/* * Copyright (c) 2013-2015, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #define pr_fmt(fmt) "%s: " fmt, __func__ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Register Offsets for RB-CPR and Bit Definitions */ /* RBCPR Version Register */ #define REG_RBCPR_VERSION 0 #define RBCPR_VER_2 0x02 /* RBCPR Gate Count and Target Registers */ #define REG_RBCPR_GCNT_TARGET(n) (0x60 + 4 * n) #define RBCPR_GCNT_TARGET_GCNT_BITS 10 #define RBCPR_GCNT_TARGET_GCNT_SHIFT 12 #define RBCPR_GCNT_TARGET_GCNT_MASK ((1<>RBCPR_DEBUG1_QUOT_SLOW_SHIFT) & \ ((1<rdesc.name, \ ##__VA_ARGS__); \ } while (0) #define cpr_debug_irq(cpr_vreg, message, ...) \ do { \ if (cpr_debug_enable & CPR_DEBUG_MASK_IRQ) \ pr_info("%s: " message, (cpr_vreg)->rdesc.name, \ ##__VA_ARGS__); \ else \ pr_debug("%s: " message, (cpr_vreg)->rdesc.name, \ ##__VA_ARGS__); \ } while (0) #define cpr_info(cpr_vreg, message, ...) \ pr_info("%s: " message, (cpr_vreg)->rdesc.name, ##__VA_ARGS__) #define cpr_err(cpr_vreg, message, ...) \ pr_err("%s: " message, (cpr_vreg)->rdesc.name, ##__VA_ARGS__) static u64 cpr_read_remapped_efuse_row(struct cpr_regulator *cpr_vreg, u32 row_num) { if (row_num - cpr_vreg->remapped_row_base >= cpr_vreg->num_remapped_rows) { cpr_err(cpr_vreg, "invalid row=%u, max remapped row=%u\n", row_num, cpr_vreg->remapped_row_base + cpr_vreg->num_remapped_rows - 1); return 0; } return cpr_vreg->remapped_row[row_num - cpr_vreg->remapped_row_base]; } static u64 cpr_read_efuse_row(struct cpr_regulator *cpr_vreg, u32 row_num, bool use_tz_api) { int rc; u64 efuse_bits; struct scm_desc desc = {0}; struct cpr_read_req { u32 row_address; int addr_type; } req; struct cpr_read_rsp { u32 row_data[2]; u32 status; } rsp; if (cpr_vreg->remapped_row && row_num >= cpr_vreg->remapped_row_base) return cpr_read_remapped_efuse_row(cpr_vreg, row_num); if (!use_tz_api) { efuse_bits = readq_relaxed(cpr_vreg->efuse_base + row_num * BYTES_PER_FUSE_ROW); return efuse_bits; } desc.args[0] = req.row_address = cpr_vreg->efuse_addr + row_num * BYTES_PER_FUSE_ROW; desc.args[1] = req.addr_type = 0; desc.arginfo = SCM_ARGS(2); efuse_bits = 0; if (!is_scm_armv8()) { rc = scm_call(SCM_SVC_FUSE, SCM_FUSE_READ, &req, sizeof(req), &rsp, sizeof(rsp)); } else { rc = scm_call2(SCM_SIP_FNID(SCM_SVC_FUSE, SCM_FUSE_READ), &desc); rsp.row_data[0] = desc.ret[0]; rsp.row_data[1] = desc.ret[1]; rsp.status = desc.ret[2]; } if (rc) { cpr_err(cpr_vreg, "read row %d failed, err code = %d", row_num, rc); } else { efuse_bits = ((u64)(rsp.row_data[1]) << 32) + (u64)rsp.row_data[0]; } return efuse_bits; } /** * cpr_read_efuse_param() - read a parameter from one or two eFuse rows * @cpr_vreg: Pointer to cpr_regulator struct for this regulator. * @row_start: Fuse row number to start reading from. * @bit_start: The LSB of the parameter to read from the fuse. * @bit_len: The length of the parameter in bits. * @use_tz_api: Flag to indicate if an SCM call should be used to read the fuse. * * This function reads a parameter of specified offset and bit size out of one * or two consecutive eFuse rows. This allows for the reading of parameters * that happen to be split between two eFuse rows. * * Returns the fuse parameter on success or 0 on failure. */ static u64 cpr_read_efuse_param(struct cpr_regulator *cpr_vreg, int row_start, int bit_start, int bit_len, bool use_tz_api) { u64 fuse[2]; u64 param = 0; int bits_first, bits_second; if (bit_start < 0) { cpr_err(cpr_vreg, "Invalid LSB = %d specified\n", bit_start); return 0; } if (bit_len < 0 || bit_len > 64) { cpr_err(cpr_vreg, "Invalid bit length = %d specified\n", bit_len); return 0; } /* Allow bit indexing to start beyond the end of the start row. */ if (bit_start >= 64) { row_start += bit_start >> 6; /* equivalent to bit_start / 64 */ bit_start &= 0x3F; } fuse[0] = cpr_read_efuse_row(cpr_vreg, row_start, use_tz_api); if (bit_start == 0 && bit_len == 64) { param = fuse[0]; } else if (bit_start + bit_len <= 64) { param = (fuse[0] >> bit_start) & ((1ULL << bit_len) - 1); } else { fuse[1] = cpr_read_efuse_row(cpr_vreg, row_start + 1, use_tz_api); bits_first = 64 - bit_start; bits_second = bit_len - bits_first; param = (fuse[0] >> bit_start) & ((1ULL << bits_first) - 1); param |= (fuse[1] & ((1ULL << bits_second) - 1)) << bits_first; } return param; } static bool cpr_is_allowed(struct cpr_regulator *cpr_vreg) { if (cpr_vreg->cpr_fuse_disable || !cpr_vreg->enable || cpr_vreg->cpr_thermal_disable) return false; else return true; } static void cpr_write(struct cpr_regulator *cpr_vreg, u32 offset, u32 value) { writel_relaxed(value, cpr_vreg->rbcpr_base + offset); } static u32 cpr_read(struct cpr_regulator *cpr_vreg, u32 offset) { return readl_relaxed(cpr_vreg->rbcpr_base + offset); } static void cpr_masked_write(struct cpr_regulator *cpr_vreg, u32 offset, u32 mask, u32 value) { u32 reg_val; reg_val = readl_relaxed(cpr_vreg->rbcpr_base + offset); reg_val &= ~mask; reg_val |= value & mask; writel_relaxed(reg_val, cpr_vreg->rbcpr_base + offset); } static void cpr_irq_clr(struct cpr_regulator *cpr_vreg) { cpr_write(cpr_vreg, REG_RBIF_IRQ_CLEAR, CPR_INT_ALL); } static void cpr_irq_clr_nack(struct cpr_regulator *cpr_vreg) { cpr_irq_clr(cpr_vreg); cpr_write(cpr_vreg, REG_RBIF_CONT_NACK_CMD, 1); } static void cpr_irq_clr_ack(struct cpr_regulator *cpr_vreg) { cpr_irq_clr(cpr_vreg); cpr_write(cpr_vreg, REG_RBIF_CONT_ACK_CMD, 1); } static void cpr_irq_set(struct cpr_regulator *cpr_vreg, u32 int_bits) { cpr_write(cpr_vreg, REG_RBIF_IRQ_EN(cpr_vreg->irq_line), int_bits); } static void cpr_ctl_modify(struct cpr_regulator *cpr_vreg, u32 mask, u32 value) { cpr_masked_write(cpr_vreg, REG_RBCPR_CTL, mask, value); } static void cpr_ctl_enable(struct cpr_regulator *cpr_vreg, int corner) { u32 val; if (cpr_vreg->is_cpr_suspended) return; /* Program Consecutive Up & Down */ val = ((cpr_vreg->timer_cons_down & RBIF_TIMER_ADJ_CONS_DOWN_MASK) << RBIF_TIMER_ADJ_CONS_DOWN_SHIFT) | (cpr_vreg->timer_cons_up & RBIF_TIMER_ADJ_CONS_UP_MASK); cpr_masked_write(cpr_vreg, REG_RBIF_TIMER_ADJUST, RBIF_TIMER_ADJ_CONS_UP_MASK | RBIF_TIMER_ADJ_CONS_DOWN_MASK, val); cpr_masked_write(cpr_vreg, REG_RBCPR_CTL, RBCPR_CTL_SW_AUTO_CONT_NACK_DN_EN | RBCPR_CTL_SW_AUTO_CONT_ACK_EN, cpr_vreg->save_ctl[corner]); cpr_irq_set(cpr_vreg, cpr_vreg->save_irq[corner]); if (cpr_is_allowed(cpr_vreg) && cpr_vreg->vreg_enabled && (cpr_vreg->ceiling_volt[corner] > cpr_vreg->floor_volt[corner])) val = RBCPR_CTL_LOOP_EN; else val = 0; cpr_ctl_modify(cpr_vreg, RBCPR_CTL_LOOP_EN, val); } static void cpr_ctl_disable(struct cpr_regulator *cpr_vreg) { if (cpr_vreg->is_cpr_suspended) return; cpr_irq_set(cpr_vreg, 0); cpr_ctl_modify(cpr_vreg, RBCPR_CTL_SW_AUTO_CONT_NACK_DN_EN | RBCPR_CTL_SW_AUTO_CONT_ACK_EN, 0); cpr_masked_write(cpr_vreg, REG_RBIF_TIMER_ADJUST, RBIF_TIMER_ADJ_CONS_UP_MASK | RBIF_TIMER_ADJ_CONS_DOWN_MASK, 0); cpr_irq_clr(cpr_vreg); cpr_write(cpr_vreg, REG_RBIF_CONT_ACK_CMD, 1); cpr_write(cpr_vreg, REG_RBIF_CONT_NACK_CMD, 1); cpr_ctl_modify(cpr_vreg, RBCPR_CTL_LOOP_EN, 0); } static bool cpr_ctl_is_enabled(struct cpr_regulator *cpr_vreg) { u32 reg_val; reg_val = cpr_read(cpr_vreg, REG_RBCPR_CTL); return reg_val & RBCPR_CTL_LOOP_EN; } static bool cpr_ctl_is_busy(struct cpr_regulator *cpr_vreg) { u32 reg_val; reg_val = cpr_read(cpr_vreg, REG_RBCPR_RESULT_0); return reg_val & RBCPR_RESULT0_BUSY_MASK; } static void cpr_corner_save(struct cpr_regulator *cpr_vreg, int corner) { cpr_vreg->save_ctl[corner] = cpr_read(cpr_vreg, REG_RBCPR_CTL); cpr_vreg->save_irq[corner] = cpr_read(cpr_vreg, REG_RBIF_IRQ_EN(cpr_vreg->irq_line)); } static void cpr_corner_restore(struct cpr_regulator *cpr_vreg, int corner) { u32 gcnt, ctl, irq, ro_sel, step_quot; int fuse_corner = cpr_vreg->corner_map[corner]; int i; ro_sel = cpr_vreg->cpr_fuse_ro_sel[fuse_corner]; gcnt = cpr_vreg->gcnt | (cpr_vreg->cpr_fuse_target_quot[fuse_corner] - cpr_vreg->quot_adjust[corner]); /* Program the step quotient and idle clocks */ step_quot = ((cpr_vreg->idle_clocks & RBCPR_STEP_QUOT_IDLE_CLK_MASK) << RBCPR_STEP_QUOT_IDLE_CLK_SHIFT) | (cpr_vreg->step_quotient[fuse_corner] & RBCPR_STEP_QUOT_STEPQUOT_MASK); cpr_write(cpr_vreg, REG_RBCPR_STEP_QUOT, step_quot); /* Clear the target quotient value and gate count of all ROs */ for (i = 0; i < CPR_NUM_RING_OSC; i++) cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(i), 0); cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(ro_sel), gcnt); ctl = cpr_vreg->save_ctl[corner]; cpr_write(cpr_vreg, REG_RBCPR_CTL, ctl); irq = cpr_vreg->save_irq[corner]; cpr_irq_set(cpr_vreg, irq); cpr_debug(cpr_vreg, "gcnt = 0x%08x, ctl = 0x%08x, irq = 0x%08x\n", gcnt, ctl, irq); } static void cpr_corner_switch(struct cpr_regulator *cpr_vreg, int corner) { if (cpr_vreg->corner == corner) return; cpr_corner_restore(cpr_vreg, corner); } static int cpr_apc_set(struct cpr_regulator *cpr_vreg, u32 new_volt) { int max_volt, rc; max_volt = cpr_vreg->ceiling_max; rc = regulator_set_voltage(cpr_vreg->vdd_apc, new_volt, max_volt); if (rc) cpr_err(cpr_vreg, "set: vdd_apc = %d uV: rc=%d\n", new_volt, rc); return rc; } static int cpr_mx_get(struct cpr_regulator *cpr_vreg, int corner, int apc_volt) { int vdd_mx; int fuse_corner = cpr_vreg->corner_map[corner]; int highest_fuse_corner = cpr_vreg->num_fuse_corners; switch (cpr_vreg->vdd_mx_vmin_method) { case VDD_MX_VMIN_APC: vdd_mx = apc_volt; break; case VDD_MX_VMIN_APC_CORNER_CEILING: vdd_mx = cpr_vreg->fuse_ceiling_volt[fuse_corner]; break; case VDD_MX_VMIN_APC_SLOW_CORNER_CEILING: vdd_mx = cpr_vreg->fuse_ceiling_volt[highest_fuse_corner]; break; case VDD_MX_VMIN_MX_VMAX: vdd_mx = cpr_vreg->vdd_mx_vmax; break; case VDD_MX_VMIN_APC_FUSE_CORNER_MAP: vdd_mx = cpr_vreg->vdd_mx_corner_map[fuse_corner]; break; case VDD_MX_VMIN_APC_CORNER_MAP: vdd_mx = cpr_vreg->vdd_mx_corner_map[corner]; break; default: vdd_mx = 0; break; } return vdd_mx; } static int cpr_mx_set(struct cpr_regulator *cpr_vreg, int corner, int vdd_mx_vmin) { int rc; int fuse_corner = cpr_vreg->corner_map[corner]; rc = regulator_set_voltage(cpr_vreg->vdd_mx, vdd_mx_vmin, cpr_vreg->vdd_mx_vmax); cpr_debug(cpr_vreg, "[corner:%d, fuse_corner:%d] %d uV\n", corner, fuse_corner, vdd_mx_vmin); if (!rc) { cpr_vreg->vdd_mx_vmin = vdd_mx_vmin; } else { cpr_err(cpr_vreg, "set: vdd_mx [corner:%d, fuse_corner:%d] = %d uV failed: rc=%d\n", corner, fuse_corner, vdd_mx_vmin, rc); } return rc; } static int cpr_scale_voltage(struct cpr_regulator *cpr_vreg, int corner, int new_apc_volt, enum voltage_change_dir dir) { int rc = 0, vdd_mx_vmin = 0; int mem_acc_corner = cpr_vreg->mem_acc_corner_map[corner]; int fuse_corner = cpr_vreg->corner_map[corner]; int apc_corner, vsens_corner; /* Determine the vdd_mx voltage */ if (dir != NO_CHANGE && cpr_vreg->vdd_mx != NULL) vdd_mx_vmin = cpr_mx_get(cpr_vreg, corner, new_apc_volt); if (cpr_vreg->vdd_vsens_voltage && cpr_vreg->vsens_enabled) { rc = regulator_disable(cpr_vreg->vdd_vsens_voltage); if (!rc) cpr_vreg->vsens_enabled = false; } if (dir == DOWN) { if (!rc && cpr_vreg->mem_acc_vreg) rc = regulator_set_voltage(cpr_vreg->mem_acc_vreg, mem_acc_corner, mem_acc_corner); if (!rc && cpr_vreg->rpm_apc_vreg) { apc_corner = cpr_vreg->rpm_apc_corner_map[corner]; rc = regulator_set_voltage(cpr_vreg->rpm_apc_vreg, apc_corner, apc_corner); if (rc) cpr_err(cpr_vreg, "apc_corner voting failed rc=%d\n", rc); } } if (!rc && vdd_mx_vmin && dir == UP) { if (vdd_mx_vmin != cpr_vreg->vdd_mx_vmin) rc = cpr_mx_set(cpr_vreg, corner, vdd_mx_vmin); } if (!rc) rc = cpr_apc_set(cpr_vreg, new_apc_volt); if (dir == UP) { if (!rc && cpr_vreg->mem_acc_vreg) rc = regulator_set_voltage(cpr_vreg->mem_acc_vreg, mem_acc_corner, mem_acc_corner); if (!rc && cpr_vreg->rpm_apc_vreg) { apc_corner = cpr_vreg->rpm_apc_corner_map[corner]; rc = regulator_set_voltage(cpr_vreg->rpm_apc_vreg, apc_corner, apc_corner); if (rc) cpr_err(cpr_vreg, "apc_corner voting failed rc=%d\n", rc); } } if (!rc && vdd_mx_vmin && dir == DOWN) { if (vdd_mx_vmin != cpr_vreg->vdd_mx_vmin) rc = cpr_mx_set(cpr_vreg, corner, vdd_mx_vmin); } if (!rc && cpr_vreg->vdd_vsens_corner) { vsens_corner = cpr_vreg->vsens_corner_map[fuse_corner]; rc = regulator_set_voltage(cpr_vreg->vdd_vsens_corner, vsens_corner, vsens_corner); } if (!rc && cpr_vreg->vdd_vsens_voltage) { rc = regulator_set_voltage(cpr_vreg->vdd_vsens_voltage, cpr_vreg->floor_volt[corner], cpr_vreg->ceiling_volt[corner]); if (!rc && !cpr_vreg->vsens_enabled) { rc = regulator_enable(cpr_vreg->vdd_vsens_voltage); if (!rc) cpr_vreg->vsens_enabled = true; } } return rc; } static void cpr_scale(struct cpr_regulator *cpr_vreg, enum voltage_change_dir dir) { u32 reg_val, error_steps, reg_mask; int last_volt, new_volt, corner, fuse_corner; u32 gcnt, quot; corner = cpr_vreg->corner; fuse_corner = cpr_vreg->corner_map[corner]; reg_val = cpr_read(cpr_vreg, REG_RBCPR_RESULT_0); error_steps = (reg_val >> RBCPR_RESULT0_ERROR_STEPS_SHIFT) & RBCPR_RESULT0_ERROR_STEPS_MASK; last_volt = cpr_vreg->last_volt[corner]; cpr_debug_irq(cpr_vreg, "last_volt[corner:%d, fuse_corner:%d] = %d uV\n", corner, fuse_corner, last_volt); gcnt = cpr_read(cpr_vreg, REG_RBCPR_GCNT_TARGET (cpr_vreg->cpr_fuse_ro_sel[fuse_corner])); quot = gcnt & ((1 << RBCPR_GCNT_TARGET_GCNT_SHIFT) - 1); if (dir == UP) { if (cpr_vreg->clamp_timer_interval && error_steps < cpr_vreg->up_threshold) { /* * Handle the case where another measurement started * after the interrupt was triggered due to a core * exiting from power collapse. */ error_steps = max(cpr_vreg->up_threshold, cpr_vreg->vdd_apc_step_up_limit); } cpr_debug_irq(cpr_vreg, "Up: cpr status = 0x%08x (error_steps=%d)\n", reg_val, error_steps); if (last_volt >= cpr_vreg->ceiling_volt[corner]) { cpr_debug_irq(cpr_vreg, "[corn:%d, fuse_corn:%d] @ ceiling: %d >= %d: NACK\n", corner, fuse_corner, last_volt, cpr_vreg->ceiling_volt[corner]); cpr_irq_clr_nack(cpr_vreg); cpr_debug_irq(cpr_vreg, "gcnt = 0x%08x (quot = %d)\n", gcnt, quot); /* Maximize the UP threshold */ reg_mask = RBCPR_CTL_UP_THRESHOLD_MASK << RBCPR_CTL_UP_THRESHOLD_SHIFT; reg_val = reg_mask; cpr_ctl_modify(cpr_vreg, reg_mask, reg_val); /* Disable UP interrupt */ cpr_irq_set(cpr_vreg, CPR_INT_DEFAULT & ~CPR_INT_UP); return; } if (error_steps > cpr_vreg->vdd_apc_step_up_limit) { cpr_debug_irq(cpr_vreg, "%d is over up-limit(%d): Clamp\n", error_steps, cpr_vreg->vdd_apc_step_up_limit); error_steps = cpr_vreg->vdd_apc_step_up_limit; } /* Calculate new voltage */ new_volt = last_volt + (error_steps * cpr_vreg->step_volt); if (new_volt > cpr_vreg->ceiling_volt[corner]) { cpr_debug_irq(cpr_vreg, "new_volt(%d) >= ceiling(%d): Clamp\n", new_volt, cpr_vreg->ceiling_volt[corner]); new_volt = cpr_vreg->ceiling_volt[corner]; } if (cpr_scale_voltage(cpr_vreg, corner, new_volt, dir)) { cpr_irq_clr_nack(cpr_vreg); return; } cpr_vreg->last_volt[corner] = new_volt; /* Disable auto nack down */ reg_mask = RBCPR_CTL_SW_AUTO_CONT_NACK_DN_EN; reg_val = 0; cpr_ctl_modify(cpr_vreg, reg_mask, reg_val); /* Re-enable default interrupts */ cpr_irq_set(cpr_vreg, CPR_INT_DEFAULT); /* Ack */ cpr_irq_clr_ack(cpr_vreg); cpr_debug_irq(cpr_vreg, "UP: -> new_volt[corner:%d, fuse_corner:%d] = %d uV\n", corner, fuse_corner, new_volt); } else if (dir == DOWN) { if (cpr_vreg->clamp_timer_interval && error_steps < cpr_vreg->down_threshold) { /* * Handle the case where another measurement started * after the interrupt was triggered due to a core * exiting from power collapse. */ error_steps = max(cpr_vreg->down_threshold, cpr_vreg->vdd_apc_step_down_limit); } cpr_debug_irq(cpr_vreg, "Down: cpr status = 0x%08x (error_steps=%d)\n", reg_val, error_steps); if (last_volt <= cpr_vreg->floor_volt[corner]) { cpr_debug_irq(cpr_vreg, "[corn:%d, fuse_corner:%d] @ floor: %d <= %d: NACK\n", corner, fuse_corner, last_volt, cpr_vreg->floor_volt[corner]); cpr_irq_clr_nack(cpr_vreg); cpr_debug_irq(cpr_vreg, "gcnt = 0x%08x (quot = %d)\n", gcnt, quot); /* Enable auto nack down */ reg_mask = RBCPR_CTL_SW_AUTO_CONT_NACK_DN_EN; reg_val = RBCPR_CTL_SW_AUTO_CONT_NACK_DN_EN; cpr_ctl_modify(cpr_vreg, reg_mask, reg_val); /* Disable DOWN interrupt */ cpr_irq_set(cpr_vreg, CPR_INT_DEFAULT & ~CPR_INT_DOWN); return; } if (error_steps > cpr_vreg->vdd_apc_step_down_limit) { cpr_debug_irq(cpr_vreg, "%d is over down-limit(%d): Clamp\n", error_steps, cpr_vreg->vdd_apc_step_down_limit); error_steps = cpr_vreg->vdd_apc_step_down_limit; } /* Calculte new voltage */ new_volt = last_volt - (error_steps * cpr_vreg->step_volt); if (new_volt < cpr_vreg->floor_volt[corner]) { cpr_debug_irq(cpr_vreg, "new_volt(%d) < floor(%d): Clamp\n", new_volt, cpr_vreg->floor_volt[corner]); new_volt = cpr_vreg->floor_volt[corner]; } if (cpr_scale_voltage(cpr_vreg, corner, new_volt, dir)) { cpr_irq_clr_nack(cpr_vreg); return; } cpr_vreg->last_volt[corner] = new_volt; /* Restore default threshold for UP */ reg_mask = RBCPR_CTL_UP_THRESHOLD_MASK << RBCPR_CTL_UP_THRESHOLD_SHIFT; reg_val = cpr_vreg->up_threshold << RBCPR_CTL_UP_THRESHOLD_SHIFT; cpr_ctl_modify(cpr_vreg, reg_mask, reg_val); /* Re-enable default interrupts */ cpr_irq_set(cpr_vreg, CPR_INT_DEFAULT); /* Ack */ cpr_irq_clr_ack(cpr_vreg); cpr_debug_irq(cpr_vreg, "DOWN: -> new_volt[corner:%d, fuse_corner:%d] = %d uV\n", corner, fuse_corner, new_volt); } } static irqreturn_t cpr_irq_handler(int irq, void *dev) { struct cpr_regulator *cpr_vreg = dev; u32 reg_val; mutex_lock(&cpr_vreg->cpr_mutex); reg_val = cpr_read(cpr_vreg, REG_RBIF_IRQ_STATUS); if (cpr_vreg->flags & FLAGS_IGNORE_1ST_IRQ_STATUS) reg_val = cpr_read(cpr_vreg, REG_RBIF_IRQ_STATUS); cpr_debug_irq(cpr_vreg, "IRQ_STATUS = 0x%02X\n", reg_val); if (!cpr_ctl_is_enabled(cpr_vreg)) { cpr_debug_irq(cpr_vreg, "CPR is disabled\n"); goto _exit; } else if (cpr_ctl_is_busy(cpr_vreg) && !cpr_vreg->clamp_timer_interval) { cpr_debug_irq(cpr_vreg, "CPR measurement is not ready\n"); goto _exit; } else if (!cpr_is_allowed(cpr_vreg)) { reg_val = cpr_read(cpr_vreg, REG_RBCPR_CTL); cpr_err(cpr_vreg, "Interrupt broken? RBCPR_CTL = 0x%02X\n", reg_val); goto _exit; } /* Following sequence of handling is as per each IRQ's priority */ if (reg_val & CPR_INT_UP) { cpr_scale(cpr_vreg, UP); } else if (reg_val & CPR_INT_DOWN) { cpr_scale(cpr_vreg, DOWN); } else if (reg_val & CPR_INT_MIN) { cpr_irq_clr_nack(cpr_vreg); } else if (reg_val & CPR_INT_MAX) { cpr_irq_clr_nack(cpr_vreg); } else if (reg_val & CPR_INT_MID) { /* RBCPR_CTL_SW_AUTO_CONT_ACK_EN is enabled */ cpr_debug_irq(cpr_vreg, "IRQ occurred for Mid Flag\n"); } else { cpr_debug_irq(cpr_vreg, "IRQ occurred for unknown flag (0x%08x)\n", reg_val); } /* Save register values for the corner */ cpr_corner_save(cpr_vreg, cpr_vreg->corner); _exit: mutex_unlock(&cpr_vreg->cpr_mutex); return IRQ_HANDLED; } /** * cmp_int() - int comparison function to be passed into the sort() function * which leads to ascending sorting * @a: First int value * @b: Second int value * * Return: >0 if a > b, 0 if a == b, <0 if a < b */ static int cmp_int(const void *a, const void *b) { return *(int *)a - *(int *)b; } static int cpr_get_aging_quot_delta(struct cpr_regulator *cpr_vreg, struct cpr_aging_sensor_info *aging_sensor_info) { int