/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include /* Defaults */ #define DEFAULT_RAW_UNIT "ma" /* DPTF-specific UUIDs */ #define DPTF_PASSIVE_POLICY_1_0_UUID "42A441D6-AE6A-462B-A84B-4A8CE79027D3" #define DPTF_CRITICAL_POLICY_UUID "97C68AE7-15FA-499c-B8C9-5DA81D606E0A" #define DPTF_ACTIVE_POLICY_UUID "3A95C389-E4B8-4629-A526-C52C88626BAE" enum { ART_REVISION = 0, DEFAULT_PRIORITY = 100, DEFAULT_TRIP_POINT = 0xFFFFFFFFull, DEFAULT_WEIGHT = 100, DPTF_MAX_ART_THRESHOLDS = 10, FPS_REVISION = 0, PPCC_REVISION = 2, RAPL_PL1_INDEX = 0, RAPL_PL2_INDEX = 1, }; /* Convert degrees C to 1/10 degree Kelvin for ACPI */ static int to_acpi_temp(int deg_c) { return deg_c * 10 + 2732; } /* Converts ms to 1/10th second for ACPI */ static int to_acpi_time(int ms) { return ms / 100; } /* Writes out a 0-argument non-Serialized Method that returns an Integer */ static void write_simple_return_method(const char *name, int value) { acpigen_write_method(name, 0); acpigen_write_return_integer(value); acpigen_pop_len(); /* Method */ } /* Writes out 'count' ZEROs in a row */ static void write_zeros(int count) { for (; count; --count) acpigen_write_integer(0); } /* Return the assigned namestring of any participant */ static const char *namestring_of(enum dptf_participant participant) { switch (participant) { case DPTF_CPU: return "TCPU"; case DPTF_CHARGER: return "TCHG"; case DPTF_FAN: return "TFN1"; case DPTF_FAN_2: return "TFN2"; case DPTF_TEMP_SENSOR_0: return "TSR0"; case DPTF_TEMP_SENSOR_1: return "TSR1"; case DPTF_TEMP_SENSOR_2: return "TSR2"; case DPTF_TEMP_SENSOR_3: return "TSR3"; case DPTF_TEMP_SENSOR_4: return "TSR4"; case DPTF_TPCH: return "TPCH"; case DPTF_POWER: return "TPWR"; case DPTF_BATTERY: return "TBAT"; default: return ""; } } /* Helper to get Scope for participants underneath \_SB.DPTF */ static const char *scope_of(enum dptf_participant participant) { static char scope[16]; if (participant == DPTF_CPU) snprintf(scope, sizeof(scope), TCPU_SCOPE ".%s", namestring_of(participant)); else snprintf(scope, sizeof(scope), DPTF_DEVICE_PATH ".%s", namestring_of(participant)); return scope; } /* * Most of the DPTF participants are underneath the \_SB.DPTF scope, so we can just get away * with using the simple namestring for references, but the TCPU has a different scope, so * either an absolute or relative path must be used instead. */ static const char *path_of(enum dptf_participant participant) { if (participant == DPTF_CPU) return scope_of(participant); else return namestring_of(participant); } /* Write out scope of a participant */ void dptf_write_scope(enum dptf_participant participant) { acpigen_write_scope(scope_of(participant)); } /* * This table describes active cooling relationships between the system's fan and the * temperature sensors that it can have an effect on. As ever-increasing temperature thresholds * are crossed (_AC9.._AC0, low to high), the corresponding fan percentages listed in this table * are used to increase the speed of the fan in order to speed up cooling. */ static void write_active_relationship_table(const struct dptf_active_policy *policies, int max_count, bool dptf_multifan_support) { char *pkg_count; int i, j; /* Nothing to do */ if (!max_count || policies[0].target == DPTF_NONE) return; acpigen_write_scope(DPTF_DEVICE_PATH); acpigen_write_method("_ART", 0); /* Return this package */ acpigen_emit_byte(RETURN_OP); /* Keep track of items added to the package */ pkg_count = acpigen_write_package(1); /* The '1' here is for the revision */ acpigen_write_integer(ART_REVISION); for (i = 0; i < max_count; ++i) { /* * These have to be filled out from AC0 down to AC9, filling in only as many * as are used. As soon as one isn't filled in, we're done. */ if (policies[i].target == DPTF_NONE) break; (*pkg_count)++; /* Source, Target, Percent, Fan % for each of _AC0 ... _AC9 */ acpigen_write_package(13); if (dptf_multifan_support) acpigen_emit_namestring(path_of(policies[i].source)); else acpigen_emit_namestring(path_of(DPTF_FAN)); acpigen_emit_namestring(path_of(policies[i].target)); acpigen_write_integer(DEFAULT_IF_0(policies[i].weight, DEFAULT_WEIGHT)); /* Write out fan %; corresponds with target's _ACx methods */ for (j = 0; j < DPTF_MAX_ART_THRESHOLDS; ++j) acpigen_write_integer(policies[i].thresholds[j].fan_pct); acpigen_pop_len(); /* inner Package */ } acpigen_pop_len(); /* outer Package */ acpigen_pop_len(); /* Method _ART */ acpigen_pop_len(); /* Scope */ } /* * _AC9 through _AC0 represent temperature thresholds, in increasing order, defined from _AC0 * down, that, when reached, DPTF will activate TFN1 in order to actively cool the temperature * sensor(s). As increasing thresholds are reached, the fan is spun faster. */ static void write_active_cooling_methods(const struct dptf_active_policy *policies, int max_count) { char name[5]; int i, j; /* Nothing to do */ if (!max_count || policies[0].target == DPTF_NONE) return; for (i = 0; i < max_count; ++i) { if (policies[i].target == DPTF_NONE) break; dptf_write_scope(policies[i].target); /* Write out as many of _AC0 through _AC9 that are applicable */ for (j = 0; j < DPTF_MAX_ACX; ++j) { if (!policies[i].thresholds[j].temp) break; snprintf(name, sizeof(name), "_AC%1X", j); write_simple_return_method(name, to_acpi_temp( policies[i].thresholds[j].temp)); } acpigen_pop_len(); /* Scope */ } } void dptf_write_active_policies(const struct dptf_active_policy *policies, int max_count, bool dptf_multifan_support) { write_active_relationship_table(policies, max_count, dptf_multifan_support); write_active_cooling_methods(policies, max_count); } /* * This writes out the Thermal Relationship Table, which describes the thermal relationships * between participants in a thermal zone. This information is used to passively cool (i.e., * throttle) the Source (source of heat), in order to indirectly cool the Target (temperature * sensor). */ static void write_thermal_relationship_table(const struct dptf_passive_policy *policies, int max_count) { char *pkg_count; int i; /* Nothing to do */ if (!max_count || policies[0].source == DPTF_NONE) return; acpigen_write_scope(DPTF_DEVICE_PATH); /* * A _TRT Revision (TRTR) of 1 means that the 'Priority' field is an arbitrary priority * value to be used for this specific relationship. The priority value determines the * order in which various sources are used in a passive thermal action for a given * target. */ acpigen_write_name_integer("TRTR", 1); /* Thermal Relationship Table */ acpigen_write_method("_TRT", 0); /* Return this package */ acpigen_emit_byte(RETURN_OP); pkg_count = acpigen_write_package(0); for (i = 0; i < max_count; ++i) { /* Stop writing the table once an entry is empty */ if (policies[i].source == DPTF_NONE) break; /* Keep track of outer package item count */ (*pkg_count)++; acpigen_write_package(8); /* Source, Target, Priority, Sampling Period */ acpigen_emit_namestring(path_of(policies[i].source)); acpigen_emit_namestring(path_of(policies[i].target)); acpigen_write_integer(DEFAULT_IF_0(policies[i].priority, DEFAULT_PRIORITY)); acpigen_write_integer(to_acpi_time(policies[i].period)); /* Reserved */ write_zeros(4); acpigen_pop_len(); /* Package */ } acpigen_pop_len(); /* Package */ acpigen_pop_len(); /* Method */ acpigen_pop_len(); /* Scope */ } /* * When a temperature sensor measures above its the temperature returned in its _PSV Method, * DPTF will begin throttling Sources in order to indirectly cool the sensor. */ static void write_all_PSV(const struct dptf_passive_policy *policies, int max_count) { int i; for (i = 0; i < max_count; ++i) { if (policies[i].source == DPTF_NONE) break; dptf_write_scope(policies[i].target); write_simple_return_method("_PSV", to_acpi_temp(policies[i].temp)); acpigen_pop_len(); /* Scope */ } } void dptf_write_passive_policies(const struct dptf_passive_policy *policies, int max_count) { write_thermal_relationship_table(policies, max_count); write_all_PSV(policies, max_count); } void dptf_write_critical_policies(const struct dptf_critical_policy *policies, int max_count) { int i; for (i = 0; i < max_count; ++i) { if (policies[i].source == DPTF_NONE) break; dptf_write_scope(policies[i].source); /* Choose _CRT or _HOT */ write_simple_return_method(policies[i].type == DPTF_CRITICAL_SHUTDOWN ? "_CRT" : "_HOT", to_acpi_temp(policies[i].temp)); acpigen_pop_len(); /* Scope */ } } void dptf_write_charger_perf(const struct dptf_charger_perf *states, int max_count) { char *pkg_count; int i; if (!max_count || !states[0].control) return; dptf_write_scope(DPTF_CHARGER); /* PPSS - Participant Performance Supported States */ acpigen_write_method("PPSS", 0); acpigen_emit_byte(RETURN_OP); pkg_count = acpigen_write_package(0); for (i = 0; i < max_count; ++i) { if (!states[i].control) break; (*pkg_count)++; /* * 0, 0, 0, 0, # Reserved * Control, Raw Performance, Raw Unit, 0 # Reserved */ acpigen_write_package(8); write_zeros(4); acpigen_write_integer(states[i].control); acpigen_write_integer(states[i].raw_perf); acpigen_write_string(DEFAULT_RAW_UNIT); acpigen_write_integer(0); acpigen_pop_len(); /* inner Package */ } acpigen_pop_len(); /* outer Package */ acpigen_pop_len(); /* Method PPSS */ acpigen_pop_len(); /* Scope */ } int dptf_write_fan_perf_fps(uint8_t percent, uint16_t power, uint16_t speed, uint16_t noise_level) { /* * Some _FPS tables do include a last entry where Percent is 0, but Power is * called out, so this table is finished when both are zero. */ if (!percent && !power) return 1; acpigen_write_package(5); acpigen_write_integer(percent); acpigen_write_integer(DEFAULT_TRIP_POINT); acpigen_write_integer(speed); acpigen_write_integer(noise_level); acpigen_write_integer(power); acpigen_pop_len(); /* inner Package */ return 0; } void dptf_write_fan_perf(const struct dptf_fan_perf *states, int max_count, enum dptf_participant participant) { char *pkg_count; int i; if (!max_count || !states[0].percent) return; dptf_write_scope(participant); /* _FPS - Fan Performance States */ acpigen_write_name("_FPS"); pkg_count = acpigen_write_package(1); /* 1 for Revision */ acpigen_write_integer(FPS_REVISION); /* revision */ for (i = 0; i < max_count; ++i) { (*pkg_count)++; if (dptf_write_fan_perf_fps(states[i].percent, states[i].power, states[i].speed, states[i].noise_level)) break; } acpigen_pop_len(); /* Package */ acpigen_pop_len(); /* Scope */ } void dptf_write_multifan_perf( const struct dptf_multifan_perf states[DPTF_MAX_FAN_PARTICIPANTS][DPTF_MAX_FAN_PERF_STATES], int