// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2022-2023, Qualcomm Innovation Center, Inc. All rights reserved. */ #define pr_fmt(fmt) "%s " fmt, KBUILD_MODNAME #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define CREATE_TRACE_POINTS #include "trace-crm.h" #define CRM_DRV_IPC_LOG_SIZE 2 #define MAX_NAME_LENGTH 20 #define PERF_OL_VCD 0 #define BW_VOTE_VCD 1 #define MAX_VCD_TYPE 2 #define VPAGE_SHIFT_BITS 0xFFF /* Common CRM Registers */ #define CRM_VERSION 0 /* Offsets for CRM_VERSION Register */ #define MAJOR_VER_MASK 0xFF #define MAJOR_VER_SHIFT 16 #define MINOR_VER_MASK 0xFF #define MINOR_VER_SHIFT 8 #define CRM_CFG_PARAM_1 0x4 /* Offsets for CRM_CFG_PARAM_1 Register */ #define NUM_SW_DRVS_MASK 0xF #define NUM_SW_DRVS_SHIFT 20 #define NUM_HW_DRVS_MASK 0xF #define NUM_HW_DRVS_SHIFT 16 #define NUM_VCD_VOTED_BY_BW_MASK 0xF #define NUM_VCD_VOTED_BY_BW_SHIFT 24 #define NUM_OF_RAILS_MASK 0xF #define NUM_OF_RAILS_SHIFT 12 #define NUM_VCD_VOTED_BY_PERF_OL_MASK 0xF #define NUM_VCD_VOTED_BY_PERF_OL_SHIFT 8 #define NUM_CH_MASK 0xF #define NUM_CH_SHIFT 4 #define NUM_PWR_STATES_PER_CH_MASK 0xF #define NUM_PWR_STATES_PER_CH_SHIFT 0 #define CRM_CFG_PARAM_2 0x8 /* Offsets for CRM_CFG_PARAM_2 Register */ #define NUM_OF_NODES_MASK 0x1F #define NUM_OF_NODES_SHIFT 26 #define CRM_ENABLE 0xC /* Applicable for HW & SW DRVs BW Registers */ #define PERF_OL_VALUE_BITS 0x7 /* Applicable for HW & SW DRVs BW Registers */ #define BW_VOTE_VALID BIT(29) /* Applicable only for SW DRVs BW Registers */ #define BW_VOTE_COMMIT BIT(30) /* Applicable only for SW DRVs BW Registers */ #define BW_VOTE_RESP_REQ BIT(31) /* Set 1 to Enable IRQ for each VCD */ #define IRQ_ENABLE_BIT BIT(0) #define IRQ_CLEAR_BIT BIT(0) /* Set 1 to Enable CHN_BEHAVE for each HW DRV */ #define CHN_BEHAVE_BIT BIT(0) /* SW DRV has ACTIVE, SLEEP and WAKE PWR STATES */ #define MAX_SW_DRV_PWR_STATES 3 /* Time out for ACTIVE Only PWR STATE completion IRQ */ #define CRM_TIMEOUT_MS 5000 #define CH0 0 #define CH0_CHN_BUSY BIT(0) #define CH1 1 #define CH1_CHN_BUSY BIT(1) #define crm_print_reg(addr, val)\ pr_err("addr:0x%x, val:0x%x\n", addr, val) #define crm_print_hw_reg(drv_num, channel, res_type, res_num, pwr_st, addr, val)\ pr_err("drv:%d, chn:%d, %s:%d, pwr_st:%d, addr:0x%x, val:0x%x\n",\ drv_num, channel, res_type == PERF_OL_VCD ?\ "vcd" : "node", res_num, pwr_st, addr, val) enum { /* CRM DRV Register */ DRV_BASE, DRV_DISTANCE, /* VCD or ND Distance */ DRV_RESOURCE_DISTANCE, /* DRV's PWR_ST Registers */ PWR_ST0, PWR_ST1, PWR_ST2, PWR_ST3, PWR_ST4, /* Offset for power state distances in a channel */ PWR_ST_CHN_DISTANCE, /* VCD's IRQ Registers, one per VCD at VCD_DISTANCE */ IRQ_STATUS, IRQ_CLEAR, IRQ_ENABLE, /* DRV's Channel Registers, one per DRV at CH_DRV_DISTANCE */ CHN_BUSY, CHN_UPDATE, CHN_BEHAVE, CHN_DRV_DISTANCE, /* SW DRV's PWR_ST mapped to PWR_ST0/1/2 for ACTIVE/SLEEP/WAKE */ ACTIVE_VOTE = PWR_ST0, SLEEP_VOTE = PWR_ST1, WAKE_VOTE = PWR_ST2, /* Status Registers */ PERF_OL_STATUS = IRQ_STATUS, PWR_IDX_STATUS = IRQ_CLEAR, }; enum channel_type { CHN_IN_USE, CHN_FREE, }; enum { /* CRM Register */ CRM_BASE, CRM_DISTANCE, /* CRMV Registers */ AGGR_VOL_STS, SEQ_VOL_STS, CURR_VOL_STS, RAIL_FSM_STS, RAIL_TCS_STS, /* CRMB Registers */ STATUS_BE, STATUS_FE, /* CRMC Registers */ AGGR_PERF_OL, CURR_PERF_OL, SEQ_STATUS, }; static u32 chn_regs[] = { [CHN_BUSY] = 0x1000, [CHN_UPDATE] = 0x1020, [CHN_BEHAVE] = 0x1040, [CHN_DRV_DISTANCE] = 0x4, }; static u32 crmv_regs[] = { [CRM_BASE] = 0x0, [CRM_DISTANCE] = 0x80, [AGGR_VOL_STS] = 0x0, [SEQ_VOL_STS] = 0x4, [CURR_VOL_STS] = 0x8, [RAIL_FSM_STS] = 0x14, [RAIL_TCS_STS] = 0x38, }; static u32 crmb_regs[] = { [CRM_BASE] = 0x0, [CRM_DISTANCE] = 0x400, [STATUS_BE] = 0x120, [STATUS_FE] = 0x124, }; static u32 crmc_regs[] = { [CRM_BASE] = 0x0, [CRM_DISTANCE] = 0x200, [AGGR_PERF_OL] = 0x4, [CURR_PERF_OL] = 0xc, [SEQ_STATUS] = 0x1a0, }; static u32 hw_drv_perf_ol_vcd_regs[] = { [DRV_BASE] = 0x200, [DRV_DISTANCE] = 0x200, [DRV_RESOURCE_DISTANCE] = 0x4, [PWR_ST0] = 0x0, [PWR_ST1] = 0x40, [PWR_ST2] = 0x80, [PWR_ST3] = 0x600, [PWR_ST4] = 0x640, [PWR_ST_CHN_DISTANCE] = 0x4, [PERF_OL_STATUS] = 0x1C0, }; static u32 hw_drv_bw_vote_vcd_regs[] = { [DRV_BASE] = 0x200, [DRV_DISTANCE] = 0x200, [DRV_RESOURCE_DISTANCE] = 0x4, [PWR_ST0] = 0xC0, [PWR_ST1] = 0x140, [PWR_ST2] = 0x680, [PWR_ST3] = 0x700, [PWR_ST4] = 0x780, [PWR_ST_CHN_DISTANCE] = 0x4, [PWR_IDX_STATUS] = 0x1F0, }; static u32 sw_drv_perf_ol_vcd_regs[] = { [DRV_BASE] = 0x1060, [DRV_DISTANCE] = 