n");
return;
}
vco = to_dp_vco_hw(hw);
pll = vco->priv;
if (!pll) {
DP_ERR("invalid input parameter\n");
return;
}
if (pll->revision == DP_PLL_5NM_V1 &&
vco->rate == DP_VCO_HSCLK_RATE_8100MHZDIV1000)
dp_regulator_enable_5nm(pll->parser, DP_PLL_PM, false);
pll->vco_cached_rate = vco->rate;
dp_pll_disable_5nm(hw);
}
static unsigned long dp_vco_recalc_rate_5nm(struct clk_hw *hw,
unsigned long parent_rate)
{
struct dp_pll_vco_clk *vco;
u32 hsclk_sel, link_clk_divsel, hsclk_div, link_clk_div = 0;
unsigned long vco_rate;
struct dp_pll *pll;
if (!hw) {
DP_ERR("invalid input parameters\n");
return 0;
}
vco = to_dp_vco_hw(hw);
pll = vco->priv;
if (is_gdsc_disabled(pll))
return 0;
DP_DEBUG("input rates: parent=%lu, vco=%lu\n", parent_rate, vco->rate);
hsclk_sel = dp_pll_read(dp_pll, QSERDES_COM_HSCLK_SEL);
hsclk_sel &= 0x0f;
if (hsclk_sel == 5)
hsclk_div = 5;
else if (hsclk_sel == 3)
hsclk_div = 3;
else if (hsclk_sel == 1)
hsclk_div = 2;
else if (hsclk_sel == 0)
hsclk_div = 1;
else {
DP_DEBUG("unknown divider. forcing to default\n");
hsclk_div = 5;
}
link_clk_divsel = dp_pll_read(dp_phy, DP_PHY_AUX_CFG2);
link_clk_divsel >>= 2;
link_clk_divsel &= 0x3;
if (link_clk_divsel == 0)
link_clk_div = 5;
else if (link_clk_divsel == 1)
link_clk_div = 10;
else if (link_clk_divsel == 2)
link_clk_div = 20;
else
DP_ERR("unsupported div. Phy_mode: %d\n", link_clk_divsel);
if (link_clk_div == 20) {
vco_rate = DP_VCO_HSCLK_RATE_2700MHZDIV1000;
} else {
if (hsclk_div == 5)
vco_rate = DP_VCO_HSCLK_RATE_1620MHZDIV1000;
else if (hsclk_div == 3)
vco_rate = DP_VCO_HSCLK_RATE_2700MHZDIV1000;
else if (hsclk_div == 2)
vco_rate = DP_VCO_HSCLK_RATE_5400MHZDIV1000;
else
vco_rate = DP_VCO_HSCLK_RATE_8100MHZDIV1000;
}
DP_DEBUG("hsclk: sel=0x%x, div=0x%x; lclk: sel=%u, div=%u, rate=%lu\n",
hsclk_sel, hsclk_div, link_clk_divsel, link_clk_div, vco_rate);
pll->vco_cached_rate = vco->rate = vco_rate;
return vco_rate;
}
static long dp_vco_round_rate_5nm(struct clk_hw *hw, unsigned long rate,
unsigned long *parent_rate)
{
unsigned long rrate = rate;
struct dp_pll_vco_clk *vco;
if (!hw) {
DP_ERR("invalid input parameters\n");
return 0;
}
vco = to_dp_vco_hw(hw);
if (rate <= vco->min_rate)
rrate = vco->min_rate;
else if (rate <= DP_VCO_HSCLK_RATE_2700MHZDIV1000)
rrate = DP_VCO_HSCLK_RATE_2700MHZDIV1000;
else if (rate <= DP_VCO_HSCLK_RATE_5400MHZDIV1000)
rrate = DP_VCO_HSCLK_RATE_5400MHZDIV1000;
else
rrate = vco->max_rate;
DP_DEBUG("rrate=%ld\n", rrate);
if (parent_rate)
*parent_rate = rrate;
return rrate;
}
/* Op structures */
static const struct clk_ops dp_5nm_vco_clk_ops = {
.recalc_rate = dp_vco_recalc_rate_5nm,
.set_rate = dp_vco_set_rate_5nm,
.round_rate = dp_vco_round_rate_5nm,
.prepare = dp_vco_prepare_5nm,
.unprepare = dp_vco_unprepare_5nm,
};
static struct dp_pll_vco_clk dp_vco_clk = {
.min_rate = DP_VCO_HSCLK_RATE_1620MHZDIV1000,
.max_rate = DP_VCO_HSCLK_RATE_8100MHZDIV1000,
.hw.init = &(struct clk_init_data){
.name = "dp_vco_clk",
.parent_names = (const char *[]){ "bi_tcxo" },
.num_parents = 1,
.ops = &dp_5nm_vco_clk_ops,
},
};
static struct clk_fixed_factor dp_phy_pll_link_clk = {
.div = 10,
.mult = 1,
.hw.init = &(struct clk_init_data){
.name = "dp_phy_pll_link_clk",
.parent_names =
(const char *[]){ "dp_vco_clk" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT,
.ops = &clk_fixed_factor_ops,
},
};
static struct clk_fixed_factor dp_vco_divsel_two_clk_src = {
.div = 2,
.mult = 1,
.hw.init = &(struct clk_init_data){
.name = "dp_vco_divsel_two_clk_src",
.parent_names =
(const char *[]){ "dp_vco_clk" },
.num_parents = 1,
.ops = &clk_fixed_factor_ops,
},
};
static struct clk_fixed_factor dp_vco_divsel_four_clk_src = {
.div = 4,
.mult = 1,
.hw.init = &(struct clk_init_data){
.name = "dp_vco_divsel_four_clk_src",
.parent_names =
(const char *[]){ "dp_vco_clk" },
