blob: 3035155e3f627767386bd367862432b19a9dfe7d [file] [log] [blame]
/*
* Copyright (c) 2015-2017, 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.
*/
/*
* This file contains utility functions to be used by platform specific CPR3
* regulator drivers.
*/
#define pr_fmt(fmt) "%s: " fmt, __func__
#include <linux/cpumask.h>
#include <linux/device.h>
#include <linux/io.h>
#include <linux/kernel.h>
#include <linux/of.h>
#include <linux/platform_device.h>
#include <linux/slab.h>
#include <linux/types.h>
#include "cpr3-regulator.h"
#define BYTES_PER_FUSE_ROW 8
#define MAX_FUSE_ROW_BIT 63
#define CPR3_CONSECUTIVE_UP_DOWN_MIN 0
#define CPR3_CONSECUTIVE_UP_DOWN_MAX 15
#define CPR3_UP_DOWN_THRESHOLD_MIN 0
#define CPR3_UP_DOWN_THRESHOLD_MAX 31
#define CPR3_STEP_QUOT_MIN 0
#define CPR3_STEP_QUOT_MAX 63
#define CPR3_IDLE_CLOCKS_MIN 0
#define CPR3_IDLE_CLOCKS_MAX 31
/* This constant has units of uV/mV so 1000 corresponds to 100%. */
#define CPR3_AGING_DERATE_UNITY 1000
/**
* cpr3_allocate_regulators() - allocate and initialize CPR3 regulators for a
* given thread based upon device tree data
* @thread: Pointer to the CPR3 thread
*
* This function allocates the thread->vreg array based upon the number of
* device tree regulator subnodes. It also initializes generic elements of each
* regulator struct such as name, of_node, and thread.
*
* Return: 0 on success, errno on failure
*/
static int cpr3_allocate_regulators(struct cpr3_thread *thread)
{
struct device_node *node;
int i, rc;
thread->vreg_count = 0;
for_each_available_child_of_node(thread->of_node, node) {
thread->vreg_count++;
}
thread->vreg = devm_kcalloc(thread->ctrl->dev, thread->vreg_count,
sizeof(*thread->vreg), GFP_KERNEL);
if (!thread->vreg)
return -ENOMEM;
i = 0;
for_each_available_child_of_node(thread->of_node, node) {
thread->vreg[i].of_node = node;
thread->vreg[i].thread = thread;
rc = of_property_read_string(node, "regulator-name",
&thread->vreg[i].name);
if (rc) {
dev_err(thread->ctrl->dev, "could not find regulator name, rc=%d\n",
rc);
return rc;
}
i++;
}
return 0;
}
/**
* cpr3_allocate_threads() - allocate and initialize CPR3 threads for a given
* controller based upon device tree data
* @ctrl: Pointer to the CPR3 controller
* @min_thread_id: Minimum allowed hardware thread ID for this controller
* @max_thread_id: Maximum allowed hardware thread ID for this controller
*
* This function allocates the ctrl->thread array based upon the number of
* device tree thread subnodes. It also initializes generic elements of each
* thread struct such as thread_id, of_node, ctrl, and vreg array.
*
* Return: 0 on success, errno on failure
*/
int cpr3_allocate_threads(struct cpr3_controller *ctrl, u32 min_thread_id,
u32 max_thread_id)
{
struct device *dev = ctrl->dev;
struct device_node *thread_node;
int i, j, rc;
ctrl->thread_count = 0;
for_each_available_child_of_node(dev->of_node, thread_node) {
ctrl->thread_count++;
}
ctrl->thread = devm_kcalloc(dev, ctrl->thread_count,
sizeof(*ctrl->thread), GFP_KERNEL);
if (!ctrl->thread)
return -ENOMEM;
i = 0;
for_each_available_child_of_node(dev->of_node, thread_node) {
ctrl->thread[i].of_node = thread_node;
ctrl->thread[i].ctrl = ctrl;
rc = of_property_read_u32(thread_node, "qcom,cpr-thread-id",
&ctrl->thread[i].thread_id);
if (rc) {
dev_err(dev, "could not read DT property qcom,cpr-thread-id, rc=%d\n",
rc);
return rc;
}
if (ctrl->thread[i].thread_id < min_thread_id ||
ctrl->thread[i].thread_id > max_thread_id) {
dev_err(dev, "invalid thread id = %u; not within [%u, %u]\n",
ctrl->thread[i].thread_id, min_thread_id,
max_thread_id);
return -EINVAL;
}
/* Verify that the thread ID is unique for all child nodes. */
for (j = 0; j < i; j++) {
if (ctrl->thread[j].thread_id
== ctrl->thread[i].thread_id) {
dev_err(dev, "duplicate thread id = %u found\n",
ctrl->thread[i].thread_id);
return -EINVAL;
}
}
rc = cpr3_allocate_regulators(&ctrl->thread[i]);
if (rc)
return rc;
i++;
}
return 0;
}
/**
* cpr3_map_fuse_base() - ioremap the base address of the fuse region
* @ctrl: Pointer to the CPR3 controller
* @pdev: Platform device pointer for the CPR3 controller
*
* Return: 0 on success, errno on failure
*/
int cpr3_map_fuse_base(struct cpr3_controller *ctrl,
struct platform_device *pdev)
{
struct resource *res;
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "fuse_base");
if (!res || !res->start) {
dev_err(&pdev->dev, "fuse base address is missing\n");
return -ENXIO;
}
ctrl->fuse_base = devm_ioremap(&pdev->dev, res->start,
resource_size(res));
return 0;
}
/**
* cpr3_read_fuse_param() - reads a CPR3 fuse parameter out of eFuses
* @fuse_base_addr: Virtual memory address of the eFuse base address
* @param: Null terminated array of fuse param segments to read
* from
* @param_value: Output with value read from the eFuses
*
* This function reads from each of the parameter segments listed in the param
* array and concatenates their values together. Reading stops when an element
* is reached which has all 0 struct values. The total number of bits specified
* for the fuse parameter across all segments must be less than or equal to 64.
*
* Return: 0 on success, errno on failure
*/
int cpr3_read_fuse_param(void __iomem *fuse_base_addr,
const struct cpr3_fuse_param *param, u64 *param_value)
{
u64 fuse_val, val;
int bits;
int bits_total = 0;
*param_value = 0;
while (param->row || param->bit_start || param->bit_end) {
if (param->bit_start > param->bit_end
|| param->bit_end > MAX_FUSE_ROW_BIT) {
pr_err("Invalid fuse parameter segment: row=%u, start=%u, end=%u\n",
param->row, param->bit_start, param->bit_end);
return -EINVAL;
}
bits = param->bit_end - param->bit_start + 1;
if (bits_total + bits > 64) {
pr_err("Invalid fuse parameter segments; total bits = %d\n",
bits_total + bits);
return -EINVAL;
}
fuse_val = readq_relaxed(fuse_base_addr
+ param->row * BYTES_PER_FUSE_ROW);
val = (fuse_val >> param->bit_start) & ((1ULL << bits) - 1);
*param_value |= val << bits_total;
bits_total += bits;
param++;
}
return 0;
}
/**
* cpr3_convert_open_loop_voltage_fuse() - converts an open loop voltage fuse
* value into an absolute voltage with units of microvolts
* @ref_volt: Reference voltage in microvolts
* @step_volt: The step size in microvolts of the fuse LSB
* @fuse: Open loop voltage fuse value
* @fuse_len: The bit length of the fuse value
*
* The MSB of the fuse parameter corresponds to a sign bit. If it is set, then
* the lower bits correspond to the number of steps to go down from the
* reference voltage. If it is not set, then the lower bits correspond to the
* number of steps to go up from the reference voltage.
*/
int cpr3_convert_open_loop_voltage_fuse(int ref_volt, int step_volt, u32 fuse,
int fuse_len)
{
int sign, steps;
sign = (fuse & (1 << (fuse_len - 1))) ? -1 : 1;
steps = fuse & ((1 << (fuse_len - 1)) - 1);
return ref_volt + sign * steps * step_volt;
}
/**
* cpr3_interpolate() - performs linear interpolation
* @x1 Lower known x value
* @y1 Lower known y value
* @x2 Upper known x value
* @y2 Upper known y value
* @x Intermediate x value
*
* Returns y where (x, y) falls on the line between (x1, y1) and (x2, y2).
* It is required that x1 < x2, y1 <= y2, and x1 <= x <= x2. If these
* conditions are not met, then y2 will be returned.
*/
u64 cpr3_interpolate(u64 x1, u64 y1, u64 x2, u64 y2, u64 x)
{
u64 temp;
if (x1 >= x2 || y1 > y2 || x1 > x || x > x2)
return y2;
temp = (x2 - x) * (y2 - y1);
do_div(temp, (u32)(x2 - x1));
return y2 - temp;
}
/**
* cpr3_parse_array_property() - fill an array from a portion of the values
* specified for a device tree property
* @vreg: Pointer to the CPR3 regulator
* @prop_name: The name of the device tree property to read from
* @tuple_size: The number of elements in each tuple
* @out: Output data array which must be of size tuple_size
*
* cpr3_parse_common_corner_data() must be called for vreg before this function
* is called so that fuse combo and speed bin size elements are initialized.