0x1000, [DRV_RESOURCE_DISTANCE] = 0x4, [PWR_ST0] = 0x0, [PWR_ST1] = 0x40, [PWR_ST2] = 0x80, [PWR_ST_CHN_DISTANCE] = 0x0, [IRQ_STATUS] = 0x100, [IRQ_CLEAR] = 0x140, [IRQ_ENABLE] = 0x180, }; static u32 sw_drv_bw_vote_vcd_regs[] = { [DRV_BASE] = 0x1060, [DRV_DISTANCE] = 0x1000, [DRV_RESOURCE_DISTANCE] = 0x4, [PWR_ST0] = 0x3A0, [PWR_ST1] = 0x3E0, [PWR_ST2] = 0x420, [PWR_ST_CHN_DISTANCE] = 0x0, [IRQ_STATUS] = 0x4A0, [IRQ_CLEAR] = 0x4E0, [IRQ_ENABLE] = 0x520, }; struct crm_desc { bool set_chn_behave; }; /** * struct crm_sw_votes: SW DRV's ACTIVE_VOTEs in progress. * One per VCD. * * @cmd: The ACTIVE_VOTE being sent to CRM. * @compl: Wait for completion if the cmd->wait is set. * Applicable only for ACTIVE_VOTEs. * @in_progress: Indicates if the cmd is in flight. * @wait: Wait queue used to wait for @in_progress to be false. * This is needed because HW do not keep a record of new * requests issued until current one is completed. */ struct crm_sw_votes { struct crm_cmd cmd; struct completion compl; bool in_progress; wait_queue_head_t wait; }; /** * struct crm_vcd: The Virtual Clock Domain's (VCDs) of the CRM. * One per VCD type. * * @cache: Cache of vcd's power_state to data * @num_pwr_states: Number of pwr state that DRV VCD can vote for. * @num_resources: Number of VCD resources (for PERF_OL votes) OR * Number of Node resoureces (for BW votes) * @cache_dirty: Flag to indicate if all the votes are applied. * @offsets: Register offsets for DRV controller. * @sw_votes: Cache of SW DRV's ACTIVE_VOTEs. */ struct crm_vcd { u32 **cache; u32 num_pwr_states; u32 num_resources; u32 *offsets; bool cache_dirty; struct crm_sw_votes *sw_votes; }; /** * struct crm_drv: The Direct Resource Voter (DRV) of the * CESTA Resource manager (CRM). * * @name: Controller identifier. * @base: Base address of the CRM device. * @drv_id: DRV (Direct Resource Voter) number. * @num_channels: Number of Channels, Applicable only for HW DRV * @vcd: VCDs in this DRV. * @irq: IRQ at gic. * @initialized: Whether DRV is initialized * @lock: Synchronize state of the controller. If CRM's cache's * lock will also be held, the order is: drv->cache_lock * then drv->lock. * @cache_lock: Synchronize VCD cache updates * @client: Handle to the DRV's client. * @ipc_log_ctx: IPC logger handle */ struct crm_drv { enum crm_drv_type drv_type; char name[MAX_NAME_LENGTH]; void __iomem *base; u32 drv_id; u32 num_channels; u32 *offsets; struct crm_vcd vcd[MAX_VCD_TYPE]; spinlock_t lock; spinlock_t cache_lock; int irq; bool initialized; void *ipc_log_ctx; }; /** * struct crm_mgr: The CRM HW block used for aggregating votes * from SW and HW DRVs. * * @name: CRM HW block name. * @base: Base address of the CRM block. * @num_resources: Number of PERF_OL or BW_VOTE resources. * @offsets: Register offsets for CRM manager. */ struct crm_mgr { char name[MAX_NAME_LENGTH]; void __iomem *base; u32 num_resources; u32 *offsets; }; /** * struct crm_drv_top: Our representation of the top CRM device. * * @name: CRM device name. * @base: Base address of the CRM device. * @hw_drvs: Controller for each HW DRV * @num_hw_drvs: Number of HW DRV controllers in the CRM device * @num_channels: Number of Channels, Applicable only for HW DRV * @sw_drvs: Controller for each SW DRV * @num_sw_drvs: Number of SW DRV controllers in the CRM device * @crmv_mgr: Controller for CRMV device. * @crmb_mgr: Controller for CRMB device. * @crmc_mgr: Controller for CRMC device. * @list: CRM device added in crm_dev_list. * @desc: CRM description * @dev: CRM dev * @pdev: CRM platform device */ struct crm_drv_top { char name[MAX_NAME_LENGTH]; void __iomem *base; struct crm_drv *hw_drvs; int num_hw_drvs; u32 num_channels; struct crm_drv *sw_drvs; int num_sw_drvs; struct crm_mgr crmv_mgr; struct crm_mgr crmb_mgr; struct crm_mgr crmc_mgr; struct list_head list; const struct crm_desc *desc; struct device *dev; struct platform_device *pdev; }; static LIST_HEAD(crm_dev_list); static inline u32 get_crm_phy_addr(void __iomem *base) { return page_to_phys(vmalloc_to_page(base)); } static inline u32 crm_get_channel_offset(const struct crm_drv *drv, u32 reg) { return drv->offsets[reg] + drv->drv_id * drv->offsets[CHN_DRV_DISTANCE]; } static void write_crm_channel(const struct crm_drv *drv, u32 reg, u32 data) { u32 offset = crm_get_channel_offset(drv, reg); writel_relaxed(data, drv->base + offset); } static u32 read_crm_channel(const struct crm_drv *drv, u32 reg) { u32 offset = crm_get_channel_offset(drv, reg); return readl_relaxed(drv->base + offset); } static inline u32 crm_get_offset(const struct crm_drv *drv, u32 reg, u32 ch, u32 vcd_type, u32 resource_idx) { const struct crm_vcd *vcd = &drv->vcd[vcd_type]; u32 offset; offset = vcd->offsets[DRV_BASE] + drv->drv_id * vcd->offsets[DRV_DISTANCE]; offset += vcd->offsets[reg]; offset += ch * vcd->num_resources * vcd->offsets[PWR_ST_CHN_DISTANCE]; offset += resource_idx * vcd->offsets[DRV_RESOURCE_DISTANCE]; return offset; } static void write_crm_reg(const struct crm_drv *drv, u32 reg, u32 ch, u32 vcd_type, u32 resource_idx, u32 data) { u32 offset = crm_get_offset(drv, reg, ch, vcd_type, resource_idx); writel_relaxed(data, drv->base + offset); } static u32 read_crm_reg(const struct crm_drv *drv, u32 reg, u32 ch, u32 vcd_type, u32 resource_idx) { u32 offset = crm_get_offset(drv, reg, ch, vcd_type, resource_idx); return readl_relaxed(drv->base + offset); } static inline u32 crm_mgr_get_offset(const struct crm_mgr *mgr, u32 reg, u32 resource_idx) { u32 offset; offset = mgr->offsets[CRM_BASE] + resource_idx * mgr->offsets[CRM_DISTANCE]; offset += mgr->offsets[reg]; return offset; } static u32 read_crm_mgr_reg(const struct crm_mgr *mgr, u32 reg, u32 resource_idx) { u32 offset = crm_mgr_get_offset(mgr, reg, resource_idx); return readl_relaxed(mgr->base + offset); } static struct crm_drv *get_crm_drv(const struct device *dev, enum crm_drv_type drv_type, u32 drv_id) { struct crm_drv_top *crm; if (!dev) return NULL; crm = dev_get_drvdata(dev); if (drv_type == CRM_HW_DRV && drv_id < crm->num_hw_drvs) return &crm->hw_drvs[drv_id]; else if (drv_type == CRM_SW_DRV && drv_id < crm->num_sw_drvs) return &crm->sw_drvs[drv_id]; return NULL; } /** * crm_get_channel() - Get the channel to Update the data * @drv: The CRM DRV controller. * @chn_type: The type of channel to find. * * Return: * * 0 - Success * * -Error - Error code */ static int crm_get_channel(struct crm_drv *drv, enum channel_type ch_type, u32 *ch) { u32 chn_update; if (drv->num_channels == 0) return -EBUSY; /* Select Unused channel */ chn_update = read_crm_channel(drv, CHN_UPDATE); if (!chn_update) { /* Start with ch0 if none are in use */ *ch = CH0; return 0; } if (chn_update & CH0_CHN_BUSY) *ch = ch_type == CHN_FREE ? CH1 : CH0; else if (chn_update & CH1_CHN_BUSY) *ch = ch_type == CHN_FREE ? CH0 : CH1; else return -EBUSY; return 0; } int crm_channel_switch_complete(const struct crm_drv *drv, u32 ch) { u32 sts; int retry = 100, ret = 0; do { sts = read_crm_channel(drv, CHN_BUSY); if (ch == 0) sts &= CH0_CHN_BUSY; else sts &= CH1_CHN_BUSY; retry--; /* * Wait till all the votes are applied to new * channel during channel switch. * Maximum delay of 5 msec. */ udelay(100); } while ((sts != BIT(ch)) && retry); if (!retry) ret = -EBUSY; trace_crm_switch_channel(drv->name, ch, ret); ipc_log_string(drv->ipc_log_ctx, "Switch Channel: ch: %u ret: %d", ch, ret); return ret; } /** * crm_switch_channel() - Switch to the channel * @drv: The controller DRV. * @ch: The channel number to switch to. * * NOTE: Caller should ensure serialization before making this call. * Return: * * 0 - Success * * -Error - Error code */ int crm_switch_channel(const struct crm_drv *drv, u32 ch) { write_crm_channel(drv, CHN_UPDATE, BIT(ch)); return crm_channel_switch_complete(drv, ch); } static u32 crm_get_pwr_state_reg(int pwr_state) { u32 reg; switch (pwr_state) { case 0: reg = PWR_ST0; break; case 1: reg = PWR_ST1; break; case 2: reg = PWR_ST2; break; case 3: reg = PWR_ST3; break; case 4: reg = PWR_ST4; break; default: WARN_ON(1); reg = PWR_ST0; } return reg; } static int _crm_dump_drv_regs(struct crm_drv *drv) { struct crm_vcd *vcd; u32 chn, reg; u32 phy_base, data, offset; int m, j, k; int ret = 0; phy_base = get_crm_phy_addr(drv->base); pr_err("HW DRV%d Regs\n", drv->drv_id); spin_lock(&drv->cache_lock); ret = crm_get_channel(drv, CHN_IN_USE, &chn); if (ret) { spin_unlock(&drv->cache_lock); return ret; } for (m = 0; m < MAX_VCD_TYPE; m++) { vcd = &drv->vcd[m]; for (k = 0; k < vcd->num_resources; k++) { for (j = 0; j < vcd->num_pwr_states; j++) { reg = crm_get_pwr_state_reg(j); offset = crm_get_offset(drv, reg, chn, m, k); data = readl_relaxed(drv->base + offset); crm_print_hw_reg(drv->drv_id, chn, m, k, reg-PWR_ST0, phy_base + offset, data); } } } vcd = &drv->vcd[PERF_OL_VCD]; pr_err("DRV%d HW PERF_OL Status\n", drv->drv_id); for (k = 0; k < vcd->num_resources; k++) { offset = crm_get_offset(drv, PERF_OL_STATUS, 0, PERF_OL_VCD, k); data = readl_relaxed(drv->base + offset); crm_print_reg(phy_base + offset, data); } pr_err("DRV%d HW BW Status\n", drv->drv_id); offset = crm_get_offset(drv, PWR_IDX_STATUS, 0, BW_VOTE_VCD, 0); data = readl_relaxed(drv->base + offset); crm_print_reg(phy_base + offset, data); offset = crm_get_channel_offset(drv, CHN_BUSY); data = readl_relaxed(drv->base + offset); crm_print_reg(phy_base + offset, data); spin_unlock(&drv->cache_lock); return ret; } static int _crm_dump_regs(const struct device *dev) { struct crm_drv_top *crm; u32 phy_base, data, offset; int i; crm = dev_get_drvdata(dev); pr_err("CRMB Regs\n"); phy_base = get_crm_phy_addr(crm->crmb_mgr.base) + ((unsigned long) crm->crmb_mgr.base & VPAGE_SHIFT_BITS); for (i = 0; i < crm->crmb_mgr.num_resources; i++) { offset = crm_mgr_get_offset(&crm->crmb_mgr, STATUS_BE, i); data = readl_relaxed(crm->crmb_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmb_mgr, STATUS_FE, i); data = readl_relaxed(crm->crmb_mgr.base + offset); crm_print_reg(phy_base + offset, data); } pr_err("CRMC Regs\n"); phy_base = get_crm_phy_addr(crm->crmc_mgr.base) + ((unsigned long) crm->crmc_mgr.base & VPAGE_SHIFT_BITS); for (i = 0; i < crm->crmc_mgr.num_resources; i++) { offset = crm_mgr_get_offset(&crm->crmc_mgr, AGGR_PERF_OL, i); data = readl_relaxed(crm->crmc_mgr.base + offset); crm_print_reg(phy_base + offset, data); } for (i = 0; i < (crm->crmc_mgr.num_resources + crm->crmb_mgr.num_resources); i++) { offset = crm_mgr_get_offset(&crm->crmc_mgr, CURR_PERF_OL, i); data = readl_relaxed(crm->crmc_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmc_mgr, SEQ_STATUS, i); data = readl_relaxed(crm->crmc_mgr.base + offset); crm_print_reg(phy_base + offset, data); } pr_err("CRMV Regs\n"); phy_base = get_crm_phy_addr(crm->crmv_mgr.base) + ((unsigned long) crm->crmv_mgr.base & VPAGE_SHIFT_BITS); for (i = 0; i < crm->crmv_mgr.num_resources; i++) { offset = crm_mgr_get_offset(&crm->crmv_mgr, AGGR_VOL_STS, i); data = readl_relaxed(crm->crmv_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmv_mgr, SEQ_VOL_STS, i); data = readl_relaxed(crm->crmv_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmv_mgr, CURR_VOL_STS, i); data = readl_relaxed(crm->crmv_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmv_mgr, RAIL_FSM_STS, i); data = readl_relaxed(crm->crmv_mgr.base + offset); crm_print_reg(phy_base + offset, data); offset = crm_mgr_get_offset(&crm->crmv_mgr, RAIL_TCS_STS, i); data = readl_relaxed(crm->crmv_mgr.base + offset); crm_print_reg(phy_base + offset, data); } return 0; } static void crm_flush_cache(struct crm_drv *drv, struct crm_vcd *vcd, u32 ch, u32 vcd_type) { int i, j; u32 reg; for (i = 0; i < vcd->num_resources; i++) { for (j = 0; j < vcd->num_pwr_states; j++) { reg = crm_get_pwr_state_reg(j); write_crm_reg(drv, reg, ch, vcd_type, i, vcd->cache[i][j]); trace_crm_write_vcd_votes(drv->name, vcd_type, i, j, vcd->cache[i][j]); ipc_log_string(drv->ipc_log_ctx, "Flush: type: %u resource_idx:%u pwr_state: %u data: %#x", vcd_type, i, j, vcd->cache[i][j]); } } } /** * crm_write_pwr_states() - Flush the power state votes for HW DRVs. * @dev: The CRM device * @drv_id: HW DRV ID for which to flush the power state votes. * * Find the non-active channel, writes various power states that * were cached with crm_write_perf_ol() and crm_write_bw_vote() * APIs and does a channel switch. * * Applicable only for HW DRVs for which the votes are cached. * SW DRVs votes are immediately written. * * Return: * * 0 - Success * * -Error - Error code */ int crm_write_pwr_states(const struct device *dev, u32 drv_id) { struct crm_drv *drv = get_crm_drv(dev, CRM_HW_DRV, drv_id); struct crm_vcd *vcd; u32 ch; int i; int ret; if (!drv || drv->drv_type == CRM_SW_DRV) return -EINVAL; spin_lock(&drv->cache_lock); ret = crm_get_channel(drv, CHN_FREE, &ch); if (ret) goto exit; for (i = 0; i < MAX_VCD_TYPE; i++) { vcd = &drv->vcd[i]; crm_flush_cache(drv, vcd, ch, i); } ret = crm_switch_channel(drv, ch); if (ret) goto exit; exit: spin_unlock(&drv->cache_lock); /* Dump CRM registers for debug */ if (ret) { _crm_dump_drv_regs(drv); _crm_dump_regs(dev); BUG_ON(1); } return ret; } EXPORT_SYMBOL_GPL(crm_write_pwr_states); /** * crm_dump_drv_regs() - Dump CRM DRV registers for debug purposes. * @name: The name of the crm device to dump for. * @drv_id: DRV ID for which to dump for. * * Return: * * 0 - Success * * -Error - Error code */ int crm_dump_drv_regs(const char *name, u32 drv_id) { struct crm_drv_top *crm; struct crm_drv *drv; const struct device *dev; dev = crm_get_device(name); if (IS_ERR(dev)) return -EINVAL; crm = dev_get_drvdata(dev); drv = get_crm_drv(dev, CRM_HW_DRV, drv_id); if (!drv) return -EINVAL; return _crm_dump_drv_regs(drv); } EXPORT_SYMBOL_GPL(crm_dump_drv_regs); /** * crm_dump_regs() - Dump CRM registers for debug purposes. * @name: The name of the crm device to dump for. * * Return: * * 0 - Success * * -Error - Error code */ int crm_dump_regs(const char *name) { const struct device *dev; dev = crm_get_device(name); if (IS_ERR(dev)) return -EINVAL; return _crm_dump_regs(dev); } EXPORT_SYMBOL_GPL(crm_dump_regs); /** * crm_dump_regs() - Dump CRM registers for debug purposes. * @name: The name of the crm device to dump for. * @vcd_idx: The VCD index to read from. * @data: Read CURR_PERF_OL register value into this. * * Return: * * 0 - Success * * -Error - Error code */ int crm_read_curr_perf_ol(const char *name, int vcd_idx, u32 *data) { struct crm_drv_top *crm; const struct device *dev; dev = crm_get_device(name); if (IS_ERR(dev)) return -EINVAL; crm = dev_get_drvdata(dev); if (vcd_idx >= crm->crmc_mgr.num_resources) return -EINVAL; *data = read_crm_mgr_reg(&crm->crmc_mgr, CURR_PERF_OL, vcd_idx); return 0; } EXPORT_SYMBOL_GPL(crm_read_curr_perf_ol); static void crm_vote_completion(struct crm_sw_votes *votes) { struct completion *compl = &votes->compl; votes->in_progress = false; complete(compl); } /** * crm_vote_complete_irq() - Vote completion interrupt handler for SW DRVs. * @irq: The IRQ number (ignored). * @p: Pointer to "struct crm_drv". * * Called for ACTIVE_VOTE transfers (those are the only ones we enable the * IRQ for) when a transfer is done. * * Return: IRQ_HANDLED */ static irqreturn_t crm_vote_complete_irq(int irq, void *p) { struct crm_drv_top *crm = p; struct crm_drv *drv; struct crm_vcd *vcd; struct crm_sw_votes *votes; unsigned long irq_status; int i, j, k; for (i = 0; i < crm->num_sw_drvs; i++) { drv = &crm->sw_drvs[i]; if (!drv->initialized) continue; spin_lock(&drv->lock); for (j = 0; j < MAX_VCD_TYPE; j++) { vcd = &drv->vcd[j]; for (k = 0; k < vcd->num_resources; k++) { irq_status = read_crm_reg(drv, IRQ_STATUS, 0, j, k); if (!irq_status) continue; write_crm_reg(drv, IRQ_CLEAR, 0, j, k, IRQ_CLEAR_BIT); trace_crm_irq(drv->name, j, k, irq_status); ipc_log_string(drv->ipc_log_ctx, "IRQ: type: %u resource_idx:%u irq_status: %lu" , j, k, irq_status); votes = &vcd->sw_votes[k]; if (!votes->in_progress) { WARN_ON(1); continue; } if (votes->cmd.wait) crm_vote_completion(votes); } } spin_unlock(&drv->lock); } return IRQ_HANDLED; } static void crm_fill_cmd(struct crm_cmd *dest, const struct crm_cmd *src) { dest->resource_idx = src->resource_idx; dest->pwr_state = src->pwr_state; dest->data = src->data; dest->wait = src->wait; } static u32 crm_get_pwr_state(struct crm_drv *drv, const struct crm_cmd *cmd) { enum crm_sw_drv_state sw; enum crm_hw_drv_state hw; u32 pwr_state; if (drv->drv_type == CRM_HW_DRV) { hw = cmd->pwr_state.hw; pwr_state = hw; } else { sw = cmd->pwr_state.sw; pwr_state = sw; } return pwr_state; } static int crm_send_cmd(struct crm_drv *drv, u32 vcd_type, const struct crm_cmd *cmd) { struct crm_vcd *vcd = &drv->vcd[vcd_type]; u32 resource_idx = cmd->resource_idx; u32 pwr_state = crm_get_pwr_state(drv, cmd); u32 data = cmd->data; bool wait = cmd->wait; unsigned long flags; struct completion *compl = NULL; u32 time_left; spin_lock_irqsave(&drv->lock, flags); /* Set COMMIT to start aggregating votes */ if (vcd_type == BW_VOTE_VCD) { data |= BW_VOTE_COMMIT; if (wait) data |= BW_VOTE_RESP_REQ; } /* Note: Set BIT(31) for RESP_REQ and BIT(30) for COMMIT */ switch (pwr_state) { case CRM_ACTIVE_STATE: /* Wait forever for a previous request to complete */ wait_event_lock_irq(vcd->sw_votes[resource_idx].wait, !vcd->sw_votes[resource_idx].in_progress, drv->lock); compl = &vcd->sw_votes[resource_idx].compl; init_completion(compl); crm_fill_cmd(&vcd->sw_votes[resource_idx].cmd, cmd); vcd->sw_votes[resource_idx].in_progress = true; write_crm_reg(drv, PWR_ST0, 0, vcd_type, resource_idx, data); break; case CRM_SLEEP_STATE: write_crm_reg(drv, PWR_ST1, 0, vcd_type, resource_idx, data); break; case CRM_WAKE_STATE: write_crm_reg(drv, PWR_ST2, 0, vcd_type, resource_idx, data); break; default: WARN_ON(1); break; } spin_unlock_irqrestore(&drv->lock, flags); trace_crm_write_vcd_votes(drv->name, vcd_type, resource_idx, pwr_state, data); ipc_log_string(drv->ipc_log_ctx, "Write: type: %u resource_idx:%u pwr_state: %u data: %#x", vcd_type, resource_idx, pwr_state, data); if (compl && wait) { time_left = CRM_TIMEOUT_MS; time_left = wait_for_completion_timeout(compl, time_left); if (!time_left) { WARN_ON(1); return -ETIMEDOUT; } /* Unblock new requests for same VCD */ wake_up(&vcd->sw_votes[resource_idx].wait); } return 0; } static void crm_cache_vcd_votes(struct crm_drv *drv, u32 vcd_type, const struct crm_cmd *cmd) { struct crm_vcd *vcd = &drv->vcd[vcd_type]; u32 resource_idx = cmd->resource_idx; u32 pwr_state = crm_get_pwr_state(drv, cmd); u32 data = cmd->data; spin_lock(&drv->cache_lock); vcd->cache[resource_idx][pwr_state] = data; vcd->cache_dirty = true; spin_unlock(&drv->cache_lock); trace_crm_cache_vcd_votes(drv->name, vcd_type, resource_idx, pwr_state, data); ipc_log_string(drv->ipc_log_ctx, "Cache: type: %u resource_idx:%u pwr_state: %u data: %#x", vcd_type, resource_idx, pwr_state, data); } static bool crm_is_invalid_cmd(struct crm_drv *drv, u32 vcd_type, const struct crm_cmd *cmd) { struct crm_vcd *vcd; u32 resource_idx; u32 pwr_state; u32 data; bool ret; if (!drv || !cmd) return true; vcd = &drv->vcd[vcd_type]; resource_idx = cmd->resource_idx; pwr_state = crm_get_pwr_state(drv, cmd); data = cmd->data; if (pwr_state >= vcd->num_pwr_states) ret = true; else if (resource_idx >= vcd->num_resources) ret = true; else if (vcd_type == BW_VOTE_VCD && !(data & BW_VOTE_VALID)) ret = true; else if (vcd_type == PERF_OL_VCD && (data & ~PERF_OL_VALUE_BITS)) ret = true; else ret = false; return ret; } /** * crm_write_perf_ol() - Write a perf ol vote for a resource * @dev: The CRM device * @drv_type: The CRM DRV type, either SW or HW DRV. * @drv_id: DRV ID for which the votes are sent * @cmd: The CRM CMD * * Caches the votes for HW DRV and immediately returns. * The votes are written to unused channel with a call to * crm_write_pwr_states(). * * Caches the votes for logging and immediately sents the votes for SW DRVs * if the @cmd have .wait set and is for ACTIVE_VOTE then waits for completion * IRQ before return. for SLEEP_VOTE and WAKE_VOTE no completion IRQ is sent * and they are triggered within HW during idle/awake scenarios. * * Return: * * 0 - Success * * -Error - Error code */ int crm_write_perf_ol(const struct device *dev, enum crm_drv_type drv_type, u32 drv_id, const struct crm_cmd *cmd) { struct crm_drv *drv = get_crm_drv(dev, drv_type, drv_id); int ret; ret = crm_is_invalid_cmd(drv, PERF_OL_VCD, cmd); if (ret) return -EINVAL; /* Cache the votes first */ crm_cache_vcd_votes(drv, PERF_OL_VCD, cmd); /* Send SW DRV votes immediately for ACTIVE/SLEEP/WAKE states */ if (drv_type == CRM_SW_DRV) return crm_send_cmd(drv, PERF_OL_VCD, cmd); return 0; } EXPORT_SYMBOL_GPL(crm_write_perf_ol); /** * crm_write_bw_vote() - Write a bw vote for a resource * @dev: The CRM device * @drv_type: The CRM DRV type, either SW or HW DRV. * @drv_id: DRV ID for which the votes are sent * @cmd: The CRM CMD * * Caches the votes for HW DRV and immediately returns. * The votes are written to unused channel with a call to * crm_write_pwr_states(). * * Caches the votes for logging and immediately sents the votes for SW DRVs * if the @cmd have .wait set and is for ACTIVE_VOTE then waits for completion * IRQ before return. for SLEEP_VOTE and WAKE_VOTE no completion IRQ is sent * and they are triggered within HW during idle/awake scenarios. * * Return: * * 0 - Success * * -Error - Error code */ int crm_write_bw_vote(const struct device *dev, enum crm_drv_type drv_type, u32 drv_id, const struct crm_cmd *cmd) { struct crm_drv *drv = get_crm_drv(dev, drv_type, drv_id); int ret; ret = crm_is_invalid_cmd(drv, BW_VOTE_VCD, cmd); if (ret) return -EINVAL; /* Cache the votes first */ crm_cache_vcd_votes(drv, BW_VOTE_VCD, cmd); /* Send SW DRV votes immediately for ACTIVE/SLEEP/WAKE states */ if (drv_type == CRM_SW_DRV) return crm_send_cmd(drv, BW_VOTE_VCD, cmd); return 0; } EXPORT_SYMBOL_GPL(crm_write_bw_vote); /** * crm_get_device() - Returns a CRM device handle. * @name: The CRM device name for which handle is needed. * * Finds the CRM device from list of available CRM devices. * The @name should match the label property in device which are "cam_crm" * or "pcie_crm". * * Return: * * Device pointer - Success * * -Error pointer - Error */ const struct device *crm_get_device(const char *name) { struct crm_drv_top *crm; list_for_each_entry(crm, &crm_dev_list, list) { if (!strcmp(name, crm->name)) return crm->dev; } return ERR_PTR(-ENODEV); } EXPORT_SYMBOL_GPL(crm_get_device); static void crm_set_chn_behave(struct