.num_parents = 1,
.ops = &clk_fixed_factor_ops,
},
};
static struct clk_fixed_factor dp_vco_divsel_six_clk_src = {
.div = 6,
.mult = 1,
.hw.init = &(struct clk_init_data){
.name = "dp_vco_divsel_six_clk_src",
.parent_names =
(const char *[]){ "dp_vco_clk" },
.num_parents = 1,
.ops = &clk_fixed_factor_ops,
},
};
static struct clk_regmap_mux dp_phy_pll_vco_div_clk = {
.reg = 0x64,
.shift = 0,
.width = 2,
.clkr = {
.hw.init = &(struct clk_init_data){
.name = "dp_phy_pll_vco_div_clk",
.parent_names =
(const char *[]){"dp_vco_divsel_two_clk_src",
"dp_vco_divsel_four_clk_src",
"dp_vco_divsel_six_clk_src"},
.num_parents = 3,
.ops = &mux_clk_ops,
.flags = CLK_SET_RATE_PARENT,
},
},
};
static int clk_mux_determine_rate(struct clk_hw *hw,
struct clk_rate_request *req)
{
int ret = 0;
if (!hw || !req) {
DP_ERR("Invalid input parameters\n");
return -EINVAL;
}
ret = __clk_mux_determine_rate_closest(hw, req);
if (ret)
return ret;
/* Set the new parent of mux if there is a new valid parent */
if (hw->clk && req->best_parent_hw->clk)
clk_set_parent(hw->clk, req->best_parent_hw->clk);
return 0;
}
static unsigned long mux_recalc_rate(struct clk_hw *hw,
unsigned long parent_rate)
{
struct clk *div_clk = NULL, *vco_clk = NULL;
struct dp_pll_vco_clk *vco = NULL;
if (!hw) {
DP_ERR("Invalid input parameter\n");
return 0;
}
div_clk = clk_get_parent(hw->clk);
if (!div_clk)
return 0;
vco_clk = clk_get_parent(div_clk);
if (!vco_clk)
return 0;
vco = to_dp_vco_hw(__clk_get_hw(vco_clk));
if (!vco)
return 0;
if (vco->rate == DP_VCO_HSCLK_RATE_8100MHZDIV1000)
return (vco->rate / 6);
else if (vco->rate == DP_VCO_HSCLK_RATE_5400MHZDIV1000)
return (vco->rate / 4);
else
return (vco->rate / 2);
}
static struct clk_hw *mdss_dp_pllcc_5nm[] = {
[DP_VCO_CLK] = &dp_vco_clk.hw,
[DP_LINK_CLK_DIVSEL_TEN] = &dp_phy_pll_link_clk.hw,
[DP_VCO_DIVIDED_TWO_CLK_SRC] = &dp_vco_divsel_two_clk_src.hw,
[DP_VCO_DIVIDED_FOUR_CLK_SRC] = &dp_vco_divsel_four_clk_src.hw,
[DP_VCO_DIVIDED_SIX_CLK_SRC] = &dp_vco_divsel_six_clk_src.hw,
[DP_PHY_PLL_VCO_DIV_CLK] = &dp_phy_pll_vco_div_clk.clkr.hw,
};
static struct dp_pll_db dp_pdb;
int dp_pll_clock_register_5nm(struct dp_pll *pll)
{
int rc = -ENOTSUPP, i = 0;
struct platform_device *pdev;
struct clk *clk;
struct regmap *regmap;
int num_clks = ARRAY_SIZE(mdss_dp_pllcc_5nm);
if (!pll) {
DP_ERR("pll data not initialized\n");
return -EINVAL;
}
pdev = pll->pdev;
pll->clk_data = kzalloc(sizeof(*pll->clk_data), GFP_KERNEL);
if (!pll->clk_data)
return -ENOMEM;
pll->clk_data->clks = kcalloc(num_clks, sizeof(struct clk *),
GFP_KERNEL);
if (!pll->clk_data->clks) {
kfree(pll->clk_data);
return -ENOMEM;
}
pll->clk_data->clk_num = num_clks;
pll->priv = &dp_pdb;
dp_pdb.pll = pll;
/* Set client data for vco, mux and div clocks */
regmap = regmap_init(&pdev->dev, &dp_pixel_mux_regmap_ops,
pll, &dp_pll_5nm_cfg);
mux_clk_ops = clk_regmap_mux_closest_ops;
mux_clk_ops.determine_rate = clk_mux_determine_rate;
mux_clk_ops.recalc_rate = mux_recalc_rate;
dp_vco_clk.priv = pll;
dp_phy_pll_vco_div_clk.clkr.regmap = regmap;
for (i = DP_VCO_CLK; i <= DP_PHY_PLL_VCO_DIV_CLK; i++) {
DP_DEBUG("reg clk: %d index: %d\n", i, pll->index);
clk = clk_register(&pdev->dev, mdss_dp_pllcc_5nm[i]);
if (IS_ERR(clk)) {
DP_ERR("clk registration failed for DP: %d\n",
pll->index);
rc = -EINVAL;
goto clk_reg_fail;
}
pll->clk_data->clks[i] = clk;
}
rc = of_clk_add_provider(pdev->dev.of_node,
of_clk_src_onecell_get, pll->clk_data);
if (rc) {
DP_ERR("Clock register failed rc=%d\n", rc);
rc = -EPROBE_DEFER;
goto clk_reg_fail;
} else {
DP_DEBUG("success\n");
}
return rc;
clk_reg_fail:
dp_pll_clock_unregister_5nm(pll);
return rc;
}
void dp_pll_clock_unregister_5nm(struct dp_pll *pll)
{
kfree(pll->clk_data->clks);
kfree(pll->clk_data);
}
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