/* Copyright (c) 2011-2015, 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. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "spm_driver.h" #define VDD_DEFAULT 0xDEADF00D #define SLP_CMD_BIT 17 #define PC_MODE_BIT 16 #define RET_MODE_BIT 15 #define EVENT_SYNC_BIT 24 #define ISAR_BIT 3 #define SPM_EN_BIT 0 struct msm_spm_power_modes { uint32_t mode; uint32_t ctl; }; struct msm_spm_device { struct list_head list; bool initialized; const char *name; struct msm_spm_driver_data reg_data; struct msm_spm_power_modes *modes; uint32_t num_modes; uint32_t cpu_vdd; struct cpumask mask; void __iomem *q2s_reg; bool qchannel_ignore; bool allow_rpm_hs; bool use_spm_clk_gating; bool use_qchannel_for_wfi; void __iomem *flush_base_addr; void __iomem *slpreq_base_addr; }; struct msm_spm_vdd_info { struct msm_spm_device *vctl_dev; uint32_t vlevel; int err; }; static LIST_HEAD(spm_list); static DEFINE_PER_CPU_SHARED_ALIGNED(struct msm_spm_device, msm_cpu_spm_device); static DEFINE_PER_CPU(struct msm_spm_device *, cpu_vctl_device); static void msm_spm_smp_set_vdd(void *data) { struct msm_spm_vdd_info *info = (struct msm_spm_vdd_info *)data; struct msm_spm_device *dev = info->vctl_dev; dev->cpu_vdd = info->vlevel; info->err = msm_spm_drv_set_vdd(&dev->reg_data, info->vlevel); } /** * msm_spm_probe_done(): Verify and return the status of the cpu(s) and l2 * probe. * Return: 0 if all spm devices have been probed, else return -EPROBE_DEFER. * if probe failed, then return the err number for that failure. */ int msm_spm_probe_done(void) { struct msm_spm_device *dev; int cpu; int ret = 0; for_each_possible_cpu(cpu) { dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -EPROBE_DEFER; ret = IS_ERR(dev); if (ret) return ret; } return 0; } EXPORT_SYMBOL(msm_spm_probe_done); void msm_spm_dump_regs(unsigned int cpu) { dump_regs(&per_cpu(msm_cpu_spm_device, cpu).reg_data, cpu); } /** * msm_spm_set_vdd(): Set core voltage * @cpu: core id * @vlevel: Encoded PMIC data. * * Return: 0 on success or -(ERRNO) on failure. */ int msm_spm_set_vdd(unsigned int cpu, unsigned int vlevel) { struct msm_spm_vdd_info info; struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); int ret; if (!dev) return -EPROBE_DEFER; ret = IS_ERR(dev); if (ret) return ret; info.vctl_dev = dev; info.vlevel = vlevel; ret = smp_call_function_any(&dev->mask, msm_spm_smp_set_vdd, &info, true); if (ret) return ret; return info.err; } EXPORT_SYMBOL(msm_spm_set_vdd); /** * msm_spm_get_vdd(): Get core voltage * @cpu: core id * @return: Returns encoded PMIC data. */ int msm_spm_get_vdd(unsigned int cpu) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -EPROBE_DEFER; return msm_spm_drv_get_vdd(&dev->reg_data) ? : -EINVAL; } EXPORT_SYMBOL(msm_spm_get_vdd); static void msm_spm_config_q2s(struct msm_spm_device *dev, unsigned int mode) { uint32_t spm_legacy_mode = 0; uint32_t qchannel_ignore = 0; uint32_t val = 0; if (!dev->q2s_reg) return; switch (mode) { case MSM_SPM_MODE_DISABLED: case MSM_SPM_MODE_CLOCK_GATING: qchannel_ignore = !dev->use_qchannel_for_wfi; spm_legacy_mode = 0; break; case MSM_SPM_MODE_RETENTION: qchannel_ignore = 0; spm_legacy_mode = 0; break; case MSM_SPM_MODE_GDHS: case MSM_SPM_MODE_POWER_COLLAPSE: qchannel_ignore = dev->qchannel_ignore; spm_legacy_mode = 1; break; default: break; } val = spm_legacy_mode << 2 | qchannel_ignore << 1; __raw_writel(val, dev->q2s_reg); mb(); } static void msm_spm_config_hw_flush(struct msm_spm_device *dev, unsigned int mode) { uint32_t val = 0; if (!dev->flush_base_addr) return; switch (mode) { case MSM_SPM_MODE_FASTPC: case MSM_SPM_MODE_POWER_COLLAPSE: val = BIT(0); break; default: break; } __raw_writel(val, dev->flush_base_addr); } static void msm_spm_config_slpreq(struct msm_spm_device *dev, unsigned int mode) { uint32_t val = 0; if (!dev->slpreq_base_addr) return; switch (mode) { case MSM_SPM_MODE_FASTPC: case MSM_SPM_MODE_GDHS: case MSM_SPM_MODE_POWER_COLLAPSE: val = BIT(4); break; default: break; } val = (__raw_readl(dev->slpreq_base_addr) & ~BIT(4)) | val; __raw_writel(val, dev->slpreq_base_addr); } static int msm_spm_dev_set_low_power_mode(struct msm_spm_device *dev, unsigned int mode, bool notify_rpm) { uint32_t i; int ret = -EINVAL; uint32_t ctl; if (!dev) { pr_err("dev is NULL\n"); return -ENODEV; } if (!dev->initialized) return -ENXIO; if (!dev->num_modes) return 0; if (mode == MSM_SPM_MODE_DISABLED) { ret = msm_spm_drv_set_spm_enable(&dev->reg_data, false); } else if (!msm_spm_drv_set_spm_enable(&dev->reg_data, true)) { for (i = 0; i < dev->num_modes; i++) { if (dev->modes[i].mode != mode) continue; ctl = dev->modes[i].ctl; if (!dev->allow_rpm_hs && notify_rpm) ctl &= ~BIT(SLP_CMD_BIT); break; } ret = msm_spm_drv_set_low_power_mode(&dev->reg_data, ctl); } msm_spm_config_q2s(dev, mode); msm_spm_config_hw_flush(dev, mode); msm_spm_config_slpreq(dev, mode); return ret; } static int msm_spm_dev_init(struct msm_spm_device *dev, struct msm_spm_platform_data *data) { int i, ret = -ENOMEM; uint32_t offset = 0; dev->cpu_vdd = VDD_DEFAULT; dev->num_modes = data->num_modes; dev->modes = kmalloc( sizeof(struct msm_spm_power_modes) * dev->num_modes, GFP_KERNEL); if (!dev->modes) goto spm_failed_malloc; ret = msm_spm_drv_init(&dev->reg_data, data); if (ret) goto spm_failed_init; for (i = 0; i < dev->num_modes; i++) { /* Default offset is 0 and gets updated as we write more * sequences into SPM */ dev->modes[i].ctl = data->modes[i].ctl | ((offset & 0x1FF) << 4); ret = msm_spm_drv_write_seq_data(&dev->reg_data, data->modes[i].cmd, &offset); if (ret < 0) goto spm_failed_init; dev->modes[i].mode = data->modes[i].mode; } msm_spm_drv_reinit(&dev->reg_data, dev->num_modes ? true : false); dev->initialized = true; return 0; spm_failed_init: kfree(dev->modes); spm_failed_malloc: return ret; } /** * msm_spm_turn_on_cpu_rail(): Power on cpu rail before turning on core * @node: The SPM node that controls the voltage for the CPU * @val: The value to be set on the rail * @cpu: The cpu for this with rail is being powered on */ int msm_spm_turn_on_cpu_rail(struct device_node *vctl_node, unsigned int val, int cpu, int vctl_offset) { uint32_t timeout = 2000; /* delay for voltage to settle on the core */ struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); void __iomem *base; base = of_iomap(vctl_node, 1); if (base) { /* * Program Q2S to disable SPM legacy mode and ignore Q2S * channel requests. * bit[1] = qchannel_ignore = 1 * bit[2] = spm_legacy_mode = 0 */ writel_relaxed(0x2, base); mb(); iounmap(base); } base = of_iomap(vctl_node, 0); if (!base) return -ENOMEM; if (dev && (dev->cpu_vdd != VDD_DEFAULT)) return 0; /* Set the CPU supply regulator voltage */ val = (val & 0xFF); writel_relaxed(val, base + vctl_offset); mb(); udelay(timeout); /* Enable the CPU supply regulator*/ val = 0x30080; writel_relaxed(val, base + vctl_offset); mb(); udelay(timeout); iounmap(base); return 0; } EXPORT_SYMBOL(msm_spm_turn_on_cpu_rail); void msm_spm_reinit(void) { unsigned int cpu; for_each_possible_cpu(cpu) msm_spm_drv_reinit( &per_cpu(msm_cpu_spm_device.reg_data, cpu), true); } EXPORT_SYMBOL(msm_spm_reinit); /* * msm_spm_is_mode_avail() - Specifies if a mode is available for the cpu * It should only be used to decide a mode before lpm driver is probed. * @mode: SPM LPM mode to be selected */ bool msm_spm_is_mode_avail(unsigned int mode) { struct msm_spm_device *dev = &__get_cpu_var(msm_cpu_spm_device); int i; for (i = 0; i < dev->num_modes; i++) { if (dev->modes[i].mode == mode) return true; } return false; } /** * msm_spm_is_avs_enabled() - Functions returns 1 if AVS is enabled and * 0 if it is not. * @cpu: specifies cpu's avs should be read * * Returns errno in case of failure or AVS enable state otherwise */ int msm_spm_is_avs_enabled(unsigned int cpu) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_get_avs_enable(&dev->reg_data); } EXPORT_SYMBOL(msm_spm_is_avs_enabled); /** * msm_spm_avs_enable() - Enables AVS on the SAW that controls this cpu's * voltage. * @cpu: specifies which cpu's avs should be enabled * * Returns errno in case of failure or 0 if successful */ int msm_spm_avs_enable(unsigned int cpu) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_avs_enable(&dev->reg_data, true); } EXPORT_SYMBOL(msm_spm_avs_enable); /** * msm_spm_avs_disable() - Disables AVS on the SAW that controls this cpu's * voltage. * @cpu: specifies which cpu's avs should be enabled * * Returns errno in case of failure or 0 if successful */ int msm_spm_avs_disable(unsigned int cpu) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_avs_enable(&dev->reg_data, false); } EXPORT_SYMBOL(msm_spm_avs_disable); /** * msm_spm_avs_set_limit() - Set maximum and minimum AVS limits on the * SAW that controls this cpu's voltage. * @cpu: specify which cpu's avs should be configured * @min_lvl: specifies the minimum PMIC output voltage control register * value that may be sent to the PMIC * @max_lvl: specifies the maximum PMIC output voltage control register * value that may be sent to the PMIC * Returns errno in case of failure or 0 if successful */ int msm_spm_avs_set_limit(unsigned int cpu, uint32_t min_lvl, uint32_t max_lvl) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_avs_limit(&dev->reg_data, min_lvl, max_lvl); } EXPORT_SYMBOL(msm_spm_avs_set_limit); /** * msm_spm_avs_enable_irq() - Enable