*
* Three formats are supported for the device tree property:
* 1. Length == tuple_size
* (reading begins at index 0)
* 2. Length == tuple_size * vreg->fuse_combos_supported
* (reading begins at index tuple_size * vreg->fuse_combo)
* 3. Length == tuple_size * vreg->speed_bins_supported
* (reading begins at index tuple_size * vreg->speed_bin_fuse)
*
* All other property lengths are treated as errors.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_array_property(struct cpr3_regulator *vreg,
const char *prop_name, int tuple_size, u32 *out)
{
struct device_node *node = vreg->of_node;
int len = 0;
int i, offset, rc;
if (!of_find_property(node, prop_name, &len)) {
cpr3_err(vreg, "property %s is missing\n", prop_name);
return -EINVAL;
}
if (len == tuple_size * sizeof(u32)) {
offset = 0;
} else if (len == tuple_size * vreg->fuse_combos_supported
* sizeof(u32)) {
offset = tuple_size * vreg->fuse_combo;
} else if (vreg->speed_bins_supported > 0 &&
len == tuple_size * vreg->speed_bins_supported * sizeof(u32)) {
offset = tuple_size * vreg->speed_bin_fuse;
} else {
if (vreg->speed_bins_supported > 0)
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu, %zu, or %zu\n",
prop_name, len,
tuple_size * sizeof(u32),
tuple_size * vreg->speed_bins_supported
* sizeof(u32),
tuple_size * vreg->fuse_combos_supported
* sizeof(u32));
else
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu or %zu\n",
prop_name, len,
tuple_size * sizeof(u32),
tuple_size * vreg->fuse_combos_supported
* sizeof(u32));
return -EINVAL;
}
for (i = 0; i < tuple_size; i++) {
rc = of_property_read_u32_index(node, prop_name, offset + i,
&out[i]);
if (rc) {
cpr3_err(vreg, "error reading property %s, rc=%d\n",
prop_name, rc);
return rc;
}
}
return 0;
}
/**
* cpr3_parse_corner_array_property() - fill a per-corner array from a portion
* of the values specified for a device tree property
* @vreg: Pointer to the CPR3 regulator
* @prop_name: The name of the device tree property to read from
* @tuple_size: The number of elements in each per-corner tuple
* @out: Output data array which must be of size:
* tuple_size * vreg->corner_count
*
* cpr3_parse_common_corner_data() must be called for vreg before this function
* is called so that fuse combo and speed bin size elements are initialized.
*
* Three formats are supported for the device tree property:
* 1. Length == tuple_size * vreg->corner_count
* (reading begins at index 0)
* 2. Length == tuple_size * vreg->fuse_combo_corner_sum
* (reading begins at index tuple_size * vreg->fuse_combo_offset)
* 3. Length == tuple_size * vreg->speed_bin_corner_sum
* (reading begins at index tuple_size * vreg->speed_bin_offset)
*
* All other property lengths are treated as errors.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_corner_array_property(struct cpr3_regulator *vreg,
const char *prop_name, int tuple_size, u32 *out)
{
struct device_node *node = vreg->of_node;
int len = 0;
int i, offset, rc;
if (!of_find_property(node, prop_name, &len)) {
cpr3_err(vreg, "property %s is missing\n", prop_name);
return -EINVAL;
}
if (len == tuple_size * vreg->corner_count * sizeof(u32)) {
offset = 0;
} else if (len == tuple_size * vreg->fuse_combo_corner_sum
* sizeof(u32)) {
offset = tuple_size * vreg->fuse_combo_offset;
} else if (vreg->speed_bin_corner_sum > 0 &&
len == tuple_size * vreg->speed_bin_corner_sum * sizeof(u32)) {
offset = tuple_size * vreg->speed_bin_offset;
} else {
if (vreg->speed_bin_corner_sum > 0)
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu, %zu, or %zu\n",
prop_name, len,
tuple_size * vreg->corner_count * sizeof(u32),
tuple_size * vreg->speed_bin_corner_sum
* sizeof(u32),
tuple_size * vreg->fuse_combo_corner_sum
* sizeof(u32));
else
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu or %zu\n",
prop_name, len,
tuple_size * vreg->corner_count * sizeof(u32),
tuple_size * vreg->fuse_combo_corner_sum
* sizeof(u32));
return -EINVAL;
}
for (i = 0; i < tuple_size * vreg->corner_count; i++) {
rc = of_property_read_u32_index(node, prop_name, offset + i,
&out[i]);
if (rc) {
cpr3_err(vreg, "error reading property %s, rc=%d\n",
prop_name, rc);
return rc;
}
}
return 0;
}
/**
* cpr3_parse_corner_band_array_property() - fill a per-corner band array
* from a portion of the values specified for a device tree
* property
* @vreg: Pointer to the CPR3 regulator
* @prop_name: The name of the device tree property to read from
* @tuple_size: The number of elements in each per-corner band tuple
* @out: Output data array which must be of size:
* tuple_size * vreg->corner_band_count
*
* cpr3_parse_common_corner_data() must be called for vreg before this function
* is called so that fuse combo and speed bin size elements are initialized.
* In addition, corner band fuse combo and speed bin sum and offset elements
* must be initialized prior to executing this function.
*
* Three formats are supported for the device tree property:
* 1. Length == tuple_size * vreg->corner_band_count
* (reading begins at index 0)
* 2. Length == tuple_size * vreg->fuse_combo_corner_band_sum
* (reading begins at index tuple_size *
* vreg->fuse_combo_corner_band_offset)
* 3. Length == tuple_size * vreg->speed_bin_corner_band_sum
* (reading begins at index tuple_size *
* vreg->speed_bin_corner_band_offset)
*
* All other property lengths are treated as errors.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_corner_band_array_property(struct cpr3_regulator *vreg,
const char *prop_name, int tuple_size, u32 *out)
{
struct device_node *node = vreg->of_node;
int len = 0;
int i, offset, rc;
if (!of_find_property(node, prop_name, &len)) {
cpr3_err(vreg, "property %s is missing\n", prop_name);
return -EINVAL;
}
if (len == tuple_size * vreg->corner_band_count * sizeof(u32)) {
offset = 0;
} else if (len == tuple_size * vreg->fuse_combo_corner_band_sum
* sizeof(u32)) {
offset = tuple_size * vreg->fuse_combo_corner_band_offset;
} else if (vreg->speed_bin_corner_band_sum > 0 &&
len == tuple_size * vreg->speed_bin_corner_band_sum *
sizeof(u32)) {
offset = tuple_size * vreg->speed_bin_corner_band_offset;
} else {
if (vreg->speed_bin_corner_band_sum > 0)
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu, %zu, or %zu\n",
prop_name, len,
tuple_size * vreg->corner_band_count *
sizeof(u32),
tuple_size * vreg->speed_bin_corner_band_sum
* sizeof(u32),
tuple_size * vreg->fuse_combo_corner_band_sum
* sizeof(u32));
else
cpr3_err(vreg, "property %s has invalid length=%d, should be %zu or %zu\n",
prop_name, len,
tuple_size * vreg->corner_band_count *
sizeof(u32),
tuple_size * vreg->fuse_combo_corner_band_sum
* sizeof(u32));
return -EINVAL;
}
for (i = 0; i < tuple_size * vreg->corner_band_count; i++) {
rc = of_property_read_u32_index(node, prop_name, offset + i,
&out[i]);
if (rc) {
cpr3_err(vreg, "error reading property %s, rc=%d\n",
prop_name, rc);
return rc;
}
}
return 0;
}
/**
* cpr3_parse_common_corner_data() - parse common CPR3 properties relating to
* the corners supported by a CPR3 regulator from device tree
* @vreg: Pointer to the CPR3 regulator
*
* This function reads, validates, and utilizes the following device tree
* properties: qcom,cpr-fuse-corners, qcom,cpr-fuse-combos, qcom,cpr-speed-bins,
* qcom,cpr-speed-bin-corners, qcom,cpr-corners, qcom,cpr-voltage-ceiling,
* qcom,cpr-voltage-floor, qcom,corner-frequencies,
* and qcom,cpr-corner-fmax-map.
*
* It initializes these CPR3 regulator elements: corner, corner_count,
* fuse_combos_supported, fuse_corner_map, and speed_bins_supported. It
* initializes these elements for each corner: ceiling_volt, floor_volt,
* proc_freq, and cpr_fuse_corner.
*
* It requires that the following CPR3 regulator elements be initialized before
* being called: fuse_corner_count, fuse_combo, and speed_bin_fuse.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_common_corner_data(struct cpr3_regulator *vreg)
{
struct device_node *node = vreg->of_node;
struct cpr3_controller *ctrl = vreg->thread->ctrl;
u32 max_fuse_combos, fuse_corners, aging_allowed = 0;
u32 max_speed_bins = 0;
u32 *combo_corners;
u32 *speed_bin_corners;
u32 *temp;
int i, j, rc;
rc = of_property_read_u32(node, "qcom,cpr-fuse-corners", &fuse_corners);
if (rc) {
cpr3_err(vreg, "error reading property qcom,cpr-fuse-corners, rc=%d\n",
rc);
return rc;
}
if (vreg->fuse_corner_count != fuse_corners) {
cpr3_err(vreg, "device tree config supports %d fuse corners but the hardware has %d fuse corners\n",
fuse_corners, vreg->fuse_corner_count);
return -EINVAL;
}
rc = of_property_read_u32(node, "qcom,cpr-fuse-combos",
&max_fuse_combos);
if (rc) {
cpr3_err(vreg, "error reading property qcom,cpr-fuse-combos, rc=%d\n",
rc);
return rc;
}
/*
* Sanity check against arbitrarily large value to avoid excessive
* memory allocation.
*/
if (max_fuse_combos > 100 || max_fuse_combos == 0) {
cpr3_err(vreg, "qcom,cpr-fuse-combos is invalid: %u\n",
max_fuse_combos);
return -EINVAL;
}
if (vreg->fuse_combo >= max_fuse_combos) {
cpr3_err(vreg, "device tree config supports fuse combos 0-%u but the hardware has combo %d\n",
max_fuse_combos - 1, vreg->fuse_combo);
BUG_ON(1);
return -EINVAL;
}
vreg->fuse_combos_supported = max_fuse_combos;
of_property_read_u32(node, "qcom,cpr-speed-bins", &max_speed_bins);
/*
* Sanity check against arbitrarily large value to avoid excessive
* memory allocation.