quot_min, quot_max, is_aging_measurement, aging_measurement_count; int quot_min_scaled, quot_max_scaled, quot_delta_scaled_sum; int retries, rc = 0, sel_fast = 0, i, quot_delta_scaled; u32 val, gcnt_ref, gcnt; int *quot_delta_results, filtered_count; quot_delta_results = kcalloc(CPR_AGING_MEASUREMENT_ITERATIONS, sizeof(*quot_delta_results), GFP_ATOMIC); if (!quot_delta_results) return -ENOMEM; /* Clear the target quotient value and gate count of all ROs */ for (i = 0; i < CPR_NUM_RING_OSC; i++) cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(i), 0); /* Program GCNT0/1 for getting aging data */ gcnt_ref = (cpr_vreg->ref_clk_khz * cpr_vreg->gcnt_time_us) / 1000; gcnt = gcnt_ref * 3 / 2; val = (gcnt & RBCPR_GCNT_TARGET_GCNT_MASK) << RBCPR_GCNT_TARGET_GCNT_SHIFT; cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(0), val); cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(1), val); val = cpr_read(cpr_vreg, REG_RBCPR_GCNT_TARGET(0)); cpr_debug(cpr_vreg, "RBCPR_GCNT_TARGET0 = 0x%08x\n", val); val = cpr_read(cpr_vreg, REG_RBCPR_GCNT_TARGET(1)); cpr_debug(cpr_vreg, "RBCPR_GCNT_TARGET1 = 0x%08x\n", val); /* Program TIMER_INTERVAL to zero */ cpr_write(cpr_vreg, REG_RBCPR_TIMER_INTERVAL, 0); /* Bypass sensors in collapsible domain */ if (cpr_vreg->aging_info->aging_sensor_bypass) cpr_write(cpr_vreg, REG_RBCPR_SENSOR_BYPASS0, (cpr_vreg->aging_info->aging_sensor_bypass & RBCPR_SENSOR_MASK0_SENSOR(aging_sensor_info->sensor_id))); /* Mask other sensors */ cpr_write(cpr_vreg, REG_RBCPR_SENSOR_MASK0, RBCPR_SENSOR_MASK0_SENSOR(aging_sensor_info->sensor_id)); val = cpr_read(cpr_vreg, REG_RBCPR_SENSOR_MASK0); cpr_debug(cpr_vreg, "RBCPR_SENSOR_MASK0 = 0x%08x\n", val); /* Enable cpr controller */ cpr_ctl_modify(cpr_vreg, RBCPR_CTL_LOOP_EN, RBCPR_CTL_LOOP_EN); /* Make sure cpr starts measurement with toggling busy bit */ mb(); /* Wait and Ignore the first measurement. Time-out after 5ms */ retries = 50; while (retries-- && cpr_ctl_is_busy(cpr_vreg)) udelay(100); if (retries < 0) { cpr_err(cpr_vreg, "Aging calibration failed\n"); rc = -EBUSY; goto _exit; } /* Set age page mode */ cpr_write(cpr_vreg, REG_RBCPR_HTOL_AGE, RBCPR_HTOL_AGE_PAGE); aging_measurement_count = 0; quot_delta_scaled_sum = 0; for (i = 0; i < CPR_AGING_MEASUREMENT_ITERATIONS; i++) { /* Send cont nack */ cpr_write(cpr_vreg, REG_RBIF_CONT_NACK_CMD, 1); /* * Make sure cpr starts next measurement with * toggling busy bit */ mb(); /* * Wait for controller to finish measurement * and time-out after 5ms */ retries = 50; while (retries-- && cpr_ctl_is_busy(cpr_vreg)) udelay(100); if (retries < 0) { cpr_err(cpr_vreg, "Aging calibration failed\n"); rc = -EBUSY; goto _exit; } /* Check for PAGE_IS_AGE flag in status register */ val = cpr_read(cpr_vreg, REG_RBCPR_HTOL_AGE); is_aging_measurement = val & RBCPR_AGE_DATA_STATUS; val = cpr_read(cpr_vreg, REG_RBCPR_RESULT_1); sel_fast = RBCPR_RESULT_1_SEL_FAST(val); cpr_debug(cpr_vreg, "RBCPR_RESULT_1 = 0x%08x\n", val); val = cpr_read(cpr_vreg, REG_RBCPR_DEBUG1); cpr_debug(cpr_vreg, "RBCPR_DEBUG1 = 0x%08x\n", val); if (sel_fast == 1) { quot_min = RBCPR_DEBUG1_QUOT_FAST(val); quot_max = RBCPR_DEBUG1_QUOT_SLOW(val); } else { quot_min = RBCPR_DEBUG1_QUOT_SLOW(val); quot_max = RBCPR_DEBUG1_QUOT_FAST(val); } /* * Scale the quotients so that they are equivalent to the fused * values. This accounts for the difference in measurement * interval times. */ quot_min_scaled = quot_min * (gcnt_ref + 1) / (gcnt + 1); quot_max_scaled = quot_max * (gcnt_ref + 1) / (gcnt + 1); quot_delta_scaled = 0; if (is_aging_measurement) { quot_delta_scaled = quot_min_scaled - quot_max_scaled; quot_delta_results[aging_measurement_count++] = quot_delta_scaled; } cpr_debug(cpr_vreg, "Age sensor[%d]: measurement[%d]: page_is_age=%u quot_min = %d, quot_max = %d quot_min_scaled = %d, quot_max_scaled = %d quot_delta_scaled = %d\n", aging_sensor_info->sensor_id, i, is_aging_measurement, quot_min, quot_max, quot_min_scaled, quot_max_scaled, quot_delta_scaled); } filtered_count = aging_measurement_count - CPR_AGING_MEASUREMENT_FILTER * 2; if (filtered_count > 0) { sort(quot_delta_results, aging_measurement_count, sizeof(*quot_delta_results), cmp_int, NULL); quot_delta_scaled_sum = 0; for (i = 0; i < filtered_count; i++) quot_delta_scaled_sum += quot_delta_results[i + CPR_AGING_MEASUREMENT_FILTER]; aging_sensor_info->current_quot_diff = quot_delta_scaled_sum / filtered_count; cpr_debug(cpr_vreg, "Age sensor[%d]: average aging quotient delta = %d (count = %d)\n", aging_sensor_info->sensor_id, aging_sensor_info->current_quot_diff, filtered_count); } else { cpr_err(cpr_vreg, "%d aging measurements completed after %d iterations\n", aging_measurement_count, CPR_AGING_MEASUREMENT_ITERATIONS); rc = -EBUSY; } _exit: /* Clear age page bit */ cpr_write(cpr_vreg, REG_RBCPR_HTOL_AGE, 0x0); /* Disable the CPR controller after aging procedure */ cpr_ctl_modify(cpr_vreg, RBCPR_CTL_LOOP_EN, 0x0); /* Clear the sensor bypass */ if (cpr_vreg->aging_info->aging_sensor_bypass) cpr_write(cpr_vreg, REG_RBCPR_SENSOR_BYPASS0, 0x0); /* Unmask all sensors */ cpr_write(cpr_vreg, REG_RBCPR_SENSOR_MASK0, 0x0); /* Clear gcnt0/1 registers */ cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(0), 0x0); cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(1), 0x0); /* Program the delay count for the timer */ val = (cpr_vreg->ref_clk_khz * cpr_vreg->timer_delay_us) / 1000; cpr_write(cpr_vreg, REG_RBCPR_TIMER_INTERVAL, val); return rc; } static void cpr_de_aging_adjustment(void *data) { struct cpr_regulator *cpr_vreg = (struct cpr_regulator *)data; struct cpr_aging_info *aging_info = cpr_vreg->aging_info; struct cpr_aging_sensor_info *aging_sensor_info; int i, num_aging_sensors, retries, rc = 0; int max_quot_diff = 0, ro_sel = 0; u32 voltage_adjust, aging_voltage_adjust = 0; aging_sensor_info = aging_info->sensor_info; num_aging_sensors = aging_info->num_aging_sensors; for (i = 0; i < num_aging_sensors; i++, aging_sensor_info++) { retries = 2; while (retries--) { rc = cpr_get_aging_quot_delta(cpr_vreg, aging_sensor_info); if (!rc) break; } if (rc && retries < 0) { cpr_err(cpr_vreg, "error in age calibration: rc = %d\n", rc); aging_info->cpr_aging_error = true; return; } max_quot_diff = max(max_quot_diff, (aging_sensor_info->current_quot_diff - aging_sensor_info->initial_quot_diff)); } cpr_debug(cpr_vreg, "Max aging quot delta = %d\n", max_quot_diff); aging_voltage_adjust = DIV_ROUND_UP(max_quot_diff * 1000000, aging_info->aging_ro_kv); for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { /* Remove initial max aging adjustment */ ro_sel = cpr_vreg->cpr_fuse_ro_sel[i]; cpr_vreg->cpr_fuse_target_quot[i] -= (aging_info->cpr_ro_kv[ro_sel] * aging_info->max_aging_margin) / 1000000; aging_info->voltage_adjust[i] = 0; if (aging_voltage_adjust > 0) { /* Add required aging adjustment */ voltage_adjust = (aging_voltage_adjust * aging_info->aging_derate[i]) / 1000; voltage_adjust = min(voltage_adjust, aging_info->max_aging_margin); cpr_vreg->cpr_fuse_target_quot[i] += (aging_info->cpr_ro_kv[ro_sel] * voltage_adjust) / 1000000; aging_info->voltage_adjust[i] = voltage_adjust; } } } static int cpr_regulator_is_enabled(struct regulator_dev *rdev) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); return cpr_vreg->vreg_enabled; } static int cpr_regulator_enable(struct regulator_dev *rdev) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); int rc = 0; /* Enable dependency power before vdd_apc */ if (cpr_vreg->vdd_mx) { rc = regulator_enable(cpr_vreg->vdd_mx); if (rc) { cpr_err(cpr_vreg, "regulator_enable: vdd_mx: rc=%d\n", rc); return rc; } } rc = regulator_enable(cpr_vreg->vdd_apc); if (rc) { cpr_err(cpr_vreg, "regulator_enable: vdd_apc: rc=%d\n", rc); return rc; } mutex_lock(&cpr_vreg->cpr_mutex); cpr_vreg->vreg_enabled = true; if (cpr_is_allowed(cpr_vreg) && cpr_vreg->corner) { cpr_irq_clr(cpr_vreg); cpr_corner_restore(cpr_vreg, cpr_vreg->corner); cpr_ctl_enable(cpr_vreg, cpr_vreg->corner); } mutex_unlock(&cpr_vreg->cpr_mutex); return rc; } static int cpr_regulator_disable(struct regulator_dev *rdev) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); int rc; rc = regulator_disable(cpr_vreg->vdd_apc); if (!rc) { if (cpr_vreg->vdd_mx) rc = regulator_disable(cpr_vreg->vdd_mx); if (rc) { cpr_err(cpr_vreg, "regulator_disable: vdd_mx: rc=%d\n", rc); return rc; } mutex_lock(&cpr_vreg->cpr_mutex); cpr_vreg->vreg_enabled = false; if (cpr_is_allowed(cpr_vreg)) cpr_ctl_disable(cpr_vreg); mutex_unlock(&cpr_vreg->cpr_mutex); } else { cpr_err(cpr_vreg, "regulator_disable: vdd_apc: rc=%d\n", rc); } return rc; } static int cpr_calculate_de_aging_margin(struct cpr_regulator *cpr_vreg) { struct cpr_aging_info *aging_info = cpr_vreg->aging_info; enum voltage_change_dir change_dir = NO_CHANGE; u32 save_ctl, save_irq; cpumask_t tmp_mask; int rc = 0, i; save_ctl = cpr_read(cpr_vreg, REG_RBCPR_CTL); save_irq = cpr_read(cpr_vreg, REG_RBIF_IRQ_EN(cpr_vreg->irq_line)); /* Disable interrupt and CPR */ cpr_irq_set(cpr_vreg, 0); cpr_write(cpr_vreg, REG_RBCPR_CTL, 0); if (aging_info->aging_corner > cpr_vreg->corner) change_dir = UP; else if (aging_info->aging_corner < cpr_vreg->corner) change_dir = DOWN; /* set selected reference voltage for de-aging */ rc = cpr_scale_voltage(cpr_vreg, aging_info->aging_corner, aging_info->aging_ref_voltage, change_dir); if (rc) { cpr_err(cpr_vreg, "Unable to set aging reference voltage, rc = %d\n", rc); return rc; } /* Force PWM mode */ rc = regulator_set_mode(cpr_vreg->vdd_apc, REGULATOR_MODE_NORMAL); if (rc) { cpr_err(cpr_vreg, "unable to configure vdd-supply for mode=%u, rc=%d\n", REGULATOR_MODE_NORMAL, rc); return rc; } get_online_cpus(); cpumask_and(&tmp_mask, &cpr_vreg->cpu_mask, cpu_online_mask); if (!cpumask_empty(&tmp_mask)) { smp_call_function_any(&tmp_mask, cpr_de_aging_adjustment, cpr_vreg, true); aging_info->cpr_aging_done = true; if (!aging_info->cpr_aging_error) for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_info(cpr_vreg, "Corner[%d]: age adjusted target quot = %d\n", i, cpr_vreg->cpr_fuse_target_quot[i]); } put_online_cpus(); /* Set to initial mode */ rc = regulator_set_mode(cpr_vreg->vdd_apc, REGULATOR_MODE_IDLE); if (rc) { cpr_err(cpr_vreg, "unable to configure vdd-supply for mode=%u, rc=%d\n", REGULATOR_MODE_IDLE, rc); return rc; } /* Clear interrupts */ cpr_irq_clr(cpr_vreg); /* Restore register values */ cpr_irq_set(cpr_vreg, save_irq); cpr_write(cpr_vreg, REG_RBCPR_CTL, save_ctl); return rc; } /* Note that cpr_vreg->cpr_mutex must be held by the caller. */ static int cpr_regulator_set_voltage(struct regulator_dev *rdev, int corner, bool reset_quot) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); struct cpr_aging_info *aging_info = cpr_vreg->aging_info; int rc; int new_volt; enum voltage_change_dir change_dir = NO_CHANGE; int fuse_corner = cpr_vreg->corner_map[corner]; if (cpr_is_allowed(cpr_vreg)) { cpr_ctl_disable(cpr_vreg); new_volt = cpr_vreg->last_volt[corner]; } else { new_volt = cpr_vreg->open_loop_volt[corner]; } cpr_debug(cpr_vreg, "[corner:%d, fuse_corner:%d] = %d uV\n", corner, fuse_corner, new_volt); if (corner > cpr_vreg->corner) change_dir = UP; else if (corner < cpr_vreg->corner) change_dir = DOWN; /* Read age sensor data and apply de-aging adjustments */ if (cpr_vreg->vreg_enabled && aging_info && !aging_info->cpr_aging_done && (corner <= aging_info->aging_corner)) { rc = cpr_calculate_de_aging_margin(cpr_vreg); if (rc) { cpr_err(cpr_vreg, "failed in de-aging calibration: rc=%d\n", rc); } else { change_dir = NO_CHANGE; if (corner > aging_info->aging_corner) change_dir = UP; else if (corner < aging_info->aging_corner) change_dir = DOWN; } reset_quot = true; } rc = cpr_scale_voltage(cpr_vreg, corner, new_volt, change_dir); if (rc) return rc; if (cpr_is_allowed(cpr_vreg) && cpr_vreg->vreg_enabled) { cpr_irq_clr(cpr_vreg); if (reset_quot) cpr_corner_restore(cpr_vreg, corner); else cpr_corner_switch(cpr_vreg, corner); cpr_ctl_enable(cpr_vreg, corner); } cpr_vreg->corner = corner; return rc; } static int cpr_regulator_set_voltage_op(struct regulator_dev *rdev, int corner, int corner_max, unsigned *selector) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); int rc; mutex_lock(&cpr_vreg->cpr_mutex); rc = cpr_regulator_set_voltage(rdev, corner, false); mutex_unlock(&cpr_vreg->cpr_mutex); return rc; } static int cpr_regulator_get_voltage(struct regulator_dev *rdev) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); return cpr_vreg->corner; } /** * cpr_regulator_list_corner_voltage() - return the ceiling voltage mapped to * the specified voltage corner * @rdev: Regulator device pointer for the cpr-regulator * @corner: Voltage corner * * This function is passed as a callback function into the regulator ops that * are registered for each cpr-regulator device. * * Return: voltage value in microvolts or -EINVAL if the corner is out of range */ static int cpr_regulator_list_corner_voltage(struct regulator_dev *rdev, int corner) { struct cpr_regulator *cpr_vreg = rdev_get_drvdata(rdev); if (corner >= CPR_CORNER_MIN && corner <= cpr_vreg->num_corners) return cpr_vreg->ceiling_volt[corner]; else return -EINVAL; } static struct regulator_ops cpr_corner_ops = { .enable = cpr_regulator_enable, .disable = cpr_regulator_disable, .is_enabled = cpr_regulator_is_enabled, .set_voltage = cpr_regulator_set_voltage_op, .get_voltage = cpr_regulator_get_voltage, .list_corner_voltage = cpr_regulator_list_corner_voltage, }; #ifdef CONFIG_PM static int cpr_suspend(struct cpr_regulator *cpr_vreg) { cpr_debug(cpr_vreg, "suspend\n"); cpr_ctl_disable(cpr_vreg); cpr_irq_clr(cpr_vreg); return 0; } static int cpr_resume(struct cpr_regulator *cpr_vreg) { cpr_debug(cpr_vreg, "resume\n"); cpr_irq_clr(cpr_vreg); cpr_ctl_enable(cpr_vreg, cpr_vreg->corner); return 0; } static int cpr_regulator_suspend(struct platform_device *pdev, pm_message_t state) { struct cpr_regulator *cpr_vreg = platform_get_drvdata(pdev); int rc = 0; mutex_lock(&cpr_vreg->cpr_mutex); if (cpr_is_allowed(cpr_vreg)) rc = cpr_suspend(cpr_vreg); cpr_vreg->is_cpr_suspended = true; mutex_unlock(&cpr_vreg->cpr_mutex); return rc; } static int cpr_regulator_resume(struct platform_device *pdev) { struct cpr_regulator *cpr_vreg = platform_get_drvdata(pdev); int rc = 0; mutex_lock(&cpr_vreg->cpr_mutex); cpr_vreg->is_cpr_suspended = false; if (cpr_is_allowed(cpr_vreg)) rc = cpr_resume(cpr_vreg); mutex_unlock(&cpr_vreg->cpr_mutex); return rc; } #else #define cpr_regulator_suspend NULL #define cpr_regulator_resume NULL #endif static int cpr_config(struct cpr_regulator *cpr_vreg, struct device *dev) { int i; u32 val, gcnt, reg; void __iomem *rbcpr_clk; int size; if (cpr_vreg->rbcpr_clk_addr) { /* Use 19.2 MHz clock for CPR. */ rbcpr_clk = ioremap(cpr_vreg->rbcpr_clk_addr, 4); if (!rbcpr_clk) { cpr_err(cpr_vreg, "Unable to map rbcpr_clk\n"); return -EINVAL; } reg = readl_relaxed(rbcpr_clk); reg &= ~RBCPR_CLK_SEL_MASK; reg |= RBCPR_CLK_SEL_19P2_MHZ & RBCPR_CLK_SEL_MASK; writel_relaxed(reg, rbcpr_clk); iounmap(rbcpr_clk); } /* Disable interrupt and CPR */ cpr_write(cpr_vreg, REG_RBIF_IRQ_EN(cpr_vreg->irq_line), 0); cpr_write(cpr_vreg, REG_RBCPR_CTL, 0); /* Program the default HW Ceiling, Floor and vlevel */ val = ((RBIF_LIMIT_CEILING_DEFAULT & RBIF_LIMIT_CEILING_MASK) << RBIF_LIMIT_CEILING_SHIFT) | (RBIF_LIMIT_FLOOR_DEFAULT & RBIF_LIMIT_FLOOR_MASK); cpr_write(cpr_vreg, REG_RBIF_LIMIT, val); cpr_write(cpr_vreg, REG_RBIF_SW_VLEVEL, RBIF_SW_VLEVEL_DEFAULT); /* Clear the target quotient value and gate count of all ROs */ for (i = 0; i < CPR_NUM_RING_OSC; i++) cpr_write(cpr_vreg, REG_RBCPR_GCNT_TARGET(i), 0); /* Init and save gcnt */ gcnt = (cpr_vreg->ref_clk_khz * cpr_vreg->gcnt_time_us) / 1000; gcnt = (gcnt & RBCPR_GCNT_TARGET_GCNT_MASK) << RBCPR_GCNT_TARGET_GCNT_SHIFT; cpr_vreg->gcnt = gcnt; /* Program the delay count for the timer */ val = (cpr_vreg->ref_clk_khz * cpr_vreg->timer_delay_us) / 1000; cpr_write(cpr_vreg, REG_RBCPR_TIMER_INTERVAL, val); cpr_info(cpr_vreg, "Timer count: 0x%0x (for %d us)\n", val, cpr_vreg->timer_delay_us); /* Program Consecutive Up & Down */ val = ((cpr_vreg->timer_cons_down & RBIF_TIMER_ADJ_CONS_DOWN_MASK) << RBIF_TIMER_ADJ_CONS_DOWN_SHIFT) | (cpr_vreg->timer_cons_up & RBIF_TIMER_ADJ_CONS_UP_MASK) | ((cpr_vreg->clamp_timer_interval & RBIF_TIMER_ADJ_CLAMP_INT_MASK) << RBIF_TIMER_ADJ_CLAMP_INT_SHIFT); cpr_write(cpr_vreg, REG_RBIF_TIMER_ADJUST, val); /* Program the control register */ cpr_vreg->up_threshold &= RBCPR_CTL_UP_THRESHOLD_MASK; cpr_vreg->down_threshold &= RBCPR_CTL_DN_THRESHOLD_MASK; val = (cpr_vreg->up_threshold << RBCPR_CTL_UP_THRESHOLD_SHIFT) | (cpr_vreg->down_threshold << RBCPR_CTL_DN_THRESHOLD_SHIFT); val |= RBCPR_CTL_TIMER_EN | RBCPR_CTL_COUNT_MODE; val |= RBCPR_CTL_SW_AUTO_CONT_ACK_EN; cpr_write(cpr_vreg, REG_RBCPR_CTL, val); cpr_irq_set(cpr_vreg, CPR_INT_DEFAULT); val = cpr_read(cpr_vreg, REG_RBCPR_VERSION); if (val <= RBCPR_VER_2) cpr_vreg->flags |= FLAGS_IGNORE_1ST_IRQ_STATUS; size = cpr_vreg->num_corners + 1; cpr_vreg->save_ctl = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); cpr_vreg->save_irq = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); if (!cpr_vreg->save_ctl || !cpr_vreg->save_irq) return -ENOMEM; for (i = 1; i < size; i++) cpr_corner_save(cpr_vreg, i); return 0; } static int cpr_fuse_is_setting_expected(struct cpr_regulator *cpr_vreg, u32 sel_array[5]) { u64 fuse_bits; u32 ret; fuse_bits = cpr_read_efuse_row(cpr_vreg, sel_array[0], sel_array[4]); ret = (fuse_bits >> sel_array[1]) & ((1 << sel_array[2]) - 1); if (ret == sel_array[3]) ret = 1; else ret = 0; cpr_info(cpr_vreg, "[row:%d] = 0x%llx @%d:%d == %d ?: %s\n", sel_array[0], fuse_bits, sel_array[1], sel_array[2], sel_array[3], (ret == 1) ? "yes" : "no"); return ret; } static int cpr_voltage_uplift_wa_inc_volt(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { u32 uplift_voltage; u32 uplift_max_volt = 0; int highest_fuse_corner = cpr_vreg->num_fuse_corners; int rc; rc = of_property_read_u32(of_node, "qcom,cpr-uplift-voltage", &uplift_voltage); if (rc < 0) { cpr_err(cpr_vreg, "cpr-uplift-voltage is missing, rc = %d", rc); return rc; } rc = of_property_read_u32(of_node, "qcom,cpr-uplift-max-volt", &uplift_max_volt); if (rc < 0) { cpr_err(cpr_vreg, "cpr-uplift-max-volt is missing, rc = %d", rc); return rc; } cpr_vreg->pvs_corner_v[highest_fuse_corner] += uplift_voltage; if (cpr_vreg->pvs_corner_v[highest_fuse_corner] > uplift_max_volt) cpr_vreg->pvs_corner_v[highest_fuse_corner] = uplift_max_volt; return rc; } static int cpr_adjust_init_voltages(struct device_node *of_node, struct cpr_regulator *cpr_vreg) { int tuple_count, tuple_match, i; u32 index; u32 volt_adjust = 0; int len = 0; int rc = 0; if (!of_find_property(of_node, "qcom,cpr-init-voltage-adjustment", &len)) { /* No initial voltage adjustment needed. */ return 0; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* * No matching index to use for initial voltage * adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_fuse_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "qcom,cpr-init-voltage-adjustment length=%d is invalid\n", len); return -EINVAL; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { index = tuple_match * cpr_vreg->num_fuse_corners + i - CPR_FUSE_CORNER_MIN; rc = of_property_read_u32_index(of_node, "qcom,cpr-init-voltage-adjustment", index, &volt_adjust); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-init-voltage-adjustment index %u, rc=%d\n", index, rc); return rc; } if (volt_adjust) { cpr_vreg->pvs_corner_v[i] += volt_adjust; cpr_info(cpr_vreg, "adjusted initial voltage[%d]: %d -> %d uV\n", i, cpr_vreg->pvs_corner_v[i] - volt_adjust, cpr_vreg->pvs_corner_v[i]); } } return rc; } /* * Property qcom,cpr-fuse-init-voltage specifies the fuse position of the * initial voltage for each fuse corner. MSB of the fuse value is a sign * bit, and the remaining bits define the steps of the offset. Each step has * units of microvolts defined in the qcom,cpr-fuse-init-voltage-step property. * The initial voltages can be calculated using the formula: * pvs_corner_v[corner] = ceiling_volt[corner] + (sign * steps * step_size_uv) */ static int cpr_pvs_per_corner_init(struct device_node *of_node, struct cpr_regulator *cpr_vreg) { u64 efuse_bits; int i, size, sign, steps, step_size_uv, rc; u32 *fuse_sel, *tmp, *ref_uv; struct property *prop; char *init_volt_str; init_volt_str = cpr_vreg->cpr_fuse_redundant ? "qcom,cpr-fuse-redun-init-voltage" : "qcom,cpr-fuse-init-voltage"; prop = of_find_property(of_node, init_volt_str, NULL); if (!prop) { cpr_err(cpr_vreg, "%s is missing\n", init_volt_str); return -EINVAL; } size = prop->length / sizeof(u32); if (size != cpr_vreg->num_fuse_corners * 4) { cpr_err(cpr_vreg, "fuse position for init voltages is invalid\n"); return -EINVAL; } fuse_sel = kzalloc(sizeof(u32) * size, GFP_KERNEL); if (!fuse_sel) { cpr_err(cpr_vreg, "memory alloc failed.