crm_drv_top *crm) { int i; if (!crm->desc->set_chn_behave) return; for (i = 0; i < crm->num_hw_drvs; i++) write_crm_channel(&crm->hw_drvs[i], CHN_BEHAVE, CHN_BEHAVE_BIT); } static int crm_probe_get_irqs(struct crm_drv_top *crm) { struct crm_drv *drvs = crm->sw_drvs; struct crm_vcd *vcd; int i, j, k; int irq; int ret; if (!crm->num_sw_drvs) return 0; irq = platform_get_irq_byname(crm->pdev, crm->name); if (irq < 0) return irq; ret = devm_request_irq(crm->dev, irq, crm_vote_complete_irq, IRQF_TRIGGER_RISING, crm->name, crm); if (ret) return ret; /* Only SW DRVs have associated vote completion IRQ */ for (i = 0; i < crm->num_sw_drvs; i++) { if (!crm->sw_drvs[i].initialized) continue; drvs[i].irq = irq; /* SW DRV do not have any channels */ drvs[i].num_channels = 0; /* Additionally allocate memory for sw_votes */ for (j = 0; j < MAX_VCD_TYPE; j++) { vcd = &drvs[i].vcd[j]; vcd->sw_votes = devm_kcalloc(crm->dev, vcd->num_resources, sizeof(struct crm_sw_votes), GFP_KERNEL); if (!vcd->sw_votes) return -ENOMEM; /* Enable IRQs for all VCDs */ for (k = 0; k < vcd->num_resources; k++) { init_waitqueue_head(&vcd->sw_votes[k].wait); write_crm_reg(&drvs[i], IRQ_ENABLE, 0, j, k, IRQ_ENABLE_BIT); } } } return 0; } static int crm_probe_alloc_vcd_caches(struct crm_drv_top *crm, struct crm_vcd *vcd) { u32 num_resources = vcd->num_resources; u32 num_pwr_states = vcd->num_pwr_states; int i; vcd->cache = devm_kcalloc(crm->dev, num_resources, sizeof(u32 *), GFP_KERNEL); if (!vcd->cache) return -ENOMEM; for (i = 0; i < num_resources; i++) { vcd->cache[i] = devm_kcalloc(crm->dev, num_pwr_states, sizeof(u32), GFP_KERNEL); if (!vcd->cache[i]) return -ENOMEM; } return 0; } static int crm_probe_set_vcd_caches(struct crm_drv_top *crm, u32 crm_cfg, u32 crm_cfg_2) { struct crm_vcd *vcd; struct crm_drv *drv; u32 num_perf_ol_vcds, num_nds, num_pwr_states; u32 num_bw_vote_vcds, num_rails; int i, j, ret; num_rails = crm_cfg & (NUM_OF_RAILS_MASK << NUM_OF_RAILS_SHIFT); num_rails >>= NUM_OF_RAILS_SHIFT; num_perf_ol_vcds = crm_cfg & (NUM_VCD_VOTED_BY_PERF_OL_MASK << NUM_VCD_VOTED_BY_PERF_OL_SHIFT); num_perf_ol_vcds >>= NUM_VCD_VOTED_BY_PERF_OL_SHIFT; num_bw_vote_vcds = crm_cfg & (NUM_VCD_VOTED_BY_BW_MASK << NUM_VCD_VOTED_BY_BW_SHIFT); num_bw_vote_vcds >>= NUM_VCD_VOTED_BY_BW_SHIFT; num_pwr_states = crm_cfg & (NUM_PWR_STATES_PER_CH_MASK << NUM_PWR_STATES_PER_CH_SHIFT); num_pwr_states >>= NUM_PWR_STATES_PER_CH_SHIFT; num_nds = crm_cfg_2 & (NUM_OF_NODES_MASK << NUM_OF_NODES_SHIFT); num_nds >>= NUM_OF_NODES_SHIFT; for (i = 0; i < crm->num_hw_drvs; i++) { drv = &crm->hw_drvs[i]; if (!drv->initialized) continue; drv->drv_type = CRM_HW_DRV; for (j = 0; j < MAX_VCD_TYPE; j++) { vcd = &drv->vcd[j]; if (j == PERF_OL_VCD) { vcd->offsets = hw_drv_perf_ol_vcd_regs; vcd->num_resources = num_perf_ol_vcds; } else if (j == BW_VOTE_VCD) { vcd->offsets = hw_drv_bw_vote_vcd_regs; /* BW_VOTE_VCD can have multiple NDs with which BW can be voted */ vcd->num_resources = num_nds; } else { continue; } vcd->num_pwr_states = num_pwr_states; ret = crm_probe_alloc_vcd_caches(crm, vcd); if (ret) return ret; } } for (i = 0; i < crm->num_sw_drvs; i++) { drv = &crm->sw_drvs[i]; if (!drv->initialized) continue; drv->drv_type = CRM_SW_DRV; for (j = 0; j < MAX_VCD_TYPE; j++) { vcd = &drv->vcd[j]; if (j == PERF_OL_VCD) { vcd->offsets = sw_drv_perf_ol_vcd_regs; vcd->num_resources = num_perf_ol_vcds; } else if (j == BW_VOTE_VCD) { vcd->offsets = sw_drv_bw_vote_vcd_regs; /* BW_VOTE_VCD can have multiple NDs with which BW can be voted */ vcd->num_resources = num_nds; } else { continue; } vcd->num_pwr_states = MAX_SW_DRV_PWR_STATES; ret = crm_probe_alloc_vcd_caches(crm, vcd); if (ret) return ret; } } crm->crmv_mgr.offsets = crmv_regs; crm->crmv_mgr.num_resources = num_rails; crm->crmb_mgr.offsets = crmb_regs; crm->crmb_mgr.num_resources = num_bw_vote_vcds; crm->crmc_mgr.offsets = crmc_regs; crm->crmc_mgr.num_resources = num_perf_ol_vcds; return 0; } static struct crm_drv *crm_probe_get_drvs(struct crm_drv_top *crm, int num_drvs, const char *prop_name, const char *name) { struct device_node *dn = crm->dev->of_node; u32 *drv_ids; int i, id; int ret; struct crm_drv *drvs; if (!num_drvs) return ERR_PTR(-EINVAL); drvs = devm_kcalloc(crm->dev, num_drvs, sizeof(struct crm_drv), GFP_KERNEL); if (!drvs) return ERR_PTR(-ENOMEM); drv_ids = kcalloc(num_drvs, sizeof(u32), GFP_KERNEL); if (!drv_ids) return ERR_PTR(-ENOMEM); ret = of_property_read_u32_array(dn, prop_name, drv_ids, num_drvs); if (ret) { kfree(drv_ids); return ERR_PTR(ret); } for (i = 0; i < num_drvs; i++) { id = drv_ids[i]; scnprintf(drvs[i].name, sizeof(drvs[i].name), "%s_%s_%d", crm->name, name, id); drvs[i].drv_id = id; drvs[i].base = crm->base; spin_lock_init(&drvs[i].lock); spin_lock_init(&drvs[i].cache_lock); drvs[i].ipc_log_ctx = ipc_log_context_create( CRM_DRV_IPC_LOG_SIZE, drvs[i].name, 0); drvs[i].offsets = chn_regs; drvs[i].num_channels = crm->num_channels; drvs[i].initialized = true; } kfree(drv_ids); return drvs; } static int crm_probe_drvs(struct crm_drv_top *crm, struct device_node *dn) { u32 crm_ver, major_ver, minor_ver; u32 crm_cfg, crm_cfg_2; int num_hw_drvs, num_sw_drvs; crm_ver = readl_relaxed(crm->base + CRM_VERSION); major_ver = crm_ver & (MAJOR_VER_MASK << MAJOR_VER_SHIFT); major_ver >>= MAJOR_VER_SHIFT; minor_ver = crm_ver & (MINOR_VER_MASK << MINOR_VER_SHIFT); minor_ver >>= MINOR_VER_SHIFT; pr_debug("CRM %s running version = %u.%u\n", crm->name, major_ver, minor_ver); crm_cfg = readl_relaxed(crm->base + CRM_CFG_PARAM_1); num_hw_drvs = crm_cfg & (NUM_HW_DRVS_MASK << NUM_HW_DRVS_SHIFT); num_hw_drvs >>= NUM_HW_DRVS_SHIFT; num_sw_drvs = crm_cfg & (NUM_SW_DRVS_MASK << NUM_SW_DRVS_SHIFT); num_sw_drvs >>= NUM_SW_DRVS_SHIFT; crm->num_channels = crm_cfg & (NUM_CH_MASK << NUM_CH_SHIFT); crm->num_channels >>= NUM_CH_SHIFT; crm->num_hw_drvs = of_property_count_u32_elems(dn, "qcom,hw-drv-ids"); if (crm->num_hw_drvs < 0) { crm->num_hw_drvs = 0; goto skip_hw_drvs; } crm->hw_drvs = crm_probe_get_drvs(crm, crm->num_hw_drvs, "qcom,hw-drv-ids", "hw_drv"); if (IS_ERR(crm->hw_drvs)) return PTR_ERR(crm->hw_drvs); skip_hw_drvs: crm->num_sw_drvs = of_property_count_u32_elems(dn, "qcom,sw-drv-ids"); if (crm->num_sw_drvs < 0) { crm->num_sw_drvs = 0; goto skip_sw_drvs; } crm->sw_drvs = crm_probe_get_drvs(crm, crm->num_sw_drvs, "qcom,sw-drv-ids", "sw_drv"); if (IS_ERR(crm->sw_drvs)) return PTR_ERR(crm->sw_drvs); skip_sw_drvs: if (crm->num_sw_drvs > num_sw_drvs || crm->num_hw_drvs > num_hw_drvs || (!crm->num_sw_drvs && !crm->num_hw_drvs)) return -EINVAL; crm_cfg_2 = readl_relaxed(crm->base + CRM_CFG_PARAM_2); return crm_probe_set_vcd_caches(crm, crm_cfg, crm_cfg_2); } static int crm_probe_platform_resources(struct platform_device *pdev, struct crm_drv_top *crm) { struct resource *res; crm->base = devm_platform_get_and_ioremap_resource(pdev, 0, NULL); if (IS_ERR(crm->base)) return -ENOMEM; crm->crmb_mgr.base = devm_platform_get_and_ioremap_resource(pdev, 1, &res); if (IS_ERR(crm->crmb_mgr.base)) return -ENOMEM; strscpy(crm->crmb_mgr.name, res->name, sizeof(crm->crmb_mgr.name)); crm->crmc_mgr.base = devm_platform_get_and_ioremap_resource(pdev, 2, &res); if (IS_ERR(crm->crmc_mgr.base)) return -ENOMEM; strscpy(crm->crmc_mgr.name, res->name, sizeof(crm->crmc_mgr.name)); crm->crmv_mgr.base = devm_platform_get_and_ioremap_resource(pdev, 3, &res); if (IS_ERR(crm->crmv_mgr.base)) return -ENOMEM; strscpy(crm->crmv_mgr.name, res->name, sizeof(crm->crmv_mgr.name)); return 0; } static int crm_probe(struct platform_device *pdev) { struct device_node *dn = pdev->dev.of_node; struct crm_drv_top *crm; const char *name; u32 crm_en; int ret; crm = devm_kzalloc(&pdev->dev, sizeof(*crm), GFP_KERNEL); if (!crm) return -ENOMEM; crm->desc = of_device_get_match_data(&pdev->dev); if (!crm->desc) return -EINVAL; name = of_get_property(dn, "label", NULL); if (!name) name = dev_name(&pdev->dev); crm->pdev = pdev; crm->dev = &pdev->dev; scnprintf(crm->name, sizeof(crm->name), "%s", name); ret = crm_probe_platform_resources(pdev, crm); if (ret) return ret; crm_en = readl_relaxed(crm->base + CRM_ENABLE); if (!crm_en) return -EINVAL; ret = crm_probe_drvs(crm, dn); if (ret) return ret; ret = crm_probe_get_irqs(crm); if (ret) return ret; crm_set_chn_behave(crm); INIT_LIST_HEAD(&crm->list); list_add_tail(&crm->list, &crm_dev_list); dev_set_drvdata(&pdev->dev, crm); return ret; } struct crm_desc cam_crm_desc = { .set_chn_behave = true, }; struct crm_desc pcie_crm_desc = { .set_chn_behave = false, }; static const struct of_device_id crm_drv_match[] = { { .compatible = "qcom,cam-crm", .data = &cam_crm_desc}, { .compatible = "qcom,pcie-crm", .data = &pcie_crm_desc}, { } }; MODULE_DEVICE_TABLE(of, crm_drv_match); static struct platform_driver crm_driver = { .probe = crm_probe, .driver = { .name = "crm", .of_match_table = crm_drv_match, .suppress_bind_attrs = true, }, }; module_platform_driver(crm_driver); MODULE_DESCRIPTION("Qualcomm Technologies, Inc. (QTI) CRM Driver"); MODULE_LICENSE("GPL");