*/
if (max_speed_bins > 100) {
cpr3_err(vreg, "qcom,cpr-speed-bins is invalid: %u\n",
max_speed_bins);
return -EINVAL;
}
if (max_speed_bins && vreg->speed_bin_fuse >= max_speed_bins) {
cpr3_err(vreg, "device tree config supports speed bins 0-%u but the hardware has speed bin %d\n",
max_speed_bins - 1, vreg->speed_bin_fuse);
BUG();
return -EINVAL;
}
vreg->speed_bins_supported = max_speed_bins;
combo_corners = kcalloc(vreg->fuse_combos_supported,
sizeof(*combo_corners), GFP_KERNEL);
if (!combo_corners)
return -ENOMEM;
rc = of_property_read_u32_array(node, "qcom,cpr-corners", combo_corners,
vreg->fuse_combos_supported);
if (rc == -EOVERFLOW) {
/* Single value case */
rc = of_property_read_u32(node, "qcom,cpr-corners",
combo_corners);
for (i = 1; i < vreg->fuse_combos_supported; i++)
combo_corners[i] = combo_corners[0];
}
if (rc) {
cpr3_err(vreg, "error reading property qcom,cpr-corners, rc=%d\n",
rc);
kfree(combo_corners);
return rc;
}
vreg->fuse_combo_offset = 0;
vreg->fuse_combo_corner_sum = 0;
for (i = 0; i < vreg->fuse_combos_supported; i++) {
vreg->fuse_combo_corner_sum += combo_corners[i];
if (i < vreg->fuse_combo)
vreg->fuse_combo_offset += combo_corners[i];
}
vreg->corner_count = combo_corners[vreg->fuse_combo];
kfree(combo_corners);
vreg->speed_bin_offset = 0;
vreg->speed_bin_corner_sum = 0;
if (vreg->speed_bins_supported > 0) {
speed_bin_corners = kcalloc(vreg->speed_bins_supported,
sizeof(*speed_bin_corners), GFP_KERNEL);
if (!speed_bin_corners)
return -ENOMEM;
rc = of_property_read_u32_array(node,
"qcom,cpr-speed-bin-corners", speed_bin_corners,
vreg->speed_bins_supported);
if (rc) {
cpr3_err(vreg, "error reading property qcom,cpr-speed-bin-corners, rc=%d\n",
rc);
kfree(speed_bin_corners);
return rc;
}
for (i = 0; i < vreg->speed_bins_supported; i++) {
vreg->speed_bin_corner_sum += speed_bin_corners[i];
if (i < vreg->speed_bin_fuse)
vreg->speed_bin_offset += speed_bin_corners[i];
}
if (speed_bin_corners[vreg->speed_bin_fuse]
!= vreg->corner_count) {
cpr3_err(vreg, "qcom,cpr-corners and qcom,cpr-speed-bin-corners conflict on number of corners: %d vs %u\n",
vreg->corner_count,
speed_bin_corners[vreg->speed_bin_fuse]);
kfree(speed_bin_corners);
return -EINVAL;
}
kfree(speed_bin_corners);
}
/*
* For CPRh compliant controllers two additional corners are
* allocated to correspond to the APM crossover voltage and the MEM ACC
* crossover voltage.
*/
vreg->corner = devm_kcalloc(ctrl->dev, ctrl->ctrl_type ==
CPR_CTRL_TYPE_CPRH ?
vreg->corner_count + 2 :
vreg->corner_count,
sizeof(*vreg->corner), GFP_KERNEL);
temp = kcalloc(vreg->corner_count, sizeof(*temp), GFP_KERNEL);
if (!vreg->corner || !temp)
return -ENOMEM;
rc = cpr3_parse_corner_array_property(vreg, "qcom,cpr-voltage-ceiling",
1, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->corner_count; i++) {
vreg->corner[i].ceiling_volt
= CPR3_ROUND(temp[i], ctrl->step_volt);
vreg->corner[i].abs_ceiling_volt = vreg->corner[i].ceiling_volt;
}
rc = cpr3_parse_corner_array_property(vreg, "qcom,cpr-voltage-floor",
1, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].floor_volt
= CPR3_ROUND(temp[i], ctrl->step_volt);
/* Validate ceiling and floor values */
for (i = 0; i < vreg->corner_count; i++) {
if (vreg->corner[i].floor_volt
> vreg->corner[i].ceiling_volt) {
cpr3_err(vreg, "CPR floor[%d]=%d > ceiling[%d]=%d uV\n",
i, vreg->corner[i].floor_volt,
i, vreg->corner[i].ceiling_volt);
rc = -EINVAL;
goto free_temp;
}
}
/* Load optional system-supply voltages */
if (of_find_property(vreg->of_node, "qcom,system-voltage", NULL)) {
rc = cpr3_parse_corner_array_property(vreg,
"qcom,system-voltage", 1, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].system_volt = temp[i];
}
rc = cpr3_parse_corner_array_property(vreg, "qcom,corner-frequencies",
1, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].proc_freq = temp[i];
/* Validate frequencies */
for (i = 1; i < vreg->corner_count; i++) {
if (vreg->corner[i].proc_freq
< vreg->corner[i - 1].proc_freq) {
cpr3_err(vreg, "invalid frequency: freq[%d]=%u < freq[%d]=%u\n",
i, vreg->corner[i].proc_freq, i - 1,
vreg->corner[i - 1].proc_freq);
rc = -EINVAL;
goto free_temp;
}
}
vreg->fuse_corner_map = devm_kcalloc(ctrl->dev, vreg->fuse_corner_count,
sizeof(*vreg->fuse_corner_map), GFP_KERNEL);
if (!vreg->fuse_corner_map) {
rc = -ENOMEM;
goto free_temp;
}
rc = cpr3_parse_array_property(vreg, "qcom,cpr-corner-fmax-map",
vreg->fuse_corner_count, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->fuse_corner_count; i++) {
vreg->fuse_corner_map[i] = temp[i] - CPR3_CORNER_OFFSET;
if (temp[i] < CPR3_CORNER_OFFSET
|| temp[i] > vreg->corner_count + CPR3_CORNER_OFFSET) {
cpr3_err(vreg, "invalid corner value specified in qcom,cpr-corner-fmax-map: %u\n",
temp[i]);
rc = -EINVAL;
goto free_temp;
} else if (i > 0 && temp[i - 1] >= temp[i]) {
cpr3_err(vreg, "invalid corner %u less than or equal to previous corner %u\n",
temp[i], temp[i - 1]);
rc = -EINVAL;
goto free_temp;
}
}
if (temp[vreg->fuse_corner_count - 1] != vreg->corner_count)
cpr3_debug(vreg, "Note: highest Fmax corner %u in qcom,cpr-corner-fmax-map does not match highest supported corner %d\n",
temp[vreg->fuse_corner_count - 1],
vreg->corner_count);
for (i = 0; i < vreg->corner_count; i++) {
for (j = 0; j < vreg->fuse_corner_count; j++) {
if (i + CPR3_CORNER_OFFSET <= temp[j]) {
vreg->corner[i].cpr_fuse_corner = j;
break;
}
}
if (j == vreg->fuse_corner_count) {
/*
* Handle the case where the highest fuse corner maps
* to a corner below the highest corner.
*/
vreg->corner[i].cpr_fuse_corner
= vreg->fuse_corner_count - 1;
}
}
if (of_find_property(vreg->of_node,
"qcom,allow-aging-voltage-adjustment", NULL)) {
rc = cpr3_parse_array_property(vreg,
"qcom,allow-aging-voltage-adjustment",
1, &aging_allowed);
if (rc)
goto free_temp;
vreg->aging_allowed = aging_allowed;
}
if (of_find_property(vreg->of_node,
"qcom,allow-aging-open-loop-voltage-adjustment", NULL)) {
rc = cpr3_parse_array_property(vreg,
"qcom,allow-aging-open-loop-voltage-adjustment",
1, &aging_allowed);
if (rc)
goto free_temp;
vreg->aging_allow_open_loop_adj = aging_allowed;
}
if (vreg->aging_allowed) {
if (ctrl->aging_ref_volt <= 0) {
cpr3_err(ctrl, "qcom,cpr-aging-ref-voltage must be specified\n");
rc = -EINVAL;
goto free_temp;
}
rc = cpr3_parse_array_property(vreg,
"qcom,cpr-aging-max-voltage-adjustment",
1, &vreg->aging_max_adjust_volt);
if (rc)
goto free_temp;
rc = cpr3_parse_array_property(vreg,
"qcom,cpr-aging-ref-corner", 1, &vreg->aging_corner);
if (rc) {
goto free_temp;
} else if (vreg->aging_corner < CPR3_CORNER_OFFSET
|| vreg->aging_corner > vreg->corner_count - 1
+ CPR3_CORNER_OFFSET) {
cpr3_err(vreg, "aging reference corner=%d not in range [%d, %d]\n",
vreg->aging_corner, CPR3_CORNER_OFFSET,
vreg->corner_count - 1 + CPR3_CORNER_OFFSET);
rc = -EINVAL;
goto free_temp;
}
vreg->aging_corner -= CPR3_CORNER_OFFSET;
if (of_find_property(vreg->of_node, "qcom,cpr-aging-derate",
NULL)) {
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-aging-derate", 1, temp);
if (rc)
goto free_temp;
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].aging_derate = temp[i];
} else {
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].aging_derate
= CPR3_AGING_DERATE_UNITY;
}
}
free_temp:
kfree(temp);
return rc;
}
/**
* cpr3_parse_thread_u32() - parse the specified property from the CPR3 thread's
* device tree node and verify that it is within the allowed limits
* @thread: Pointer to the CPR3 thread
* @propname: The name of the device tree property to read
* @out_value: The output pointer to fill with the value read
* @value_min: The minimum allowed property value
* @value_max: The maximum allowed property value
*
* This function prints a verbose error message if the property is missing or
* has a value which is not within the specified range.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_thread_u32(struct cpr3_thread *thread, const char *propname,
u32 *out_value, u32 value_min, u32 value_max)
{
int rc;
rc = of_property_read_u32(thread->of_node, propname, out_value);
if (rc) {
cpr3_err(thread->ctrl, "thread %u error reading property %s, rc=%d\n",
thread->thread_id, propname, rc);
return rc;
}
if (*out_value < value_min || *out_value > value_max) {
cpr3_err(thread->ctrl, "thread %u %s=%u is invalid; allowed range: [%u, %u]\n",
thread->thread_id, propname, *out_value, value_min,
value_max);
return -EINVAL;
}
return 0;
}
/**
* cpr3_parse_ctrl_u32() - parse the specified property from the CPR3
* controller's device tree node and verify that it is within the
* allowed limits
* @ctrl: Pointer to the CPR3 controller
* @propname: The name of the device tree property to read
* @out_value: The output pointer to fill with the value read
* @value_min: The minimum allowed property value
* @value_max: The maximum allowed property value
*
* This function prints a verbose error message if the property is missing or
* has a value which is not within the specified range.