an AVS interrupt * @cpu: specifies which CPU's AVS should be configured * @irq: specifies which interrupt to enable * * Returns errno in case of failure or 0 if successful. */ int msm_spm_avs_enable_irq(unsigned int cpu, enum msm_spm_avs_irq irq) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_avs_irq_enable(&dev->reg_data, irq, true); } EXPORT_SYMBOL(msm_spm_avs_enable_irq); /** * msm_spm_avs_disable_irq() - Disable an AVS interrupt * @cpu: specifies which CPU's AVS should be configured * @irq: specifies which interrupt to disable * * Returns errno in case of failure or 0 if successful. */ int msm_spm_avs_disable_irq(unsigned int cpu, enum msm_spm_avs_irq irq) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_avs_irq_enable(&dev->reg_data, irq, false); } EXPORT_SYMBOL(msm_spm_avs_disable_irq); /** * msm_spm_avs_clear_irq() - Clear a latched AVS interrupt * @cpu: specifies which CPU's AVS should be configured * @irq: specifies which interrupt to clear * * Returns errno in case of failure or 0 if successful. */ int msm_spm_avs_clear_irq(unsigned int cpu, enum msm_spm_avs_irq irq) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_avs_clear_irq(&dev->reg_data, irq); } EXPORT_SYMBOL(msm_spm_avs_clear_irq); /** * msm_spm_set_low_power_mode() - Configure SPM start address for low power mode * @mode: SPM LPM mode to enter * @notify_rpm: Notify RPM in this mode */ int msm_spm_set_low_power_mode(unsigned int mode, bool notify_rpm) { struct msm_spm_device *dev = &__get_cpu_var(msm_cpu_spm_device); return msm_spm_dev_set_low_power_mode(dev, mode, notify_rpm); } EXPORT_SYMBOL(msm_spm_set_low_power_mode); /** * msm_spm_init(): Board initalization function * @data: platform specific SPM register configuration data * @nr_devs: Number of SPM devices being initialized */ int __init msm_spm_init(struct msm_spm_platform_data *data, int nr_devs) { unsigned int cpu; int ret = 0; BUG_ON((nr_devs < num_possible_cpus()) || !data); for_each_possible_cpu(cpu) { struct msm_spm_device *dev = &per_cpu(msm_cpu_spm_device, cpu); ret = msm_spm_dev_init(dev, &data[cpu]); if (ret < 0) { pr_warn("%s():failed CPU:%u ret:%d\n", __func__, cpu, ret); break; } } return ret; } struct msm_spm_device *msm_spm_get_device_by_name(const char *name) { struct list_head *list; list_for_each(list, &spm_list) { struct msm_spm_device *dev = list_entry(list, typeof(*dev), list); if (dev->name && !strcmp(dev->name, name)) return dev; } return ERR_PTR(-ENODEV); } int msm_spm_config_low_power_mode(struct msm_spm_device *dev, unsigned int mode, bool notify_rpm) { return msm_spm_dev_set_low_power_mode(dev, mode, notify_rpm); } #ifdef CONFIG_MSM_L2_SPM /** * msm_spm_apcs_set_phase(): Set number of SMPS phases. * @cpu: cpu which is requesting the change in number of phases. * @phase_cnt: Number of phases to be set active */ int msm_spm_apcs_set_phase(int cpu, unsigned int phase_cnt) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_pmic_data(&dev->reg_data, MSM_SPM_PMIC_PHASE_PORT, phase_cnt); } EXPORT_SYMBOL(msm_spm_apcs_set_phase); /** msm_spm_enable_fts_lpm() : Enable