/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include "chip.h" #include "dptf.h" /* Generic DPTF participants have a PTYP field to distinguish them */ enum dptf_generic_participant_type { DPTF_GENERIC_PARTICIPANT_TYPE_TSR = 0x3, DPTF_GENERIC_PARTICIPANT_TYPE_TPCH = 0x5, DPTF_GENERIC_PARTICIPANT_TYPE_CHARGER = 0xB, }; #define DEFAULT_CHARGER_STR "Battery Charger" #define DEFAULT_TPCH_STR "Intel PCH FIVR Participant" #define PMC_IPC_COMMAND_FIVR_SIZE 0x8 /* * Helper method to determine if a device is "used" (called out anywhere as a source or a target * of any policies, and therefore should be included in the ACPI tables. */ static bool is_participant_used(const struct drivers_intel_dptf_config *config, enum dptf_participant participant) { int i; /* Active? */ for (i = 0; i < DPTF_MAX_ACTIVE_POLICIES; ++i) if (config->policies.active[i].target == participant) return true; /* Passive? */ for (i = 0; i < DPTF_MAX_PASSIVE_POLICIES; ++i) if (config->policies.passive[i].source == participant || config->policies.passive[i].target == participant) return true; /* Critical? */ for (i = 0; i < DPTF_MAX_CRITICAL_POLICIES; ++i) if (config->policies.critical[i].source == participant) return true; /* Check fan as well (its use is implicit in the Active policy) */ if (participant == DPTF_FAN && config->policies.active[0].target != DPTF_NONE) return true; return false; } static const char *dptf_acpi_name(const struct device *dev) { return "DPTF"; } static int get_STA_value(const struct drivers_intel_dptf_config *config, enum dptf_participant participant) { return is_participant_used(config, participant) ? ACPI_STATUS_DEVICE_ALL_ON : ACPI_STATUS_DEVICE_ALL_OFF; } static void dptf_write_hid(bool is_eisa, const char *hid) { if (is_eisa) acpigen_emit_eisaid(hid); else acpigen_write_string(hid); } /* Devices with GENERIC _HID (distinguished by PTYP) */ static void dptf_write_generic_participant(const char *name, enum dptf_generic_participant_type ptype, const char *str, int sta_val, const struct dptf_platform_info *platform_info) { /* Auto-incrementing UID for generic participants */ static int generic_uid = 0; acpigen_write_device(name); acpigen_write_name("_HID"); dptf_write_hid(platform_info->use_eisa_hids, platform_info->generic_hid); acpigen_write_name_integer("_UID", generic_uid++); acpigen_write_STA(sta_val); if (str) acpigen_write_name_string("_STR", str); acpigen_write_name_integer("PTYP", ptype); acpigen_pop_len(); /* Device */ } /* \_SB.PCI0.TCPU */ static void write_tcpu(const struct device *pci_dev, const struct drivers_intel_dptf_config *config) { /* DPTF CPU device - \_SB.PCI0.TCPU */ acpigen_write_scope(TCPU_SCOPE); acpigen_write_device("TCPU"); acpigen_write_ADR_pci_device(pci_dev); acpigen_write_STA(get_STA_value(config, DPTF_CPU)); acpigen_pop_len(); /* Device */ acpigen_pop_len(); /* TCPU Scope */ } /* \_SB.DPTF.TFN1 */ static void write_fan(const struct drivers_intel_dptf_config *config, const struct dptf_platform_info *platform_info) { acpigen_write_device("TFN1"); acpigen_write_name("_HID"); dptf_write_hid(platform_info->use_eisa_hids, platform_info->fan_hid); acpigen_write_name_integer("_UID", 0); acpigen_write_STA(get_STA_value(config, DPTF_FAN)); acpigen_pop_len(); /* Device */ } /* \_SB.DPTF */ static void write_imok(void) { acpigen_write_method("IMOK", 1); /* Return (Arg0) */ acpigen_emit_byte(RETURN_OP); acpigen_emit_byte(ARG0_OP); acpigen_write_method_end(); } /* \_SB.DPTF */ static void write_oem_variables(const struct drivers_intel_dptf_config *config) { int i; acpigen_write_name("ODVX"); acpigen_write_package(DPTF_OEM_VARIABLE_COUNT); for (i = 0; i < DPTF_OEM_VARIABLE_COUNT; i++) acpigen_write_dword(config->oem_data.oem_variables[i]); acpigen_write_package_end(); /* * Method (ODUP, 2) * Arg0 = Index of ODVX to update * Arg1 = Value to place in ODVX[Arg0] */ acpigen_write_method_serialized("ODUP", 2); /* ODVX[Arg0] = Arg1 */ acpigen_write_store(); acpigen_emit_byte(ARG1_OP); acpigen_emit_byte(INDEX_OP); acpigen_emit_namestring("ODVX"); acpigen_emit_byte(ARG0_OP); acpigen_emit_byte(ZERO_OP); /* Ignore Index() Destination */ acpigen_write_method_end(); /* * Method (ODGT, 1) * Arg0 = Index of ODVX to get */ acpigen_write_method_serialized("ODGT", 1); /* Return (ODVX[Arg0]) */ acpigen_emit_byte(RETURN_OP); acpigen_emit_byte(DEREF_OP); acpigen_emit_byte(INDEX_OP); acpigen_emit_namestring("ODVX"); acpigen_emit_byte(ARG0_OP); acpigen_emit_byte(ZERO_OP); /* Ignore Index() Destination */ acpigen_write_method_end(); /* Method (ODVP) { Return (ODVX) } */ acpigen_write_method_serialized("ODVP", 0); acpigen_emit_byte(RETURN_OP); acpigen_emit_namestring("ODVX"); acpigen_write_method_end(); } /* \_SB.DPTF.xxxx */ static void write_generic_devices(const struct drivers_intel_dptf_config *config, const struct dptf_platform_info *platform_info) { enum dptf_participant participant; char name[ACPI_NAME_BUFFER_SIZE]; int i; dptf_write_generic_participant("TCHG", DPTF_GENERIC_PARTICIPANT_TYPE_CHARGER, DEFAULT_CHARGER_STR, get_STA_value(config, DPTF_CHARGER), platform_info); for (i = 0, participant = DPTF_TEMP_SENSOR_0; i < DPTF_MAX_TSR; ++i, ++participant) { snprintf(name, sizeof(name), "TSR%1d", i); dptf_write_generic_participant(name, DPTF_GENERIC_PARTICIPANT_TYPE_TSR, NULL, get_STA_value(config, participant), platform_info); } } static const char *get_pmc_ipcs_method(void) { const char *method = acpi_device_path_join( pcidev_path_on_root(PCH_DEVFN_PMC), "IPCS"); if (!method) { printk(BIOS_ERR, "%s: Unable to find PMC device IPCS method\n", __func__); return NULL; } return method; } static void write_tpch_write_method(const char *tpch_write_method_name, unsigned int ipc_subcmd_ctrl_value) { /* Get IPCS method from the PMC device */ const char *ipcs = get_pmc_ipcs_method(); acpigen_write_method_serialized(tpch_write_method_name, 1); acpigen_emit_namestring(ipcs); acpigen_write_integer(PMC_IPC_CMD_COMMAND_FIVR); acpigen_write_integer(PMC_IPC_CMD_CMD_ID_FIVR_WRITE); acpigen_write_integer(PMC_IPC_COMMAND_FIVR_SIZE); acpigen_write_integer(ipc_subcmd_ctrl_value); acpigen_emit_byte(ARG0_OP); acpigen_write_zero(); acpigen_write_zero(); /* The reason for returning a value here is a W/A for the ESIF shell */ acpigen_emit_byte(RETURN_OP); acpigen_write_package(1); acpigen_write_zero(); acpigen_write_package_end(); acpigen_write_method_end(); } static void write_ppkg_package(const uint8_t i) { acpigen_write_store(); acpigen_emit_byte(DEREF_OP); acpigen_emit_byte(INDEX_OP); acpigen_emit_byte(ARG0_OP); acpigen_write_integer(i); acpigen_emit_byte(ZERO_OP); acpigen_emit_byte(INDEX_OP); acpigen_emit_namestring("PPKG"); acpigen_write_integer(i); acpigen_emit_byte(ZERO_OP); } /* * Truncate Package received from IPC * Arguments: * Arg0: Package returned from the IPCS read call from the Pmc * Return Value: * Return Package with just the Status and ReadBuf0 * Status returns 0 for