\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, init_volt_str, fuse_sel, size); if (rc < 0) { cpr_err(cpr_vreg, "read cpr-fuse-init-voltage failed, rc = %d\n", rc); kfree(fuse_sel); return rc; } rc = of_property_read_u32(of_node, "qcom,cpr-init-voltage-step", &step_size_uv); if (rc < 0) { cpr_err(cpr_vreg, "read cpr-init-voltage-step failed, rc = %d\n", rc); kfree(fuse_sel); return rc; } ref_uv = kzalloc((cpr_vreg->num_fuse_corners + 1) * sizeof(*ref_uv), GFP_KERNEL); if (!ref_uv) { cpr_err(cpr_vreg, "Could not allocate memory for reference voltages\n"); kfree(fuse_sel); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,cpr-init-voltage-ref", &ref_uv[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "read qcom,cpr-init-voltage-ref failed, rc = %d\n", rc); kfree(fuse_sel); kfree(ref_uv); return rc; } tmp = fuse_sel; for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { efuse_bits = cpr_read_efuse_param(cpr_vreg, fuse_sel[0], fuse_sel[1], fuse_sel[2], fuse_sel[3]); sign = (efuse_bits & (1 << (fuse_sel[2] - 1))) ? -1 : 1; steps = efuse_bits & ((1 << (fuse_sel[2] - 1)) - 1); cpr_vreg->pvs_corner_v[i] = ref_uv[i] + sign * steps * step_size_uv; cpr_vreg->pvs_corner_v[i] = DIV_ROUND_UP( cpr_vreg->pvs_corner_v[i], cpr_vreg->step_volt) * cpr_vreg->step_volt; cpr_debug(cpr_vreg, "corner %d: sign = %d, steps = %d, volt = %d uV\n", i, sign, steps, cpr_vreg->pvs_corner_v[i]); fuse_sel += 4; } rc = cpr_adjust_init_voltages(of_node, cpr_vreg); if (rc) goto done; for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { if (cpr_vreg->pvs_corner_v[i] > cpr_vreg->fuse_ceiling_volt[i]) { cpr_info(cpr_vreg, "Warning: initial voltage[%d] %d above ceiling %d\n", i, cpr_vreg->pvs_corner_v[i], cpr_vreg->fuse_ceiling_volt[i]); cpr_vreg->pvs_corner_v[i] = cpr_vreg->fuse_ceiling_volt[i]; } else if (cpr_vreg->pvs_corner_v[i] < cpr_vreg->fuse_floor_volt[i]) { cpr_info(cpr_vreg, "Warning: initial voltage[%d] %d below floor %d\n", i, cpr_vreg->pvs_corner_v[i], cpr_vreg->fuse_floor_volt[i]); cpr_vreg->pvs_corner_v[i] = cpr_vreg->fuse_floor_volt[i]; } } done: kfree(tmp); kfree(ref_uv); return rc; } /* * A single PVS bin is stored in a fuse that's position is defined either * in the qcom,pvs-fuse-redun property or in the qcom,pvs-fuse property. * The fuse value defined in the qcom,pvs-fuse-redun-sel property is used * to pick between the primary or redudant PVS fuse position. * After the PVS bin value is read out successfully, it is used as the row * index to get initial voltages for each fuse corner from the voltage table * defined in the qcom,pvs-voltage-table property. */ static int cpr_pvs_single_bin_init(struct device_node *of_node, struct cpr_regulator *cpr_vreg) { u64 efuse_bits; u32 pvs_fuse[4], pvs_fuse_redun_sel[5]; int rc, i, stripe_size; bool redundant; size_t pvs_bins; u32 *tmp; rc = of_property_read_u32_array(of_node, "qcom,pvs-fuse-redun-sel", pvs_fuse_redun_sel, 5); if (rc < 0) { cpr_err(cpr_vreg, "pvs-fuse-redun-sel missing: rc=%d\n", rc); return rc; } redundant = cpr_fuse_is_setting_expected(cpr_vreg, pvs_fuse_redun_sel); if (redundant) { rc = of_property_read_u32_array(of_node, "qcom,pvs-fuse-redun", pvs_fuse, 4); if (rc < 0) { cpr_err(cpr_vreg, "pvs-fuse-redun missing: rc=%d\n", rc); return rc; } } else { rc = of_property_read_u32_array(of_node, "qcom,pvs-fuse", pvs_fuse, 4); if (rc < 0) { cpr_err(cpr_vreg, "pvs-fuse missing: rc=%d\n", rc); return rc; } } /* Construct PVS process # from the efuse bits */ efuse_bits = cpr_read_efuse_row(cpr_vreg, pvs_fuse[0], pvs_fuse[3]); cpr_vreg->pvs_bin = (efuse_bits >> pvs_fuse[1]) & ((1 << pvs_fuse[2]) - 1); pvs_bins = 1 << pvs_fuse[2]; stripe_size = cpr_vreg->num_fuse_corners; tmp = kzalloc(sizeof(u32) * pvs_bins * stripe_size, GFP_KERNEL); if (!tmp) { cpr_err(cpr_vreg, "memory alloc failed\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,pvs-voltage-table", tmp, pvs_bins * stripe_size); if (rc < 0) { cpr_err(cpr_vreg, "pvs-voltage-table missing: rc=%d\n", rc); kfree(tmp); return rc; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->pvs_corner_v[i] = tmp[cpr_vreg->pvs_bin * stripe_size + i - 1]; kfree(tmp); rc = cpr_adjust_init_voltages(of_node, cpr_vreg); if (rc) return rc; return 0; } /* * The function reads VDD_MX dependency parameters from device node. * Select the qcom,vdd-mx-corner-map length equal to either num_fuse_corners * or num_corners based on selected vdd-mx-vmin-method. */ static int cpr_parse_vdd_mx_parameters(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; u32 corner_map_len; int rc, len, size; rc = of_property_read_u32(of_node, "qcom,vdd-mx-vmax", &cpr_vreg->vdd_mx_vmax); if (rc < 0) { cpr_err(cpr_vreg, "vdd-mx-vmax missing: rc=%d\n", rc); return rc; } rc = of_property_read_u32(of_node, "qcom,vdd-mx-vmin-method", &cpr_vreg->vdd_mx_vmin_method); if (rc < 0) { cpr_err(cpr_vreg, "vdd-mx-vmin-method missing: rc=%d\n", rc); return rc; } if (cpr_vreg->vdd_mx_vmin_method > VDD_MX_VMIN_APC_CORNER_MAP) { cpr_err(cpr_vreg, "Invalid vdd-mx-vmin-method(%d)\n", cpr_vreg->vdd_mx_vmin_method); return -EINVAL; } switch (cpr_vreg->vdd_mx_vmin_method) { case VDD_MX_VMIN_APC_FUSE_CORNER_MAP: corner_map_len = cpr_vreg->num_fuse_corners; break; case VDD_MX_VMIN_APC_CORNER_MAP: corner_map_len = cpr_vreg->num_corners; break; default: cpr_vreg->vdd_mx_corner_map = NULL; return 0; } if (!of_find_property(of_node, "qcom,vdd-mx-corner-map", &len)) { cpr_err(cpr_vreg, "qcom,vdd-mx-corner-map missing"); return -EINVAL; } size = len / sizeof(u32); if (size != corner_map_len) { cpr_err(cpr_vreg, "qcom,vdd-mx-corner-map length=%d is invalid: required:%u\n", size, corner_map_len); return -EINVAL; } cpr_vreg->vdd_mx_corner_map = devm_kzalloc(&pdev->dev, (corner_map_len + 1) * sizeof(*cpr_vreg->vdd_mx_corner_map), GFP_KERNEL); if (!cpr_vreg->vdd_mx_corner_map) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->vdd_mx_corner_map\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,vdd-mx-corner-map", &cpr_vreg->vdd_mx_corner_map[1], corner_map_len); if (rc) cpr_err(cpr_vreg, "read qcom,vdd-mx-corner-map failed, rc = %d\n", rc); return rc; } #define MAX_CHARS_PER_INT 10 /* * The initial voltage for each fuse corner may be determined by one of two * possible styles of fuse. If qcom,cpr-fuse-init-voltage is present, then * the initial voltages are encoded in a fuse for each fuse corner. If it is * not present, then the initial voltages are all determined using a single * PVS bin fuse value. */ static int cpr_pvs_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int highest_fuse_corner = cpr_vreg->num_fuse_corners; int i, rc, pos; size_t buflen; char *buf; rc = of_property_read_u32(of_node, "qcom,cpr-apc-volt-step", &cpr_vreg->step_volt); if (rc < 0) { cpr_err(cpr_vreg, "read cpr-apc-volt-step failed, rc = %d\n", rc); return rc; } else if (cpr_vreg->step_volt == 0) { cpr_err(cpr_vreg, "apc voltage step size can't be set to 0.\n"); return -EINVAL; } if (of_find_property(of_node, "qcom,cpr-fuse-init-voltage", NULL)) { rc = cpr_pvs_per_corner_init(of_node, cpr_vreg); if (rc < 0) { cpr_err(cpr_vreg, "get pvs per corner failed, rc = %d", rc); return rc; } } else { rc = cpr_pvs_single_bin_init(of_node, cpr_vreg); if (rc < 0) { cpr_err(cpr_vreg, "get pvs from single bin failed, rc = %d", rc); return rc; } } if (cpr_vreg->flags & FLAGS_UPLIFT_QUOT_VOLT) { rc = cpr_voltage_uplift_wa_inc_volt(cpr_vreg, of_node); if (rc < 0) { cpr_err(cpr_vreg, "pvs volt uplift wa apply failed: %d", rc); return rc; } } /* * Allow the highest fuse corner's PVS voltage to define the ceiling * voltage for that corner in order to support SoC's in which variable * ceiling values are required. */ if (cpr_vreg->pvs_corner_v[highest_fuse_corner] > cpr_vreg->fuse_ceiling_volt[highest_fuse_corner]) cpr_vreg->fuse_ceiling_volt[highest_fuse_corner] = cpr_vreg->pvs_corner_v[highest_fuse_corner]; /* * Restrict all fuse corner PVS voltages based upon per corner * ceiling and floor voltages. */ for (i = CPR_FUSE_CORNER_MIN; i <= highest_fuse_corner; i++) if (cpr_vreg->pvs_corner_v[i] > cpr_vreg->fuse_ceiling_volt[i]) cpr_vreg->pvs_corner_v[i] = cpr_vreg->fuse_ceiling_volt[i]; else if (cpr_vreg->pvs_corner_v[i] < cpr_vreg->fuse_floor_volt[i]) cpr_vreg->pvs_corner_v[i] = cpr_vreg->fuse_floor_volt[i]; cpr_vreg->ceiling_max = cpr_vreg->fuse_ceiling_volt[highest_fuse_corner]; /* * Log ceiling, floor, and inital voltages since they are critical for * all CPR debugging. */ buflen = cpr_vreg->num_fuse_corners * (MAX_CHARS_PER_INT + 2) * sizeof(*buf); buf = kzalloc(buflen, GFP_KERNEL); if (buf == NULL) { cpr_err(cpr_vreg, "Could not allocate memory for corner voltage logging\n"); return 0; } for (i = CPR_FUSE_CORNER_MIN, pos = 0; i <= highest_fuse_corner; i++) pos += scnprintf(buf + pos, buflen - pos, "%u%s", cpr_vreg->pvs_corner_v[i], i < highest_fuse_corner ? " " : ""); cpr_info(cpr_vreg, "pvs voltage: [%s] uV\n", buf); for (i = CPR_FUSE_CORNER_MIN, pos = 0; i <= highest_fuse_corner; i++) pos += scnprintf(buf + pos, buflen - pos, "%d%s", cpr_vreg->fuse_ceiling_volt[i], i < highest_fuse_corner ? " " : ""); cpr_info(cpr_vreg, "ceiling voltage: [%s] uV\n", buf); for (i = CPR_FUSE_CORNER_MIN, pos = 0; i <= highest_fuse_corner; i++) pos += scnprintf(buf + pos, buflen - pos, "%d%s", cpr_vreg->fuse_floor_volt[i], i < highest_fuse_corner ? " " : ""); cpr_info(cpr_vreg, "floor voltage: [%s] uV\n", buf); kfree(buf); return 0; } #define CPR_PROP_READ_U32(cpr_vreg, of_node, cpr_property, cpr_config, rc) \ do { \ if (!rc) { \ rc = of_property_read_u32(of_node, \ "qcom," cpr_property, \ cpr_config); \ if (rc) { \ cpr_err(cpr_vreg, "Missing " #cpr_property \ ": rc = %d\n", rc); \ } \ } \ } while (0) static int cpr_apc_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int i, rc = 0; for (i = 0; i < ARRAY_SIZE(vdd_apc_name); i++) { cpr_vreg->vdd_apc = devm_regulator_get_optional(&pdev->dev, vdd_apc_name[i]); rc = PTR_RET(cpr_vreg->vdd_apc); if (!IS_ERR_OR_NULL(cpr_vreg->vdd_apc)) break; } if (rc) { if (rc != -EPROBE_DEFER) cpr_err(cpr_vreg, "devm_regulator_get: rc=%d\n", rc); return rc; } /* Check dependencies */ if (of_find_property(of_node, "vdd-mx-supply", NULL)) { cpr_vreg->vdd_mx = devm_regulator_get(&pdev->dev, "vdd-mx"); if (IS_ERR_OR_NULL(cpr_vreg->vdd_mx)) { rc = PTR_RET(cpr_vreg->vdd_mx); if (rc != -EPROBE_DEFER) cpr_err(cpr_vreg, "devm_regulator_get: vdd-mx: rc=%d\n", rc); return rc; } } return 0; } static void cpr_apc_exit(struct cpr_regulator *cpr_vreg) { if (cpr_vreg->vreg_enabled) { regulator_disable(cpr_vreg->vdd_apc); if (cpr_vreg->vdd_mx) regulator_disable(cpr_vreg->vdd_mx); } } static int cpr_voltage_uplift_wa_inc_quot(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { u32 delta_quot[3]; int rc, i; rc = of_property_read_u32_array(of_node, "qcom,cpr-uplift-quotient", delta_quot, 3); if (rc < 0) { cpr_err(cpr_vreg, "cpr-uplift-quotient is missing: %d", rc); return rc; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->cpr_fuse_target_quot[i] += delta_quot[i-1]; return rc; } static void cpr_parse_pvs_version_fuse(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { int rc; u64 fuse_bits; u32 fuse_sel[4]; rc = of_property_read_u32_array(of_node, "qcom,pvs-version-fuse-sel", fuse_sel, 4); if (!rc) { fuse_bits = cpr_read_efuse_row(cpr_vreg, fuse_sel[0], fuse_sel[3]); cpr_vreg->pvs_version = (fuse_bits >> fuse_sel[1]) & ((1 << fuse_sel[2]) - 1); cpr_info(cpr_vreg, "[row: %d]: 0x%llx, pvs_version = %d\n", fuse_sel[0], fuse_bits, cpr_vreg->pvs_version); } else { cpr_vreg->pvs_version = 0; } } /** * cpr_get_open_loop_voltage() - fill the open_loop_volt array with linearly * interpolated open-loop CPR voltage values. * @cpr_vreg: Handle to the cpr-regulator device * @dev: Device pointer for the cpr-regulator device * @corner_max: Array of length (cpr_vreg->num_fuse_corners + 1) which maps from * fuse corners to the highest virtual corner corresponding to a * given fuse corner * @freq_map: Array of length (cpr_vreg->num_corners + 1) which maps from * virtual corners to frequencies in Hz. * @maps_valid: Boolean which indicates if the values in corner_max and freq_map * are valid. If they are not valid, then the open_loop_volt * values are not interpolated. */ static int cpr_get_open_loop_voltage(struct cpr_regulator *cpr_vreg, struct device *dev, const u32 *corner_max, const u32 *freq_map, bool maps_valid) { int rc = 0; int i, j; u64 volt_high, volt_low, freq_high, freq_low, freq, temp, temp_limit; u32 *max_factor = NULL; cpr_vreg->open_loop_volt = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!cpr_vreg->open_loop_volt) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->open_loop_volt\n"); return -ENOMEM; } /* * Set open loop voltage to be equal to per-fuse-corner initial voltage * by default. This ensures that the open loop voltage is valid for * all virtual corners even if some virtual corner to frequency mappings * are missing. It also ensures that the voltage is valid for the * higher corners not utilized by a given speed-bin. */ for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) cpr_vreg->open_loop_volt[i] = cpr_vreg->pvs_corner_v[cpr_vreg->corner_map[i]]; if (!maps_valid || !corner_max || !freq_map || !of_find_property(dev->of_node, "qcom,cpr-voltage-scaling-factor-max", NULL)) { /* Not using interpolation */ return 0; } max_factor = kzalloc(sizeof(*max_factor) * (cpr_vreg->num_fuse_corners + 1), GFP_KERNEL); if (!max_factor) { cpr_err(cpr_vreg, "Could not allocate memory for max_factor array\n"); return -ENOMEM; } rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-voltage-scaling-factor-max", &max_factor[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc) { cpr_debug(cpr_vreg, "failed to read qcom,cpr-voltage-scaling-factor-max; initial voltage interpolation not possible\n"); kfree(max_factor); return 0; } for (j = CPR_FUSE_CORNER_MIN + 1; j <= cpr_vreg->num_fuse_corners; j++) { freq_high = freq_map[corner_max[j]]; freq_low = freq_map[corner_max[j - 1]]; volt_high = cpr_vreg->pvs_corner_v[j]; volt_low = cpr_vreg->pvs_corner_v[j - 1]; if (freq_high <= freq_low || volt_high <= volt_low) continue; for (i = corner_max[j - 1] + 1; i < corner_max[j]; i++) { freq = freq_map[i]; if (freq_high <= freq) continue; temp = (freq_high - freq) * (volt_high - volt_low); do_div(temp, (u32)(freq_high - freq_low)); /* * max_factor[j] has units of uV/MHz while freq values * have units of Hz. Divide by 1000000 to convert. */ temp_limit = (freq_high - freq) * max_factor[j]; do_div(temp_limit, 1000000); cpr_vreg->open_loop_volt[i] = volt_high - min(temp, temp_limit); cpr_vreg->open_loop_volt[i] = DIV_ROUND_UP(cpr_vreg->open_loop_volt[i], cpr_vreg->step_volt) * cpr_vreg->step_volt; } } kfree(max_factor); return 0; } /* * Limit the per-virtual-corner open-loop voltages using the per-virtual-corner * ceiling and floor voltage values. This must be called only after the * open_loop_volt, ceiling, and floor arrays have all been initialized. */ static int cpr_limit_open_loop_voltage(struct cpr_regulator *cpr_vreg) { int i; for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { if (cpr_vreg->open_loop_volt[i] > cpr_vreg->ceiling_volt[i]) cpr_vreg->open_loop_volt[i] = cpr_vreg->ceiling_volt[i]; else if (cpr_vreg->open_loop_volt[i] < cpr_vreg->floor_volt[i]) cpr_vreg->open_loop_volt[i] = cpr_vreg->floor_volt[i]; } return 0; } /* * Fill an OPP table for the cpr-regulator device struct with pairs of * tuples. */ static int cpr_populate_opp_table(struct cpr_regulator *cpr_vreg, struct device *dev) { int i, rc = 0; for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { rc |= dev_pm_opp_add(dev, i, cpr_vreg->open_loop_volt[i]); if (rc) cpr_debug(cpr_vreg, "could not add OPP entry <%d, %d>, rc=%d\n", i, cpr_vreg->open_loop_volt[i], rc); } if (rc) cpr_err(cpr_vreg, "adding OPP entry failed - OPP may not be enabled, rc=%d\n", rc); return 0; } /* * Conditionally reduce the per-virtual-corner ceiling voltages if certain * device tree flags are present. This must be called only after the ceiling * array has been initialized and the open_loop_volt array values have been * initialized and limited to the existing floor to ceiling voltage range. */ static int cpr_reduce_ceiling_voltage(struct cpr_regulator *cpr_vreg, struct device *dev) { bool reduce_to_fuse_open_loop, reduce_to_interpolated_open_loop; int i; reduce_to_fuse_open_loop = of_property_read_bool(dev->of_node, "qcom,cpr-init-voltage-as-ceiling"); reduce_to_interpolated_open_loop = of_property_read_bool(dev->of_node, "qcom,cpr-scaled-init-voltage-as-ceiling"); if (!reduce_to_fuse_open_loop && !reduce_to_interpolated_open_loop) return 0; for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { if (reduce_to_interpolated_open_loop && cpr_vreg->open_loop_volt[i] < cpr_vreg->ceiling_volt[i]) cpr_vreg->ceiling_volt[i] = cpr_vreg->open_loop_volt[i]; else if (reduce_to_fuse_open_loop && cpr_vreg->pvs_corner_v[cpr_vreg->corner_map[i]] < cpr_vreg->ceiling_volt[i]) cpr_vreg->ceiling_volt[i] = max((u32)cpr_vreg->floor_volt[i], cpr_vreg->pvs_corner_v[cpr_vreg->corner_map[i]]); cpr_debug(cpr_vreg, "lowered ceiling[%d] = %d uV\n", i, cpr_vreg->ceiling_volt[i]); } return 0; } static int cpr_adjust_target_quot_offsets(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int tuple_count, tuple_match, i; u32 index; u32 quot_offset_adjust = 0; int len = 0; int rc = 0; char *quot_offset_str; quot_offset_str = "qcom,cpr-quot-offset-adjustment"; if (!of_find_property(of_node, quot_offset_str, &len)) { /* No static quotient adjustment needed. */ return 0; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for quotient adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_fuse_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "%s length=%d is invalid\n", quot_offset_str, len); return -EINVAL; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { index = tuple_match * cpr_vreg->num_fuse_corners + i - CPR_FUSE_CORNER_MIN; rc = of_property_read_u32_index(of_node, quot_offset_str, index, "_offset_adjust); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", quot_offset_str, index, rc); return rc; } if (quot_offset_adjust) { cpr_vreg->fuse_quot_offset[i] += quot_offset_adjust; cpr_info(cpr_vreg, "Corner[%d]: adjusted target quot = %d\n", i, cpr_vreg->fuse_quot_offset[i]); } } return rc; } static int cpr_get_fuse_quot_offset(struct cpr_regulator *cpr_vreg, struct platform_device *pdev, struct cpr_quot_scale *quot_scale) { struct device *dev = &pdev->dev; struct property *prop; u32 *fuse_sel, *tmp, *offset_multiplier = NULL; int rc = 0, i, size, len; char *quot_offset_str; quot_offset_str = cpr_vreg->cpr_fuse_redundant ? "qcom,cpr-fuse-redun-quot-offset" : "qcom,cpr-fuse-quot-offset"; prop = of_find_property(dev->of_node, quot_offset_str, NULL); if (!prop) { cpr_debug(cpr_vreg, "%s not present\n", quot_offset_str); return 0; } else { size = prop->length / sizeof(u32); if (size != cpr_vreg->num_fuse_corners * 4) { cpr_err(cpr_vreg, "fuse position for quot offset is invalid\n"); return -EINVAL; } } fuse_sel = kzalloc(sizeof(u32) * size, GFP_KERNEL); if (!fuse_sel) { cpr_err(cpr_vreg, "memory alloc failed.