bool LPCSensors::addTemperatureSensors(OSDictionary *configuration)
{
HWSensorsDebugLog("adding temperature sensors...");
for (int i = 0; i < temperatureSensorsLimit(); i++)
{
char key[8];
snprintf(key, 8, "TEMPIN%X", i);
if (OSObject* node = configuration->getObject(key)) {
if (!addSensorFromNode(node, kFakeSMCCategoryTemperature, kFakeSMCTemperatureSensor, i)) {
if (checkConfigurationNode(configuration, "GPU Die")) {
if (gpuIndex < 0)
gpuIndex = takeVacantGPUIndex();
else
continue;
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, gpuIndex);
if (!addSensorFromConfigurationNode(node, key, TYPE_SP78, TYPE_SPXX_SIZE, kFakeSMCTemperatureSensor, i)) {
releaseGPUIndex(gpuIndex);
gpuIndex = -1;
}
}
}
}
}
return true;
}
bool SuperIOPlugin::addTemperatureSensors(OSDictionary *configuration)
{
HWSensorsDebugLog("adding temperature sensors...");
for (int i = 0; i < temperatureSensorsLimit(); i++)
{
char key[8];
snprintf(key, 8, "TEMPIN%X", i);
if (OSObject* node = configuration->getObject(key)) {
for (int j = 0; j < FakeSMCTemperatureCount; j++) {
if (addSensorFromConfigurationNode(node, FakeSMCTemperature[j].name, FakeSMCTemperature[j].key, FakeSMCTemperature[j].type, FakeSMCTemperature[j].size, kFakeSMCTemperatureSensor, i))
break;
}
if (gpuIndex < 0)
gpuIndex = takeVacantGPUIndex();
if (gpuIndex >= 0) {
snprintf(key, 5, KEY_FORMAT_GPU_HEATSINK_TEMPERATURE, gpuIndex);
if (!addSensorFromConfigurationNode(node, "GPU", key, TYPE_SP78, TYPE_SPXX_SIZE, kFakeSMCTemperatureSensor, i)) {
releaseGPUIndex(gpuIndex);
gpuIndex = -1;
}
}
}
}
return true;
}
bool SuperIOPlugin::addVoltageSensors(OSDictionary *configuration)
{
HWSensorsDebugLog("adding voltage sensors...");
for (int i = 0; i < voltageSensorsLimit(); i++)
{
char key[5];
snprintf(key, 5, "VIN%X", i);
if (OSObject* node = configuration->getObject(key)) {
for (int j = 0; j < FakeSMCVolatgeCount; j++) {
if (addSensorFromConfigurationNode(node, FakeSMCVolatge[j].name, FakeSMCVolatge[j].key, FakeSMCVolatge[j].type, FakeSMCVolatge[j].size, kFakeSMCVoltageSensor, i))
break;
}
if (gpuIndex < 0)
gpuIndex = takeVacantGPUIndex();
if (gpuIndex >= 0) {
snprintf(key, 5, KEY_FORMAT_GPU_VOLTAGE, gpuIndex);
if (!addSensorFromConfigurationNode(node, "GPU", key, TYPE_FP2E, TYPE_FPXX_SIZE, kFakeSMCVoltageSensor, i)) {
releaseGPUIndex(gpuIndex);
gpuIndex = -1;
}
}
}
}
return true;
}
bool LPCSensors::addVoltageSensors(OSDictionary *configuration)
{
HWSensorsDebugLog("adding voltage sensors...");
for (int i = 0; i < voltageSensorsLimit(); i++)
{
char key[5];
snprintf(key, 5, "VIN%X", i);
if (OSObject* node = configuration->getObject(key)) {
if (!addSensorFromNode(node, kFakeSMCCategoryVoltage, kFakeSMCVoltageSensor, i)) {
if (checkConfigurationNode(configuration, "GPU Core")) {
if (gpuIndex < 0)
gpuIndex = takeVacantGPUIndex();
else
continue;
snprintf(key, 5, KEY_FORMAT_GPU_VOLTAGE, gpuIndex);
if (!addSensorFromConfigurationNode(node, key, TYPE_FP2E, TYPE_FPXX_SIZE, kFakeSMCVoltageSensor, i)) {
releaseGPUIndex(gpuIndex);
gpuIndex = -1;
}
}
}
}
}
return true;
}
void GmaSensors::stop(IOService* provider)
{
if (gpuIndex >= 0)
releaseGPUIndex(gpuIndex);
super::stop(provider);
}
void SuperIOPlugin::stop(IOService *provider)
{
if (gpuIndex >= 0)
if (!releaseGPUIndex(gpuIndex))
HWSensorsFatalLog("failed to release GPU index");
super::stop(provider);
}
bool GmaSensors::managedStart(IOService *provider)
{
IOPhysicalAddress bar = (IOPhysicalAddress)((pciDevice->configRead32(kMCHBAR)) & ~0xf);
HWSensorsDebugLog("Fx3100: register space=%08lx", (long unsigned int)bar);
if(IOMemoryDescriptor * theDescriptor = IOMemoryDescriptor::withPhysicalAddress (bar, 0x2000, kIODirectionOutIn)) {
