Google Git
Sign in
android-kvm / linux / 976b029d06607f98f4156d8690d447ea8ed61c84 / . / drivers / cpufreq / tegra194-cpufreq.c
blob: 59865ea455a8e07c53721dbb5b5c9307ec478b18 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2020 - 2022, NVIDIA CORPORATION. All rights reserved
*/
#include <linux/cpu.h>
#include <linux/cpufreq.h>
#include <linux/dma-mapping.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/of_platform.h>
#include <linux/platform_device.h>
#include <linux/slab.h>
#include <linux/units.h>
#include <asm/smp_plat.h>
#include <soc/tegra/bpmp.h>
#include <soc/tegra/bpmp-abi.h>
#define KHZ 1000
#define REF_CLK_MHZ 408 /* 408 MHz */
#define CPUFREQ_TBL_STEP_HZ (50 * KHZ * KHZ)
#define MAX_CNT ~0U
#define MAX_DELTA_KHZ 115200
#define NDIV_MASK 0x1FF
#define CORE_OFFSET(cpu) (cpu * 8)
#define CMU_CLKS_BASE 0x2000
#define SCRATCH_FREQ_CORE_REG(data, cpu) (data->regs + CMU_CLKS_BASE + CORE_OFFSET(cpu))
#define MMCRAB_CLUSTER_BASE(cl) (0x30000 + (cl * 0x10000))
#define CLUSTER_ACTMON_BASE(data, cl) \
(data->regs + (MMCRAB_CLUSTER_BASE(cl) + data->soc->actmon_cntr_base))
#define CORE_ACTMON_CNTR_REG(data, cl, cpu) (CLUSTER_ACTMON_BASE(data, cl) + CORE_OFFSET(cpu))
/* cpufreq transisition latency */
#define TEGRA_CPUFREQ_TRANSITION_LATENCY (300 * 1000) /* unit in nanoseconds */
struct tegra_cpu_data {
u32 cpuid;
u32 clusterid;
void __iomem *freq_core_reg;
};
struct tegra_cpu_ctr {
u32 cpu;
u32 coreclk_cnt, last_coreclk_cnt;
u32 refclk_cnt, last_refclk_cnt;
};
struct read_counters_work {
struct work_struct work;
struct tegra_cpu_ctr c;
};
struct tegra_cpufreq_ops {
void (*read_counters)(struct tegra_cpu_ctr *c);
void (*set_cpu_ndiv)(struct cpufreq_policy *policy, u64 ndiv);
void (*get_cpu_cluster_id)(u32 cpu, u32 *cpuid, u32 *clusterid);
int (*get_cpu_ndiv)(u32 cpu, u32 cpuid, u32 clusterid, u64 *ndiv);
};
struct tegra_cpufreq_soc {
struct tegra_cpufreq_ops *ops;
int maxcpus_per_cluster;
unsigned int num_clusters;
phys_addr_t actmon_cntr_base;
u32 refclk_delta_min;
};
struct tegra194_cpufreq_data {
void __iomem *regs;
struct cpufreq_frequency_table **bpmp_luts;
const struct tegra_cpufreq_soc *soc;
bool icc_dram_bw_scaling;
struct tegra_cpu_data *cpu_data;
};
static struct workqueue_struct *read_counters_wq;
static int tegra_cpufreq_set_bw(struct cpufreq_policy *policy, unsigned long freq_khz)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
struct dev_pm_opp *opp;
struct device *dev;
int ret;
dev = get_cpu_device(policy->cpu);
if (!dev)
return -ENODEV;
opp = dev_pm_opp_find_freq_exact(dev, freq_khz * KHZ, true);
if (IS_ERR(opp))
return PTR_ERR(opp);
ret = dev_pm_opp_set_opp(dev, opp);
if (ret)
data->icc_dram_bw_scaling = false;
dev_pm_opp_put(opp);
return ret;
}
static void tegra_get_cpu_mpidr(void *mpidr)
{
*((u64 *)mpidr) = read_cpuid_mpidr() & MPIDR_HWID_BITMASK;
}
static void tegra234_get_cpu_cluster_id(u32 cpu, u32 *cpuid, u32 *clusterid)
{
u64 mpidr;
smp_call_function_single(cpu, tegra_get_cpu_mpidr, &mpidr, true);
if (cpuid)
*cpuid = MPIDR_AFFINITY_LEVEL(mpidr, 1);
if (clusterid)
*clusterid = MPIDR_AFFINITY_LEVEL(mpidr, 2);
}
static int tegra234_get_cpu_ndiv(u32 cpu, u32 cpuid, u32 clusterid, u64 *ndiv)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
*ndiv = readl(data->cpu_data[cpu].freq_core_reg) & NDIV_MASK;
return 0;
}
static void tegra234_set_cpu_ndiv(struct cpufreq_policy *policy, u64 ndiv)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
u32 cpu;
for_each_cpu(cpu, policy->cpus)
writel(ndiv, data->cpu_data[cpu].freq_core_reg);
}
/*
* This register provides access to two counter values with a single
* 64-bit read. The counter values are used to determine the average
* actual frequency a core has run at over a period of time.