FTS to switch to low power * when the cores are in low power modes * @cpu: cpu that is entering low power mode. * @mode: The mode configuration for FTS */ int msm_spm_enable_fts_lpm(int cpu, uint32_t mode) { struct msm_spm_device *dev = per_cpu(cpu_vctl_device, cpu); if (!dev) return -ENXIO; return msm_spm_drv_set_pmic_data(&dev->reg_data, MSM_SPM_PMIC_PFM_PORT, mode); } EXPORT_SYMBOL(msm_spm_enable_fts_lpm); #endif static int get_cpu_id(struct device_node *node) { struct device_node *cpu_node; u32 cpu; char *key = "qcom,cpu"; cpu_node = of_parse_phandle(node, key, 0); if (cpu_node) { for_each_possible_cpu(cpu) { if (of_get_cpu_node(cpu, NULL) == cpu_node) return cpu; } } else return num_possible_cpus(); return -EINVAL; } static struct msm_spm_device *msm_spm_get_device(struct platform_device *pdev) { struct msm_spm_device *dev = NULL; const char *val = NULL; char *key = "qcom,name"; int cpu = get_cpu_id(pdev->dev.of_node); if ((cpu >= 0) && cpu < num_possible_cpus()) dev = &per_cpu(msm_cpu_spm_device, cpu); else if (cpu == num_possible_cpus()) dev = devm_kzalloc(&pdev->dev, sizeof(struct msm_spm_device), GFP_KERNEL); if (!dev) return NULL; if (of_property_read_string(pdev->dev.of_node, key, &val)) { pr_err("%s(): Cannot find a required node key:%s\n", __func__, key); return NULL; } dev->name = val; list_add(&dev->list, &spm_list); return dev; } static void get_cpumask(struct device_node *node, struct cpumask *mask) { unsigned c; int idx = 0; struct device_node *cpu_node; char *key = "qcom,cpu-vctl-list"; cpu_node = of_parse_phandle(node, key, idx++); while (cpu_node) { for_each_possible_cpu(c) { if (of_get_cpu_node(c, NULL) == cpu_node) cpumask_set_cpu(c, mask); } cpu_node = of_parse_phandle(node, key, idx++); }; } static int msm_spm_dev_probe(struct platform_device *pdev) { int ret = 0; int cpu = 0; int i = 0; struct device_node *node = pdev->dev.of_node; struct device_node *n = NULL; struct msm_spm_platform_data spm_data; char *key = NULL; uint32_t val = 0; struct msm_spm_seq_entry modes[MSM_SPM_MODE_NR]; int len = 0; struct msm_spm_device *dev = NULL; struct resource *res = NULL; uint32_t mode_count = 0; struct spm_of { char *key; uint32_t id; }; struct spm_of spm_of_data[] = { {"qcom,saw2-cfg", MSM_SPM_REG_SAW_CFG}, {"qcom,saw2-avs-ctl", MSM_SPM_REG_SAW_AVS_CTL}, {"qcom,saw2-avs-hysteresis", MSM_SPM_REG_SAW_AVS_HYSTERESIS}, {"qcom,saw2-avs-limit", MSM_SPM_REG_SAW_AVS_LIMIT}, {"qcom,saw2-avs-dly", MSM_SPM_REG_SAW_AVS_DLY}, {"qcom,saw2-spm-dly", MSM_SPM_REG_SAW_SPM_DLY}, {"qcom,saw2-spm-ctl", MSM_SPM_REG_SAW_SPM_CTL}, {"qcom,saw2-pmic-data0", MSM_SPM_REG_SAW_PMIC_DATA_0}, {"qcom,saw2-pmic-data1", MSM_SPM_REG_SAW_PMIC_DATA_1}, {"qcom,saw2-pmic-data2", MSM_SPM_REG_SAW_PMIC_DATA_2}, {"qcom,saw2-pmic-data3", MSM_SPM_REG_SAW_PMIC_DATA_3}, {"qcom,saw2-pmic-data4", MSM_SPM_REG_SAW_PMIC_DATA_4}, {"qcom,saw2-pmic-data5", MSM_SPM_REG_SAW_PMIC_DATA_5}, {"qcom,saw2-pmic-data6", MSM_SPM_REG_SAW_PMIC_DATA_6}, {"qcom,saw2-pmic-data7", MSM_SPM_REG_SAW_PMIC_DATA_7}, }; struct mode_of { char *key; uint32_t id; }; struct mode_of