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_ctrl_u32(struct cpr3_controller *ctrl, const char *propname,
u32 *out_value, u32 value_min, u32 value_max)
{
int rc;
rc = of_property_read_u32(ctrl->dev->of_node, propname, out_value);
if (rc) {
cpr3_err(ctrl, "error reading property %s, rc=%d\n",
propname, rc);
return rc;
}
if (*out_value < value_min || *out_value > value_max) {
cpr3_err(ctrl, "%s=%u is invalid; allowed range: [%u, %u]\n",
propname, *out_value, value_min, value_max);
return -EINVAL;
}
return 0;
}
/**
* cpr3_parse_common_thread_data() - parse common CPR3 thread properties from
* device tree
* @thread: Pointer to the CPR3 thread
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_common_thread_data(struct cpr3_thread *thread)
{
int rc;
rc = cpr3_parse_thread_u32(thread, "qcom,cpr-consecutive-up",
&thread->consecutive_up, CPR3_CONSECUTIVE_UP_DOWN_MIN,
CPR3_CONSECUTIVE_UP_DOWN_MAX);
if (rc)
return rc;
rc = cpr3_parse_thread_u32(thread, "qcom,cpr-consecutive-down",
&thread->consecutive_down, CPR3_CONSECUTIVE_UP_DOWN_MIN,
CPR3_CONSECUTIVE_UP_DOWN_MAX);
if (rc)
return rc;
rc = cpr3_parse_thread_u32(thread, "qcom,cpr-up-threshold",
&thread->up_threshold, CPR3_UP_DOWN_THRESHOLD_MIN,
CPR3_UP_DOWN_THRESHOLD_MAX);
if (rc)
return rc;
rc = cpr3_parse_thread_u32(thread, "qcom,cpr-down-threshold",
&thread->down_threshold, CPR3_UP_DOWN_THRESHOLD_MIN,
CPR3_UP_DOWN_THRESHOLD_MAX);
if (rc)
return rc;
return rc;
}
/**
* cpr3_parse_irq_affinity() - parse CPR IRQ affinity information
* @ctrl: Pointer to the CPR3 controller
*
* Return: 0 on success, errno on failure
*/
static int cpr3_parse_irq_affinity(struct cpr3_controller *ctrl)
{
struct device_node *cpu_node;
int i, cpu;
int len = 0;
if (!of_find_property(ctrl->dev->of_node, "qcom,cpr-interrupt-affinity",
&len)) {
/* No IRQ affinity required */
return 0;
}
len /= sizeof(u32);
for (i = 0; i < len; i++) {
cpu_node = of_parse_phandle(ctrl->dev->of_node,
"qcom,cpr-interrupt-affinity", i);
if (!cpu_node) {
cpr3_err(ctrl, "could not find CPU node %d\n", i);
return -EINVAL;
}
for_each_possible_cpu(cpu) {
if (of_get_cpu_node(cpu, NULL) == cpu_node) {
cpumask_set_cpu(cpu, &ctrl->irq_affinity_mask);
break;
}
}
of_node_put(cpu_node);
}
return 0;
}
static int cpr3_panic_notifier_init(struct cpr3_controller *ctrl)
{
struct device_node *node = ctrl->dev->of_node;
struct cpr3_panic_regs_info *panic_regs_info;
struct cpr3_reg_info *regs;
int i, reg_count, len, rc = 0;
if (!of_find_property(node, "qcom,cpr-panic-reg-addr-list", &len)) {
/* panic register address list not specified */
return rc;
}
reg_count = len / sizeof(u32);
if (!reg_count) {
cpr3_err(ctrl, "qcom,cpr-panic-reg-addr-list has invalid len = %d\n",
len);
return -EINVAL;
}
if (!of_find_property(node, "qcom,cpr-panic-reg-name-list", NULL)) {
cpr3_err(ctrl, "property qcom,cpr-panic-reg-name-list not specified\n");
return -EINVAL;
}
len = of_property_count_strings(node, "qcom,cpr-panic-reg-name-list");
if (reg_count != len) {
cpr3_err(ctrl, "qcom,cpr-panic-reg-name-list should have %d strings\n",
reg_count);
return -EINVAL;
}
panic_regs_info = devm_kzalloc(ctrl->dev, sizeof(*panic_regs_info),
GFP_KERNEL);
if (!panic_regs_info)
return -ENOMEM;
regs = devm_kcalloc(ctrl->dev, reg_count, sizeof(*regs), GFP_KERNEL);
if (!regs)
return -ENOMEM;
for (i = 0; i < reg_count; i++) {
rc = of_property_read_string_index(node,
"qcom,cpr-panic-reg-name-list", i,
&(regs[i].name));
if (rc) {
cpr3_err(ctrl, "error reading property qcom,cpr-panic-reg-name-list, rc=%d\n",
rc);
return rc;
}
rc = of_property_read_u32_index(node,
"qcom,cpr-panic-reg-addr-list", i,
&(regs[i].addr));
if (rc) {
cpr3_err(ctrl, "error reading property qcom,cpr-panic-reg-addr-list, rc=%d\n",
rc);
return rc;
}
regs[i].virt_addr = devm_ioremap(ctrl->dev, regs[i].addr, 0x4);
if (!regs[i].virt_addr) {
pr_err("Unable to map panic register addr 0x%08x\n",
regs[i].addr);
return -EINVAL;
}
regs[i].value = 0xFFFFFFFF;
}
panic_regs_info->reg_count = reg_count;
panic_regs_info->regs = regs;
ctrl->panic_regs_info = panic_regs_info;
return rc;
}
/**
* cpr3_parse_common_ctrl_data() - parse common CPR3 controller properties from
* device tree
* @ctrl: Pointer to the CPR3 controller
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_common_ctrl_data(struct cpr3_controller *ctrl)
{
int rc;
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-sensor-time",
&ctrl->sensor_time, 0, UINT_MAX);
if (rc)
return rc;
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-loop-time",
&ctrl->loop_time, 0, UINT_MAX);
if (rc)
return rc;
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-idle-cycles",
&ctrl->idle_clocks, CPR3_IDLE_CLOCKS_MIN,
CPR3_IDLE_CLOCKS_MAX);
if (rc)
return rc;
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-step-quot-init-min",
&ctrl->step_quot_init_min, CPR3_STEP_QUOT_MIN,
CPR3_STEP_QUOT_MAX);
if (rc)
return rc;
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-step-quot-init-max",
&ctrl->step_quot_init_max, CPR3_STEP_QUOT_MIN,
CPR3_STEP_QUOT_MAX);
if (rc)
return rc;
rc = of_property_read_u32(ctrl->dev->of_node, "qcom,voltage-step",
&ctrl->step_volt);
if (rc) {
cpr3_err(ctrl, "error reading property qcom,voltage-step, rc=%d\n",
rc);
return rc;
}
if (ctrl->step_volt <= 0) {
cpr3_err(ctrl, "qcom,voltage-step=%d is invalid\n",
ctrl->step_volt);
return -EINVAL;
}
rc = cpr3_parse_ctrl_u32(ctrl, "qcom,cpr-count-mode",
&ctrl->count_mode, CPR3_COUNT_MODE_ALL_AT_ONCE_MIN,
CPR3_COUNT_MODE_STAGGERED);
if (rc)
return rc;
/* Count repeat is optional */
ctrl->count_repeat = 0;
of_property_read_u32(ctrl->dev->of_node, "qcom,cpr-count-repeat",
&ctrl->count_repeat);
ctrl->cpr_allowed_sw = of_property_read_bool(ctrl->dev->of_node,
"qcom,cpr-enable");
rc = cpr3_parse_irq_affinity(ctrl);
if (rc)
return rc;
ctrl->ignore_invalid_fuses = of_property_read_bool(ctrl->dev->of_node,
"qcom,cpr-ignore-invalid-fuses");
/* Aging reference voltage is optional */
ctrl->aging_ref_volt = 0;
of_property_read_u32(ctrl->dev->of_node, "qcom,cpr-aging-ref-voltage",
&ctrl->aging_ref_volt);
/* Aging possible bitmask is optional */
ctrl->aging_possible_mask = 0;
of_property_read_u32(ctrl->dev->of_node,
"qcom,cpr-aging-allowed-reg-mask",
&ctrl->aging_possible_mask);
if (ctrl->aging_possible_mask) {
/*
* Aging possible register value required if bitmask is
* specified
*/
rc = cpr3_parse_ctrl_u32(ctrl,
"qcom,cpr-aging-allowed-reg-value",
&ctrl->aging_possible_val, 0, UINT_MAX);
if (rc)
return rc;
}
if (of_find_property(ctrl->dev->of_node, "clock-names", NULL)) {
ctrl->core_clk = devm_clk_get(ctrl->dev, "core_clk");
if (IS_ERR(ctrl->core_clk)) {
rc = PTR_ERR(ctrl->core_clk);
if (rc != -EPROBE_DEFER)
cpr3_err(ctrl, "unable request core clock, rc=%d\n",
rc);
return rc;
}
}
rc = cpr3_panic_notifier_init(ctrl);
if (rc)
return rc;
if (of_find_property(ctrl->dev->of_node, "vdd-supply", NULL)) {
ctrl->vdd_regulator = devm_regulator_get(ctrl->dev, "vdd");
if (IS_ERR(ctrl->vdd_regulator)) {
rc = PTR_ERR(ctrl->vdd_regulator);
if (rc != -EPROBE_DEFER)
cpr3_err(ctrl, "unable to request vdd regulator, rc=%d\n",
rc);
return rc;
}
} else if (ctrl->ctrl_type == CPR_CTRL_TYPE_CPRH) {
/* vdd-supply is optional for CPRh controllers. */
ctrl->vdd_regulator = NULL;
} else {
cpr3_err(ctrl, "vdd supply is not defined\n");
return -ENODEV;
}
/*
* Reset step_quot to default on each loop_en = 0 transition is
* optional.