if ((mmio = theDescriptor->map())) {
mmio_base = (volatile UInt8 *)mmio->getVirtualAddress();
/*HWSensorsDebugLog("MCHBAR mapped");
for (int i = 0; i < 0x2f; i += 16) {
HWSensorsDebugLog("%04lx: ", (long unsigned int)i+0x1000);
for (int j=0; j<16; j += 1) {
HWSensorsDebugLog("%02lx ", (long unsigned int)INVID8(i+j+0x1000));
}
HWSensorsDebugLog("");
}*/
}
else {
HWSensorsInfoLog("MCHBAR failed to map");
return false;
}
}
enableExclusiveAccessMode();
//Find card number
gpuIndex = takeVacantGPUIndex();
if (gpuIndex < 0) {
HWSensorsFatalLog("failed to obtain vacant GPU index");
return false;
}
char key[5];
snprintf(key, 5, KEY_FORMAT_GPU_PROXIMITY_TEMPERATURE, gpuIndex);
if (!addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, 0)) {
HWSensorsFatalLog("failed to register temperature sensor");
releaseGPUIndex(gpuIndex);
gpuIndex = -1;
return false;
}
disableExclusiveAccessMode();
registerService();
return true;
}
void LPCSensors::stop(IOService *provider)
{
PMstop();
timerEventSource->cancelTimeout();
workloop->removeEventSource(timerEventSource);
if (gpuIndex >= 0)
releaseGPUIndex(gpuIndex);
super::stop(provider);
}
void GeforceSensors::stop(IOService * provider)
{
if (card.mmio)
OSSafeRelease(card.mmio);
if (card.bios.data) {
IOFree(card.bios.data, card.bios.size);
card.bios.data = 0;
}
if (card.card_index >= 0)
releaseGPUIndex(card.card_index);
super::stop(provider);
}
void RadeonSensors::stop(IOService *provider)
{
if (card.mmio)
OSSafeReleaseNULL(card.mmio);
if (card.bios && card.bios_size > 0) {
IOFree(card.bios, card.bios_size);
card.bios = 0;
}
if (card.card_index >= 0)
releaseGPUIndex(card.card_index);
super::stop(provider);
}
void GeforceSensors::stop(IOService * provider)
{
if (card.mmio)
OSSafeRelease(card.mmio);
if (card.bios.data) {
IOFree(card.bios.data, card.bios.size);
card.bios.data = 0;
}
if (card.card_index >= 0) {
if (!releaseGPUIndex(card.card_index))
HWSensorsFatalLog("failed to release GPU index");
}
super::stop(provider);
}
void RadeonMonitor::free(void)
{
if (card.mmio)
OSSafeRelease(card.mmio);
if (card.bios && card.bios_size > 0) {
IOFree(card.bios, card.bios_size);
card.bios = 0;
}
if (card.card_index >= 0) {
if (!releaseGPUIndex(card.card_index))
HWSensorsFatalLog("failed to release GPU index");
}
super::free();
}
bool GeforceSensors::start(IOService *provider)
{
HWSensorsDebugLog("Starting...");
if (!super::start(provider))
return false;
struct nouveau_device *device = &card;
// map device memory
if ((device->pcidev = (IOPCIDevice*)provider)) {
device->pcidev->setMemoryEnable(true);
if ((device->mmio = device->pcidev->mapDeviceMemoryWithIndex(0))) {
nv_debug(device, "memory mapped successfully\n");
}
else {
HWSensorsFatalLog("failed to map memory");
return false;
}
}
else {
HWSensorsFatalLog("failed to assign PCI device");
return false;
}
card.card_index = -1;
if (OSData *multiboard_capable = OSDynamicCast(OSData, provider->getProperty("rm_multiboard_capable"))) {
if (0x1 == *((UInt32*)multiboard_capable->getBytesNoCopy())) {
if (OSData *board_number = OSDynamicCast(OSData, provider->getProperty("rm_board_number"))) {
UInt8 index = *((UInt32*)board_number->getBytesNoCopy());
card.card_index = takeGPUIndex(index);
}
}
}
if (card.card_index < 0)
card.card_index = takeVacantGPUIndex();
if (card.card_index < 0) {
HWSensorsFatalLog("failed to take vacant GPU index");
return false;
}
// identify chipset
if (!nouveau_identify(device)) {
releaseGPUIndex(card.card_index);
return false;
}
// shadow and parse bios
//try to load bios from registry first from "vbios" property created by Chameleon boolloader