* [63:32] PLLP counter: Counts at fixed frequency (408 MHz)
* [31:0] Core clock counter: Counts on every core clock cycle
*/
static void tegra234_read_counters(struct tegra_cpu_ctr *c)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
void __iomem *actmon_reg;
u32 delta_refcnt;
int cnt = 0;
u64 val;
actmon_reg = CORE_ACTMON_CNTR_REG(data, data->cpu_data[c->cpu].clusterid,
data->cpu_data[c->cpu].cpuid);
val = readq(actmon_reg);
c->last_refclk_cnt = upper_32_bits(val);
c->last_coreclk_cnt = lower_32_bits(val);
/*
* The sampling window is based on the minimum number of reference
* clock cycles which is known to give a stable value of CPU frequency.
*/
do {
val = readq(actmon_reg);
c->refclk_cnt = upper_32_bits(val);
c->coreclk_cnt = lower_32_bits(val);
if (c->refclk_cnt < c->last_refclk_cnt)
delta_refcnt = c->refclk_cnt + (MAX_CNT - c->last_refclk_cnt);
else
delta_refcnt = c->refclk_cnt - c->last_refclk_cnt;
if (++cnt >= 0xFFFF) {
pr_warn("cpufreq: problem with refclk on cpu:%d, delta_refcnt:%u, cnt:%d\n",
c->cpu, delta_refcnt, cnt);
break;
}
} while (delta_refcnt < data->soc->refclk_delta_min);
}
static struct tegra_cpufreq_ops tegra234_cpufreq_ops = {
.read_counters = tegra234_read_counters,
.get_cpu_cluster_id = tegra234_get_cpu_cluster_id,
.get_cpu_ndiv = tegra234_get_cpu_ndiv,
.set_cpu_ndiv = tegra234_set_cpu_ndiv,
};
static const struct tegra_cpufreq_soc tegra234_cpufreq_soc = {
.ops = &tegra234_cpufreq_ops,
.actmon_cntr_base = 0x9000,
.maxcpus_per_cluster = 4,
.num_clusters = 3,
.refclk_delta_min = 16000,
};
static const struct tegra_cpufreq_soc tegra239_cpufreq_soc = {
.ops = &tegra234_cpufreq_ops,
.actmon_cntr_base = 0x4000,
.maxcpus_per_cluster = 8,
.num_clusters = 1,
.refclk_delta_min = 16000,
};
static void tegra194_get_cpu_cluster_id(u32 cpu, u32 *cpuid, u32 *clusterid)
{
u64 mpidr;
smp_call_function_single(cpu, tegra_get_cpu_mpidr, &mpidr, true);
if (cpuid)
*cpuid = MPIDR_AFFINITY_LEVEL(mpidr, 0);
if (clusterid)
*clusterid = MPIDR_AFFINITY_LEVEL(mpidr, 1);
}
/*
* Read per-core Read-only system register NVFREQ_FEEDBACK_EL1.
* The register provides frequency feedback information to
* determine the average actual frequency a core has run at over
* a period of time.