*/
ctrl->reset_step_quot_loop_en
= of_property_read_bool(ctrl->dev->of_node,
"qcom,cpr-reset-step-quot-loop-en");
/*
* Regulator device handles are not necessary for CPRh controllers
* since communication with the regulators is completely managed
* in hardware.
*/
if (ctrl->ctrl_type == CPR_CTRL_TYPE_CPRH)
return rc;
ctrl->system_regulator = devm_regulator_get_optional(ctrl->dev,
"system");
if (IS_ERR(ctrl->system_regulator)) {
rc = PTR_ERR(ctrl->system_regulator);
if (rc != -EPROBE_DEFER) {
rc = 0;
ctrl->system_regulator = NULL;
} else {
return rc;
}
}
ctrl->mem_acc_regulator = devm_regulator_get_optional(ctrl->dev,
"mem-acc");
if (IS_ERR(ctrl->mem_acc_regulator)) {
rc = PTR_ERR(ctrl->mem_acc_regulator);
if (rc != -EPROBE_DEFER) {
rc = 0;
ctrl->mem_acc_regulator = NULL;
} else {
return rc;
}
}
return rc;
}
/**
* cpr3_limit_open_loop_voltages() - modify the open-loop voltage of each corner
* so that it fits within the floor to ceiling
* voltage range of the corner
* @vreg: Pointer to the CPR3 regulator
*
* This function clips the open-loop voltage for each corner so that it is
* limited to the floor to ceiling range. It also rounds each open-loop voltage
* so that it corresponds to a set point available to the underlying regulator.
*
* Return: 0 on success, errno on failure
*/
int cpr3_limit_open_loop_voltages(struct cpr3_regulator *vreg)
{
int i, volt;
cpr3_debug(vreg, "open-loop voltages after trimming and rounding:\n");
for (i = 0; i < vreg->corner_count; i++) {
volt = CPR3_ROUND(vreg->corner[i].open_loop_volt,
vreg->thread->ctrl->step_volt);
if (volt < vreg->corner[i].floor_volt)
volt = vreg->corner[i].floor_volt;
else if (volt > vreg->corner[i].ceiling_volt)
volt = vreg->corner[i].ceiling_volt;
vreg->corner[i].open_loop_volt = volt;
cpr3_debug(vreg, "corner[%2d]: open-loop=%d uV\n", i, volt);
}
return 0;
}
/**
* cpr3_open_loop_voltage_as_ceiling() - configures the ceiling voltage for each
* corner to equal the open-loop voltage if the relevant device
* tree property is found for the CPR3 regulator
* @vreg: Pointer to the CPR3 regulator
*
* This function assumes that the the open-loop voltage for each corner has
* already been rounded to the nearest allowed set point and that it falls
* within the floor to ceiling range.
*
* Return: none
*/
void cpr3_open_loop_voltage_as_ceiling(struct cpr3_regulator *vreg)
{
int i;
if (!of_property_read_bool(vreg->of_node,
"qcom,cpr-scaled-open-loop-voltage-as-ceiling"))
return;
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].ceiling_volt
= vreg->corner[i].open_loop_volt;
}
/**
* cpr3_limit_floor_voltages() - raise the floor voltage of each corner so that
* the optional maximum floor to ceiling voltage range specified in
* device tree is satisfied
* @vreg: Pointer to the CPR3 regulator
*
* This function also ensures that the open-loop voltage for each corner falls
* within the final floor to ceiling voltage range and that floor voltages
* increase monotonically.
*
* Return: 0 on success, errno on failure
*/
int cpr3_limit_floor_voltages(struct cpr3_regulator *vreg)
{
char *prop = "qcom,cpr-floor-to-ceiling-max-range";
int i, floor_new;
u32 *floor_range;
int rc = 0;
if (!of_find_property(vreg->of_node, prop, NULL))
goto enforce_monotonicity;
floor_range = kcalloc(vreg->corner_count, sizeof(*floor_range),
GFP_KERNEL);
if (!floor_range)
return -ENOMEM;
rc = cpr3_parse_corner_array_property(vreg, prop, 1, floor_range);
if (rc)
goto free_floor_adjust;
for (i = 0; i < vreg->corner_count; i++) {
if ((s32)floor_range[i] >= 0) {
floor_new = CPR3_ROUND(vreg->corner[i].ceiling_volt
- floor_range[i],
vreg->thread->ctrl->step_volt);
vreg->corner[i].floor_volt = max(floor_new,
vreg->corner[i].floor_volt);
if (vreg->corner[i].open_loop_volt
< vreg->corner[i].floor_volt)
vreg->corner[i].open_loop_volt
= vreg->corner[i].floor_volt;
}
}
free_floor_adjust:
kfree(floor_range);
enforce_monotonicity:
/* Ensure that floor voltages increase monotonically. */
for (i = 1; i < vreg->corner_count; i++) {
if (vreg->corner[i].floor_volt
< vreg->corner[i - 1].floor_volt) {
cpr3_debug(vreg, "corner %d floor voltage=%d uV < corner %d voltage=%d uV; overriding: corner %d voltage=%d\n",
i, vreg->corner[i].floor_volt,
i - 1, vreg->corner[i - 1].floor_volt,
i, vreg->corner[i - 1].floor_volt);
vreg->corner[i].floor_volt
= vreg->corner[i - 1].floor_volt;
if (vreg->corner[i].open_loop_volt
< vreg->corner[i].floor_volt)
vreg->corner[i].open_loop_volt
= vreg->corner[i].floor_volt;
if (vreg->corner[i].ceiling_volt
< vreg->corner[i].floor_volt)
vreg->corner[i].ceiling_volt
= vreg->corner[i].floor_volt;
}
}
return rc;
}
/**
* cpr3_print_quots() - print CPR target quotients into the kernel log for
* debugging purposes
* @vreg: Pointer to the CPR3 regulator
*
* Return: none
*/
void cpr3_print_quots(struct cpr3_regulator *vreg)
{
int i, j, pos;
size_t buflen;
char *buf;
buflen = sizeof(*buf) * CPR3_RO_COUNT * (MAX_CHARS_PER_INT + 2);
buf = kzalloc(buflen, GFP_KERNEL);
if (!buf)
return;
for (i = 0; i < vreg->corner_count; i++) {
for (j = 0, pos = 0; j < CPR3_RO_COUNT; j++)
pos += scnprintf(buf + pos, buflen - pos, " %u",
vreg->corner[i].target_quot[j]);
cpr3_debug(vreg, "target quots[%2d]:%s\n", i, buf);
}
kfree(buf);
}
/**
* cpr3_adjust_fused_open_loop_voltages() - adjust the fused open-loop voltages
* for each fuse corner according to device tree values
* @vreg: Pointer to the CPR3 regulator
* @fuse_volt: Pointer to an array of the fused open-loop voltage
* values
*
* Voltage values in fuse_volt are modified in place.
*
* Return: 0 on success, errno on failure
*/
int cpr3_adjust_fused_open_loop_voltages(struct cpr3_regulator *vreg,
int *fuse_volt)
{
int i, rc, prev_volt;
int *volt_adjust;
if (!of_find_property(vreg->of_node,
"qcom,cpr-open-loop-voltage-fuse-adjustment", NULL)) {
/* No adjustment required. */
return 0;
}
volt_adjust = kcalloc(vreg->fuse_corner_count, sizeof(*volt_adjust),
GFP_KERNEL);
if (!volt_adjust)
return -ENOMEM;
rc = cpr3_parse_array_property(vreg,
"qcom,cpr-open-loop-voltage-fuse-adjustment",
vreg->fuse_corner_count, volt_adjust);
if (rc) {
cpr3_err(vreg, "could not load open-loop fused voltage adjustments, rc=%d\n",
rc);
goto done;
}
for (i = 0; i < vreg->fuse_corner_count; i++) {
if (volt_adjust[i]) {
prev_volt = fuse_volt[i];
fuse_volt[i] += volt_adjust[i];
cpr3_debug(vreg, "adjusted fuse corner %d open-loop voltage: %d --> %d uV\n",
i, prev_volt, fuse_volt[i]);
}
}
done:
kfree(volt_adjust);
return rc;
}
/**
* cpr3_adjust_open_loop_voltages() - adjust the open-loop voltages for each
* corner according to device tree values
* @vreg: Pointer to the CPR3 regulator
*
* Return: 0 on success, errno on failure
*/
int cpr3_adjust_open_loop_voltages(struct cpr3_regulator *vreg)
{
int i, rc, prev_volt, min_volt;
int *volt_adjust, *volt_diff;
if (!of_find_property(vreg->of_node,
"qcom,cpr-open-loop-voltage-adjustment", NULL)) {
/* No adjustment required. */
return 0;
}
volt_adjust = kcalloc(vreg->corner_count, sizeof(*volt_adjust),
GFP_KERNEL);
volt_diff = kcalloc(vreg->corner_count, sizeof(*volt_diff), GFP_KERNEL);
if (!volt_adjust || !volt_diff) {
rc = -ENOMEM;
goto done;
}
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-open-loop-voltage-adjustment", 1, volt_adjust);
if (rc) {
cpr3_err(vreg, "could not load open-loop voltage adjustments, rc=%d\n",
rc);
goto done;
}
for (i = 0; i < vreg->corner_count; i++) {
if (volt_adjust[i]) {
prev_volt = vreg->corner[i].open_loop_volt;
vreg->corner[i].open_loop_volt += volt_adjust[i];
cpr3_debug(vreg, "adjusted corner %d open-loop voltage: %d --> %d uV\n",
i, prev_volt, vreg->corner[i].open_loop_volt);
}
}
if (of_find_property(vreg->of_node,
"qcom,cpr-open-loop-voltage-min-diff", NULL)) {
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-open-loop-voltage-min-diff", 1, volt_diff);
if (rc) {
cpr3_err(vreg, "could not load minimum open-loop voltage differences, rc=%d\n",
rc);
goto done;
}
}
/*
* Ensure that open-loop voltages increase monotonically with respect
* to configurable minimum allowed differences.