mode_of_data[] = { {"qcom,saw2-spm-cmd-wfi", MSM_SPM_MODE_CLOCK_GATING}, {"qcom,saw2-spm-cmd-ret", MSM_SPM_MODE_RETENTION}, {"qcom,saw2-spm-cmd-gdhs", MSM_SPM_MODE_GDHS}, {"qcom,saw2-spm-cmd-spc", MSM_SPM_MODE_POWER_COLLAPSE}, {"qcom,saw2-spm-cmd-pc", MSM_SPM_MODE_POWER_COLLAPSE}, {"qcom,saw2-spm-cmd-fpc", MSM_SPM_MODE_FASTPC}, }; dev = msm_spm_get_device(pdev); if (!dev) { /* * For partial goods support some CPUs might not be available * in which case, shouldn't throw an error */ return 0; } get_cpumask(node, &dev->mask); memset(&spm_data, 0, sizeof(struct msm_spm_platform_data)); memset(&modes, 0, (MSM_SPM_MODE_NR - 2) * sizeof(struct msm_spm_seq_entry)); key = "qcom,saw2-ver-reg"; ret = of_property_read_u32(node, key, &val); if (ret) goto fail; spm_data.ver_reg = val; key = "qcom,vctl-timeout-us"; ret = of_property_read_u32(node, key, &val); if (!ret) spm_data.vctl_timeout_us = val; /* SAW start address */ res = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!res) { ret = -EFAULT; goto fail; } spm_data.reg_base_addr = devm_ioremap(&pdev->dev, res->start, resource_size(res)); if (!spm_data.reg_base_addr) { ret = -ENOMEM; goto fail; } spm_data.vctl_port = -1; spm_data.phase_port = -1; spm_data.pfm_port = -1; key = "qcom,vctl-port"; of_property_read_u32(node, key, &spm_data.vctl_port); key = "qcom,phase-port"; of_property_read_u32(node, key, &spm_data.phase_port); key = "qcom,pfm-port"; of_property_read_u32(node, key, &spm_data.pfm_port); /* Q2S (QChannel-2-SPM) register */ res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "q2s"); if (res) { dev->q2s_reg = devm_ioremap(&pdev->dev, res->start, resource_size(res)); if (!dev->q2s_reg) { pr_err("%s(): Unable to iomap Q2S register\n", __func__); ret = -EADDRNOTAVAIL; goto fail; } } key = "qcom,use-qchannel-for-pc"; dev->qchannel_ignore = !of_property_read_bool(node, key); key = "qcom,use-spm-clock-gating"; dev->use_spm_clk_gating = of_property_read_bool(node, key); key = "qcom,use-qchannel-for-wfi"; dev->use_qchannel_for_wfi = of_property_read_bool(node, key); /* HW flush address */ res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "hw-flush"); if (res) { dev->flush_base_addr = devm_ioremap_resource(&pdev->dev, res); if (IS_ERR(dev->flush_base_addr)) { ret = PTR_ERR(dev->flush_base_addr); pr_err("%s(): Unable to iomap hw flush register %d\n", __func__, ret); goto fail; } } /* Sleep req address */ res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "slpreq"); if (res) { dev->slpreq_base_addr = devm_ioremap(&pdev->dev, res->start, resource_size(res)); if (!dev->slpreq_base_addr) { ret = -ENOMEM; pr_err("%s(): Unable to iomap slpreq register\n", __func__); ret = -EADDRNOTAVAIL; goto fail; } } /* * At system boot, cpus and or clusters can remain in reset. CCI SPM * will not be triggered unless SPM_LEGACY_MODE bit is set for the * cluster in reset. Initialize q2s registers and set the * SPM_LEGACY_MODE bit. */ msm_spm_config_q2s(dev, MSM_SPM_MODE_POWER_COLLAPSE); msm_spm_drv_reg_init(&dev->reg_data, &spm_data); for (i = 0; i < ARRAY_SIZE(spm_of_data); i++) { ret = of_property_read_u32(node, spm_of_data[i].key, &val); if (ret) continue; msm_spm_drv_upd_reg_shadow(&dev->reg_data, spm_of_data[i].id, val); } for_each_child_of_node(node, n) { const char *name; bool bit_set; int sync; if (!n->name) continue; ret = of_property_read_string(n, "qcom,label", &name); if (ret) continue; for (i = 0; i < ARRAY_SIZE(mode_of_data); i++) if (!strcmp(name, mode_of_data[i].key)) break; if (i == ARRAY_SIZE(mode_of_data)) { pr_err("Mode name invalid %s\n", name); break; } modes[mode_count].mode = mode_of_data[i].id; modes[mode_count].cmd = (uint8_t *)of_get_property(n, "qcom,sequence", &len); if (!modes[mode_count].cmd) { pr_err("cmd is empty\n"); continue; } bit_set = of_property_read_bool(n, "qcom,pc_mode"); modes[mode_count].ctl |= bit_set ? BIT(PC_MODE_BIT) : 0; bit_set = of_property_read_bool(n, "qcom,ret_mode"); modes[mode_count].ctl |= bit_set ? BIT(RET_MODE_BIT) : 0; bit_set = of_property_read_bool(n, "qcom,slp_cmd_mode"); modes[mode_count].ctl |= bit_set ? BIT(SLP_CMD_BIT) : 0; bit_set = of_property_read_bool(n, "qcom,isar"); modes[mode_count].ctl |= bit_set ? BIT(ISAR_BIT) : 0; bit_set = of_property_read_bool(n, "qcom,spm_en"); modes[mode_count].ctl |= bit_set ? BIT(SPM_EN_BIT) : 0; ret = of_property_read_u32(n, "qcom,event_sync", &sync); if (!ret) modes[mode_count].ctl |= sync << EVENT_SYNC_BIT; mode_count++; } spm_data.modes = modes; spm_data.num_modes = mode_count; key = "qcom,supports-rpm-hs"; dev->allow_rpm_hs = of_property_read_bool(pdev->dev.of_node, key); ret = msm_spm_dev_init(dev, &spm_data); if (ret) pr_err("SPM modes programming is not available from HLOS\n"); platform_set_drvdata(pdev, dev); for_each_cpu(cpu, &dev->mask) per_cpu(cpu_vctl_device, cpu) = dev; if (!spm_data.num_modes) return 0; cpu = get_cpu_id(pdev->dev.of_node); /* For CPUs that are online, the SPM has to be programmed for * clockgating mode to ensure that it can use SPM for entering these * low power modes. */ get_online_cpus(); if ((cpu >= 0) && (cpu < num_possible_cpus()) && (cpu_online(cpu))) msm_spm_config_low_power_mode(dev, MSM_SPM_MODE_CLOCK_GATING, false); put_online_cpus(); return ret; fail: cpu = get_cpu_id(pdev->dev.of_node); if (dev && (cpu >= num_possible_cpus() || (cpu < 0))) { for_each_cpu(cpu, &dev->mask) per_cpu(cpu_vctl_device, cpu) = ERR_PTR(ret); } pr_err("%s: CPU%d SPM device probe failed: %d\n", __func__, cpu, ret); return ret; } static int msm_spm_dev_remove(struct platform_device *pdev) { struct msm_spm_device *dev = platform_get_drvdata(pdev); list_del(&dev->list); return 0; } static struct of_device_id msm_spm_match_table[] = { {.compatible = "qcom,spm-v2"}, {}, }; static struct platform_driver msm_spm_device_driver = { .probe = msm_spm_dev_probe, .remove = msm_spm_dev_remove, .driver = { .name = "spm-v2", .owner = THIS_MODULE, .of_match_table = msm_spm_match_table, }, }; /** * msm_spm_device_init(): Device tree initialization function */ int __init msm_spm_device_init(void) { static bool registered; if (registered) return 0; registered = true; return platform_driver_register(&msm_spm_device_driver); } arch_initcall(msm_spm_device_init);