\n"); return -ENOMEM; } rc = of_property_read_u32_array(dev->of_node, quot_offset_str, fuse_sel, size); if (rc < 0) { cpr_err(cpr_vreg, "read %s failed, rc = %d\n", quot_offset_str, rc); kfree(fuse_sel); return rc; } cpr_vreg->fuse_quot_offset = devm_kzalloc(dev, sizeof(u32) * (cpr_vreg->num_fuse_corners + 1), GFP_KERNEL); if (!cpr_vreg->fuse_quot_offset) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->fuse_quot_offset\n"); kfree(fuse_sel); return -ENOMEM; } if (!of_find_property(dev->of_node, "qcom,cpr-fuse-quot-offset-scale", &len)) { cpr_debug(cpr_vreg, "qcom,cpr-fuse-quot-offset-scale not present\n"); } else { if (len != cpr_vreg->num_fuse_corners * sizeof(u32)) { cpr_err(cpr_vreg, "the size of qcom,cpr-fuse-quot-offset-scale is invalid\n"); kfree(fuse_sel); return -EINVAL; } offset_multiplier = kzalloc(sizeof(*offset_multiplier) * (cpr_vreg->num_fuse_corners + 1), GFP_KERNEL); if (!offset_multiplier) { cpr_err(cpr_vreg, "memory alloc failed.\n"); kfree(fuse_sel); return -ENOMEM; } rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-fuse-quot-offset-scale", &offset_multiplier[1], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "read qcom,cpr-fuse-quot-offset-scale failed, rc = %d\n", rc); kfree(fuse_sel); goto out; } } tmp = fuse_sel; for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { cpr_vreg->fuse_quot_offset[i] = cpr_read_efuse_param(cpr_vreg, fuse_sel[0], fuse_sel[1], fuse_sel[2], fuse_sel[3]); if (offset_multiplier) cpr_vreg->fuse_quot_offset[i] *= offset_multiplier[i]; fuse_sel += 4; } rc = cpr_adjust_target_quot_offsets(pdev, cpr_vreg); kfree(tmp); out: kfree(offset_multiplier); return rc; } /* * Adjust the per-virtual-corner open loop voltage with an offset specfied by a * device-tree property. This must be called after open-loop voltage scaling. */ static int cpr_virtual_corner_voltage_adjust(struct cpr_regulator *cpr_vreg, struct device *dev) { char *prop_name = "qcom,cpr-virtual-corner-init-voltage-adjustment"; int i, rc, tuple_count, tuple_match, index, len; u32 voltage_adjust; if (!of_find_property(dev->of_node, prop_name, &len)) { cpr_debug(cpr_vreg, "%s not specified\n", prop_name); return 0; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for voltage adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "%s length=%d is invalid\n", prop_name, len); return -EINVAL; } for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { index = tuple_match * cpr_vreg->num_corners + i - CPR_CORNER_MIN; rc = of_property_read_u32_index(dev->of_node, prop_name, index, &voltage_adjust); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", prop_name, index, rc); return rc; } if (voltage_adjust) { cpr_vreg->open_loop_volt[i] += (int)voltage_adjust; cpr_info(cpr_vreg, "corner=%d adjusted open-loop voltage=%d\n", i, cpr_vreg->open_loop_volt[i]); } } return 0; } /* * Adjust the per-virtual-corner quot with an offset specfied by a * device-tree property. This must be called after the quot-scaling adjustments * are completed. */ static int cpr_virtual_corner_quot_adjust(struct cpr_regulator *cpr_vreg, struct device *dev) { char *prop_name = "qcom,cpr-virtual-corner-quotient-adjustment"; int i, rc, tuple_count, tuple_match, index, len; u32 quot_adjust; if (!of_find_property(dev->of_node, prop_name, &len)) { cpr_debug(cpr_vreg, "%s not specified\n", prop_name); return 0; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for quotient adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "%s length=%d is invalid\n", prop_name, len); return -EINVAL; } for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { index = tuple_match * cpr_vreg->num_corners + i - CPR_CORNER_MIN; rc = of_property_read_u32_index(dev->of_node, prop_name, index, "_adjust); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", prop_name, index, rc); return rc; } if (quot_adjust) { cpr_vreg->quot_adjust[i] -= (int)quot_adjust; cpr_info(cpr_vreg, "corner=%d adjusted quotient=%d\n", i, cpr_vreg->cpr_fuse_target_quot[cpr_vreg->corner_map[i]] - cpr_vreg->quot_adjust[i]); } } return 0; } /* * cpr_get_corner_quot_adjustment() -- get the quot_adjust for each corner. * * Get the virtual corner to fuse corner mapping and virtual corner to APC clock * frequency mapping from device tree. * Calculate the quotient adjustment scaling factor for those corners mapping to * all fuse corners except for the lowest one using linear interpolation. * Calculate the quotient adjustment for each of these virtual corners using the * min of the calculated scaling factor and the constant max scaling factor * defined for each fuse corner in device tree. */ static int cpr_get_corner_quot_adjustment(struct cpr_regulator *cpr_vreg, struct device *dev) { int rc = 0; int highest_fuse_corner = cpr_vreg->num_fuse_corners; int i, j, size; struct property *prop; bool corners_mapped, match_found; u32 *tmp, *freq_map = NULL; u32 corner, freq_corner; u32 *freq_max = NULL; u32 *scaling = NULL; u32 *max_factor = NULL; u32 *corner_max = NULL; bool maps_valid = false; prop = of_find_property(dev->of_node, "qcom,cpr-corner-map", NULL); if (prop) { size = prop->length / sizeof(u32); corners_mapped = true; } else { size = cpr_vreg->num_fuse_corners; corners_mapped = false; } cpr_vreg->corner_map = devm_kzalloc(dev, sizeof(int) * (size + 1), GFP_KERNEL); if (!cpr_vreg->corner_map) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->corner_map\n"); return -ENOMEM; } cpr_vreg->num_corners = size; cpr_vreg->quot_adjust = devm_kzalloc(dev, sizeof(u32) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!cpr_vreg->quot_adjust) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->quot_adjust\n"); return -ENOMEM; } if (!corners_mapped) { for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->corner_map[i] = i; goto free_arrays; } else { rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-corner-map", &cpr_vreg->corner_map[1], size); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-corner-map missing, rc = %d\n", rc); return rc; } /* * Verify that the virtual corner to fuse corner mapping is * valid. */ for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { if (cpr_vreg->corner_map[i] > cpr_vreg->num_fuse_corners || cpr_vreg->corner_map[i] < CPR_FUSE_CORNER_MIN) { cpr_err(cpr_vreg, "qcom,cpr-corner-map contains an element %d which isn't in the allowed range [%d, %d]\n", cpr_vreg->corner_map[i], CPR_FUSE_CORNER_MIN, cpr_vreg->num_fuse_corners); return -EINVAL; } } } prop = of_find_property(dev->of_node, "qcom,cpr-speed-bin-max-corners", NULL); if (!prop) { cpr_debug(cpr_vreg, "qcom,cpr-speed-bin-max-corner missing\n"); goto free_arrays; } size = prop->length / sizeof(u32); tmp = kzalloc(size * sizeof(u32), GFP_KERNEL); if (!tmp) { cpr_err(cpr_vreg, "memory alloc failed\n"); return -ENOMEM; } rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-speed-bin-max-corners", tmp, size); if (rc < 0) { kfree(tmp); cpr_err(cpr_vreg, "get cpr-speed-bin-max-corners failed, rc = %d\n", rc); return rc; } corner_max = kzalloc((cpr_vreg->num_fuse_corners + 1) * sizeof(*corner_max), GFP_KERNEL); freq_max = kzalloc((cpr_vreg->num_fuse_corners + 1) * sizeof(*freq_max), GFP_KERNEL); if (corner_max == NULL || freq_max == NULL) { cpr_err(cpr_vreg, "Could not allocate memory for quotient scaling arrays\n"); kfree(tmp); rc = -ENOMEM; goto free_arrays; } /* * Get the maximum virtual corner for each fuse corner based upon the * speed_bin and pvs_version values. */ match_found = false; for (i = 0; i < size; i += cpr_vreg->num_fuse_corners + 2) { if (tmp[i] != cpr_vreg->speed_bin && tmp[i] != FUSE_PARAM_MATCH_ANY) continue; if (tmp[i + 1] != cpr_vreg->pvs_version && tmp[i + 1] != FUSE_PARAM_MATCH_ANY) continue; for (j = CPR_FUSE_CORNER_MIN; j <= cpr_vreg->num_fuse_corners; j++) corner_max[j] = tmp[i + 2 + j - CPR_FUSE_CORNER_MIN]; match_found = true; break; } kfree(tmp); if (!match_found) { cpr_debug(cpr_vreg, "No quotient adjustment possible for speed bin=%u, pvs version=%u\n", cpr_vreg->speed_bin, cpr_vreg->pvs_version); goto free_arrays; } /* Verify that fuse corner to max virtual corner mapping is valid. */ for (i = CPR_FUSE_CORNER_MIN; i <= highest_fuse_corner; i++) { if (corner_max[i] < CPR_CORNER_MIN || corner_max[i] > cpr_vreg->num_corners) { cpr_err(cpr_vreg, "Invalid corner=%d in qcom,cpr-speed-bin-max-corners\n", corner_max[i]); goto free_arrays; } } /* * Return success if the virtual corner values read from * qcom,cpr-speed-bin-max-corners property are incorrect. This allows * the driver to continue to run without quotient scaling. */ for (i = CPR_FUSE_CORNER_MIN + 1; i <= highest_fuse_corner; i++) { if (corner_max[i] <= corner_max[i - 1]) { cpr_err(cpr_vreg, "fuse corner=%d (%u) should be larger than the fuse corner=%d (%u)\n", i, corner_max[i], i - 1, corner_max[i - 1]); goto free_arrays; } } prop = of_find_property(dev->of_node, "qcom,cpr-corner-frequency-map", NULL); if (!prop) { cpr_debug(cpr_vreg, "qcom,cpr-corner-frequency-map missing\n"); goto free_arrays; } size = prop->length / sizeof(u32); tmp = kzalloc(sizeof(u32) * size, GFP_KERNEL); if (!tmp) { cpr_err(cpr_vreg, "memory alloc failed\n"); rc = -ENOMEM; goto free_arrays; } rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-corner-frequency-map", tmp, size); if (rc < 0) { cpr_err(cpr_vreg, "get cpr-corner-frequency-map failed, rc = %d\n", rc); kfree(tmp); goto free_arrays; } freq_map = kzalloc(sizeof(u32) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!freq_map) { cpr_err(cpr_vreg, "memory alloc for freq_map failed!\n"); kfree(tmp); rc = -ENOMEM; goto free_arrays; } for (i = 0; i < size; i += 2) { corner = tmp[i]; if ((corner < 1) || (corner > cpr_vreg->num_corners)) { cpr_err(cpr_vreg, "corner should be in 1~%d range: %d\n", cpr_vreg->num_corners, corner); continue; } freq_map[corner] = tmp[i + 1]; cpr_debug(cpr_vreg, "Frequency at virtual corner %d is %d Hz.\n", corner, freq_map[corner]); } kfree(tmp); prop = of_find_property(dev->of_node, "qcom,cpr-quot-adjust-scaling-factor-max", NULL); if (!prop) { cpr_debug(cpr_vreg, "qcom,cpr-quot-adjust-scaling-factor-max missing\n"); rc = 0; goto free_arrays; } size = prop->length / sizeof(u32); if ((size != 1) && (size != cpr_vreg->num_fuse_corners)) { cpr_err(cpr_vreg, "The size of qcom,cpr-quot-adjust-scaling-factor-max should be 1 or %d\n", cpr_vreg->num_fuse_corners); rc = 0; goto free_arrays; } max_factor = kzalloc(sizeof(u32) * (cpr_vreg->num_fuse_corners + 1), GFP_KERNEL); if (!max_factor) { cpr_err(cpr_vreg, "Could not allocate memory for max_factor array\n"); rc = -ENOMEM; goto free_arrays; } /* * Leave max_factor[CPR_FUSE_CORNER_MIN ... highest_fuse_corner-1] = 0 * if cpr-quot-adjust-scaling-factor-max is a single value in order to * maintain backward compatibility. */ i = (size == cpr_vreg->num_fuse_corners) ? CPR_FUSE_CORNER_MIN : highest_fuse_corner; rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-quot-adjust-scaling-factor-max", &max_factor[i], size); if (rc < 0) { cpr_debug(cpr_vreg, "could not read qcom,cpr-quot-adjust-scaling-factor-max, rc=%d\n", rc); rc = 0; goto free_arrays; } /* * Get the quotient adjustment scaling factor, according to: * scaling = min(1000 * (QUOT(corner_N) - QUOT(corner_N-1)) * / (freq(corner_N) - freq(corner_N-1)), max_factor) * * QUOT(corner_N): quotient read from fuse for fuse corner N * QUOT(corner_N-1): quotient read from fuse for fuse corner (N - 1) * freq(corner_N): max frequency in MHz supported by fuse corner N * freq(corner_N-1): max frequency in MHz supported by fuse corner * (N - 1) */ for (i = CPR_FUSE_CORNER_MIN; i <= highest_fuse_corner; i++) freq_max[i] = freq_map[corner_max[i]]; for (i = CPR_FUSE_CORNER_MIN + 1; i <= highest_fuse_corner; i++) { if (freq_max[i] <= freq_max[i - 1] || freq_max[i - 1] == 0) { cpr_err(cpr_vreg, "fuse corner %d freq=%u should be larger than fuse corner %d freq=%u\n", i, freq_max[i], i - 1, freq_max[i - 1]); rc = -EINVAL; goto free_arrays; } } scaling = kzalloc((cpr_vreg->num_fuse_corners + 1) * sizeof(*scaling), GFP_KERNEL); if (!scaling) { cpr_err(cpr_vreg, "Could not allocate memory for scaling array\n"); rc = -ENOMEM; goto free_arrays; } /* Convert corner max frequencies from Hz to MHz. */ for (i = CPR_FUSE_CORNER_MIN; i <= highest_fuse_corner; i++) freq_max[i] /= 1000000; for (i = CPR_FUSE_CORNER_MIN + 1; i <= highest_fuse_corner; i++) { if (cpr_vreg->fuse_quot_offset && (cpr_vreg->cpr_fuse_ro_sel[i] != cpr_vreg->cpr_fuse_ro_sel[i - 1])) { scaling[i] = 1000 * cpr_vreg->fuse_quot_offset[i] / (freq_max[i] - freq_max[i - 1]); } else { scaling[i] = 1000 * (cpr_vreg->cpr_fuse_target_quot[i] - cpr_vreg->cpr_fuse_target_quot[i - 1]) / (freq_max[i] - freq_max[i - 1]); if (cpr_vreg->cpr_fuse_target_quot[i] < cpr_vreg->cpr_fuse_target_quot[i - 1]) scaling[i] = 0; } scaling[i] = min(scaling[i], max_factor[i]); cpr_info(cpr_vreg, "fuse corner %d quotient adjustment scaling factor: %d.%03d\n", i, scaling[i] / 1000, scaling[i] % 1000); } /* * Walk through the virtual corners mapped to each fuse corner * and calculate the quotient adjustment for each one using the * following formula: * quot_adjust = (freq_max - freq_corner) * scaling / 1000 * * @freq_max: max frequency in MHz supported by the fuse corner * @freq_corner: frequency in MHz corresponding to the virtual corner */ for (j = CPR_FUSE_CORNER_MIN + 1; j <= highest_fuse_corner; j++) { for (i = corner_max[j - 1] + 1; i < corner_max[j]; i++) { freq_corner = freq_map[i] / 1000000; /* MHz */ if (freq_corner > 0) { cpr_vreg->quot_adjust[i] = scaling[j] * (freq_max[j] - freq_corner) / 1000; } } } rc = cpr_virtual_corner_quot_adjust(cpr_vreg, dev); if (rc) { cpr_err(cpr_vreg, "count not adjust virtual-corner quot rc=%d\n", rc); goto free_arrays; } for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) cpr_info(cpr_vreg, "adjusted quotient[%d] = %d\n", i, cpr_vreg->cpr_fuse_target_quot[cpr_vreg->corner_map[i]] - cpr_vreg->quot_adjust[i]); maps_valid = true; free_arrays: if (!rc) { rc = cpr_get_open_loop_voltage(cpr_vreg, dev, corner_max, freq_map, maps_valid); if (rc) { cpr_err(cpr_vreg, "could not fill open loop voltage array, rc=%d\n", rc); goto free_arrays_1; } rc = cpr_virtual_corner_voltage_adjust(cpr_vreg, dev); if (rc) cpr_err(cpr_vreg, "count not adjust virtual-corner voltage rc=%d\n", rc); } free_arrays_1: kfree(max_factor); kfree(scaling); kfree(freq_map); kfree(corner_max); kfree(freq_max); return rc; } /* * Check if the redundant set of CPR fuses should be used in place of the * primary set and configure the cpr_fuse_redundant element accordingly. */ static int cpr_check_redundant(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; u32 cpr_fuse_redun_sel[5]; int rc; if (of_find_property(of_node, "qcom,cpr-fuse-redun-sel", NULL)) { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-redun-sel", cpr_fuse_redun_sel, 5); if (rc < 0) { cpr_err(cpr_vreg, "qcom,cpr-fuse-redun-sel missing: rc=%d\n", rc); return rc; } cpr_vreg->cpr_fuse_redundant = cpr_fuse_is_setting_expected(cpr_vreg, cpr_fuse_redun_sel); } else { cpr_vreg->cpr_fuse_redundant = false; } if (cpr_vreg->cpr_fuse_redundant) cpr_info(cpr_vreg, "using redundant fuse parameters\n"); return 0; } static int cpr_read_fuse_revision(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; u32 fuse_sel[4]; int rc; if (of_find_property(of_node, "qcom,cpr-fuse-revision", NULL)) { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-revision", fuse_sel, 4); if (rc < 0) { cpr_err(cpr_vreg, "qcom,cpr-fuse-revision read failed: rc=%d\n", rc); return rc; } cpr_vreg->cpr_fuse_revision = cpr_read_efuse_param(cpr_vreg, fuse_sel[0], fuse_sel[1], fuse_sel[2], fuse_sel[3]); cpr_info(cpr_vreg, "fuse revision = %d\n", cpr_vreg->cpr_fuse_revision); } else { cpr_vreg->cpr_fuse_revision = FUSE_REVISION_UNKNOWN; } return 0; } static int cpr_read_ro_select(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int rc = 0; u32 cpr_fuse_row[2]; char *ro_sel_str; int *bp_ro_sel; int i; bp_ro_sel = kzalloc((cpr_vreg->num_fuse_corners + 1) * sizeof(*bp_ro_sel), GFP_KERNEL); if (!bp_ro_sel) { cpr_err(cpr_vreg, "could not allocate memory for temp array\n"); return -ENOMEM; } if (cpr_vreg->cpr_fuse_redundant) { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-redun-row", cpr_fuse_row, 2); ro_sel_str = "qcom,cpr-fuse-redun-ro-sel"; } else { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-row", cpr_fuse_row, 2); ro_sel_str = "qcom,cpr-fuse-ro-sel"; } if (rc) goto error; rc = of_property_read_u32_array(of_node, ro_sel_str, &bp_ro_sel[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc) { cpr_err(cpr_vreg, "%s read error, rc=%d\n", ro_sel_str, rc); goto error; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->cpr_fuse_ro_sel[i] = cpr_read_efuse_param(cpr_vreg, cpr_fuse_row[0], bp_ro_sel[i], CPR_FUSE_RO_SEL_BITS, cpr_fuse_row[1]); error: kfree(bp_ro_sel); return rc; } static int cpr_find_fuse_map_match(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int i, j, rc, tuple_size; int len = 0; u32 *tmp, val, ro; /* Specify default no match case. */ cpr_vreg->cpr_fuse_map_match = FUSE_MAP_NO_MATCH; cpr_vreg->cpr_fuse_map_count = 0; if (!of_find_property(of_node, "qcom,cpr-fuse-version-map", &len)) { /* No mapping present. */ return 0; } tuple_size = cpr_vreg->num_fuse_corners + 3; cpr_vreg->cpr_fuse_map_count = len / (sizeof(u32) * tuple_size); if (len == 0 || len % (sizeof(u32) * tuple_size)) { cpr_err(cpr_vreg, "qcom,cpr-fuse-version-map length=%d is invalid\n", len); return -EINVAL; } tmp = kzalloc(len, GFP_KERNEL); if (!tmp) { cpr_err(cpr_vreg, "could not allocate memory for temp array\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-version-map", tmp, cpr_vreg->cpr_fuse_map_count * tuple_size); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-fuse-version-map, rc=%d\n", rc); goto done; } /* * qcom,cpr-fuse-version-map tuple format: * for n == number of fuse corners */ for (i = 0; i < cpr_vreg->cpr_fuse_map_count; i++) { if (tmp[i * tuple_size] != cpr_vreg->speed_bin && tmp[i * tuple_size] != FUSE_PARAM_MATCH_ANY) continue; if (tmp[i * tuple_size + 1] != cpr_vreg->pvs_version && tmp[i * tuple_size + 1] != FUSE_PARAM_MATCH_ANY) continue; if (tmp[i * tuple_size + 2] != cpr_vreg->cpr_fuse_revision && tmp[i * tuple_size + 2] != FUSE_PARAM_MATCH_ANY) continue; for (j = 0; j < cpr_vreg->num_fuse_corners; j++) { val = tmp[i * tuple_size + 3 + j]; ro = cpr_vreg->cpr_fuse_ro_sel[j + CPR_FUSE_CORNER_MIN]; if (val != ro && val != FUSE_PARAM_MATCH_ANY) break; } if (j == cpr_vreg->num_fuse_corners) { cpr_vreg->cpr_fuse_map_match = i; break; } } if (cpr_vreg->cpr_fuse_map_match != FUSE_MAP_NO_MATCH) cpr_debug(cpr_vreg, "qcom,cpr-fuse-version-map tuple match found: %d\n", cpr_vreg->cpr_fuse_map_match); else cpr_debug(cpr_vreg, "qcom,cpr-fuse-version-map tuple match not found\n"); done: kfree(tmp); return rc; } static int cpr_minimum_quot_difference_adjustment(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int tuple_count, tuple_match; int rc, i, len = 0; u32 index, adjust_quot = 0; u32 *min_diff_quot; if (!of_find_property(of_node, "qcom,cpr-fuse-min-quot-diff", NULL)) /* No conditional adjustment needed on revised quotients. */ return 0; if (!of_find_property(of_node, "qcom,cpr-min-quot-diff-adjustment", &len)) { cpr_err(cpr_vreg, "qcom,cpr-min-quot-diff-adjustment not specified\n"); return -ENODEV; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) /* No matching index to use for quotient adjustment. */ return 0; tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_fuse_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "qcom,cpr-min-quot-diff-adjustment length=%d is invalid\n", len); return -EINVAL; } min_diff_quot = kzalloc(cpr_vreg->num_fuse_corners * sizeof(u32), GFP_KERNEL); if (!min_diff_quot) { cpr_err(cpr_vreg, "memory alloc failed\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-min-quot-diff", min_diff_quot, cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "qcom,cpr-fuse-min-quot-diff reading failed, rc = %d\n", rc); goto error; } for (i = CPR_FUSE_CORNER_MIN + 1; i <= cpr_vreg->num_fuse_corners; i++) { if ((cpr_vreg->cpr_fuse_target_quot[i] - cpr_vreg->cpr_fuse_target_quot[i - 1]) <= (int)min_diff_quot[i - CPR_FUSE_CORNER_MIN]) { index = tuple_match * cpr_vreg->num_fuse_corners + i - CPR_FUSE_CORNER_MIN; rc = of_property_read_u32_index(of_node, "qcom,cpr-min-quot-diff-adjustment", index, &adjust_quot); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-min-quot-diff-adjustment index %u, rc=%d\n", index, rc); goto error; } cpr_vreg->cpr_fuse_target_quot[i] = cpr_vreg->cpr_fuse_target_quot[i - 1] + adjust_quot; cpr_info(cpr_vreg, "Corner[%d]: revised adjusted quotient = %d\n", i, cpr_vreg->cpr_fuse_target_quot[i]); }; } error: kfree(min_diff_quot); return rc; } static int cpr_adjust_target_quots(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int tuple_count, tuple_match, i; u32 index; u32 quot_adjust = 0; int len = 0; int rc = 0; if (!of_find_property(of_node, "qcom,cpr-quotient-adjustment", &len)) { /* No static quotient adjustment needed. */ return 0; } if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for quotient adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_fuse_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "qcom,cpr-quotient-adjustment length=%d is invalid\n", len); return -EINVAL; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { index = tuple_match * cpr_vreg->num_fuse_corners + i - CPR_FUSE_CORNER_MIN; rc = of_property_read_u32_index(of_node, "qcom,cpr-quotient-adjustment", index, "_adjust); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-quotient-adjustment index %u, rc=%d\n", index, rc); return rc; } if (quot_adjust) { cpr_vreg->cpr_fuse_target_quot[i] += quot_adjust; cpr_info(cpr_vreg, "Corner[%d]: adjusted target quot = %d\n", i, cpr_vreg->cpr_fuse_target_quot[i]); } } rc = cpr_minimum_quot_difference_adjustment(pdev, cpr_vreg); if (rc) cpr_err(cpr_vreg, "failed to apply minimum quot difference rc=%d\n", rc); return rc; } static int cpr_check_allowed(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; char *allow_str = "qcom,cpr-allowed"; int rc = 0, count; int tuple_count, tuple_match; u32 allow_status; if (!of_find_property(of_node, allow_str, &count)) /* CPR is allowed for all fuse revisions. */ return 0; count /= sizeof(u32); if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) /* No matching index to use for CPR allowed. */ return 0; tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (count != tuple_count) { cpr_err(cpr_vreg, "%s count=%d is invalid\n", allow_str, count); return -EINVAL; } rc = of_property_read_u32_index(of_node, allow_str, tuple_match, &allow_status); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", allow_str, tuple_match, rc); return rc; } if (allow_status && !cpr_vreg->cpr_fuse_disable) cpr_vreg->cpr_fuse_disable = false; else cpr_vreg->cpr_fuse_disable = true; cpr_info(cpr_vreg, "CPR closed loop is %s for fuse revision %d\n", cpr_vreg->cpr_fuse_disable ? "disabled" : "enabled", cpr_vreg->cpr_fuse_revision); return rc; } static int cpr_check_de_aging_allowed(struct cpr_regulator *cpr_vreg, struct device *dev) { struct device_node *of_node = dev->of_node; char *allow_str = "qcom,cpr-de-aging-allowed"; int rc = 0, count; int tuple_count, tuple_match; u32 allow_status = 0; if (!of_find_property(of_node, allow_str, &count)) { /* CPR de-aging is not allowed for all fuse revisions. */ return allow_status; } count /= sizeof(u32); if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) /* No matching index to use for CPR de-aging allowed. */ return 0; tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (count != tuple_count) { cpr_err(cpr_vreg, "%s count=%d is invalid\n", allow_str, count); return -EINVAL; } rc = of_property_read_u32_index(of_node, allow_str, tuple_match, &allow_status); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", allow_str, tuple_match, rc); return rc; } cpr_info(cpr_vreg, "CPR de-aging is %s for fuse revision %d\n", allow_status ? "allowed" : "not allowed", cpr_vreg->cpr_fuse_revision); return allow_status; } static int cpr_aging_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; struct cpr_aging_info *aging_info; struct cpr_aging_sensor_info *sensor_info; int num_fuse_corners = cpr_vreg->num_fuse_corners; int i, rc = 0, len = 0, num_aging_sensors, ro_sel, bits; u32 *aging_sensor_id, *fuse_sel, *fuse_sel_orig; u32 sensor = 0, non_collapsible_sensor_mask = 0; u64 efuse_val; struct property *prop; if (!of_find_property(of_node, "qcom,cpr-aging-sensor-id", &len)) { /* No CPR de-aging adjustments needed */ return 0; } if (len == 0) { cpr_err(cpr_vreg, "qcom,cpr-aging-sensor-id property format is invalid\n"); return -EINVAL; } num_aging_sensors = len / sizeof(u32); cpr_debug(cpr_vreg, "No of aging sensors = %d\n", num_aging_sensors); if (cpumask_empty(&cpr_vreg->cpu_mask)) { cpr_err(cpr_vreg, "qcom,cpr-cpus property missing\n"); return -EINVAL; } rc = cpr_check_de_aging_allowed(cpr_vreg, &pdev->dev); if (rc < 0) { cpr_err(cpr_vreg, "cpr_check_de_aging_allowed failed: rc=%d\n", rc); return rc; } else if (rc == 0) { /* CPR de-aging is not allowed for the current fuse combo */ return 0; } aging_info = devm_kzalloc(&pdev->dev, sizeof(*aging_info), GFP_KERNEL); if (!aging_info) return -ENOMEM; cpr_vreg->aging_info = aging_info; aging_info->num_aging_sensors = num_aging_sensors; rc = of_property_read_u32(of_node, "qcom,cpr-aging-ref-corner", &aging_info->aging_corner); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-aging-ref-corner missing rc=%d\n", rc); return rc; } CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-aging-ref-voltage", &aging_info->aging_ref_voltage, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-max-aging-margin", &aging_info->max_aging_margin, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-aging-ro-scaling-factor", &aging_info->aging_ro_kv, rc); if (rc) return rc; /* Check for DIV by 0 error */ if (aging_info->aging_ro_kv == 0) { cpr_err(cpr_vreg, "invalid cpr-aging-ro-scaling-factor value: %u\n", aging_info->aging_ro_kv); return -EINVAL; } rc = of_property_read_u32_array(of_node, "qcom,cpr-ro-scaling-factor", aging_info->cpr_ro_kv, CPR_NUM_RING_OSC); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-ro-scaling-factor property read failed, rc = %d\n", rc); return rc; } if (of_find_property(of_node, "qcom,cpr-non-collapsible-sensors", &len)) { len = len / sizeof(u32); if (len <= 0 || len > 32) { cpr_err(cpr_vreg, "qcom,cpr-non-collapsible-sensors has an incorrect size\n"); return -EINVAL; } for (i = 0; i < len; i++) { rc = of_property_read_u32_index(of_node, "qcom,cpr-non-collapsible-sensors", i, &sensor); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-non-collapsible-sensors index %u, rc=%d\n", i, rc); return rc; } if (sensor > 31) { cpr_err(cpr_vreg, "invalid non-collapsible sensor = %u\n", sensor); return -EINVAL; } non_collapsible_sensor_mask |= BIT(sensor); } /* * Bypass the sensors in collapsible domain for * de-aging measurements */ aging_info->aging_sensor_bypass = ~(non_collapsible_sensor_mask); cpr_debug(cpr_vreg, "sensor bypass mask for aging = 0x%08x\n", aging_info->aging_sensor_bypass); } prop = of_find_property(pdev->dev.of_node, "qcom,cpr-aging-derate", NULL); if ((!prop) || (prop->length != num_fuse_corners * sizeof(u32))) { cpr_err(cpr_vreg, "qcom,cpr-aging-derate incorrectly configured\n"); return -EINVAL; } aging_sensor_id = kcalloc(num_aging_sensors, sizeof(*aging_sensor_id), GFP_KERNEL); fuse_sel = kcalloc(num_aging_sensors * 4, sizeof(*fuse_sel), GFP_KERNEL); aging_info->voltage_adjust = devm_kcalloc(&pdev->dev, num_fuse_corners + 1, sizeof(*aging_info->voltage_adjust), GFP_KERNEL); aging_info->sensor_info = devm_kcalloc(&pdev->dev, num_aging_sensors, sizeof(*aging_info->sensor_info), GFP_KERNEL); aging_info->aging_derate = devm_kcalloc(&pdev->dev, num_fuse_corners + 1, sizeof(*aging_info->aging_derate), GFP_KERNEL); if (!aging_info->aging_derate || !aging_sensor_id || !aging_info->sensor_info || !fuse_sel || !aging_info->voltage_adjust) goto err; rc = of_property_read_u32_array(of_node, "qcom,cpr-aging-sensor-id", aging_sensor_id, num_aging_sensors); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-aging-sensor-id property read failed, rc = %d\n", rc); goto err; } for (i = 0; i < num_aging_sensors; i++) if (aging_sensor_id[i] < 0 || aging_sensor_id[i] > 31) { cpr_err(cpr_vreg, "Invalid aging sensor id: %u\n", aging_sensor_id[i]); rc = -EINVAL; goto err; } rc = of_property_read_u32_array(of_node, "qcom,cpr-aging-derate", &aging_info->aging_derate[CPR_FUSE_CORNER_MIN], num_fuse_corners); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-aging-derate property read failed, rc = %d\n", rc); goto err; } rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-aging-init-quot-diff", fuse_sel, (num_aging_sensors * 4)); if (rc) { cpr_err(cpr_vreg, "qcom,cpr-fuse-aging-init-quot-diff read failed, rc = %d\n", rc); goto err; } fuse_sel_orig = fuse_sel; sensor_info = aging_info->sensor_info; for (i = 0; i < num_aging_sensors; i++, sensor_info++) { sensor_info->sensor_id = aging_sensor_id[i]; efuse_val = cpr_read_efuse_param(cpr_vreg, fuse_sel[0], fuse_sel[1], fuse_sel[2], fuse_sel[3]); bits = fuse_sel[2]; sensor_info->initial_quot_diff = ((efuse_val & BIT(bits - 1)) ? -1 : 1) * (efuse_val & (BIT(bits - 1) - 1)); cpr_debug(cpr_vreg, "Age sensor[%d] Initial quot diff = %d\n", sensor_info->sensor_id, sensor_info->initial_quot_diff); fuse_sel += 4; } /* * Add max aging margin here. This can be adjusted later in * de-aging algorithm. */ for (i = CPR_FUSE_CORNER_MIN; i <= num_fuse_corners; i++) { ro_sel = cpr_vreg->cpr_fuse_ro_sel[i]; cpr_vreg->cpr_fuse_target_quot[i] += (aging_info->cpr_ro_kv[ro_sel] * aging_info->max_aging_margin) / 1000000; aging_info->voltage_adjust[i] = aging_info->max_aging_margin; cpr_info(cpr_vreg, "Corner[%d]: age margin adjusted quotient = %d\n", i, cpr_vreg->cpr_fuse_target_quot[i]); } err: kfree(fuse_sel_orig); kfree(aging_sensor_id); return rc; } static int cpr_cpu_map_init(struct cpr_regulator *cpr_vreg, struct device *dev) { struct device_node *cpu_node; int i, cpu; if (!of_find_property(dev->of_node, "qcom,cpr-cpus", &cpr_vreg->num_adj_cpus)) { /* No adjustments based on online cores */ return 0; } cpr_vreg->num_adj_cpus /= sizeof(u32); cpr_vreg->adj_cpus = devm_kcalloc(dev, cpr_vreg->num_adj_cpus, sizeof(int), GFP_KERNEL); if (!cpr_vreg->adj_cpus) return -ENOMEM; for (i = 0; i < cpr_vreg->num_adj_cpus; i++) { cpu_node = of_parse_phandle(dev->of_node, "qcom,cpr-cpus", i); if (!cpu_node) { cpr_err(cpr_vreg, "could not find CPU node %d\n", i); return -EINVAL; } cpr_vreg->adj_cpus[i] = -1; for_each_possible_cpu(cpu) { if (of_get_cpu_node(cpu, NULL) == cpu_node) { cpr_vreg->adj_cpus[i] = cpu; cpumask_set_cpu(cpu, &cpr_vreg->cpu_mask); break; } } of_node_put(cpu_node); } return 0; } static int cpr_init_cpr_efuse(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int i, rc = 0; bool scheme_fuse_valid = false; bool disable_fuse_valid = false; char *targ_quot_str; u32 cpr_fuse_row[2]; u32 bp_cpr_disable, bp_scheme; size_t len; int *bp_target_quot; u64 fuse_bits, fuse_bits_2; u32 *target_quot_size; struct cpr_quot_scale *quot_scale; len = cpr_vreg->num_fuse_corners + 1; bp_target_quot = kzalloc(len * sizeof(*bp_target_quot), GFP_KERNEL); target_quot_size = kzalloc(len * sizeof(*target_quot_size), GFP_KERNEL); quot_scale = kzalloc(len * sizeof(*quot_scale), GFP_KERNEL); if (!bp_target_quot || !target_quot_size || !quot_scale) { cpr_err(cpr_vreg, "Could not allocate memory for fuse parsing arrays\n"); rc = -ENOMEM; goto error; } if (cpr_vreg->cpr_fuse_redundant) { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-redun-row", cpr_fuse_row, 2); targ_quot_str = "qcom,cpr-fuse-redun-target-quot"; } else { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-row", cpr_fuse_row, 2); targ_quot_str = "qcom,cpr-fuse-target-quot"; } if (rc) goto error; rc = of_property_read_u32_array(of_node, targ_quot_str, &bp_target_quot[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "missing %s: rc=%d\n", targ_quot_str, rc); goto error; } if (of_find_property(of_node, "qcom,cpr-fuse-target-quot-size", NULL)) { rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-target-quot-size", &target_quot_size[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "error while reading qcom,cpr-fuse-target-quot-size: rc=%d\n", rc); goto error; } } else { /* * Default fuse quotient parameter size to match target register * size. */ for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) target_quot_size[i] = CPR_FUSE_TARGET_QUOT_BITS; } if (of_find_property(of_node, "qcom,cpr-fuse-target-quot-scale", NULL)) { for (i = 0; i < cpr_vreg->num_fuse_corners; i++) { rc = of_property_read_u32_index(of_node, "qcom,cpr-fuse-target-quot-scale", i * 2, "_scale[i + CPR_FUSE_CORNER_MIN].offset); if (rc < 0) { cpr_err(cpr_vreg, "error while reading qcom,cpr-fuse-target-quot-scale: rc=%d\n", rc); goto error; } rc = of_property_read_u32_index(of_node, "qcom,cpr-fuse-target-quot-scale", i * 2 + 1, "_scale[i + CPR_FUSE_CORNER_MIN].multiplier); if (rc < 0) { cpr_err(cpr_vreg, "error while reading qcom,cpr-fuse-target-quot-scale: rc=%d\n", rc); goto error; } } } else { /* * In the default case, target quotients require no scaling so * use offset = 0, multiplier = 1. */ for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { quot_scale[i].offset = 0; quot_scale[i].multiplier = 1; } } /* Read the control bits of eFuse */ fuse_bits = cpr_read_efuse_row(cpr_vreg, cpr_fuse_row[0], cpr_fuse_row[1]); cpr_info(cpr_vreg, "[row:%d] = 0x%llx\n", cpr_fuse_row[0], fuse_bits); if (cpr_vreg->cpr_fuse_redundant) { if (of_find_property(of_node, "qcom,cpr-fuse-redun-bp-cpr-disable", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-redun-bp-cpr-disable", &bp_cpr_disable, rc); disable_fuse_valid = true; if (of_find_property(of_node, "qcom,cpr-fuse-redun-bp-scheme", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-redun-bp-scheme", &bp_scheme, rc); scheme_fuse_valid = true; } if (rc) goto error; fuse_bits_2 = fuse_bits; } else { u32 temp_row[2]; /* Use original fuse if no optional property */ if (of_find_property(of_node, "qcom,cpr-fuse-bp-cpr-disable", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-bp-cpr-disable", &bp_cpr_disable, rc); disable_fuse_valid = true; } if (of_find_property(of_node, "qcom,cpr-fuse-bp-scheme", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-bp-scheme", &bp_scheme, rc); scheme_fuse_valid = true; } rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-row", temp_row, 2); if (rc) goto error; fuse_bits_2 = cpr_read_efuse_row(cpr_vreg, temp_row[0], temp_row[1]); cpr_info(cpr_vreg, "[original row:%d] = 0x%llx\n", temp_row[0], fuse_bits_2); } } else { if (of_find_property(of_node, "qcom,cpr-fuse-bp-cpr-disable", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-bp-cpr-disable", &bp_cpr_disable, rc); disable_fuse_valid = true; } if (of_find_property(of_node, "qcom,cpr-fuse-bp-scheme", NULL)) { CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-fuse-bp-scheme", &bp_scheme, rc); scheme_fuse_valid = true; } if (rc) goto error; fuse_bits_2 = fuse_bits; } if (disable_fuse_valid) { cpr_vreg->cpr_fuse_disable = (fuse_bits_2 >> bp_cpr_disable) & 0x01; cpr_info(cpr_vreg, "CPR disable fuse = %d\n", cpr_vreg->cpr_fuse_disable); } else { cpr_vreg->cpr_fuse_disable = false; } if (scheme_fuse_valid) { cpr_vreg->cpr_fuse_local = (fuse_bits_2 >> bp_scheme) & 0x01; cpr_info(cpr_vreg, "local = %d\n", cpr_vreg->cpr_fuse_local); } else { cpr_vreg->cpr_fuse_local = true; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { cpr_vreg->cpr_fuse_target_quot[i] = cpr_read_efuse_param(cpr_vreg, cpr_fuse_row[0], bp_target_quot[i], target_quot_size[i], cpr_fuse_row[1]); /* Unpack the target quotient by scaling. */ cpr_vreg->cpr_fuse_target_quot[i] *= quot_scale[i].multiplier; cpr_vreg->cpr_fuse_target_quot[i] += quot_scale[i].offset; cpr_info(cpr_vreg, "Corner[%d]: ro_sel = %d, target quot = %d\n", i, cpr_vreg->cpr_fuse_ro_sel[i], cpr_vreg->cpr_fuse_target_quot[i]); } rc = cpr_cpu_map_init(cpr_vreg, &pdev->dev); if (rc) { cpr_err(cpr_vreg, "CPR cpu map init failed: rc=%d\n", rc); goto error; } rc = cpr_aging_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "CPR aging init failed: rc=%d\n", rc); goto error; } rc = cpr_adjust_target_quots(pdev, cpr_vreg); if (rc) goto error; for (i = CPR_FUSE_CORNER_MIN + 1; i <= cpr_vreg->num_fuse_corners; i++) { if (cpr_vreg->cpr_fuse_target_quot[i] < cpr_vreg->cpr_fuse_target_quot[i - 1] && cpr_vreg->cpr_fuse_ro_sel[i] == cpr_vreg->cpr_fuse_ro_sel[i - 1]) { cpr_vreg->cpr_fuse_disable = true; cpr_err(cpr_vreg, "invalid quotient values; permanently disabling CPR\n"); } } if (cpr_vreg->flags & FLAGS_UPLIFT_QUOT_VOLT) { cpr_voltage_uplift_wa_inc_quot(cpr_vreg, of_node); for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { cpr_info(cpr_vreg, "Corner[%d]: uplifted target quot = %d\n", i, cpr_vreg->cpr_fuse_target_quot[i]); } } /* * Check whether the fuse-quot-offset is defined per fuse corner. * If it is defined, use it (quot_offset) in the calculation * below for obtaining scaling factor per fuse corner. */ rc = cpr_get_fuse_quot_offset(cpr_vreg, pdev, quot_scale); if (rc < 0) goto error; rc = cpr_get_corner_quot_adjustment(cpr_vreg, &pdev->dev); if (rc) goto error; cpr_vreg->cpr_fuse_bits = fuse_bits; if (!cpr_vreg->cpr_fuse_bits) { cpr_vreg->cpr_fuse_disable = true; cpr_err(cpr_vreg, "cpr_fuse_bits == 0; permanently disabling CPR\n"); } else if (!cpr_vreg->fuse_quot_offset) { /* * Check if the target quotients for the highest two fuse * corners are too close together. */ int *quot = cpr_vreg->cpr_fuse_target_quot; int highest_fuse_corner = cpr_vreg->num_fuse_corners; u32 min_diff_quot; bool valid_fuse = true; min_diff_quot = CPR_FUSE_MIN_QUOT_DIFF; of_property_read_u32(of_node, "qcom,cpr-quot-min-diff", &min_diff_quot); if (quot[highest_fuse_corner] > quot[highest_fuse_corner - 1]) { if ((quot[highest_fuse_corner] - quot[highest_fuse_corner - 1]) <= min_diff_quot) valid_fuse = false; } else { valid_fuse = false; } if (!valid_fuse) { cpr_vreg->cpr_fuse_disable = true; cpr_err(cpr_vreg, "invalid quotient values; permanently disabling CPR\n"); } } rc = cpr_check_allowed(pdev, cpr_vreg); error: kfree(bp_target_quot); kfree(target_quot_size); kfree(quot_scale); return rc; } static int cpr_init_cpr_voltages(struct cpr_regulator *cpr_vreg, struct device *dev) { int i; int size = cpr_vreg->num_corners + 1; cpr_vreg->last_volt = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); if (!cpr_vreg->last_volt) return -EINVAL; for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) cpr_vreg->last_volt[i] = cpr_vreg->open_loop_volt[i]; return 0; } /* * This function fills the virtual_limit array with voltages read from the * prop_name device tree property if a given tuple in the property matches * the speedbin and PVS version fuses found on the chip. Otherwise, * it fills the virtual_limit_array with corresponding values from the * fuse_limit_array. */ static int cpr_fill_override_voltage(struct cpr_regulator *cpr_vreg, struct device *dev, const char *prop_name, const char *label, int *virtual_limit, int *fuse_limit) { int rc = 0; int i, j, size, pos; struct property *prop; bool match_found = false; size_t buflen; char *buf; u32 *tmp; prop = of_find_property(dev->of_node, prop_name, NULL); if (!prop) goto use_fuse_corner_limits; size = prop->length / sizeof(u32); if (size == 0 || size % (cpr_vreg->num_corners + 2)) { cpr_err(cpr_vreg, "%s property format is invalid; reusing per-fuse-corner limits\n", prop_name); goto use_fuse_corner_limits; } tmp = kzalloc(size * sizeof(u32), GFP_KERNEL); if (!tmp) { cpr_err(cpr_vreg, "memory alloc failed\n"); return -ENOMEM; } rc = of_property_read_u32_array(dev->of_node, prop_name, tmp, size); if (rc < 0) { kfree(tmp); cpr_err(cpr_vreg, "%s reading failed, rc = %d\n", prop_name, rc); return rc; } /* * Get limit voltage for each virtual corner based upon the speed_bin * and pvs_version values. */ for (i = 0; i < size; i += cpr_vreg->num_corners + 2) { if (tmp[i] != cpr_vreg->speed_bin && tmp[i] != FUSE_PARAM_MATCH_ANY) continue; if (tmp[i + 1] != cpr_vreg->pvs_version && tmp[i + 1] != FUSE_PARAM_MATCH_ANY) continue; for (j = CPR_CORNER_MIN; j <= cpr_vreg->num_corners; j++) virtual_limit[j] = tmp[i + 2 + j - CPR_FUSE_CORNER_MIN]; match_found = true; break; } kfree(tmp); if (!match_found) goto use_fuse_corner_limits; /* * Log per-virtual-corner voltage limits since they are useful for * baseline CPR debugging. */ buflen = cpr_vreg->num_corners * (MAX_CHARS_PER_INT + 2) * sizeof(*buf); buf = kzalloc(buflen, GFP_KERNEL); if (buf == NULL) { cpr_err(cpr_vreg, "Could not allocate memory for corner limit voltage logging\n"); return 0; } for (i = CPR_CORNER_MIN, pos = 0; i <= cpr_vreg->num_corners; i++) pos += scnprintf(buf + pos, buflen - pos, "%d%s", virtual_limit[i], i < cpr_vreg->num_corners ? " " : ""); cpr_info(cpr_vreg, "%s override voltage: [%s] uV\n", label, buf); kfree(buf); return rc; use_fuse_corner_limits: for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) virtual_limit[i] = fuse_limit[cpr_vreg->corner_map[i]]; return rc; } /* * This function loads per-virtual-corner ceiling and floor voltages from device * tree if their respective device tree properties are present. These limits * override those found in the per-fuse-corner arrays fuse_ceiling_volt and * fuse_floor_volt. */ static int cpr_init_ceiling_floor_override_voltages( struct cpr_regulator *cpr_vreg, struct device *dev) { int rc, i; int size = cpr_vreg->num_corners + 1; cpr_vreg->ceiling_volt = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); cpr_vreg->floor_volt = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); cpr_vreg->cpr_max_ceiling = devm_kzalloc(dev, sizeof(int) * size, GFP_KERNEL); if (!cpr_vreg->ceiling_volt || !cpr_vreg->floor_volt || !cpr_vreg->cpr_max_ceiling) return -ENOMEM; rc = cpr_fill_override_voltage(cpr_vreg, dev, "qcom,cpr-voltage-ceiling-override", "ceiling", cpr_vreg->ceiling_volt, cpr_vreg->fuse_ceiling_volt); if (rc) return rc; rc = cpr_fill_override_voltage(cpr_vreg, dev, "qcom,cpr-voltage-floor-override", "floor", cpr_vreg->floor_volt, cpr_vreg->fuse_floor_volt); if (rc) return rc; for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { if (cpr_vreg->floor_volt[i] > cpr_vreg->ceiling_volt[i]) { cpr_err(cpr_vreg, "virtual corner %d floor=%d uV > ceiling=%d uV\n", i, cpr_vreg->floor_volt[i], cpr_vreg->ceiling_volt[i]); return -EINVAL; } if (cpr_vreg->ceiling_max < cpr_vreg->ceiling_volt[i]) cpr_vreg->ceiling_max = cpr_vreg->ceiling_volt[i]; cpr_vreg->cpr_max_ceiling[i] = cpr_vreg->ceiling_volt[i]; } return rc; } /* * This function computes the per-virtual-corner floor voltages from * per-virtual-corner ceiling voltages with an offset specified by a * device-tree property. This must be called after open-loop voltage * scaling, floor_volt array loading and the ceiling voltage is * conditionally reduced to the open-loop voltage. It selects the * maximum value between the calculated floor voltage values and * the floor_volt array values and stores them in the floor_volt array. */ static int cpr_init_floor_to_ceiling_range( struct cpr_regulator *cpr_vreg, struct device *dev) { int rc, i, tuple_count, tuple_match, len, pos; u32 index, floor_volt_adjust = 0; char *prop_str, *buf; size_t buflen; prop_str = "qcom,cpr-floor-to-ceiling-max-range"; if (!of_find_property(dev->of_node, prop_str, &len)) return 0; if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* * No matching index to use for floor-to-ceiling * max range. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } if (len != cpr_vreg->num_corners * tuple_count * sizeof(u32)) { cpr_err(cpr_vreg, "%s length=%d is invalid\n", prop_str, len); return -EINVAL; } for (i = CPR_CORNER_MIN; i <= cpr_vreg->num_corners; i++) { index = tuple_match * cpr_vreg->num_corners + i - CPR_CORNER_MIN; rc = of_property_read_u32_index(dev->of_node, prop_str, index, &floor_volt_adjust); if (rc) { cpr_err(cpr_vreg, "could not read %s index %u, rc=%d\n", prop_str, index, rc); return rc; } if ((int)floor_volt_adjust >= 0) { cpr_vreg->floor_volt[i] = max(cpr_vreg->floor_volt[i], (cpr_vreg->ceiling_volt[i] - (int)floor_volt_adjust)); cpr_vreg->floor_volt[i] = DIV_ROUND_UP(cpr_vreg->floor_volt[i], cpr_vreg->step_volt) * cpr_vreg->step_volt; if (cpr_vreg->open_loop_volt[i] < cpr_vreg->floor_volt[i]) cpr_vreg->open_loop_volt[i] = cpr_vreg->floor_volt[i]; } } /* * Log per-virtual-corner voltage limits resulted after considering the * floor-to-ceiling max range since they are useful for baseline CPR * debugging. */ buflen = cpr_vreg->num_corners * (MAX_CHARS_PER_INT + 2) * sizeof(*buf); buf = kzalloc(buflen, GFP_KERNEL); if (buf == NULL) { cpr_err(cpr_vreg, "Could not allocate memory for corner limit voltage logging\n"); return 0; } for (i = CPR_CORNER_MIN, pos = 0; i <= cpr_vreg->num_corners; i++) pos += scnprintf(buf + pos, buflen - pos, "%d%s", cpr_vreg->floor_volt[i], i < cpr_vreg->num_corners ? " " : ""); cpr_info(cpr_vreg, "Final floor override voltages: [%s] uV\n", buf); kfree(buf); return 0; } static int cpr_init_step_quotient(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int len = 0; u32 step_quot[CPR_NUM_RING_OSC]; int i, rc; if (!of_find_property(of_node, "qcom,cpr-step-quotient", &len)) { cpr_err(cpr_vreg, "qcom,cpr-step-quotient property missing\n"); return -EINVAL; } if (len == sizeof(u32)) { /* Single step quotient used for all ring oscillators. */ rc = of_property_read_u32(of_node, "qcom,cpr-step-quotient", step_quot); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-step-quotient, rc=%d\n", rc); return rc; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->step_quotient[i] = step_quot[0]; } else if (len == sizeof(u32) * CPR_NUM_RING_OSC) { /* Unique step quotient used per ring oscillator. */ rc = of_property_read_u32_array(of_node, "qcom,cpr-step-quotient", step_quot, CPR_NUM_RING_OSC); if (rc) { cpr_err(cpr_vreg, "could not read qcom,cpr-step-quotient, rc=%d\n", rc); return rc; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_vreg->step_quotient[i] = step_quot[cpr_vreg->cpr_fuse_ro_sel[i]]; } else { cpr_err(cpr_vreg, "qcom,cpr-step-quotient has invalid length=%d\n", len); return -EINVAL; } for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) cpr_debug(cpr_vreg, "step_quotient[%d]=%u\n", i, cpr_vreg->step_quotient[i]); return 0; } static int cpr_init_cpr_parameters(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int rc = 0; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-ref-clk", &cpr_vreg->ref_clk_khz, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-timer-delay", &cpr_vreg->timer_delay_us, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-timer-cons-up", &cpr_vreg->timer_cons_up, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-timer-cons-down", &cpr_vreg->timer_cons_down, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-irq-line", &cpr_vreg->irq_line, rc); if (rc) return rc; rc = cpr_init_step_quotient(pdev, cpr_vreg); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-up-threshold", &cpr_vreg->up_threshold, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-down-threshold", &cpr_vreg->down_threshold, rc); if (rc) return rc; cpr_info(cpr_vreg, "up threshold = %u, down threshold = %u\n", cpr_vreg->up_threshold, cpr_vreg->down_threshold); CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-idle-clocks", &cpr_vreg->idle_clocks, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-gcnt-time", &cpr_vreg->gcnt_time_us, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "vdd-apc-step-up-limit", &cpr_vreg->vdd_apc_step_up_limit, rc); if (rc) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "vdd-apc-step-down-limit", &cpr_vreg->vdd_apc_step_down_limit, rc); if (rc) return rc; rc = of_property_read_u32(of_node, "qcom,cpr-clamp-timer-interval", &cpr_vreg->clamp_timer_interval); if (rc && rc != -EINVAL) { cpr_err(cpr_vreg, "error reading qcom,cpr-clamp-timer-interval, rc=%d\n", rc); return rc; } cpr_vreg->clamp_timer_interval = min(cpr_vreg->clamp_timer_interval, (u32)RBIF_TIMER_ADJ_CLAMP_INT_MASK); /* Init module parameter with the DT value */ cpr_vreg->enable = of_property_read_bool(of_node, "qcom,cpr-enable"); cpr_info(cpr_vreg, "CPR is %s by default.\n", cpr_vreg->enable ? "enabled" : "disabled"); return 0; } static void cpr_regulator_switch_adj_cpus(struct cpr_regulator *cpr_vreg) { cpr_vreg->last_volt = cpr_vreg->adj_cpus_last_volt [cpr_vreg->online_cpus]; cpr_vreg->save_ctl = cpr_vreg->adj_cpus_save_ctl[cpr_vreg->online_cpus]; cpr_vreg->save_irq = cpr_vreg->adj_cpus_save_irq[cpr_vreg->online_cpus]; if (cpr_vreg->adj_cpus_quot_adjust) cpr_vreg->quot_adjust = cpr_vreg->adj_cpus_quot_adjust [cpr_vreg->online_cpus]; if (cpr_vreg->adj_cpus_open_loop_volt) cpr_vreg->open_loop_volt = cpr_vreg->adj_cpus_open_loop_volt [cpr_vreg->online_cpus]; if (cpr_vreg->adj_cpus_open_loop_volt_as_ceiling) cpr_vreg->ceiling_volt = cpr_vreg->open_loop_volt; } static void cpr_regulator_set_online_cpus(struct cpr_regulator *cpr_vreg) { int i, j; cpr_vreg->online_cpus = 0; get_online_cpus(); for_each_online_cpu(i) for (j = 0; j < cpr_vreg->num_adj_cpus; j++) if (i == cpr_vreg->adj_cpus[j]) cpr_vreg->online_cpus++; put_online_cpus(); } static int cpr_regulator_cpu_callback(struct notifier_block *nb, unsigned long action, void *data) { struct cpr_regulator *cpr_vreg = container_of(nb, struct cpr_regulator, cpu_notifier); int cpu = (long)data; int prev_online_cpus, rc, i; action &= ~CPU_TASKS_FROZEN; if (action != CPU_UP_PREPARE && action != CPU_UP_CANCELED && action != CPU_DEAD) return NOTIFY_OK; mutex_lock(&cpr_vreg->cpr_mutex); if (cpr_vreg->skip_voltage_change_during_suspend && cpr_vreg->is_cpr_suspended) { /* Do nothing during system suspend/resume */ goto done; } prev_online_cpus = cpr_vreg->online_cpus; cpr_regulator_set_online_cpus(cpr_vreg); if (action == CPU_UP_PREPARE) for (i = 0; i < cpr_vreg->num_adj_cpus; i++) if (cpu == cpr_vreg->adj_cpus[i]) { cpr_vreg->online_cpus++; break; } if (cpr_vreg->online_cpus == prev_online_cpus) goto done; cpr_debug(cpr_vreg, "adjusting corner %d quotient for %d cpus\n", cpr_vreg->corner, cpr_vreg->online_cpus); cpr_regulator_switch_adj_cpus(cpr_vreg); if (cpr_vreg->corner) { rc = cpr_regulator_set_voltage(cpr_vreg->rdev, cpr_vreg->corner, true); if (rc) cpr_err(cpr_vreg, "could not update quotient, rc=%d\n", rc); } done: mutex_unlock(&cpr_vreg->cpr_mutex); return NOTIFY_OK; } static void cpr_pm_disable(struct cpr_regulator *cpr_vreg, bool disable) { u32 reg_val; if (cpr_vreg->is_cpr_suspended) return; reg_val = cpr_read(cpr_vreg, REG_RBCPR_CTL); if (disable) { /* Proceed only if CPR is enabled */ if (!(reg_val & RBCPR_CTL_LOOP_EN)) return; cpr_ctl_disable(cpr_vreg); cpr_vreg->cpr_disabled_in_pc = true; } else { /* Proceed only if CPR was disabled in PM_ENTER */ if (!cpr_vreg->cpr_disabled_in_pc) return; cpr_vreg->cpr_disabled_in_pc = false; cpr_ctl_enable(cpr_vreg, cpr_vreg->corner); } /* Make sure register write is complete */ mb(); } static int cpr_pm_callback(struct notifier_block *nb, unsigned long action, void *data) { struct cpr_regulator *cpr_vreg = container_of(nb, struct cpr_regulator, pm_notifier); if (action != CPU_PM_ENTER && action != CPU_PM_ENTER_FAILED && action != CPU_PM_EXIT) return NOTIFY_OK; switch (action) { case CPU_PM_ENTER: cpr_pm_disable(cpr_vreg, true); break; case CPU_PM_ENTER_FAILED: case CPU_PM_EXIT: cpr_pm_disable(cpr_vreg, false); break; } return NOTIFY_OK; } static int cpr_parse_adj_cpus_init_voltage(struct cpr_regulator *cpr_vreg, struct device *dev) { int rc, i, j, k, tuple_count, tuple_match, len, offset; int *temp; if (!of_find_property(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-init-voltage-adjustment", NULL)) return 0; if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for voltage adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } len = (cpr_vreg->num_adj_cpus + 1) * tuple_count * cpr_vreg->num_corners; temp = kzalloc(sizeof(int) * len, GFP_KERNEL); if (!temp) { cpr_err(cpr_vreg, "Could not allocate memory\n"); return -ENOMEM; } cpr_vreg->adj_cpus_open_loop_volt = devm_kzalloc(dev, sizeof(int *) * (cpr_vreg->num_adj_cpus + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_open_loop_volt) { cpr_err(cpr_vreg, "Could not allocate memory\n"); rc = -ENOMEM; goto done; } cpr_vreg->adj_cpus_open_loop_volt[0] = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_adj_cpus + 1) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_open_loop_volt[0]) { cpr_err(cpr_vreg, "Could not allocate memory\n"); rc = -ENOMEM; goto done; } for (i = 1; i <= cpr_vreg->num_adj_cpus; i++) cpr_vreg->adj_cpus_open_loop_volt[i] = cpr_vreg->adj_cpus_open_loop_volt[0] + i * (cpr_vreg->num_corners + 1); rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-init-voltage-adjustment", temp, len); if (rc) { cpr_err(cpr_vreg, "failed to read qcom,cpr-online-cpu-virtual-corner-init-voltage-adjustment, rc=%d\n", rc); goto done; } cpr_debug(cpr_vreg, "Open loop voltage based on number of online CPUs:\n"); offset = tuple_match * cpr_vreg->num_corners * (cpr_vreg->num_adj_cpus + 1); for (i = 0; i <= cpr_vreg->num_adj_cpus; i++) { for (j = CPR_CORNER_MIN; j <= cpr_vreg->num_corners; j++) { k = j - 1 + offset; cpr_vreg->adj_cpus_open_loop_volt[i][j] = cpr_vreg->open_loop_volt[j] + temp[k]; cpr_vreg->adj_cpus_open_loop_volt[i][j] = DIV_ROUND_UP(cpr_vreg-> adj_cpus_open_loop_volt[i][j], cpr_vreg->step_volt) * cpr_vreg->step_volt; if (cpr_vreg->adj_cpus_open_loop_volt[i][j] > cpr_vreg->ceiling_volt[j]) cpr_vreg->adj_cpus_open_loop_volt[i][j] = cpr_vreg->ceiling_volt[j]; if (cpr_vreg->adj_cpus_open_loop_volt[i][j] < cpr_vreg->floor_volt[j]) cpr_vreg->adj_cpus_open_loop_volt[i][j] = cpr_vreg->floor_volt[j]; cpr_debug(cpr_vreg, "cpus=%d, corner=%d, volt=%d\n", i, j, cpr_vreg->adj_cpus_open_loop_volt[i][j]); } offset += cpr_vreg->num_corners; } cpr_vreg->adj_cpus_open_loop_volt_as_ceiling = of_property_read_bool(dev->of_node, "qcom,cpr-online-cpu-init-voltage-as-ceiling"); done: kfree(temp); return rc; } static int cpr_parse_adj_cpus_target_quot(struct cpr_regulator *cpr_vreg, struct device *dev) { int rc, i, j, k, tuple_count, tuple_match, len, offset; int *temp; if (!of_find_property(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-quotient-adjustment", NULL)) return 0; if (cpr_vreg->cpr_fuse_map_count) { if (cpr_vreg->cpr_fuse_map_match == FUSE_MAP_NO_MATCH) { /* No matching index to use for quotient adjustment. */ return 0; } tuple_count = cpr_vreg->cpr_fuse_map_count; tuple_match = cpr_vreg->cpr_fuse_map_match; } else { tuple_count = 1; tuple_match = 0; } len = (cpr_vreg->num_adj_cpus + 1) * tuple_count * cpr_vreg->num_corners; temp = kzalloc(sizeof(int) * len, GFP_KERNEL); if (!temp) { cpr_err(cpr_vreg, "Could not allocate memory\n"); return -ENOMEM; } cpr_vreg->adj_cpus_quot_adjust = devm_kzalloc(dev, sizeof(int *) * (cpr_vreg->num_adj_cpus + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_quot_adjust) { cpr_err(cpr_vreg, "Could not allocate memory\n"); rc = -ENOMEM; goto done; } cpr_vreg->adj_cpus_quot_adjust[0] = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_adj_cpus + 1) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_quot_adjust[0]) { cpr_err(cpr_vreg, "Could