*/
for (i = 1; i < vreg->corner_count; i++) {
min_volt = vreg->corner[i - 1].open_loop_volt + volt_diff[i];
if (vreg->corner[i].open_loop_volt < min_volt) {
cpr3_debug(vreg, "adjusted corner %d open-loop voltage=%d uV < corner %d voltage=%d uV + min diff=%d uV; overriding: corner %d voltage=%d\n",
i, vreg->corner[i].open_loop_volt,
i - 1, vreg->corner[i - 1].open_loop_volt,
volt_diff[i], i, min_volt);
vreg->corner[i].open_loop_volt = min_volt;
}
}
done:
kfree(volt_diff);
kfree(volt_adjust);
return rc;
}
/**
* cpr3_quot_adjustment() - returns the quotient adjustment value resulting from
* the specified voltage adjustment and RO scaling factor
* @ro_scale: The CPR ring oscillator (RO) scaling factor with units
* of QUOT/V
* @volt_adjust: The amount to adjust the voltage by in units of
* microvolts. This value may be positive or negative.
*/
int cpr3_quot_adjustment(int ro_scale, int volt_adjust)
{
unsigned long long temp;
int quot_adjust;
int sign = 1;
if (ro_scale < 0) {
sign = -sign;
ro_scale = -ro_scale;
}
if (volt_adjust < 0) {
sign = -sign;
volt_adjust = -volt_adjust;
}
temp = (unsigned long long)ro_scale * (unsigned long long)volt_adjust;
do_div(temp, 1000000);
quot_adjust = temp;
quot_adjust *= sign;
return quot_adjust;
}
/**
* cpr3_voltage_adjustment() - returns the voltage adjustment value resulting
* from the specified quotient adjustment and RO scaling factor
* @ro_scale: The CPR ring oscillator (RO) scaling factor with units
* of QUOT/V
* @quot_adjust: The amount to adjust the quotient by in units of
* QUOT. This value may be positive or negative.
*/
int cpr3_voltage_adjustment(int ro_scale, int quot_adjust)
{
unsigned long long temp;
int volt_adjust;
int sign = 1;
if (ro_scale < 0) {
sign = -sign;
ro_scale = -ro_scale;
}
if (quot_adjust < 0) {
sign = -sign;
quot_adjust = -quot_adjust;
}
if (ro_scale == 0)
return 0;
temp = (unsigned long long)quot_adjust * 1000000;
do_div(temp, ro_scale);
volt_adjust = temp;
volt_adjust *= sign;
return volt_adjust;
}
/**
* cpr3_parse_closed_loop_voltage_adjustments() - load per-fuse-corner and
* per-corner closed-loop adjustment values from device tree
* @vreg: Pointer to the CPR3 regulator
* @ro_sel: Array of ring oscillator values selected for each
* fuse corner
* @volt_adjust: Pointer to array which will be filled with the
* per-corner closed-loop adjustment voltages
* @volt_adjust_fuse: Pointer to array which will be filled with the
* per-fuse-corner closed-loop adjustment voltages
* @ro_scale: Pointer to array which will be filled with the
* per-fuse-corner RO scaling factor values with units of
* QUOT/V
*
* Return: 0 on success, errno on failure
*/
int cpr3_parse_closed_loop_voltage_adjustments(
struct cpr3_regulator *vreg, u64 *ro_sel,
int *volt_adjust, int *volt_adjust_fuse, int *ro_scale)
{
int i, rc;
u32 *ro_all_scale;
if (!of_find_property(vreg->of_node,
"qcom,cpr-closed-loop-voltage-adjustment", NULL)
&& !of_find_property(vreg->of_node,
"qcom,cpr-closed-loop-voltage-fuse-adjustment", NULL)
&& !vreg->aging_allowed) {
/* No adjustment required. */
return 0;
} else if (!of_find_property(vreg->of_node,
"qcom,cpr-ro-scaling-factor", NULL)) {
cpr3_err(vreg, "qcom,cpr-ro-scaling-factor is required for closed-loop voltage adjustment, but is missing\n");
return -EINVAL;
}
ro_all_scale = kcalloc(vreg->fuse_corner_count * CPR3_RO_COUNT,
sizeof(*ro_all_scale), GFP_KERNEL);
if (!ro_all_scale)
return -ENOMEM;
rc = cpr3_parse_array_property(vreg, "qcom,cpr-ro-scaling-factor",
vreg->fuse_corner_count * CPR3_RO_COUNT, ro_all_scale);
if (rc) {
cpr3_err(vreg, "could not load RO scaling factors, rc=%d\n",
rc);
goto done;
}
for (i = 0; i < vreg->fuse_corner_count; i++)
ro_scale[i] = ro_all_scale[i * CPR3_RO_COUNT + ro_sel[i]];
for (i = 0; i < vreg->corner_count; i++)
memcpy(vreg->corner[i].ro_scale,
&ro_all_scale[vreg->corner[i].cpr_fuse_corner * CPR3_RO_COUNT],
sizeof(*ro_all_scale) * CPR3_RO_COUNT);
if (of_find_property(vreg->of_node,
"qcom,cpr-closed-loop-voltage-fuse-adjustment", NULL)) {
rc = cpr3_parse_array_property(vreg,
"qcom,cpr-closed-loop-voltage-fuse-adjustment",
vreg->fuse_corner_count, volt_adjust_fuse);
if (rc) {
cpr3_err(vreg, "could not load closed-loop fused voltage adjustments, rc=%d\n",
rc);
goto done;
}
}
if (of_find_property(vreg->of_node,
"qcom,cpr-closed-loop-voltage-adjustment", NULL)) {
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-closed-loop-voltage-adjustment",
1, volt_adjust);
if (rc) {
cpr3_err(vreg, "could not load closed-loop voltage adjustments, rc=%d\n",
rc);
goto done;
}
}
done:
kfree(ro_all_scale);
return rc;
}
/**
* cpr3_apm_init() - initialize APM data for a CPR3 controller
* @ctrl: Pointer to the CPR3 controller
*
* This function loads memory array power mux (APM) data from device tree
* if it is present and requests a handle to the appropriate APM controller
* device.
*
* Return: 0 on success, errno on failure
*/
int cpr3_apm_init(struct cpr3_controller *ctrl)
{
struct device_node *node = ctrl->dev->of_node;
int rc;
if (!of_find_property(node, "qcom,apm-ctrl", NULL)) {
/* No APM used */
return 0;
}
ctrl->apm = msm_apm_ctrl_dev_get(ctrl->dev);
if (IS_ERR(ctrl->apm)) {
rc = PTR_ERR(ctrl->apm);
if (rc != -EPROBE_DEFER)
cpr3_err(ctrl, "APM get failed, rc=%d\n", rc);
return rc;
}
rc = of_property_read_u32(node, "qcom,apm-threshold-voltage",
&ctrl->apm_threshold_volt);
if (rc) {
cpr3_err(ctrl, "error reading qcom,apm-threshold-voltage, rc=%d\n",
rc);
return rc;
}
ctrl->apm_threshold_volt
= CPR3_ROUND(ctrl->apm_threshold_volt, ctrl->step_volt);
/* No error check since this is an optional property. */
of_property_read_u32(node, "qcom,apm-hysteresis-voltage",
&ctrl->apm_adj_volt);
ctrl->apm_adj_volt = CPR3_ROUND(ctrl->apm_adj_volt, ctrl->step_volt);
ctrl->apm_high_supply = MSM_APM_SUPPLY_APCC;
ctrl->apm_low_supply = MSM_APM_SUPPLY_MX;
return 0;
}
/**
* cpr3_mem_acc_init() - initialize mem-acc regulator data for
* a CPR3 regulator
* @ctrl: Pointer to the CPR3 controller
*
* Return: 0 on success, errno on failure
*/
int cpr3_mem_acc_init(struct cpr3_regulator *vreg)
{
struct cpr3_controller *ctrl = vreg->thread->ctrl;
u32 *temp;
int i, rc;
if (!ctrl->mem_acc_regulator) {
cpr3_info(ctrl, "not using memory accelerator regulator\n");
return 0;
}
temp = kcalloc(vreg->corner_count, sizeof(*temp), GFP_KERNEL);
if (!temp)
return -ENOMEM;
rc = cpr3_parse_corner_array_property(vreg, "qcom,mem-acc-voltage",
1, temp);
if (rc) {
cpr3_err(ctrl, "could not load mem-acc corners, rc=%d\n", rc);
} else {
for (i = 0; i < vreg->corner_count; i++)
vreg->corner[i].mem_acc_volt = temp[i];
}
kfree(temp);
return rc;
}
/**
* cpr4_load_core_and_temp_adj() - parse amount of voltage adjustment for
* per-online-core and per-temperature voltage adjustment for a
* given corner or corner band from device tree.
* @vreg: Pointer to the CPR3 regulator
* @num: Corner number or corner band number
* @use_corner_band: Boolean indicating if the CPR3 regulator supports
* adjustments per corner band
*
* Return: 0 on success, errno on failure
*/
static int cpr4_load_core_and_temp_adj(struct cpr3_regulator *vreg,
int num, bool use_corner_band)
{
struct cpr3_controller *ctrl = vreg->thread->ctrl;
struct cpr4_sdelta *sdelta;
int sdelta_size, i, j, pos, rc = 0;
char str[75];
size_t buflen;
char *buf;
sdelta = use_corner_band ? vreg->corner_band[num].sdelta :
vreg->corner[num].sdelta;
if (!sdelta->allow_core_count_adj && !sdelta->allow_temp_adj) {
/* corner doesn't need sdelta table */
sdelta->max_core_count = 0;
sdelta->temp_band_count = 0;
return rc;
}
sdelta_size = sdelta->max_core_count * sdelta->temp_band_count;
snprintf(str, sizeof(str), use_corner_band ?
"corner_band=%d core_config_count=%d temp_band_count=%d sdelta_size=%d\n"
: "corner=%d core_config_count=%d temp_band_count=%d sdelta_size=%d\n",
num, sdelta->max_core_count,
sdelta->temp_band_count, sdelta_size);
cpr3_debug(vreg, "%s", str);
sdelta->table = devm_kcalloc(ctrl->dev, sdelta_size,
sizeof(*sdelta->table), GFP_KERNEL);
if (!sdelta->table)
return -ENOMEM;
snprintf(str, sizeof(str), use_corner_band ?