* [31:0] PLLP counter: Counts at fixed frequency (408 MHz)
* [63:32] Core clock counter: counts on every core clock cycle
* where the core is architecturally clocking
*/
static u64 read_freq_feedback(void)
{
u64 val = 0;
asm volatile("mrs %0, s3_0_c15_c0_5" : "=r" (val) : );
return val;
}
static inline u32 map_ndiv_to_freq(struct mrq_cpu_ndiv_limits_response
*nltbl, u16 ndiv)
{
return nltbl->ref_clk_hz / KHZ * ndiv / (nltbl->pdiv * nltbl->mdiv);
}
static void tegra194_read_counters(struct tegra_cpu_ctr *c)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
u32 delta_refcnt;
int cnt = 0;
u64 val;
val = read_freq_feedback();
c->last_refclk_cnt = lower_32_bits(val);
c->last_coreclk_cnt = upper_32_bits(val);
/*
* The sampling window is based on the minimum number of reference
* clock cycles which is known to give a stable value of CPU frequency.
*/
do {
val = read_freq_feedback();
c->refclk_cnt = lower_32_bits(val);
c->coreclk_cnt = upper_32_bits(val);
if (c->refclk_cnt < c->last_refclk_cnt)
delta_refcnt = c->refclk_cnt + (MAX_CNT - c->last_refclk_cnt);
else
delta_refcnt = c->refclk_cnt - c->last_refclk_cnt;
if (++cnt >= 0xFFFF) {
pr_warn("cpufreq: problem with refclk on cpu:%d, delta_refcnt:%u, cnt:%d\n",
c->cpu, delta_refcnt, cnt);
break;
}
} while (delta_refcnt < data->soc->refclk_delta_min);
}
static void tegra_read_counters(struct work_struct *work)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
struct read_counters_work *read_counters_work;
struct tegra_cpu_ctr *c;
/*
* ref_clk_counter(32 bit counter) runs on constant clk,
* pll_p(408MHz).
* It will take = 2 ^ 32 / 408 MHz to overflow ref clk counter
* = 10526880 usec = 10.527 sec to overflow
*
* Like wise core_clk_counter(32 bit counter) runs on core clock.
* It's synchronized to crab_clk (cpu_crab_clk) which runs at
* freq of cluster. Assuming max cluster clock ~2000MHz,
* It will take = 2 ^ 32 / 2000 MHz to overflow core clk counter
* = ~2.147 sec to overflow
*/
read_counters_work = container_of(work, struct read_counters_work,
work);
c = &read_counters_work->c;
data->soc->ops->read_counters(c);
}
/*
* Return instantaneous cpu speed
* Instantaneous freq is calculated as -
* -Takes sample on every query of getting the freq.
* - Read core and ref clock counters;
* - Delay for X us
* - Read above cycle counters again
* - Calculates freq by subtracting current and previous counters
* divided by the delay time or eqv. of ref_clk_counter in delta time
* - Return Kcycles/second, freq in KHz
*
* delta time period = x sec
* = delta ref_clk_counter / (408 * 10^6) sec
* freq in Hz = cycles/sec
* = (delta cycles / x sec
* = (delta cycles * 408 * 10^6) / delta ref_clk_counter
* in KHz = (delta cycles * 408 * 10^3) / delta ref_clk_counter
*
* @cpu - logical cpu whose freq to be updated
* Returns freq in KHz on success, 0 if cpu is offline
*/
static unsigned int tegra194_calculate_speed(u32 cpu)
{
struct read_counters_work read_counters_work;
struct tegra_cpu_ctr c;
u32 delta_refcnt;
u32 delta_ccnt;
u32 rate_mhz;
/*
* Reconstruct cpu frequency over an observation/sampling window.
* Using workqueue to keep interrupts enabled during the interval.