not allocate memory\n"); rc = -ENOMEM; goto done; } for (i = 1; i <= cpr_vreg->num_adj_cpus; i++) cpr_vreg->adj_cpus_quot_adjust[i] = cpr_vreg->adj_cpus_quot_adjust[0] + i * (cpr_vreg->num_corners + 1); rc = of_property_read_u32_array(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-quotient-adjustment", temp, len); if (rc) { cpr_err(cpr_vreg, "failed to read qcom,cpr-online-cpu-virtual-corner-quotient-adjustment, rc=%d\n", rc); goto done; } cpr_debug(cpr_vreg, "Target quotients based on number of online CPUs:\n"); offset = tuple_match * cpr_vreg->num_corners * (cpr_vreg->num_adj_cpus + 1); for (i = 0; i <= cpr_vreg->num_adj_cpus; i++) { for (j = CPR_CORNER_MIN; j <= cpr_vreg->num_corners; j++) { k = j - 1 + offset; cpr_vreg->adj_cpus_quot_adjust[i][j] = cpr_vreg->quot_adjust[j] - temp[k]; cpr_debug(cpr_vreg, "cpus=%d, corner=%d, quot=%d\n", i, j, cpr_vreg->cpr_fuse_target_quot[ cpr_vreg->corner_map[j]] - cpr_vreg->adj_cpus_quot_adjust[i][j]); } offset += cpr_vreg->num_corners; } done: kfree(temp); return rc; } static int cpr_init_per_cpu_adjustments(struct cpr_regulator *cpr_vreg, struct device *dev) { int rc, i, j; if (!of_find_property(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-init-voltage-adjustment", NULL) && !of_find_property(dev->of_node, "qcom,cpr-online-cpu-virtual-corner-quotient-adjustment", NULL)) { /* No per-online CPU adjustment needed */ return 0; } if (!cpr_vreg->num_adj_cpus) { cpr_err(cpr_vreg, "qcom,cpr-cpus property missing\n"); return -EINVAL; } rc = cpr_parse_adj_cpus_init_voltage(cpr_vreg, dev); if (rc) { cpr_err(cpr_vreg, "cpr_parse_adj_cpus_init_voltage failed: rc =%d\n", rc); return rc; } rc = cpr_parse_adj_cpus_target_quot(cpr_vreg, dev); if (rc) { cpr_err(cpr_vreg, "cpr_parse_adj_cpus_target_quot failed: rc =%d\n", rc); return rc; } cpr_vreg->adj_cpus_last_volt = devm_kzalloc(dev, sizeof(int *) * (cpr_vreg->num_adj_cpus + 1), GFP_KERNEL); cpr_vreg->adj_cpus_save_ctl = devm_kzalloc(dev, sizeof(int *) * (cpr_vreg->num_adj_cpus + 1), GFP_KERNEL); cpr_vreg->adj_cpus_save_irq = devm_kzalloc(dev, sizeof(int *) * (cpr_vreg->num_adj_cpus + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_last_volt || !cpr_vreg->adj_cpus_save_ctl || !cpr_vreg->adj_cpus_save_irq) { cpr_err(cpr_vreg, "Could not allocate memory\n"); return -ENOMEM; } cpr_vreg->adj_cpus_last_volt[0] = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_adj_cpus + 1) * (cpr_vreg->num_corners + 1), GFP_KERNEL); cpr_vreg->adj_cpus_save_ctl[0] = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_adj_cpus + 1) * (cpr_vreg->num_corners + 1), GFP_KERNEL); cpr_vreg->adj_cpus_save_irq[0] = devm_kzalloc(dev, sizeof(int) * (cpr_vreg->num_adj_cpus + 1) * (cpr_vreg->num_corners + 1), GFP_KERNEL); if (!cpr_vreg->adj_cpus_last_volt[0] || !cpr_vreg->adj_cpus_save_ctl[0] || !cpr_vreg->adj_cpus_save_irq[0]) { cpr_err(cpr_vreg, "Could not allocate memory\n"); return -ENOMEM; } for (i = 1; i <= cpr_vreg->num_adj_cpus; i++) { j = i * (cpr_vreg->num_corners + 1); cpr_vreg->adj_cpus_last_volt[i] = cpr_vreg->adj_cpus_last_volt[0] + j; cpr_vreg->adj_cpus_save_ctl[i] = cpr_vreg->adj_cpus_save_ctl[0] + j; cpr_vreg->adj_cpus_save_irq[i] = cpr_vreg->adj_cpus_save_irq[0] + j; } for (i = 0; i <= cpr_vreg->num_adj_cpus; i++) { for (j = CPR_CORNER_MIN; j <= cpr_vreg->num_corners; j++) { cpr_vreg->adj_cpus_save_ctl[i][j] = cpr_vreg->save_ctl[j]; cpr_vreg->adj_cpus_save_irq[i][j] = cpr_vreg->save_irq[j]; cpr_vreg->adj_cpus_last_volt[i][j] = cpr_vreg->adj_cpus_open_loop_volt ? cpr_vreg->adj_cpus_open_loop_volt[i][j] : cpr_vreg->open_loop_volt[j]; } } cpr_regulator_set_online_cpus(cpr_vreg); cpr_debug(cpr_vreg, "%d cpus online\n", cpr_vreg->online_cpus); devm_kfree(dev, cpr_vreg->last_volt); devm_kfree(dev, cpr_vreg->save_ctl); devm_kfree(dev, cpr_vreg->save_irq); if (cpr_vreg->adj_cpus_quot_adjust) devm_kfree(dev, cpr_vreg->quot_adjust); if (cpr_vreg->adj_cpus_open_loop_volt) devm_kfree(dev, cpr_vreg->open_loop_volt); if (cpr_vreg->adj_cpus_open_loop_volt_as_ceiling) devm_kfree(dev, cpr_vreg->ceiling_volt); cpr_regulator_switch_adj_cpus(cpr_vreg); cpr_vreg->skip_voltage_change_during_suspend = of_property_read_bool(dev->of_node, "qcom,cpr-skip-voltage-change-during-suspend"); cpr_vreg->cpu_notifier.notifier_call = cpr_regulator_cpu_callback; register_hotcpu_notifier(&cpr_vreg->cpu_notifier); return rc; } static int cpr_init_pm_notification(struct cpr_regulator *cpr_vreg) { int rc; /* enabled only for single-core designs */ if (cpr_vreg->num_adj_cpus != 1) { pr_warn("qcom,cpr-cpus not defined or invalid %d\n", cpr_vreg->num_adj_cpus); return 0; } cpr_vreg->pm_notifier.notifier_call = cpr_pm_callback; rc = cpu_pm_register_notifier(&cpr_vreg->pm_notifier); if (rc) cpr_err(cpr_vreg, "Unable to register pm notifier rc=%d\n", rc); return rc; } static int cpr_rpm_apc_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { int rc, len = 0; struct device_node *of_node = pdev->dev.of_node; if (!of_find_property(of_node, "rpm-apc-supply", NULL)) return 0; cpr_vreg->rpm_apc_vreg = devm_regulator_get(&pdev->dev, "rpm-apc"); if (IS_ERR_OR_NULL(cpr_vreg->rpm_apc_vreg)) { rc = PTR_RET(cpr_vreg->rpm_apc_vreg); if (rc != -EPROBE_DEFER) cpr_err(cpr_vreg, "devm_regulator_get: rpm-apc: rc=%d\n", rc); return rc; } if (!of_find_property(of_node, "qcom,rpm-apc-corner-map", &len)) { cpr_err(cpr_vreg, "qcom,rpm-apc-corner-map missing:\n"); return -EINVAL; } if (len != cpr_vreg->num_corners * sizeof(u32)) { cpr_err(cpr_vreg, "qcom,rpm-apc-corner-map length=%d is invalid: required:%d\n", len, cpr_vreg->num_corners); return -EINVAL; } cpr_vreg->rpm_apc_corner_map = devm_kzalloc(&pdev->dev, (cpr_vreg->num_corners + 1) * sizeof(*cpr_vreg->rpm_apc_corner_map), GFP_KERNEL); if (!cpr_vreg->rpm_apc_corner_map) { cpr_err(cpr_vreg, "Can't allocate memory for cpr_vreg->rpm_apc_corner_map\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,rpm-apc-corner-map", &cpr_vreg->rpm_apc_corner_map[1], cpr_vreg->num_corners); if (rc) cpr_err(cpr_vreg, "read qcom,rpm-apc-corner-map failed, rc = %d\n", rc); return rc; } static int cpr_vsens_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { int rc = 0, len = 0; struct device_node *of_node = pdev->dev.of_node; if (of_find_property(of_node, "vdd-vsens-voltage-supply", NULL)) { cpr_vreg->vdd_vsens_voltage = devm_regulator_get(&pdev->dev, "vdd-vsens-voltage"); if (IS_ERR_OR_NULL(cpr_vreg->vdd_vsens_voltage)) { rc = PTR_ERR(cpr_vreg->vdd_vsens_voltage); cpr_vreg->vdd_vsens_voltage = NULL; if (rc == -EPROBE_DEFER) return rc; /* device not found */ cpr_debug(cpr_vreg, "regulator_get: vdd-vsens-voltage: rc=%d\n", rc); return 0; } } if (of_find_property(of_node, "vdd-vsens-corner-supply", NULL)) { cpr_vreg->vdd_vsens_corner = devm_regulator_get(&pdev->dev, "vdd-vsens-corner"); if (IS_ERR_OR_NULL(cpr_vreg->vdd_vsens_corner)) { rc = PTR_ERR(cpr_vreg->vdd_vsens_corner); cpr_vreg->vdd_vsens_corner = NULL; if (rc == -EPROBE_DEFER) return rc; /* device not found */ cpr_debug(cpr_vreg, "regulator_get: vdd-vsens-corner: rc=%d\n", rc); return 0; } if (!of_find_property(of_node, "qcom,vsens-corner-map", &len)) { cpr_err(cpr_vreg, "qcom,vsens-corner-map missing\n"); return -EINVAL; } if (len != cpr_vreg->num_fuse_corners * sizeof(u32)) { cpr_err(cpr_vreg, "qcom,vsens-corner-map length=%d is invalid: required:%d\n", len, cpr_vreg->num_fuse_corners); return -EINVAL; } cpr_vreg->vsens_corner_map = devm_kcalloc(&pdev->dev, (cpr_vreg->num_fuse_corners + 1), sizeof(*cpr_vreg->vsens_corner_map), GFP_KERNEL); if (!cpr_vreg->vsens_corner_map) return -ENOMEM; rc = of_property_read_u32_array(of_node, "qcom,vsens-corner-map", &cpr_vreg->vsens_corner_map[1], cpr_vreg->num_fuse_corners); if (rc) cpr_err(cpr_vreg, "read qcom,vsens-corner-map failed, rc = %d\n", rc); } return rc; } static int cpr_disable_on_temp(struct cpr_regulator *cpr_vreg, bool disable) { int rc = 0; mutex_lock(&cpr_vreg->cpr_mutex); if (cpr_vreg->cpr_fuse_disable || (cpr_vreg->cpr_thermal_disable == disable)) goto out; cpr_vreg->cpr_thermal_disable = disable; if (cpr_vreg->enable && cpr_vreg->corner) { if (disable) { cpr_debug(cpr_vreg, "Disabling CPR - below temperature threshold [%d]\n", cpr_vreg->cpr_disable_temp_threshold); /* disable CPR and force open-loop */ cpr_ctl_disable(cpr_vreg); rc = cpr_regulator_set_voltage(cpr_vreg->rdev, cpr_vreg->corner, false); if (rc < 0) cpr_err(cpr_vreg, "Failed to set voltage, rc=%d\n", rc); } else { /* enable CPR */ cpr_debug(cpr_vreg, "Enabling CPR - above temperature thresold [%d]\n", cpr_vreg->cpr_enable_temp_threshold); rc = cpr_regulator_set_voltage(cpr_vreg->rdev, cpr_vreg->corner, true); if (rc < 0) cpr_err(cpr_vreg, "Failed to set voltage, rc=%d\n", rc); } } out: mutex_unlock(&cpr_vreg->cpr_mutex); return rc; } static void tsens_threshold_notify(struct therm_threshold *tsens_cb_data) { struct threshold_info *info = tsens_cb_data->parent; struct cpr_regulator *cpr_vreg = container_of(info, struct cpr_regulator, tsens_threshold_config); int rc = 0; cpr_debug(cpr_vreg, "Triggered tsens-notification trip_type=%d for thermal_zone_id=%d\n", tsens_cb_data->trip_triggered, tsens_cb_data->sensor_id); switch (tsens_cb_data->trip_triggered) { case THERMAL_TRIP_CONFIGURABLE_HI: rc = cpr_disable_on_temp(cpr_vreg, false); if (rc < 0) cpr_err(cpr_vreg, "Failed to enable CPR, rc=%d\n", rc); break; case THERMAL_TRIP_CONFIGURABLE_LOW: rc = cpr_disable_on_temp(cpr_vreg, true); if (rc < 0) cpr_err(cpr_vreg, "Failed to disable CPR, rc=%d\n", rc); break; default: cpr_debug(cpr_vreg, "trip-type %d not supported\n", tsens_cb_data->trip_triggered); break; } rc = sensor_mgr_set_threshold(tsens_cb_data->sensor_id, tsens_cb_data->threshold); if (rc < 0) cpr_err(cpr_vreg, "Failed to set temp. threshold, rc=%d\n", rc); } static int cpr_check_tsens(struct cpr_regulator *cpr_vreg) { int rc = 0; struct tsens_device tsens_dev; unsigned long temp = 0; bool disable; if (tsens_is_ready() > 0) { tsens_dev.sensor_num = cpr_vreg->tsens_id; rc = tsens_get_temp(&tsens_dev, &temp); if (rc < 0) { cpr_err(cpr_vreg, "Faled to read tsens, rc=%d\n", rc); return rc; } disable = (int) temp <= cpr_vreg->cpr_disable_temp_threshold; rc = cpr_disable_on_temp(cpr_vreg, disable); if (rc) cpr_err(cpr_vreg, "Failed to %s CPR, rc=%d\n", disable ? "disable" : "enable", rc); } return rc; } static int cpr_thermal_init(struct cpr_regulator *cpr_vreg) { int rc; struct device_node *of_node = cpr_vreg->dev->of_node; if (!of_find_property(of_node, "qcom,cpr-thermal-sensor-id", NULL)) return 0; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-thermal-sensor-id", &cpr_vreg->tsens_id, rc); if (rc < 0) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-disable-temp-threshold", &cpr_vreg->cpr_disable_temp_threshold, rc); if (rc < 0) return rc; CPR_PROP_READ_U32(cpr_vreg, of_node, "cpr-enable-temp-threshold", &cpr_vreg->cpr_enable_temp_threshold, rc); if (rc < 0) return rc; if (cpr_vreg->cpr_disable_temp_threshold >= cpr_vreg->cpr_enable_temp_threshold) { cpr_err(cpr_vreg, "Invalid temperature threshold cpr_disable_temp[%d] >= cpr_enable_temp[%d]\n", cpr_vreg->cpr_disable_temp_threshold, cpr_vreg->cpr_enable_temp_threshold); return -EINVAL; } cpr_vreg->cpr_disable_on_temperature = true; return 0; } static int cpr_init_cpr(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct resource *res; int rc = 0; res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "rbcpr_clk"); if (res && res->start) cpr_vreg->rbcpr_clk_addr = res->start; res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "rbcpr"); if (!res || !res->start) { cpr_err(cpr_vreg, "missing rbcpr address: res=%p\n", res); return -EINVAL; } cpr_vreg->rbcpr_base = devm_ioremap(&pdev->dev, res->start, resource_size(res)); /* Init CPR configuration parameters */ rc = cpr_init_cpr_parameters(pdev, cpr_vreg); if (rc) return rc; rc = cpr_init_cpr_efuse(pdev, cpr_vreg); if (rc) return rc; /* Load per corner ceiling and floor voltages if they exist. */ rc = cpr_init_ceiling_floor_override_voltages(cpr_vreg, &pdev->dev); if (rc) return rc; /* * Limit open loop voltages based upon per corner ceiling and floor * voltages. */ rc = cpr_limit_open_loop_voltage(cpr_vreg); if (rc) return rc; /* * Fill the OPP table for this device with virtual voltage corner to * open-loop voltage pairs. */ rc = cpr_populate_opp_table(cpr_vreg, &pdev->dev); if (rc) return rc; /* Reduce the ceiling voltage if allowed. */ rc = cpr_reduce_ceiling_voltage(cpr_vreg, &pdev->dev); if (rc) return rc; /* Load CPR floor to ceiling range if exist. */ rc = cpr_init_floor_to_ceiling_range(cpr_vreg, &pdev->dev); if (rc) return rc; /* Init all voltage set points of APC regulator for CPR */ rc = cpr_init_cpr_voltages(cpr_vreg, &pdev->dev); if (rc) return rc; /* Get and Init interrupt */ cpr_vreg->cpr_irq = platform_get_irq(pdev, 0); if (!cpr_vreg->cpr_irq) { cpr_err(cpr_vreg, "missing CPR IRQ\n"); return -EINVAL; } /* Configure CPR HW but keep it disabled */ rc = cpr_config(cpr_vreg, &pdev->dev); if (rc) return rc; rc = request_threaded_irq(cpr_vreg->cpr_irq, NULL, cpr_irq_handler, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "cpr", cpr_vreg); if (rc) { cpr_err(cpr_vreg, "CPR: request irq failed for IRQ %d\n", cpr_vreg->cpr_irq); return rc; } return 0; } /* * Create a set of virtual fuse rows if optional device tree properties are * present. */ static int cpr_remap_efuse_data(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; struct property *prop; u64 fuse_param; u32 *temp; int size, rc, i, bits, in_row, in_bit, out_row, out_bit; prop = of_find_property(of_node, "qcom,fuse-remap-source", NULL); if (!prop) { /* No fuse remapping needed. */ return 0; } size = prop->length / sizeof(u32); if (size == 0 || size % 4) { cpr_err(cpr_vreg, "qcom,fuse-remap-source has invalid size=%d\n", size); return -EINVAL; } size /= 4; rc = of_property_read_u32(of_node, "qcom,fuse-remap-base-row", &cpr_vreg->remapped_row_base); if (rc) { cpr_err(cpr_vreg, "could not read qcom,fuse-remap-base-row, rc=%d\n", rc); return rc; } temp = kzalloc(sizeof(*temp) * size * 4, GFP_KERNEL); if (!temp) { cpr_err(cpr_vreg, "temp memory allocation failed\n"); return -ENOMEM; } rc = of_property_read_u32_array(of_node, "qcom,fuse-remap-source", temp, size * 4); if (rc) { cpr_err(cpr_vreg, "could not read qcom,fuse-remap-source, rc=%d\n", rc); goto done; } /* * Format of tuples in qcom,fuse-remap-source property: * */ for (i = 0, bits = 0; i < size; i++) bits += temp[i * 4 + 2]; cpr_vreg->num_remapped_rows = DIV_ROUND_UP(bits, 64); cpr_vreg->remapped_row = devm_kzalloc(&pdev->dev, sizeof(*cpr_vreg->remapped_row) * cpr_vreg->num_remapped_rows, GFP_KERNEL); if (!cpr_vreg->remapped_row) { cpr_err(cpr_vreg, "remapped_row memory allocation failed\n"); rc = -ENOMEM; goto done; } for (i = 0, out_row = 0, out_bit = 0; i < size; i++) { in_row = temp[i * 4]; in_bit = temp[i * 4 + 1]; bits = temp[i * 4 + 2]; while (bits > 64) { fuse_param = cpr_read_efuse_param(cpr_vreg, in_row, in_bit, 64, temp[i * 4 + 3]); cpr_vreg->remapped_row[out_row++] |= fuse_param << out_bit; if (out_bit > 0) cpr_vreg->remapped_row[out_row] |= fuse_param >> (64 - out_bit); bits -= 64; in_bit += 64; } fuse_param = cpr_read_efuse_param(cpr_vreg, in_row, in_bit, bits, temp[i * 4 + 3]); cpr_vreg->remapped_row[out_row] |= fuse_param << out_bit; if (bits < 64 - out_bit) { out_bit += bits; } else { out_row++; if (out_bit > 0) cpr_vreg->remapped_row[out_row] |= fuse_param >> (64 - out_bit); out_bit = bits - (64 - out_bit); } } done: kfree(temp); return rc; } static int cpr_efuse_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct resource *res; int len; res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "efuse_addr"); if (!res || !res->start) { cpr_err(cpr_vreg, "efuse_addr missing: res=%p\n", res); return -EINVAL; } cpr_vreg->efuse_addr = res->start; len = res->end - res->start + 1; cpr_info(cpr_vreg, "efuse_addr = %pa (len=0x%x)\n", &res->start, len); cpr_vreg->efuse_base = ioremap(cpr_vreg->efuse_addr, len); if (!cpr_vreg->efuse_base) { cpr_err(cpr_vreg, "Unable to map efuse_addr %pa\n", &cpr_vreg->efuse_addr); return -EINVAL; } return 0; } static void cpr_efuse_free(struct cpr_regulator *cpr_vreg) { iounmap(cpr_vreg->efuse_base); } static void cpr_parse_cond_min_volt_fuse(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { int rc; u32 fuse_sel[5]; /* * Restrict all pvs corner voltages to a minimum value of * qcom,cpr-cond-min-voltage if the fuse defined in * qcom,cpr-fuse-cond-min-volt-sel does not read back with * the expected value. */ rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-cond-min-volt-sel", fuse_sel, 5); if (!rc) { if (!cpr_fuse_is_setting_expected(cpr_vreg, fuse_sel)) cpr_vreg->flags |= FLAGS_SET_MIN_VOLTAGE; } } static void cpr_parse_speed_bin_fuse(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { int rc; u64 fuse_bits; u32 fuse_sel[4]; u32 speed_bits; rc = of_property_read_u32_array(of_node, "qcom,speed-bin-fuse-sel", fuse_sel, 4); if (!rc) { fuse_bits = cpr_read_efuse_row(cpr_vreg, fuse_sel[0], fuse_sel[3]); speed_bits = (fuse_bits >> fuse_sel[1]) & ((1 << fuse_sel[2]) - 1); cpr_info(cpr_vreg, "[row: %d]: 0x%llx, speed_bits = %d\n", fuse_sel[0], fuse_bits, speed_bits); cpr_vreg->speed_bin = speed_bits; } else { cpr_vreg->speed_bin = SPEED_BIN_NONE; } } static int cpr_voltage_uplift_enable_check(struct cpr_regulator *cpr_vreg, struct device_node *of_node) { int rc; u32 fuse_sel[5]; u32 uplift_speed_bin; rc = of_property_read_u32_array(of_node, "qcom,cpr-fuse-uplift-sel", fuse_sel, 5); if (!rc) { rc = of_property_read_u32(of_node, "qcom,cpr-uplift-speed-bin", &uplift_speed_bin); if (rc < 0) { cpr_err(cpr_vreg, "qcom,cpr-uplift-speed-bin missing\n"); return rc; } if (cpr_fuse_is_setting_expected(cpr_vreg, fuse_sel) && (uplift_speed_bin == cpr_vreg->speed_bin) && !