"qcom,cpr-corner-band%d-temp-core-voltage-adjustment" :
"qcom,cpr-corner%d-temp-core-voltage-adjustment",
num + CPR3_CORNER_OFFSET);
rc = cpr3_parse_array_property(vreg, str, sdelta_size,
sdelta->table);
if (rc) {
cpr3_err(vreg, "could not load %s, rc=%d\n", str, rc);
return rc;
}
/*
* Convert sdelta margins from uV to PMIC steps and apply negation to
* follow the SDELTA register semantics.
*/
for (i = 0; i < sdelta_size; i++)
sdelta->table[i] = -(sdelta->table[i] / ctrl->step_volt);
buflen = sizeof(*buf) * sdelta_size * (MAX_CHARS_PER_INT + 2);
buf = kzalloc(buflen, GFP_KERNEL);
if (!buf)
return rc;
for (i = 0; i < sdelta->max_core_count; i++) {
for (j = 0, pos = 0; j < sdelta->temp_band_count; j++)
pos += scnprintf(buf + pos, buflen - pos, " %u",
sdelta->table[i * sdelta->temp_band_count + j]);
cpr3_debug(vreg, "sdelta[%d]:%s\n", i, buf);
}
kfree(buf);
return rc;
}
/**
* cpr4_parse_core_count_temp_voltage_adj() - parse configuration data for
* per-online-core and per-temperature voltage adjustment for
* a CPR3 regulator from device tree.
* @vreg: Pointer to the CPR3 regulator
* @use_corner_band: Boolean indicating if the CPR3 regulator supports
* adjustments per corner band
*
* This function supports parsing of per-online-core and per-temperature
* adjustments per corner or per corner band. CPR controllers which support
* corner bands apply the same adjustments to all corners within a corner band.
*
* Return: 0 on success, errno on failure
*/
int cpr4_parse_core_count_temp_voltage_adj(
struct cpr3_regulator *vreg, bool use_corner_band)
{
struct cpr3_controller *ctrl = vreg->thread->ctrl;
struct device_node *node = vreg->of_node;
struct cpr3_corner *corner;
struct cpr4_sdelta *sdelta;
int i, sdelta_table_count, rc = 0;
int *allow_core_count_adj = NULL, *allow_temp_adj = NULL;
char prop_str[75];
if (of_find_property(node, use_corner_band ?
"qcom,corner-band-allow-temp-adjustment"
: "qcom,corner-allow-temp-adjustment", NULL)) {
if (!ctrl->allow_temp_adj) {
cpr3_err(ctrl, "Temperature adjustment configurations missing\n");
return -EINVAL;
}
vreg->allow_temp_adj = true;
}
if (of_find_property(node, use_corner_band ?
"qcom,corner-band-allow-core-count-adjustment"
: "qcom,corner-allow-core-count-adjustment",
NULL)) {
rc = of_property_read_u32(node, "qcom,max-core-count",
&vreg->max_core_count);
if (rc) {
cpr3_err(vreg, "error reading qcom,max-core-count, rc=%d\n",
rc);
return -EINVAL;
}
vreg->allow_core_count_adj = true;
ctrl->allow_core_count_adj = true;
}
if (!vreg->allow_temp_adj && !vreg->allow_core_count_adj) {
/*
* Both per-online-core and temperature based adjustments are
* disabled for this regulator.
*/
return 0;
} else if (!vreg->allow_core_count_adj) {
/*
* Only per-temperature voltage adjusments are allowed.
* Keep max core count value as 1 to allocate SDELTA.
*/
vreg->max_core_count = 1;
}
if (vreg->allow_core_count_adj) {
allow_core_count_adj = kcalloc(vreg->corner_count,
sizeof(*allow_core_count_adj),
GFP_KERNEL);
if (!allow_core_count_adj)
return -ENOMEM;
snprintf(prop_str, sizeof(prop_str), use_corner_band ?
"qcom,corner-band-allow-core-count-adjustment" :
"qcom,corner-allow-core-count-adjustment");
rc = use_corner_band ?
cpr3_parse_corner_band_array_property(vreg, prop_str,
1, allow_core_count_adj) :
cpr3_parse_corner_array_property(vreg, prop_str,
1, allow_core_count_adj);
if (rc) {
cpr3_err(vreg, "error reading %s, rc=%d\n", prop_str,
rc);
goto done;
}
}
if (vreg->allow_temp_adj) {
allow_temp_adj = kcalloc(vreg->corner_count,
sizeof(*allow_temp_adj), GFP_KERNEL);
if (!allow_temp_adj) {
rc = -ENOMEM;
goto done;
}
snprintf(prop_str, sizeof(prop_str), use_corner_band ?
"qcom,corner-band-allow-temp-adjustment" :
"qcom,corner-allow-temp-adjustment");
rc = use_corner_band ?
cpr3_parse_corner_band_array_property(vreg, prop_str,
1, allow_temp_adj) :
cpr3_parse_corner_array_property(vreg, prop_str,
1, allow_temp_adj);
if (rc) {
cpr3_err(vreg, "error reading %s, rc=%d\n", prop_str,
rc);
goto done;
}
}
sdelta_table_count = use_corner_band ? vreg->corner_band_count :
vreg->corner_count;
for (i = 0; i < sdelta_table_count; i++) {
sdelta = devm_kzalloc(ctrl->dev, sizeof(*corner->sdelta),
GFP_KERNEL);
if (!sdelta) {
rc = -ENOMEM;
goto done;
}
if (allow_core_count_adj)
sdelta->allow_core_count_adj = allow_core_count_adj[i];
if (allow_temp_adj)
sdelta->allow_temp_adj = allow_temp_adj[i];
sdelta->max_core_count = vreg->max_core_count;
sdelta->temp_band_count = ctrl->temp_band_count;
if (use_corner_band)
vreg->corner_band[i].sdelta = sdelta;
else
vreg->corner[i].sdelta = sdelta;
rc = cpr4_load_core_and_temp_adj(vreg, i, use_corner_band);
if (rc) {
cpr3_err(vreg, "corner/band %d core and temp adjustment loading failed, rc=%d\n",
i, rc);
goto done;
}
}
done:
kfree(allow_core_count_adj);
kfree(allow_temp_adj);
return rc;
}
/**
* cprh_adjust_voltages_for_apm() - adjust per-corner floor and ceiling voltages
* so that they do not overlap the APM threshold voltage.
* @vreg: Pointer to the CPR3 regulator
*
* The memory array power mux (APM) must be configured for a specific supply
* based upon where the VDD voltage lies with respect to the APM threshold
* voltage. When using CPR hardware closed-loop, the voltage may vary anywhere
* between the floor and ceiling voltage without software notification.
* Therefore, it is required that the floor to ceiling range for every corner
* not intersect the APM threshold voltage. This function adjusts the floor to
* ceiling range for each corner which violates this requirement.
*
* The following algorithm is applied:
* if floor < threshold <= ceiling:
* if open_loop >= threshold, then floor = threshold - adj
* else ceiling = threshold - step
* where:
* adj = APM hysteresis voltage established to minimize the number of
* corners with artificially increased floor voltages
* step = voltage in microvolts of a single step of the VDD supply
*
* The open-loop voltage is also bounded by the new floor or ceiling value as
* needed.
*
* Return: none
*/
void cprh_adjust_voltages_for_apm(struct cpr3_regulator *vreg)
{
struct cpr3_controller *ctrl = vreg->thread->ctrl;
struct cpr3_corner *corner;
int i, adj, threshold, prev_ceiling, prev_floor, prev_open_loop;
if (!ctrl->apm_threshold_volt) {
/* APM not being used. */
return;
}
ctrl->apm_threshold_volt = CPR3_ROUND(ctrl->apm_threshold_volt,
ctrl->step_volt);
ctrl->apm_adj_volt = CPR3_ROUND(ctrl->apm_adj_volt, ctrl->step_volt);
threshold = ctrl->apm_threshold_volt;
adj = ctrl->apm_adj_volt;
for (i = 0; i < vreg->corner_count; i++) {
corner = &vreg->corner[i];
if (threshold <= corner->floor_volt
|| threshold > corner->ceiling_volt)
continue;
prev_floor = corner->floor_volt;
prev_ceiling = corner->ceiling_volt;
prev_open_loop = corner->open_loop_volt;
if (corner->open_loop_volt >= threshold) {
corner->floor_volt = max(corner->floor_volt,
threshold - adj);
if (corner->open_loop_volt < corner->floor_volt)
corner->open_loop_volt = corner->floor_volt;
} else {
corner->ceiling_volt = threshold - ctrl->step_volt;
}
if (corner->floor_volt != prev_floor
|| corner->ceiling_volt != prev_ceiling
|| corner->open_loop_volt != prev_open_loop)
cpr3_debug(vreg, "APM threshold=%d, APM adj=%d changed corner %d voltages; prev: floor=%d, ceiling=%d, open-loop=%d; new: floor=%d, ceiling=%d, open-loop=%d\n",
threshold, adj, i, prev_floor, prev_ceiling,
prev_open_loop, corner->floor_volt,
corner->ceiling_volt, corner->open_loop_volt);
}
}
/**
* cprh_adjust_voltages_for_mem_acc() - adjust per-corner floor and ceiling
* voltages so that they do not intersect the MEM ACC threshold
* voltage
* @vreg: Pointer to the CPR3 regulator
*
* The following algorithm is applied:
* if floor < threshold <= ceiling:
* if open_loop >= threshold, then floor = threshold
* else ceiling = threshold - step
* where:
* step = voltage in microvolts of a single step of the VDD supply
*
* The open-loop voltage is also bounded by the new floor or ceiling value as
* needed.