*/
read_counters_work.c.cpu = cpu;
INIT_WORK_ONSTACK(&read_counters_work.work, tegra_read_counters);
queue_work_on(cpu, read_counters_wq, &read_counters_work.work);
flush_work(&read_counters_work.work);
c = read_counters_work.c;
if (c.coreclk_cnt < c.last_coreclk_cnt)
delta_ccnt = c.coreclk_cnt + (MAX_CNT - c.last_coreclk_cnt);
else
delta_ccnt = c.coreclk_cnt - c.last_coreclk_cnt;
if (!delta_ccnt)
return 0;
/* ref clock is 32 bits */
if (c.refclk_cnt < c.last_refclk_cnt)
delta_refcnt = c.refclk_cnt + (MAX_CNT - c.last_refclk_cnt);
else
delta_refcnt = c.refclk_cnt - c.last_refclk_cnt;
if (!delta_refcnt) {
pr_debug("cpufreq: %d is idle, delta_refcnt: 0\n", cpu);
return 0;
}
rate_mhz = ((unsigned long)(delta_ccnt * REF_CLK_MHZ)) / delta_refcnt;
return (rate_mhz * KHZ); /* in KHz */
}
static void tegra194_get_cpu_ndiv_sysreg(void *ndiv)
{
u64 ndiv_val;
asm volatile("mrs %0, s3_0_c15_c0_4" : "=r" (ndiv_val) : );
*(u64 *)ndiv = ndiv_val;
}
static int tegra194_get_cpu_ndiv(u32 cpu, u32 cpuid, u32 clusterid, u64 *ndiv)
{
return smp_call_function_single(cpu, tegra194_get_cpu_ndiv_sysreg, &ndiv, true);
}
static void tegra194_set_cpu_ndiv_sysreg(void *data)
{
u64 ndiv_val = *(u64 *)data;
asm volatile("msr s3_0_c15_c0_4, %0" : : "r" (ndiv_val));
}
static void tegra194_set_cpu_ndiv(struct cpufreq_policy *policy, u64 ndiv)
{
on_each_cpu_mask(policy->cpus, tegra194_set_cpu_ndiv_sysreg, &ndiv, true);
}
static unsigned int tegra194_get_speed(u32 cpu)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
u32 clusterid = data->cpu_data[cpu].clusterid;
struct cpufreq_frequency_table *pos;
unsigned int rate;
u64 ndiv;
int ret;
/* reconstruct actual cpu freq using counters */
rate = tegra194_calculate_speed(cpu);
/* get last written ndiv value */
ret = data->soc->ops->get_cpu_ndiv(cpu, data->cpu_data[cpu].cpuid, clusterid, &ndiv);
if (WARN_ON_ONCE(ret))
return rate;
/*
* If the reconstructed frequency has acceptable delta from
* the last written value, then return freq corresponding
* to the last written ndiv value from freq_table. This is
* done to return consistent value.
*/
cpufreq_for_each_valid_entry(pos, data->bpmp_luts[clusterid]) {
if (pos->driver_data != ndiv)
continue;
if (abs(pos->frequency - rate) > MAX_DELTA_KHZ) {
pr_warn("cpufreq: cpu%d,cur:%u,set:%u,delta:%d,set ndiv:%llu\n",
cpu, rate, pos->frequency, abs(rate - pos->frequency), ndiv);
} else {
rate = pos->frequency;
}
break;
}
return rate;
}
static int tegra_cpufreq_init_cpufreq_table(struct cpufreq_policy *policy,
struct cpufreq_frequency_table *bpmp_lut,
struct cpufreq_frequency_table **opp_table)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
struct cpufreq_frequency_table *freq_table = NULL;
struct cpufreq_frequency_table *pos;
struct device *cpu_dev;
struct dev_pm_opp *opp;
unsigned long rate;
int ret, max_opps;
int j = 0;
cpu_dev = get_cpu_device(policy->cpu);
if (!cpu_dev) {
pr_err("%s: failed to get cpu%d device\n", __func__, policy->cpu);
return -ENODEV;
}
/* Initialize OPP table mentioned in operating-points-v2 property in DT */
ret = dev_pm_opp_of_add_table_indexed(cpu_dev, 0);
if (!ret) {
max_opps = dev_pm_opp_get_opp_count(cpu_dev);
if (max_opps <= 0) {
dev_err(cpu_dev, "Failed to add OPPs\n");
return max_opps;
}
/* Disable all opps and cross-validate against LUT later */
for (rate = 0; ; rate++) {
opp = dev_pm_opp_find_freq_ceil(cpu_dev, &rate);
if (IS_ERR(opp))
break;
dev_pm_opp_put(opp);
dev_pm_opp_disable(cpu_dev, rate);
}
} else {
dev_err(cpu_dev, "Invalid or empty opp table in device tree\n");
data->icc_dram_bw_scaling = false;
return ret;
}
freq_table = kcalloc((max_opps + 1), sizeof(*freq_table), GFP_KERNEL);
if (!freq_table)
return -ENOMEM;
/*
* Cross check the frequencies from BPMP-FW LUT against the OPP's present in DT.
* Enable only those DT OPP's which are present in LUT also.