if (OSData *vbios = OSDynamicCast(OSData, provider->getProperty("vbios"))) {
device->bios.size = vbios->getLength();
device->bios.data = (u8*)IOMalloc(card.bios.size);
memcpy(device->bios.data, vbios->getBytesNoCopy(), device->bios.size);
}
if (!device->bios.data || !device->bios.size || nouveau_bios_score(device, true) < 1)
if (!nouveau_bios_shadow(device)) {
if (device->bios.data && device->bios.size) {
IOFree(card.bios.data, card.bios.size);
device->bios.data = NULL;
device->bios.size = 0;
}
nv_fatal(device, "unable to shadow VBIOS\n");
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
nouveau_vbios_init(device);
nouveau_bios_parse(device);
// initialize funcs and variables
if (!nouveau_init(device)) {
nv_error(device, "unable to initialize monitoring driver\n");
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
nv_info(device, "chipset: %s (NV%02X) bios: %02x.%02x.%02x.%02x\n", device->cname, device->chipset, device->bios.version.major, device->bios.version.chip, device->bios.version.minor, device->bios.version.micro);
if (device->card_type < NV_C0) {
// init i2c structures
nouveau_i2c_create(device);
// setup nouveau i2c sensors
nouveau_i2c_probe(device);
}
// Register sensors
char key[5];
if (card.core_temp_get || card.board_temp_get) {
nv_debug(device, "registering i2c temperature sensors...\n");
if (card.core_temp_get && card.board_temp_get) {
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_core);
snprintf(key, 5, KEY_FORMAT_GPU_HEATSINK_TEMPERATURE, card.card_index);
addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_board);
}
else if (card.core_temp_get) {
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_core);
}
else if (card.board_temp_get) {
snprintf(key, 5, KEY_FORMAT_GPU_HEATSINK_TEMPERATURE, card.card_index);
addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_board);
}
}
else if (card.temp_get)
{
nv_debug(device, "registering temperature sensors...\n");
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_diode);
}
int arg_value = 1;
if (card.clocks_get && !PE_parse_boot_argn("-gpusensors-no-clocks", &arg_value, sizeof(arg_value))) {
nv_debug(device, "registering clocks sensors...\n");
if (card.clocks_get(&card, nouveau_clock_core) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_FREQUENCY, card.card_index);
addSensor(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_core);
}
// if (card.clocks_get(&card, nouveau_clock_shader) > 0) {
// snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_SHADER_FREQUENCY, card.card_index);
// addSensor(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_shader);
// }
if (card.clocks_get(&card, nouveau_clock_rop) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_ROP_FREQUENCY, card.card_index);
addSensor(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_rop);
}
if (card.clocks_get(&card, nouveau_clock_memory) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_MEMORY_FREQUENCY, card.card_index);
addSensor(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_memory);
}
}
if (card.fan_pwm_get || card.fan_rpm_get) {
nv_debug(device, "registering PWM sensors...\n");
char title[DIAG_FUNCTION_STR_LEN];
snprintf (title, DIAG_FUNCTION_STR_LEN, "GPU %X", card.card_index + 1);
if (card.fan_rpm_get && card.fan_rpm_get(device) >= 0)
addTachometer(nouveau_fan_rpm, title, GPU_FAN_RPM, card.card_index);
if (card.fan_pwm_get && card.fan_pwm_get(device) >= 0)
addTachometer(nouveau_fan_pwm, title, GPU_FAN_PWM_CYCLE, card.card_index);
}
if (card.voltage_get && card.voltage.supported) {
nv_debug(device, "registering voltage sensors...\n");