success and 2 for device error */ static void write_pkgc_method(void) { acpigen_write_method_serialized("PKGC", 1); acpigen_write_name("PPKG"); acpigen_write_package(2); acpigen_write_zero(); acpigen_write_zero(); acpigen_write_package_end(); write_ppkg_package(0); write_ppkg_package(1); acpigen_write_return_namestr("PPKG"); acpigen_write_method_end(); } static void write_tpch_read_method(const char *tpch_read_method_name, unsigned int ipc_subcmd_ctrl_value) { /* Get IPCS method from the PMC device */ const char *ipcs = get_pmc_ipcs_method(); acpigen_write_method_serialized(tpch_read_method_name, 0); acpigen_write_store(); acpigen_emit_namestring(ipcs); acpigen_write_integer(PMC_IPC_CMD_COMMAND_FIVR); acpigen_write_integer(PMC_IPC_CMD_CMD_ID_FIVR_READ); acpigen_write_integer(PMC_IPC_COMMAND_FIVR_SIZE); acpigen_write_integer(ipc_subcmd_ctrl_value); acpigen_write_zero(); acpigen_write_zero(); acpigen_write_zero(); acpigen_emit_byte(LOCAL0_OP); acpigen_write_store(); acpigen_emit_namestring("PKGC"); acpigen_emit_byte(LOCAL0_OP); acpigen_emit_byte(LOCAL1_OP); acpigen_emit_byte(RETURN_OP); acpigen_emit_byte(LOCAL1_OP); acpigen_write_method_end(); } static void write_create_tpch(const struct dptf_platform_info *platform_info) { acpigen_write_device("TPCH"); acpigen_write_name("_HID"); dptf_write_hid(platform_info->use_eisa_hids, platform_info->tpch_device_hid); acpigen_write_name_string("_STR", DEFAULT_TPCH_STR); acpigen_write_name_integer("PTYP", DPTF_GENERIC_PARTICIPANT_TYPE_TPCH); acpigen_write_STA(ACPI_STATUS_DEVICE_ALL_ON); } static void write_tpch_methods(const struct dptf_platform_info *platform_info) { write_create_tpch(platform_info); const struct { enum { READ, WRITE } type; const char *method_name; unsigned int subcommand; } tpch_methods[] = { { .type = WRITE, .method_name = platform_info->tpch_method_names.set_fivr_low_clock_method, .subcommand = PMC_IPC_SUBCMD_RFI_CTRL0_LOGIC }, { .type = WRITE, .method_name = platform_info->tpch_method_names.set_fivr_high_clock_method, .subcommand = PMC_IPC_SUBCMD_RFI_CTRL4_LOGIC }, { .type = READ, .method_name = platform_info->tpch_method_names.get_fivr_low_clock_method, .subcommand = PMC_IPC_SUBCMD_RFI_CTRL0_LOGIC }, { .type = READ, .method_name = platform_info->tpch_method_names.get_fivr_high_clock_method, .subcommand = PMC_IPC_SUBCMD_RFI_CTRL4_LOGIC }, { .type = READ, .method_name = platform_info->tpch_method_names.get_fivr_ssc_method, .subcommand = PMC_IPC_SUBCMD_EMI_CTRL0_LOGIC }, { .type = READ, .method_name = platform_info->tpch_method_names.get_fivr_switching_fault_status, .subcommand = PMC_IPC_SUBCMD_FFFC_FAULT_STATUS }, { .type = READ, .method_name = platform_info->tpch_method_names.get_fivr_switching_freq_mhz, .subcommand = PMC_IPC_SUBCMD_FFFC_RFI_STATUS }, }; write_pkgc_method(); for (size_t i = 0; i < ARRAY_SIZE(tpch_methods); i++) { if (tpch_methods[i].type == READ) { write_tpch_read_method(tpch_methods[i].method_name, tpch_methods[i].subcommand); } else if (tpch_methods[i].type == WRITE) { write_tpch_write_method(tpch_methods[i].method_name, tpch_methods[i].subcommand); } } acpigen_write_device_end(); /* TPCH Device */ } /* \_SB.DPTF - note: leaves the Scope open for child devices */ static void write_open_dptf_device(const struct device *dev, const struct dptf_platform_info *platform_info) { acpigen_write_scope("\\_SB"); acpigen_write_device(acpi_device_name(dev)); acpigen_write_name("_HID"); dptf_write_hid(platform_info->use_eisa_hids, platform_info->dptf_device_hid); acpigen_write_name_integer("_UID", 