max_count, enum dptf_participant participant, int fan_num) { char *pkg_count; int i; if (!max_count || !states[fan_num][0].percent) return; dptf_write_scope(participant); /* _FPS - Fan Performance States */ acpigen_write_name("_FPS"); pkg_count = acpigen_write_package(1); /* 1 for Revision */ acpigen_write_integer(FPS_REVISION); /* revision */ for (i = 0; i < max_count; ++i) { (*pkg_count)++; if (dptf_write_fan_perf_fps(states[fan_num][i].percent, states[fan_num][i].power, states[fan_num][i].speed, states[fan_num][i].noise_level)) break; } acpigen_pop_len(); /* Package */ acpigen_pop_len(); /* Scope */ } void dptf_write_power_limits(const struct dptf_power_limits *limits) { char *pkg_count; /* Nothing to do */ if (!limits->pl1.min_power && !limits->pl2.min_power) return; dptf_write_scope(DPTF_CPU); acpigen_write_method("PPCC", 0); acpigen_emit_byte(RETURN_OP); pkg_count = acpigen_write_package(1); /* 1 for the Revision */ acpigen_write_integer(PPCC_REVISION); /* revision */ if (limits->pl1.min_power) { (*pkg_count)++; acpigen_write_package(6); acpigen_write_integer(RAPL_PL1_INDEX); acpigen_write_integer(limits->pl1.min_power); acpigen_write_integer(limits->pl1.max_power); acpigen_write_integer(limits->pl1.time_window_min); acpigen_write_integer(limits->pl1.time_window_max); acpigen_write_integer(limits->pl1.granularity); acpigen_pop_len(); /* inner Package */ } if (limits->pl2.min_power) { (*pkg_count)++; acpigen_write_package(6); acpigen_write_integer(RAPL_PL2_INDEX); acpigen_write_integer(limits->pl2.min_power); acpigen_write_integer(limits->pl2.max_power); acpigen_write_integer(limits->pl2.time_window_min); acpigen_write_integer(limits->pl2.time_window_max); acpigen_write_integer(limits->pl2.granularity); acpigen_pop_len(); /* inner Package */ } acpigen_pop_len(); /* outer Package */ acpigen_pop_len(); /* Method */ acpigen_pop_len(); /* Scope */ } void dptf_write_STR(const char *str) { if (!str) return; acpigen_write_name_unicode("_STR", str); } void dptf_write_fan_options(bool fine_grained, int step_size, bool low_speed_notify) { acpigen_write_name("_FIF"); acpigen_write_package(4); acpigen_write_integer(0); /* Revision */ acpigen_write_integer(fine_grained); acpigen_write_integer(step_size); acpigen_write_integer(low_speed_notify); acpigen_pop_len(); /* Package */ } void dptf_write_tsr_hysteresis(uint8_t hysteresis) { if (!hysteresis) return; acpigen_write_name_integer("GTSH", hysteresis); } void dptf_write_enabled_policies(const struct dptf_active_policy *active_policies, int active_count, const struct dptf_passive_policy *passive_policies, int passive_count, const struct dptf_critical_policy *critical_policies, int critical_count) { bool is_active_used; bool is_passive_used; bool is_critical_used; int pkg_count; is_active_used = (active_count && active_policies[0].target != DPTF_NONE); is_passive_used = (passive_count && passive_policies[0].target != DPTF_NONE); is_critical_used = (critical_count && critical_policies[0].source != DPTF_NONE); pkg_count = is_active_used + is_passive_used + is_critical_used; if (!pkg_count) return; acpigen_write_scope(DPTF_DEVICE_PATH); acpigen_write_name("IDSP"); acpigen_write_package(pkg_count); if (is_active_used) acpigen_write_uuid(DPTF_ACTIVE_POLICY_UUID); if (is_passive_used) acpigen_write_uuid(DPTF_PASSIVE_POLICY_1_0_UUID); if (is_critical_used) acpigen_write_uuid(DPTF_CRITICAL_POLICY_UUID); acpigen_pop_len(); /* Package */ acpigen_pop_len(); /* Scope */ }