*/
cpufreq_for_each_valid_entry(pos, bpmp_lut) {
opp = dev_pm_opp_find_freq_exact(cpu_dev, pos->frequency * KHZ, false);
if (IS_ERR(opp))
continue;
dev_pm_opp_put(opp);
ret = dev_pm_opp_enable(cpu_dev, pos->frequency * KHZ);
if (ret < 0)
return ret;
freq_table[j].driver_data = pos->driver_data;
freq_table[j].frequency = pos->frequency;
j++;
}
freq_table[j].driver_data = pos->driver_data;
freq_table[j].frequency = CPUFREQ_TABLE_END;
*opp_table = &freq_table[0];
dev_pm_opp_set_sharing_cpus(cpu_dev, policy->cpus);
return ret;
}
static int tegra194_cpufreq_init(struct cpufreq_policy *policy)
{
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
int maxcpus_per_cluster = data->soc->maxcpus_per_cluster;
u32 clusterid = data->cpu_data[policy->cpu].clusterid;
struct cpufreq_frequency_table *freq_table;
struct cpufreq_frequency_table *bpmp_lut;
u32 start_cpu, cpu;
int ret;
if (clusterid >= data->soc->num_clusters || !data->bpmp_luts[clusterid])
return -EINVAL;
start_cpu = rounddown(policy->cpu, maxcpus_per_cluster);
/* set same policy for all cpus in a cluster */
for (cpu = start_cpu; cpu < (start_cpu + maxcpus_per_cluster); cpu++) {
if (cpu_possible(cpu))
cpumask_set_cpu(cpu, policy->cpus);
}
policy->cpuinfo.transition_latency = TEGRA_CPUFREQ_TRANSITION_LATENCY;
bpmp_lut = data->bpmp_luts[clusterid];
if (data->icc_dram_bw_scaling) {
ret = tegra_cpufreq_init_cpufreq_table(policy, bpmp_lut, &freq_table);
if (!ret) {
policy->freq_table = freq_table;
return 0;
}
}
data->icc_dram_bw_scaling = false;
policy->freq_table = bpmp_lut;
pr_info("OPP tables missing from DT, EMC frequency scaling disabled\n");
return 0;
}
static int tegra194_cpufreq_online(struct cpufreq_policy *policy)
{
/* We did light-weight tear down earlier, nothing to do here */
return 0;
}
static int tegra194_cpufreq_offline(struct cpufreq_policy *policy)
{
/*
* Preserve policy->driver_data and don't free resources on light-weight
* tear down.
*/
return 0;
}
static int tegra194_cpufreq_exit(struct cpufreq_policy *policy)
{
struct device *cpu_dev = get_cpu_device(policy->cpu);
dev_pm_opp_remove_all_dynamic(cpu_dev);
dev_pm_opp_of_cpumask_remove_table(policy->related_cpus);
return 0;
}
static int tegra194_cpufreq_set_target(struct cpufreq_policy *policy,
unsigned int index)
{
struct cpufreq_frequency_table *tbl = policy->freq_table + index;
struct tegra194_cpufreq_data *data = cpufreq_get_driver_data();
/*
* Each core writes frequency in per core register. Then both cores
* in a cluster run at same frequency which is the maximum frequency
* request out of the values requested by both cores in that cluster.