0); acpigen_write_STA(ACPI_STATUS_DEVICE_ALL_ON); } /* Add minimal definitions of DPTF devices into the SSDT */ static void write_device_definitions(const struct device *dev) { const struct dptf_platform_info *platform_info = get_dptf_platform_info(); const struct drivers_intel_dptf_config *config; struct device *parent; /* The CPU device gets an _ADR that matches the ACPI PCI address for 00:04.00 */ parent = dev && dev->bus ? dev->bus->dev : NULL; if (!parent || parent->path.type != DEVICE_PATH_PCI) { printk(BIOS_ERR, "%s: DPTF objects must live under 00:04.0 PCI device\n", __func__); return; } config = config_of(dev); write_tcpu(parent, config); write_open_dptf_device(dev, platform_info); write_fan(config, platform_info); write_oem_variables(config); write_imok(); write_generic_devices(config, platform_info); if (CONFIG(DRIVERS_INTEL_DPTF_SUPPORTS_TPCH)) write_tpch_methods(platform_info); acpigen_pop_len(); /* DPTF Device (write_open_dptf_device) */ acpigen_pop_len(); /* Scope */ } /* Emites policy definitions for each policy type */ static void write_policies(const struct drivers_intel_dptf_config *config) { dptf_write_enabled_policies(config->policies.active, DPTF_MAX_ACTIVE_POLICIES, config->policies.passive, DPTF_MAX_PASSIVE_POLICIES, config->policies.critical, DPTF_MAX_CRITICAL_POLICIES); dptf_write_active_policies(config->policies.active, DPTF_MAX_ACTIVE_POLICIES); dptf_write_passive_policies(config->policies.passive, DPTF_MAX_PASSIVE_POLICIES); dptf_write_critical_policies(config->policies.critical, DPTF_MAX_CRITICAL_POLICIES); } /* Writes other static tables that are used by DPTF */ static void write_controls(const struct drivers_intel_dptf_config *config) { dptf_write_charger_perf(config->controls.charger_perf, DPTF_MAX_CHARGER_PERF_STATES); dptf_write_fan_perf(config->controls.fan_perf, DPTF_MAX_FAN_PERF_STATES); dptf_write_power_limits(&config->controls.power_limits); } /* Options to control the behavior of devices */ static void write_options(const struct drivers_intel_dptf_config *config) { enum dptf_participant p; int i; /* Fan options */ dptf_write_scope(DPTF_FAN); dptf_write_fan_options(config->options.fan.fine_grained_control, config->options.fan.step_size, config->options.fan.low_speed_notify); acpigen_pop_len(); /* Scope */ /* TSR options */ for (p = DPTF_TEMP_SENSOR_0, i = 0; p <= DPTF_TEMP_SENSOR_4; ++p, ++i) { if (is_participant_used(config, p) && (config->options.tsr[i].hysteresis || config->options.tsr[i].desc)) { dptf_write_scope(p); dptf_write_tsr_hysteresis(config->options.tsr[i].hysteresis); dptf_write_STR(config->options.tsr[i].desc); acpigen_pop_len(); /* Scope */ } } } /* Add custom tables and methods to SSDT */ static void dptf_fill_ssdt(const struct device *dev) { struct drivers_intel_dptf_config *config = config_of(dev); write_device_definitions(dev); write_policies(config); write_controls(config); write_options(config); printk(BIOS_INFO, DPTF_DEVICE_PATH ": %s at %s\n", dev->chip_ops->name, dev_path(dev)); } static struct device_operations dptf_ops = { .read_resources = noop_read_resources, .set_resources = noop_set_resources, .acpi_name = dptf_acpi_name, .acpi_fill_ssdt = dptf_fill_ssdt, }; static void dptf_enable_dev(struct device *dev) { dev->ops = &dptf_ops; } struct chip_operations drivers_intel_dptf_ops = { CHIP_NAME("Intel DPTF") .enable_dev = dptf_enable_dev, };