snprintf(key, 5, KEY_FORMAT_GPU_VOLTAGE, card.card_index);
addSensor(key, TYPE_FP2E, TYPE_FPXX_SIZE, kFakeSMCVoltageSensor, 0);
}
registerService();
nv_info(device, "started\n");
return true;
}
bool GeforceSensors::managedStart(IOService *provider)
{
HWSensorsDebugLog("Starting...");
struct nouveau_device *device = &card;
if (!device->bios.data || !device->bios.size) {
if (!shadowBios()) {
nv_fatal(device, "unable to shadow VBIOS\n");
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
}
nouveau_vbios_init(device);
nouveau_bios_parse(device);
// initialize funcs and variables
if (!nouveau_init(device)) {
nv_error(device, "unable to initialize monitoring driver\n");
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
nv_info(device, "chipset: %s (NV%02X) bios: %02x.%02x.%02x.%02x\n", device->cname, device->chipset, device->bios.version.major, device->bios.version.chip, device->bios.version.minor, device->bios.version.micro);
if (device->card_type < NV_C0) {
// init i2c structures
nouveau_i2c_create(device);
// setup nouveau i2c sensors
nouveau_i2c_probe(device);
}
// Register sensors
char key[5];
if (card.core_temp_get || card.board_temp_get) {
nv_debug(device, "registering i2c temperature sensors...\n");
if (card.core_temp_get) {
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
addSensorForKey(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_core);
}
else if (card.board_temp_get) {
snprintf(key, 5, KEY_FORMAT_GPU_HEATSINK_TEMPERATURE, card.card_index);
addSensorForKey(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_board);
}
}
else if (card.temp_get)
{
nv_debug(device, "registering temperature sensors...\n");
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
addSensorForKey(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, nouveau_temp_diode);
}
int arg_value = 1;
if (card.clocks_get && !PE_parse_boot_argn("-gpusensors-no-clocks", &arg_value, sizeof(arg_value))) {
nv_debug(device, "registering clocks sensors...\n");
if (card.clocks_get(&card, nouveau_clock_core) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_FREQUENCY, card.card_index);
addSensorForKey(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_core);
}
// if (card.clocks_get(&card, nouveau_clock_shader) > 0) {
// snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_SHADER_FREQUENCY, card.card_index);
// addSensor(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_shader);
// }
if (card.clocks_get(&card, nouveau_clock_rop) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_ROP_FREQUENCY, card.card_index);
addSensorForKey(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_rop);
}
if (card.clocks_get(&card, nouveau_clock_memory) > 0) {
snprintf(key, 5, KEY_FAKESMC_FORMAT_GPU_MEMORY_FREQUENCY, card.card_index);
addSensorForKey(key, TYPE_UI32, TYPE_UI32_SIZE, kFakeSMCFrequencySensor, nouveau_clock_memory);
}
}
if (card.fan_pwm_get || card.fan_rpm_get) {
nv_debug(device, "registering PWM sensors...\n");
char title[DIAG_FUNCTION_STR_LEN];
snprintf (title, DIAG_FUNCTION_STR_LEN, "GPU %X", card.card_index + 1);
if (card.fan_rpm_get && card.fan_rpm_get(&card) >= 0)
addTachometer(nouveau_fan_rpm, title, GPU_FAN_RPM, card.card_index);
if (card.fan_pwm_get && card.fan_pwm_get(&card) >= 0)
addTachometer(nouveau_fan_pwm, title, GPU_FAN_PWM_CYCLE, card.card_index);
}
if (card.volt.get && card.volt.get(&card) >= 0/*card.voltage_get && card.voltage.supported*/) {
nv_debug(device, "registering voltage sensors...\n");
snprintf(key, 5, KEY_FORMAT_GPU_VOLTAGE, card.card_index);
addSensorForKey(key, TYPE_FP2E, TYPE_FPXX_SIZE, kFakeSMCVoltageSensor, 0);
}
registerService();