*/
data->soc->ops->set_cpu_ndiv(policy, (u64)tbl->driver_data);
if (data->icc_dram_bw_scaling)
tegra_cpufreq_set_bw(policy, tbl->frequency);
return 0;
}
static struct cpufreq_driver tegra194_cpufreq_driver = {
.name = "tegra194",
.flags = CPUFREQ_CONST_LOOPS | CPUFREQ_NEED_INITIAL_FREQ_CHECK |
CPUFREQ_IS_COOLING_DEV,
.verify = cpufreq_generic_frequency_table_verify,
.target_index = tegra194_cpufreq_set_target,
.get = tegra194_get_speed,
.init = tegra194_cpufreq_init,
.exit = tegra194_cpufreq_exit,
.online = tegra194_cpufreq_online,
.offline = tegra194_cpufreq_offline,
.attr = cpufreq_generic_attr,
};
static struct tegra_cpufreq_ops tegra194_cpufreq_ops = {
.read_counters = tegra194_read_counters,
.get_cpu_cluster_id = tegra194_get_cpu_cluster_id,
.get_cpu_ndiv = tegra194_get_cpu_ndiv,
.set_cpu_ndiv = tegra194_set_cpu_ndiv,
};
static const struct tegra_cpufreq_soc tegra194_cpufreq_soc = {
.ops = &tegra194_cpufreq_ops,
.maxcpus_per_cluster = 2,
.num_clusters = 4,
.refclk_delta_min = 16000,
};
static void tegra194_cpufreq_free_resources(void)
{
destroy_workqueue(read_counters_wq);
}
static struct cpufreq_frequency_table *
tegra_cpufreq_bpmp_read_lut(struct platform_device *pdev, struct tegra_bpmp *bpmp,
unsigned int cluster_id)
{
struct cpufreq_frequency_table *freq_table;
struct mrq_cpu_ndiv_limits_response resp;
unsigned int num_freqs, ndiv, delta_ndiv;
struct mrq_cpu_ndiv_limits_request req;
struct tegra_bpmp_message msg;
u16 freq_table_step_size;
int err, index;
memset(&req, 0, sizeof(req));
req.cluster_id = cluster_id;
memset(&msg, 0, sizeof(msg));
msg.mrq = MRQ_CPU_NDIV_LIMITS;
msg.tx.data = &req;
msg.tx.size = sizeof(req);
msg.rx.data = &resp;
msg.rx.size = sizeof(resp);
err = tegra_bpmp_transfer(bpmp, &msg);
if (err)
return ERR_PTR(err);
if (msg.rx.ret == -BPMP_EINVAL) {
/* Cluster not available */
return NULL;
}
if (msg.rx.ret)
return ERR_PTR(-EINVAL);
/*
* Make sure frequency table step is a multiple of mdiv to match
* vhint table granularity.
*/
freq_table_step_size = resp.mdiv *
DIV_ROUND_UP(CPUFREQ_TBL_STEP_HZ, resp.ref_clk_hz);
dev_dbg(&pdev->dev, "cluster %d: frequency table step size: %d\n",
cluster_id, freq_table_step_size);
delta_ndiv = resp.ndiv_max - resp.ndiv_min;
if (unlikely(delta_ndiv == 0)) {
num_freqs = 1;
} else {
/* We store both ndiv_min and ndiv_max hence the +1 */
num_freqs = delta_ndiv / freq_table_step_size + 1;
}
num_freqs += (delta_ndiv % freq_table_step_size) ? 1 : 0;
freq_table = devm_kcalloc(&pdev->dev, num_freqs + 1,
sizeof(*freq_table), GFP_KERNEL);
if (!freq_table)
return ERR_PTR(-ENOMEM);
for (index = 0, ndiv = resp.ndiv_min;
ndiv < resp.ndiv_max;
index++, ndiv += freq_table_step_size) {
freq_table[index].driver_data = ndiv;
freq_table[index].frequency = map_ndiv_to_freq(&resp, ndiv);
}
freq_table[index].driver_data = resp.ndiv_max;
freq_table[index++].frequency = map_ndiv_to_freq(&resp, resp.ndiv_max);
freq_table[index].frequency = CPUFREQ_TABLE_END;
return freq_table;
}
static int tegra194_cpufreq_store_physids(unsigned int cpu, struct tegra194_cpufreq_data *data)
{
int num_cpus = data->soc->maxcpus_per_cluster * data->soc->num_clusters;
u32 cpuid, clusterid;
u64 mpidr_id;
if (cpu > (num_cpus - 1)) {
pr_err("cpufreq: wrong num of cpus or clusters in soc data\n");
return -EINVAL;
}
data->soc->ops->get_cpu_cluster_id(cpu, &cpuid, &clusterid);
mpidr_id = (clusterid * data->soc->maxcpus_per_cluster) + cpuid;