(cpr_vreg->flags & FLAGS_SET_MIN_VOLTAGE)) { cpr_vreg->flags |= FLAGS_UPLIFT_QUOT_VOLT; } } return 0; } /* * Read in the number of fuse corners and then allocate memory for arrays that * are sized based upon the number of fuse corners. */ static int cpr_fuse_corner_array_alloc(struct device *dev, struct cpr_regulator *cpr_vreg) { int rc; size_t len; rc = of_property_read_u32(dev->of_node, "qcom,cpr-fuse-corners", &cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "qcom,cpr-fuse-corners missing: rc=%d\n", rc); return rc; } if (cpr_vreg->num_fuse_corners < CPR_FUSE_CORNER_MIN || cpr_vreg->num_fuse_corners > CPR_FUSE_CORNER_LIMIT) { cpr_err(cpr_vreg, "corner count=%d is invalid\n", cpr_vreg->num_fuse_corners); return -EINVAL; } /* * The arrays sized based on the fuse corner count ignore element 0 * in order to simplify indexing throughout the driver since min_uV = 0 * cannot be passed into a set_voltage() callback. */ len = cpr_vreg->num_fuse_corners + 1; cpr_vreg->pvs_corner_v = devm_kzalloc(dev, len * sizeof(*cpr_vreg->pvs_corner_v), GFP_KERNEL); cpr_vreg->cpr_fuse_target_quot = devm_kzalloc(dev, len * sizeof(*cpr_vreg->cpr_fuse_target_quot), GFP_KERNEL); cpr_vreg->cpr_fuse_ro_sel = devm_kzalloc(dev, len * sizeof(*cpr_vreg->cpr_fuse_ro_sel), GFP_KERNEL); cpr_vreg->fuse_ceiling_volt = devm_kzalloc(dev, len * (sizeof(*cpr_vreg->fuse_ceiling_volt)), GFP_KERNEL); cpr_vreg->fuse_floor_volt = devm_kzalloc(dev, len * (sizeof(*cpr_vreg->fuse_floor_volt)), GFP_KERNEL); cpr_vreg->step_quotient = devm_kzalloc(dev, len * sizeof(*cpr_vreg->step_quotient), GFP_KERNEL); if (cpr_vreg->pvs_corner_v == NULL || cpr_vreg->cpr_fuse_ro_sel == NULL || cpr_vreg->fuse_ceiling_volt == NULL || cpr_vreg->fuse_floor_volt == NULL || cpr_vreg->cpr_fuse_target_quot == NULL || cpr_vreg->step_quotient == NULL) { cpr_err(cpr_vreg, "Could not allocate memory for CPR arrays\n"); return -ENOMEM; } return 0; } static int cpr_voltage_plan_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { struct device_node *of_node = pdev->dev.of_node; int rc, i; u32 min_uv = 0; rc = of_property_read_u32_array(of_node, "qcom,cpr-voltage-ceiling", &cpr_vreg->fuse_ceiling_volt[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "cpr-voltage-ceiling missing: rc=%d\n", rc); return rc; } rc = of_property_read_u32_array(of_node, "qcom,cpr-voltage-floor", &cpr_vreg->fuse_floor_volt[CPR_FUSE_CORNER_MIN], cpr_vreg->num_fuse_corners); if (rc < 0) { cpr_err(cpr_vreg, "cpr-voltage-floor missing: rc=%d\n", rc); return rc; } cpr_parse_cond_min_volt_fuse(cpr_vreg, of_node); rc = cpr_voltage_uplift_enable_check(cpr_vreg, of_node); if (rc < 0) { cpr_err(cpr_vreg, "voltage uplift enable check failed, %d\n", rc); return rc; } if (cpr_vreg->flags & FLAGS_SET_MIN_VOLTAGE) { of_property_read_u32(of_node, "qcom,cpr-cond-min-voltage", &min_uv); for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) if (cpr_vreg->fuse_ceiling_volt[i] < min_uv) { cpr_vreg->fuse_ceiling_volt[i] = min_uv; cpr_vreg->fuse_floor_volt[i] = min_uv; } else if (cpr_vreg->fuse_floor_volt[i] < min_uv) { cpr_vreg->fuse_floor_volt[i] = min_uv; } } return 0; } static int cpr_mem_acc_init(struct platform_device *pdev, struct cpr_regulator *cpr_vreg) { int rc, size; struct property *prop; char *corner_map_str; if (of_find_property(pdev->dev.of_node, "mem-acc-supply", NULL)) { cpr_vreg->mem_acc_vreg = devm_regulator_get(&pdev->dev, "mem-acc"); if (IS_ERR_OR_NULL(cpr_vreg->mem_acc_vreg)) { rc = PTR_RET(cpr_vreg->mem_acc_vreg); if (rc != -EPROBE_DEFER) cpr_err(cpr_vreg, "devm_regulator_get: mem-acc: rc=%d\n", rc); return rc; } } corner_map_str = "qcom,mem-acc-corner-map"; prop = of_find_property(pdev->dev.of_node, corner_map_str, NULL); if (!prop) { corner_map_str = "qcom,cpr-corner-map"; prop = of_find_property(pdev->dev.of_node, corner_map_str, NULL); if (!prop) { cpr_err(cpr_vreg, "qcom,cpr-corner-map missing\n"); return -EINVAL; } } size = prop->length / sizeof(u32); cpr_vreg->mem_acc_corner_map = devm_kzalloc(&pdev->dev, sizeof(int) * (size + 1), GFP_KERNEL); rc = of_property_read_u32_array(pdev->dev.of_node, corner_map_str, &cpr_vreg->mem_acc_corner_map[CPR_FUSE_CORNER_MIN], size); if (rc) { cpr_err(cpr_vreg, "%s missing, rc = %d\n", corner_map_str, rc); return rc; } return 0; } #if defined(CONFIG_DEBUG_FS) static int cpr_enable_set(void *data, u64 val) { struct cpr_regulator *cpr_vreg = data; bool old_cpr_enable; mutex_lock(&cpr_vreg->cpr_mutex); old_cpr_enable = cpr_vreg->enable; cpr_vreg->enable = val; if (old_cpr_enable == cpr_vreg->enable) goto _exit; if (cpr_vreg->enable && cpr_vreg->cpr_fuse_disable) { cpr_info(cpr_vreg, "CPR permanently disabled due to fuse values\n"); cpr_vreg->enable = false; goto _exit; } cpr_debug(cpr_vreg, "%s CPR [corner=%d, fuse_corner=%d]\n", cpr_vreg->enable ? "enabling" : "disabling", cpr_vreg->corner, cpr_vreg->corner_map[cpr_vreg->corner]); if (cpr_vreg->corner) { if (cpr_vreg->enable) { cpr_ctl_disable(cpr_vreg); cpr_irq_clr(cpr_vreg); cpr_corner_restore(cpr_vreg, cpr_vreg->corner); cpr_ctl_enable(cpr_vreg, cpr_vreg->corner); } else { cpr_ctl_disable(cpr_vreg); cpr_irq_set(cpr_vreg, 0); } } _exit: mutex_unlock(&cpr_vreg->cpr_mutex); return 0; } static int cpr_enable_get(void *data, u64 *val) { struct cpr_regulator *cpr_vreg = data; *val = cpr_vreg->enable; return 0; } DEFINE_SIMPLE_ATTRIBUTE(cpr_enable_fops, cpr_enable_get, cpr_enable_set, "%llu\n"); static int cpr_get_cpr_ceiling(void *data, u64 *val) { struct cpr_regulator *cpr_vreg = data; *val = cpr_vreg->ceiling_volt[cpr_vreg->corner]; return 0; } DEFINE_SIMPLE_ATTRIBUTE(cpr_ceiling_fops, cpr_get_cpr_ceiling, NULL, "%llu\n"); static int cpr_get_cpr_floor(void *data, u64 *val) { struct cpr_regulator *cpr_vreg = data; *val = cpr_vreg->floor_volt[cpr_vreg->corner]; return 0; } DEFINE_SIMPLE_ATTRIBUTE(cpr_floor_fops, cpr_get_cpr_floor, NULL, "%llu\n"); static int cpr_get_cpr_max_ceiling(void *data, u64 *val) { struct cpr_regulator *cpr_vreg = data; *val = cpr_vreg->cpr_max_ceiling[cpr_vreg->corner]; return 0; } DEFINE_SIMPLE_ATTRIBUTE(cpr_max_ceiling_fops, cpr_get_cpr_max_ceiling, NULL, "%llu\n"); static int cpr_debug_info_open(struct inode *inode, struct file *file) { file->private_data = inode->i_private; return 0; } static ssize_t cpr_debug_info_read(struct file *file, char __user *buff, size_t count, loff_t *ppos) { struct cpr_regulator *cpr_vreg = file->private_data; char *debugfs_buf; ssize_t len, ret = 0; u32 gcnt, ro_sel, ctl, irq_status, reg, error_steps; u32 step_dn, step_up, error, error_lt0, busy; int fuse_corner; debugfs_buf = kmalloc(PAGE_SIZE, GFP_KERNEL); if (!debugfs_buf) return -ENOMEM; mutex_lock(&cpr_vreg->cpr_mutex); fuse_corner = cpr_vreg->corner_map[cpr_vreg->corner]; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "corner = %d, current_volt = %d uV\n", cpr_vreg->corner, cpr_vreg->last_volt[cpr_vreg->corner]); ret += len; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "fuse_corner = %d, current_volt = %d uV\n", fuse_corner, cpr_vreg->last_volt[cpr_vreg->corner]); ret += len; ro_sel = cpr_vreg->cpr_fuse_ro_sel[fuse_corner]; gcnt = cpr_read(cpr_vreg, REG_RBCPR_GCNT_TARGET(ro_sel)); len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "rbcpr_gcnt_target (%u) = 0x%02X\n", ro_sel, gcnt); ret += len; ctl = cpr_read(cpr_vreg, REG_RBCPR_CTL); len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "rbcpr_ctl = 0x%02X\n", ctl); ret += len; irq_status = cpr_read(cpr_vreg, REG_RBIF_IRQ_STATUS); len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "rbcpr_irq_status = 0x%02X\n", irq_status); ret += len; reg = cpr_read(cpr_vreg, REG_RBCPR_RESULT_0); len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "rbcpr_result_0 = 0x%02X\n", reg); ret += len; step_dn = reg & 0x01; step_up = (reg >> RBCPR_RESULT0_STEP_UP_SHIFT) & 0x01; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, " [step_dn = %u", step_dn); ret += len; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, ", step_up = %u", step_up); ret += len; error_steps = (reg >> RBCPR_RESULT0_ERROR_STEPS_SHIFT) & RBCPR_RESULT0_ERROR_STEPS_MASK; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, ", error_steps = %u", error_steps); ret += len; error = (reg >> RBCPR_RESULT0_ERROR_SHIFT) & RBCPR_RESULT0_ERROR_MASK; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, ", error = %u", error); ret += len; error_lt0 = (reg >> RBCPR_RESULT0_ERROR_LT0_SHIFT) & 0x01; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, ", error_lt_0 = %u", error_lt0); ret += len; busy = (reg >> RBCPR_RESULT0_BUSY_SHIFT) & 0x01; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, ", busy = %u]\n", busy); ret += len; mutex_unlock(&cpr_vreg->cpr_mutex); ret = simple_read_from_buffer(buff, count, ppos, debugfs_buf, ret); kfree(debugfs_buf); return ret; } static const struct file_operations cpr_debug_info_fops = { .open = cpr_debug_info_open, .read = cpr_debug_info_read, }; static int cpr_aging_debug_info_open(struct inode *inode, struct file *file) { file->private_data = inode->i_private; return 0; } static ssize_t cpr_aging_debug_info_read(struct file *file, char __user *buff, size_t count, loff_t *ppos) { struct cpr_regulator *cpr_vreg = file->private_data; struct cpr_aging_info *aging_info = cpr_vreg->aging_info; char *debugfs_buf; ssize_t len, ret = 0; int i; debugfs_buf = kmalloc(PAGE_SIZE, GFP_KERNEL); if (!debugfs_buf) return -ENOMEM; mutex_lock(&cpr_vreg->cpr_mutex); len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "aging_adj_volt = ["); ret += len; for (i = CPR_FUSE_CORNER_MIN; i <= cpr_vreg->num_fuse_corners; i++) { len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, " %d", aging_info->voltage_adjust[i]); ret += len; } len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, " ]uV\n"); ret += len; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "aging_measurement_done = %s\n", aging_info->cpr_aging_done ? "true" : "false"); ret += len; len = snprintf(debugfs_buf + ret, PAGE_SIZE - ret, "aging_measurement_error = %s\n", aging_info->cpr_aging_error ? "true" : "false"); ret += len; mutex_unlock(&cpr_vreg->cpr_mutex); ret = simple_read_from_buffer(buff, count, ppos, debugfs_buf, ret); kfree(debugfs_buf); return ret; } static const struct file_operations cpr_aging_debug_info_fops = { .open = cpr_aging_debug_info_open, .read = cpr_aging_debug_info_read, }; static void cpr_debugfs_init(struct cpr_regulator *cpr_vreg) { struct dentry *temp; if (IS_ERR_OR_NULL(cpr_debugfs_base)) { cpr_err(cpr_vreg, "Could not create debugfs nodes since base directory is missing\n"); return; } cpr_vreg->debugfs = debugfs_create_dir(cpr_vreg->rdesc.name, cpr_debugfs_base); if (IS_ERR_OR_NULL(cpr_vreg->debugfs)) { cpr_err(cpr_vreg, "debugfs directory creation failed\n"); return; } temp = debugfs_create_file("debug_info", S_IRUGO, cpr_vreg->debugfs, cpr_vreg, &cpr_debug_info_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "debug_info node creation failed\n"); return; } temp = debugfs_create_file("cpr_enable", S_IRUGO | S_IWUSR, cpr_vreg->debugfs, cpr_vreg, &cpr_enable_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "cpr_enable node creation failed\n"); return; } temp = debugfs_create_file("cpr_ceiling", S_IRUGO, cpr_vreg->debugfs, cpr_vreg, &cpr_ceiling_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "cpr_ceiling node creation failed\n"); return; } temp = debugfs_create_file("cpr_floor", S_IRUGO, cpr_vreg->debugfs, cpr_vreg, &cpr_floor_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "cpr_floor node creation failed\n"); return; } temp = debugfs_create_file("cpr_max_ceiling", S_IRUGO, cpr_vreg->debugfs, cpr_vreg, &cpr_max_ceiling_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "cpr_max_ceiling node creation failed\n"); return; } if (cpr_vreg->aging_info) { temp = debugfs_create_file("aging_debug_info", S_IRUGO, cpr_vreg->debugfs, cpr_vreg, &cpr_aging_debug_info_fops); if (IS_ERR_OR_NULL(temp)) { cpr_err(cpr_vreg, "aging_debug_info node creation failed\n"); return; } } } static void cpr_debugfs_remove(struct cpr_regulator *cpr_vreg) { debugfs_remove_recursive(cpr_vreg->debugfs); } static void cpr_debugfs_base_init(void) { cpr_debugfs_base = debugfs_create_dir("cpr-regulator", NULL); if (IS_ERR_OR_NULL(cpr_debugfs_base)) pr_err("cpr-regulator debugfs base directory creation failed\n"); } static void cpr_debugfs_base_remove(void) { debugfs_remove_recursive(cpr_debugfs_base); } #else static void cpr_debugfs_init(struct cpr_regulator *cpr_vreg) {} static void cpr_debugfs_remove(struct cpr_regulator *cpr_vreg) {} static void cpr_debugfs_base_init(void) {} static void cpr_debugfs_base_remove(void) {} #endif static int cpr_regulator_probe(struct platform_device *pdev) { struct regulator_config reg_config = {}; struct cpr_regulator *cpr_vreg; struct regulator_desc *rdesc; struct device *dev = &pdev->dev; struct regulator_init_data *init_data = pdev->dev.platform_data; int rc; if (!pdev->dev.of_node) { dev_err(dev, "Device tree node is missing\n"); return -EINVAL; } init_data = of_get_regulator_init_data(&pdev->dev, pdev->dev.of_node); if (!init_data) { dev_err(dev, "regulator init data is missing\n"); return -EINVAL; } else { init_data->constraints.input_uV = init_data->constraints.max_uV; init_data->constraints.valid_ops_mask |= REGULATOR_CHANGE_VOLTAGE | REGULATOR_CHANGE_STATUS; } cpr_vreg = devm_kzalloc(&pdev->dev, sizeof(struct cpr_regulator), GFP_KERNEL); if (!cpr_vreg) { dev_err(dev, "Can't allocate cpr_regulator memory\n"); return -ENOMEM; } cpr_vreg->dev = &pdev->dev; cpr_vreg->rdesc.name = init_data->constraints.name; if (cpr_vreg->rdesc.name == NULL) { dev_err(dev, "regulator-name missing\n"); return -EINVAL; } rc = cpr_fuse_corner_array_alloc(&pdev->dev, cpr_vreg); if (rc) return rc; rc = cpr_mem_acc_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "mem_acc intialization error rc=%d\n", rc); return rc; } rc = cpr_efuse_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Wrong eFuse address specified: rc=%d\n", rc); return rc; } rc = cpr_remap_efuse_data(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Could not remap fuse data: rc=%d\n", rc); return rc; } rc = cpr_check_redundant(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Could not check redundant fuse: rc=%d\n", rc); goto err_out; } rc = cpr_read_fuse_revision(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Could not read fuse revision: rc=%d\n", rc); goto err_out; } cpr_parse_speed_bin_fuse(cpr_vreg, dev->of_node); cpr_parse_pvs_version_fuse(cpr_vreg, dev->of_node); rc = cpr_read_ro_select(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Could not read RO select: rc=%d\n", rc); goto err_out; } rc = cpr_find_fuse_map_match(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Could not determine fuse mapping match: rc=%d\n", rc); goto err_out; } rc = cpr_voltage_plan_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Wrong DT parameter specified: rc=%d\n", rc); goto err_out; } rc = cpr_pvs_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Initialize PVS wrong: rc=%d\n", rc); goto err_out; } rc = cpr_vsens_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Initialize vsens configuration failed rc=%d\n", rc); return rc; } rc = cpr_apc_init(pdev, cpr_vreg); if (rc) { if (rc != -EPROBE_DEFER) cpr_err(cpr_vreg, "Initialize APC wrong: rc=%d\n", rc); goto err_out; } rc = cpr_init_cpr(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Initialize CPR failed: rc=%d\n", rc); goto err_out; } rc = cpr_rpm_apc_init(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Initialize RPM APC regulator failed rc=%d\n", rc); return rc; } rc = cpr_thermal_init(cpr_vreg); if (rc) { cpr_err(cpr_vreg, "Thermal intialization failed rc=%d\n", rc); return rc; } if (of_property_read_bool(pdev->dev.of_node, "qcom,disable-closed-loop-in-pc")) { rc = cpr_init_pm_notification(cpr_vreg); if (rc) { cpr_err(cpr_vreg, "cpr_init_pm_notification failed rc=%d\n", rc); return rc; } } /* Load per-online CPU adjustment data */ rc = cpr_init_per_cpu_adjustments(cpr_vreg, &pdev->dev); if (rc) { cpr_err(cpr_vreg, "cpr_init_per_cpu_adjustments failed: rc=%d\n", rc); goto err_out; } /* Parse dependency parameters */ if (cpr_vreg->vdd_mx) { rc = cpr_parse_vdd_mx_parameters(pdev, cpr_vreg); if (rc) { cpr_err(cpr_vreg, "parsing vdd_mx parameters failed: rc=%d\n", rc); goto err_out; } } cpr_efuse_free(cpr_vreg); /* * Ensure that enable state accurately reflects the case in which CPR * is permanently disabled. */ cpr_vreg->enable &= !cpr_vreg->cpr_fuse_disable; mutex_init(&cpr_vreg->cpr_mutex); rdesc = &cpr_vreg->rdesc; rdesc->owner = THIS_MODULE; rdesc->type = REGULATOR_VOLTAGE; rdesc->ops = &cpr_corner_ops; reg_config.dev = &pdev->dev; reg_config.init_data = init_data; reg_config.driver_data = cpr_vreg; reg_config.of_node = pdev->dev.of_node; cpr_vreg->rdev = regulator_register(rdesc, ®_config); if (IS_ERR(cpr_vreg->rdev)) { rc = PTR_ERR(cpr_vreg->rdev); cpr_err(cpr_vreg, "regulator_register failed: rc=%d\n", rc); cpr_apc_exit(cpr_vreg); return rc; } platform_set_drvdata(pdev, cpr_vreg); cpr_debugfs_init(cpr_vreg); if (cpr_vreg->cpr_disable_on_temperature) { rc = cpr_check_tsens(cpr_vreg); if (rc < 0) { cpr_err(cpr_vreg, "Unable to config CPR on tsens, rc=%d\n", rc); cpr_apc_exit(cpr_vreg); cpr_debugfs_remove(cpr_vreg); return rc; } } mutex_lock(&cpr_regulator_list_mutex); list_add(&cpr_vreg->list, &cpr_regulator_list); mutex_unlock(&cpr_regulator_list_mutex); return 0; err_out: cpr_efuse_free(cpr_vreg); return rc; } static int cpr_regulator_remove(struct platform_device *pdev) { struct cpr_regulator *cpr_vreg; cpr_vreg = platform_get_drvdata(pdev); if (cpr_vreg) { /* Disable CPR */ if (cpr_is_allowed(cpr_vreg)) { cpr_ctl_disable(cpr_vreg); cpr_irq_set(cpr_vreg, 0); } mutex_lock(&cpr_regulator_list_mutex); list_del(&cpr_vreg->list); mutex_unlock(&cpr_regulator_list_mutex); if (cpr_vreg->cpu_notifier.notifier_call) unregister_hotcpu_notifier(&cpr_vreg->cpu_notifier); if (cpr_vreg->cpr_disable_on_temperature) sensor_mgr_remove_threshold( &cpr_vreg->tsens_threshold_config); cpr_apc_exit(cpr_vreg); cpr_debugfs_remove(cpr_vreg); regulator_unregister(cpr_vreg->rdev); } return 0; } static struct of_device_id cpr_regulator_match_table[] = { { .compatible = CPR_REGULATOR_DRIVER_NAME, }, {} }; static struct platform_driver cpr_regulator_driver = { .driver = { .name = CPR_REGULATOR_DRIVER_NAME, .of_match_table = cpr_regulator_match_table, .owner = THIS_MODULE, }, .probe = cpr_regulator_probe, .remove = cpr_regulator_remove, .suspend = cpr_regulator_suspend, .resume = cpr_regulator_resume, }; static int initialize_tsens_monitor(struct cpr_regulator *cpr_vreg) { int rc; rc = cpr_check_tsens(cpr_vreg); if (rc < 0) { cpr_err(cpr_vreg, "Unable to check tsens, rc=%d\n", rc); return rc; } rc = sensor_mgr_init_threshold(&cpr_vreg->tsens_threshold_config, cpr_vreg->tsens_id, cpr_vreg->cpr_enable_temp_threshold, /* high */ cpr_vreg->cpr_disable_temp_threshold, /* low */ tsens_threshold_notify); if (rc < 0) { cpr_err(cpr_vreg, "Failed to init tsens monitor, rc=%d\n", rc); return rc; } rc = sensor_mgr_convert_id_and_set_threshold( &cpr_vreg->tsens_threshold_config); if (rc < 0) cpr_err(cpr_vreg, "Failed to set tsens threshold, rc=%d\n", rc); return rc; } int __init cpr_regulator_late_init(void) { int rc; struct cpr_regulator *cpr_vreg; mutex_lock(&cpr_regulator_list_mutex); list_for_each_entry(cpr_vreg, &cpr_regulator_list, list) { if (cpr_vreg->cpr_disable_on_temperature) { rc = initialize_tsens_monitor(cpr_vreg); if (rc) cpr_err(cpr_vreg, "Failed to initialize temperature monitor, rc=%d\n", rc); } } mutex_unlock(&cpr_regulator_list_mutex); return 0; } late_initcall(cpr_regulator_late_init); /** * cpr_regulator_init() - register cpr-regulator driver * * This initialization function should be called in systems in which driver * registration ordering must be controlled precisely. */ int __init cpr_regulator_init(void) { static bool initialized; if (initialized) return 0; else initialized = true; cpr_debugfs_base_init(); return platform_driver_register(&cpr_regulator_driver); } EXPORT_SYMBOL(cpr_regulator_init); static void __exit cpr_regulator_exit(void) { platform_driver_unregister(&cpr_regulator_driver); cpr_debugfs_base_remove(); } MODULE_DESCRIPTION("CPR regulator driver"); MODULE_LICENSE("GPL v2"); arch_initcall(cpr_regulator_init); module_exit(cpr_regulator_exit);