*
* Return: none
*/
void cprh_adjust_voltages_for_mem_acc(struct cpr3_regulator *vreg)
{
struct cpr3_controller *ctrl = vreg->thread->ctrl;
struct cpr3_corner *corner;
int i, threshold, prev_ceiling, prev_floor, prev_open_loop;
if (!ctrl->mem_acc_threshold_volt) {
/* MEM ACC not being used. */
return;
}
ctrl->mem_acc_threshold_volt = CPR3_ROUND(ctrl->mem_acc_threshold_volt,
ctrl->step_volt);
threshold = ctrl->mem_acc_threshold_volt;
for (i = 0; i < vreg->corner_count; i++) {
corner = &vreg->corner[i];
if (threshold <= corner->floor_volt
|| threshold > corner->ceiling_volt)
continue;
prev_floor = corner->floor_volt;
prev_ceiling = corner->ceiling_volt;
prev_open_loop = corner->open_loop_volt;
if (corner->open_loop_volt >= threshold) {
corner->floor_volt = max(corner->floor_volt, threshold);
if (corner->open_loop_volt < corner->floor_volt)
corner->open_loop_volt = corner->floor_volt;
} else {
corner->ceiling_volt = threshold - ctrl->step_volt;
}
if (corner->floor_volt != prev_floor
|| corner->ceiling_volt != prev_ceiling
|| corner->open_loop_volt != prev_open_loop)
cpr3_debug(vreg, "MEM ACC threshold=%d changed corner %d voltages; prev: floor=%d, ceiling=%d, open-loop=%d; new: floor=%d, ceiling=%d, open-loop=%d\n",
threshold, i, prev_floor, prev_ceiling,
prev_open_loop, corner->floor_volt,
corner->ceiling_volt, corner->open_loop_volt);
}
}
/**
* cpr3_apply_closed_loop_offset_voltages() - modify the closed-loop voltage
* adjustments by the amounts that are needed for this
* fuse combo
* @vreg: Pointer to the CPR3 regulator
* @volt_adjust: Array of closed-loop voltage adjustment values of length
* vreg->corner_count which is further adjusted based upon
* offset voltage fuse values.
* @fuse_volt_adjust: Fused closed-loop voltage adjustment values of length
* vreg->fuse_corner_count.
*
* Return: 0 on success, errno on failure
*/
static int cpr3_apply_closed_loop_offset_voltages(struct cpr3_regulator *vreg,
int *volt_adjust, int *fuse_volt_adjust)
{
u32 *corner_map;
int rc = 0, i;
if (!of_find_property(vreg->of_node,
"qcom,cpr-fused-closed-loop-voltage-adjustment-map", NULL)) {
/* No closed-loop offset required. */
return 0;
}
corner_map = kcalloc(vreg->corner_count, sizeof(*corner_map),
GFP_KERNEL);
if (!corner_map)
return -ENOMEM;
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-fused-closed-loop-voltage-adjustment-map",
1, corner_map);
if (rc)
goto done;
for (i = 0; i < vreg->corner_count; i++) {
if (corner_map[i] == 0) {
continue;
} else if (corner_map[i] > vreg->fuse_corner_count) {
cpr3_err(vreg, "corner %d mapped to invalid fuse corner: %u\n",
i, corner_map[i]);
rc = -EINVAL;
goto done;
}
volt_adjust[i] += fuse_volt_adjust[corner_map[i] - 1];
}
done:
kfree(corner_map);
return rc;
}
/**
* cpr3_enforce_inc_quotient_monotonicity() - Ensure that target quotients
* increase monotonically from lower to higher corners
* @vreg: Pointer to the CPR3 regulator
*
* Return: 0 on success, errno on failure
*/
static void cpr3_enforce_inc_quotient_monotonicity(struct cpr3_regulator *vreg)
{
int i, j;
for (i = 1; i < vreg->corner_count; i++) {
for (j = 0; j < CPR3_RO_COUNT; j++) {
if (vreg->corner[i].target_quot[j]
&& vreg->corner[i].target_quot[j]
< vreg->corner[i - 1].target_quot[j]) {
cpr3_debug(vreg, "corner %d RO%u target quot=%u < corner %d RO%u target quot=%u; overriding: corner %d RO%u target quot=%u\n",
i, j,
vreg->corner[i].target_quot[j],
i - 1, j,
vreg->corner[i - 1].target_quot[j],
i, j,
vreg->corner[i - 1].target_quot[j]);
vreg->corner[i].target_quot[j]
= vreg->corner[i - 1].target_quot[j];
}
}
}
}
/**
* cpr3_enforce_dec_quotient_monotonicity() - Ensure that target quotients
* decrease monotonically from higher to lower corners
* @vreg: Pointer to the CPR3 regulator
*
* Return: 0 on success, errno on failure
*/
static void cpr3_enforce_dec_quotient_monotonicity(struct cpr3_regulator *vreg)
{
int i, j;
for (i = vreg->corner_count - 2; i >= 0; i--) {
for (j = 0; j < CPR3_RO_COUNT; j++) {
if (vreg->corner[i + 1].target_quot[j]
&& vreg->corner[i].target_quot[j]
> vreg->corner[i + 1].target_quot[j]) {
cpr3_debug(vreg, "corner %d RO%u target quot=%u > corner %d RO%u target quot=%u; overriding: corner %d RO%u target quot=%u\n",
i, j,
vreg->corner[i].target_quot[j],
i + 1, j,
vreg->corner[i + 1].target_quot[j],
i, j,
vreg->corner[i + 1].target_quot[j]);
vreg->corner[i].target_quot[j]
= vreg->corner[i + 1].target_quot[j];
}
}
}
}
/**
* _cpr3_adjust_target_quotients() - adjust the target quotients for each
* corner of the regulator according to input adjustment and
* scaling arrays
* @vreg: Pointer to the CPR3 regulator
* @volt_adjust: Pointer to an array of closed-loop voltage adjustments
* with units of microvolts. The array must have
* vreg->corner_count number of elements.
* @ro_scale: Pointer to a flattened 2D array of RO scaling factors.
* The array must have an inner dimension of CPR3_RO_COUNT
* and an outer dimension of vreg->corner_count
* @label: Null terminated string providing a label for the type
* of adjustment.
*
* Return: true if any corners received a positive voltage adjustment (> 0),
* else false
*/
static bool _cpr3_adjust_target_quotients(struct cpr3_regulator *vreg,
const int *volt_adjust, const int *ro_scale, const char *label)
{
int i, j, quot_adjust;
bool is_increasing = false;
u32 prev_quot;
for (i = 0; i < vreg->corner_count; i++) {
for (j = 0; j < CPR3_RO_COUNT; j++) {
if (vreg->corner[i].target_quot[j]) {
quot_adjust = cpr3_quot_adjustment(
ro_scale[i * CPR3_RO_COUNT + j],
volt_adjust[i]);
if (quot_adjust) {
prev_quot = vreg->corner[i].
target_quot[j];
vreg->corner[i].target_quot[j]
+= quot_adjust;
cpr3_debug(vreg, "adjusted corner %d RO%d target quot %s: %u --> %u (%d uV)\n",
i, j, label, prev_quot,
vreg->corner[i].target_quot[j],
volt_adjust[i]);
}
}
}
if (volt_adjust[i] > 0)
is_increasing = true;
}
return is_increasing;
}
/**
* cpr3_adjust_target_quotients() - adjust the target quotients for each
* corner according to device tree values and fuse values
* @vreg: Pointer to the CPR3 regulator
* @fuse_volt_adjust: Fused closed-loop voltage adjustment values of length
* vreg->fuse_corner_count. This parameter could be null
* pointer when no fused adjustments are needed.
*
* Return: 0 on success, errno on failure
*/
int cpr3_adjust_target_quotients(struct cpr3_regulator *vreg,
int *fuse_volt_adjust)
{
int i, rc;
int *volt_adjust, *ro_scale;
bool explicit_adjustment, fused_adjustment, is_increasing;
explicit_adjustment = of_find_property(vreg->of_node,
"qcom,cpr-closed-loop-voltage-adjustment", NULL);
fused_adjustment = of_find_property(vreg->of_node,
"qcom,cpr-fused-closed-loop-voltage-adjustment-map", NULL);
if (!explicit_adjustment && !fused_adjustment && !vreg->aging_allowed) {
/* No adjustment required. */
return 0;
} else if (!of_find_property(vreg->of_node,
"qcom,cpr-ro-scaling-factor", NULL)) {
cpr3_err(vreg, "qcom,cpr-ro-scaling-factor is required for closed-loop voltage adjustment, but is missing\n");
return -EINVAL;
}
volt_adjust = kcalloc(vreg->corner_count, sizeof(*volt_adjust),
GFP_KERNEL);
ro_scale = kcalloc(vreg->corner_count * CPR3_RO_COUNT,
sizeof(*ro_scale), GFP_KERNEL);
if (!volt_adjust || !ro_scale) {
rc = -ENOMEM;
goto done;
}
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-ro-scaling-factor", CPR3_RO_COUNT, ro_scale);
if (rc) {
cpr3_err(vreg, "could not load RO scaling factors, rc=%d\n",
rc);
goto done;
}
for (i = 0; i < vreg->corner_count; i++)
memcpy(vreg->corner[i].ro_scale, &ro_scale[i * CPR3_RO_COUNT],
sizeof(*ro_scale) * CPR3_RO_COUNT);
if (explicit_adjustment) {
rc = cpr3_parse_corner_array_property(vreg,
"qcom,cpr-closed-loop-voltage-adjustment",
1, volt_adjust);
if (rc) {
cpr3_err(vreg, "could not load closed-loop voltage adjustments, rc=%d\n",
rc);
goto done;
}
_cpr3_adjust_target_quotients(vreg, volt_adjust, ro_scale,
"from DT");
cpr3_enforce_inc_quotient_monotonicity(vreg);
}
if (fused_adjustment && fuse_volt_adjust) {
memset(volt_adjust, 0,
sizeof(*volt_adjust) * vreg->corner_count);
rc = cpr3_apply_closed_loop_offset_voltages(vreg, volt_adjust,
fuse_volt_adjust);
if (rc) {
cpr3_err(vreg, "could not apply fused closed-loop voltage reductions, rc=%d\n",
rc);
goto done;
}
is_increasing = _cpr3_adjust_target_quotients(vreg, volt_adjust,
ro_scale, "from fuse");
if (is_increasing)
cpr3_enforce_inc_quotient_monotonicity(vreg);
else
cpr3_enforce_dec_quotient_monotonicity(vreg);
}
done:
kfree(volt_adjust);
kfree(ro_scale);
return rc;
}