data->cpu_data[cpu].cpuid = cpuid;
data->cpu_data[cpu].clusterid = clusterid;
data->cpu_data[cpu].freq_core_reg = SCRATCH_FREQ_CORE_REG(data, mpidr_id);
return 0;
}
static int tegra194_cpufreq_probe(struct platform_device *pdev)
{
const struct tegra_cpufreq_soc *soc;
struct tegra194_cpufreq_data *data;
struct tegra_bpmp *bpmp;
struct device *cpu_dev;
int err, i;
u32 cpu;
data = devm_kzalloc(&pdev->dev, sizeof(*data), GFP_KERNEL);
if (!data)
return -ENOMEM;
soc = of_device_get_match_data(&pdev->dev);
if (soc->ops && soc->maxcpus_per_cluster && soc->num_clusters && soc->refclk_delta_min) {
data->soc = soc;
} else {
dev_err(&pdev->dev, "soc data missing\n");
return -EINVAL;
}
data->bpmp_luts = devm_kcalloc(&pdev->dev, data->soc->num_clusters,
sizeof(*data->bpmp_luts), GFP_KERNEL);
if (!data->bpmp_luts)
return -ENOMEM;
if (soc->actmon_cntr_base) {
/* mmio registers are used for frequency request and re-construction */
data->regs = devm_platform_ioremap_resource(pdev, 0);
if (IS_ERR(data->regs))
return PTR_ERR(data->regs);
}
data->cpu_data = devm_kcalloc(&pdev->dev, data->soc->num_clusters *
data->soc->maxcpus_per_cluster,
sizeof(*data->cpu_data), GFP_KERNEL);
if (!data->cpu_data)
return -ENOMEM;
platform_set_drvdata(pdev, data);
bpmp = tegra_bpmp_get(&pdev->dev);
if (IS_ERR(bpmp))
return PTR_ERR(bpmp);
read_counters_wq = alloc_workqueue("read_counters_wq", __WQ_LEGACY, 1);
if (!read_counters_wq) {
dev_err(&pdev->dev, "fail to create_workqueue\n");
err = -EINVAL;
goto put_bpmp;
}
for (i = 0; i < data->soc->num_clusters; i++) {
data->bpmp_luts[i] = tegra_cpufreq_bpmp_read_lut(pdev, bpmp, i);
if (IS_ERR(data->bpmp_luts[i])) {
err = PTR_ERR(data->bpmp_luts[i]);
goto err_free_res;
}
}
for_each_possible_cpu(cpu) {
err = tegra194_cpufreq_store_physids(cpu, data);
if (err)
goto err_free_res;
}
tegra194_cpufreq_driver.driver_data = data;
/* Check for optional OPPv2 and interconnect paths on CPU0 to enable ICC scaling */
cpu_dev = get_cpu_device(0);
if (!cpu_dev) {
err = -EPROBE_DEFER;
goto err_free_res;
}
if (dev_pm_opp_of_get_opp_desc_node(cpu_dev)) {
err = dev_pm_opp_of_find_icc_paths(cpu_dev, NULL);
if (!err)
data->icc_dram_bw_scaling = true;
}
err = cpufreq_register_driver(&tegra194_cpufreq_driver);
if (!err)
goto put_bpmp;
err_free_res:
tegra194_cpufreq_free_resources();
put_bpmp:
tegra_bpmp_put(bpmp);
return err;
}
static void tegra194_cpufreq_remove(struct platform_device *pdev)
{
cpufreq_unregister_driver(&tegra194_cpufreq_driver);
tegra194_cpufreq_free_resources();
}
static const struct of_device_id tegra194_cpufreq_of_match[] = {
{ .compatible = "nvidia,tegra194-ccplex", .data = &tegra194_cpufreq_soc },
{ .compatible = "nvidia,tegra234-ccplex-cluster", .data = &tegra234_cpufreq_soc },
{ .compatible = "nvidia,tegra239-ccplex-cluster", .data = &tegra239_cpufreq_soc },
{ /* sentinel */ }
};
MODULE_DEVICE_TABLE(of, tegra194_cpufreq_of_match);
static struct platform_driver tegra194_ccplex_driver = {
.driver = {
.name = "tegra194-cpufreq",
.of_match_table = tegra194_cpufreq_of_match,
},
.probe = tegra194_cpufreq_probe,
.remove_new = tegra194_cpufreq_remove,
};
module_platform_driver(tegra194_ccplex_driver);
MODULE_AUTHOR("Mikko Perttunen <mperttunen@nvidia.com>");
MODULE_AUTHOR("Sumit Gupta <sumitg@nvidia.com>");
MODULE_DESCRIPTION("NVIDIA Tegra194 cpufreq driver");
MODULE_LICENSE("GPL v2");