nv_info(device, "started\n");
return true;
}
bool RadeonMonitor::start(IOService * provider)
{
HWSensorsDebugLog("Starting...");
if (!super::start(provider))
return false;
if (!(card.pdev = (IOPCIDevice*)provider))
return false;
if (OSData *data = OSDynamicCast(OSData, provider->getProperty("device-id"))) {
card.chip_id = *(UInt32*)data->getBytesNoCopy();
}
else {
HWSensorsFatalLog("device-id property not found");
return false;
}
card.pdev->setMemoryEnable(true);
for (UInt32 i = 0; (card.mmio = card.pdev->mapDeviceMemoryWithIndex(i)); i++) {
long unsigned int mmio_base_phys = card.mmio->getPhysicalAddress();
// Make sure we select MMIO registers
if (((card.mmio->getLength()) <= 0x00020000) && (mmio_base_phys != 0))
break;
}
if (!card.mmio) {
HWSensorsInfoLog("failed to map device memory");
return false;
}
card.family = CHIP_FAMILY_UNKNOW;
card.int_thermal_type = THERMAL_TYPE_NONE;
card.card_index = takeVacantGPUIndex();
if (card.card_index < 0) {
radeon_fatal(&card, "failed to obtain vacant GPU index\n");
return false;
}
RADEONCardInfo *devices = RADEONCards;
while (devices->device_id != NULL) {
if ((devices->device_id & 0xffff) == (card.chip_id & 0xffff)) {
card.family = devices->ChipFamily;
card.info.device_id = devices->device_id;
card.info.ChipFamily = devices->ChipFamily;
card.info.igp = devices->igp;
card.info.is_mobility = devices->is_mobility;
radeon_info(&card, "found ATI Radeon 0x%04x\n", card.chip_id & 0xffff);
break;
}
devices++;
}
if (card.family == CHIP_FAMILY_UNKNOW) {
radeon_fatal(&card, "unknown card 0x%04x\n", card.chip_id & 0xffff);
//return false;
}
//try to load bios from ATY,bin_image property of GPU registry node
if (OSData *vbios = OSDynamicCast(OSData, provider->getProperty("ATY,bin_image"))) {
card.bios_size = vbios->getLength();
card.bios = (UInt8*)IOMalloc(vbios->getLength());
memcpy(card.bios, vbios->getBytesNoCopy(), card.bios_size);
if (card.bios[0] == 0x55 && card.bios[1] == 0xaa) {
radeon_device *rdev = &card;
UInt16 tmp = RBIOS16(0x18);
if (RBIOS8(tmp + 0x14) == 0x0) {
if ((card.bios_header_start = RBIOS16(0x48))) {
tmp = card.bios_header_start + 4;
if (!memcmp(card.bios + tmp, "ATOM", 4) ||
!memcmp(card.bios + tmp, "MOTA", 4)) {
card.is_atom_bios = true;
} else {
card.is_atom_bios = false;
}
radeon_info(&card, "%sBIOS detected\n", card.is_atom_bios ? "ATOM" : "COM");
}
}
else radeon_error(&card, "not an x86 BIOS ROM, not using\n");
}
else radeon_error(&card, "BIOS signature incorrect %x %x\n", card.bios[0], card.bios[1]);
}
else radeon_error(&card, "unable to locate ATY,bin_image\n");
if (!card.bios_header_start) {
// Free memory for bios image if it was allocated
if (card.bios && card.bios_size) {
IOFree(card.bios, card.bios_size);
card.bios = 0;
card.bios_size = 0;
}
}
else if (atom_parse(&card)) {
radeon_atombios_get_power_modes(&card);
}
// Use temperature sensor type based on BIOS name
if (card.int_thermal_type == THERMAL_TYPE_NONE && card.bios && card.bios_size) {
if (!strncasecmp("R600", card.bios_name, 64) ||
!strncasecmp("RV610", card.bios_name, 64) ||
!strncasecmp("RV630", card.bios_name, 64) ||
!strncasecmp("RV620", card.bios_name, 64) ||
!strncasecmp("RV635", card.bios_name, 64) ||
!strncasecmp("RV670", card.bios_name, 64) ||
!strncasecmp("RS780", card.bios_name, 64) ||
!strncasecmp("RS880", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_RV6XX;
}
else if (!strncasecmp("RV770", card.bios_name, 64) ||
!strncasecmp("RV730", card.bios_name, 64) ||
!strncasecmp("RV710", card.bios_name, 64) ||
!strncasecmp("RV740", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_RV770;
}
else if (!strncasecmp("CEDAR", card.bios_name, 64) ||
!strncasecmp("REDWOOD", card.bios_name, 64) ||
!strncasecmp("JUNIPER", card.bios_name, 64) ||
!strncasecmp("CYPRESS", card.bios_name, 64) ||
!strncasecmp("PALM", card.bios_name, 64) ||
!strncasecmp("Wrestler", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_EVERGREEN;
}
else if (!strncasecmp("SUMO", card.bios_name, 64) ||
!strncasecmp("SUMO2", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_SUMO;
}
else if (!strncasecmp("ARUBA", card.bios_name, 64) ||
!strncasecmp("BARTS", card.bios_name, 64) ||
!strncasecmp("TURKS", card.bios_name, 64) ||
!strncasecmp("CAICOS", card.bios_name, 64) ||
!strncasecmp("CAYMAN", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_NI;
}
else if (!strncasecmp("CAPE VERDE", card.bios_name, 64) ||
!strncasecmp("PITCAIRN", card.bios_name, 64) ||
!strncasecmp("TAHITI", card.bios_name, 64)) {
card.int_thermal_type = THERMAL_TYPE_SI;
}
}
// Use driver's configuration to resolve temperature sensor type
if (card.int_thermal_type == THERMAL_TYPE_NONE) {
radeon_info(&card, "using device-id to resolve temperature sensor type\n");
// Enable temperature monitoring
switch (card.family) {
case CHIP_FAMILY_R600: /* r600 */
case CHIP_FAMILY_RV610:
case CHIP_FAMILY_RV630:
case CHIP_FAMILY_RV670:
case CHIP_FAMILY_RV620:
case CHIP_FAMILY_RV635:
case CHIP_FAMILY_RS780:
case CHIP_FAMILY_RS880:
card.int_thermal_type = THERMAL_TYPE_RV6XX;
break;
case CHIP_FAMILY_RV770: /* r700 */
case CHIP_FAMILY_RV730:
case CHIP_FAMILY_RV710:
case CHIP_FAMILY_RV740:
card.int_thermal_type = THERMAL_TYPE_RV770;
break;
case CHIP_FAMILY_CEDAR: /* evergreen */
case CHIP_FAMILY_REDWOOD:
case CHIP_FAMILY_JUNIPER:
case CHIP_FAMILY_CYPRESS:
case CHIP_FAMILY_HEMLOCK:
case CHIP_FAMILY_PALM:
card.int_thermal_type = THERMAL_TYPE_EVERGREEN;
break;
case CHIP_FAMILY_BARTS:
case CHIP_FAMILY_TURKS:
case CHIP_FAMILY_CAICOS:
case CHIP_FAMILY_CAYMAN:
case CHIP_FAMILY_ARUBA:
card.int_thermal_type = THERMAL_TYPE_NI;
break;
case CHIP_FAMILY_SUMO:
case CHIP_FAMILY_SUMO2:
card.int_thermal_type = THERMAL_TYPE_SUMO;
break;
case CHIP_FAMILY_TAHITI:
case CHIP_FAMILY_PITCAIRN:
case CHIP_FAMILY_VERDE:
card.int_thermal_type = THERMAL_TYPE_SI;
break;
// default:
// radeon_fatal(&card, "card 0x%04x is unsupported\n", card.chip_id & 0xffff);
// return false;
}
}
// Setup temperature sensor
if (card.int_thermal_type != THERMAL_TYPE_NONE ) {
switch (card.int_thermal_type) {
case THERMAL_TYPE_RV6XX:
card.get_core_temp = rv6xx_get_temp;
radeon_info(&card, "adding rv6xx thermal sensor\n");
break;
case THERMAL_TYPE_RV770:
card.get_core_temp = rv770_get_temp;
radeon_info(&card, "adding rv770 thermal sensor\n");
break;
case THERMAL_TYPE_EVERGREEN:
case THERMAL_TYPE_NI:
card.get_core_temp = evergreen_get_temp;
radeon_info(&card, "adding EverGreen thermal sensor\n");
break;
case THERMAL_TYPE_SUMO:
card.get_core_temp = sumo_get_temp;
radeon_info(&card, "adding Sumo thermal sensor\n");
break;
case THERMAL_TYPE_SI:
card.get_core_temp = si_get_temp;
radeon_info(&card, "adding Southern Islands thermal sensor\n");
break;
default:
radeon_fatal(&card, "card 0x%04x is unsupported\n", card.chip_id & 0xffff);
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
}
if (card.get_core_temp) {
char key[5];
snprintf(key, 5, KEY_FORMAT_GPU_DIODE_TEMPERATURE, card.card_index);
if (!addSensor(key, TYPE_SP78, 2, kFakeSMCTemperatureSensor, 0)) {
//radeon_error(&card, "failed to register temperature sensor for key %s\n", key);
radeon_fatal(&card, "failed to register temperature sensor for key %s\n", key);
releaseGPUIndex(card.card_index);
card.card_index = -1;
return false;
}
}
registerService();
return true;
}
