Sysman API

oneAPI Level Zero Specification - Version 1.2.43

Common

Common Enums

zes_structure_type_t

enum zes_structure_type_t

Defines structure types.

Values:

ZES_STRUCTURE_TYPE_DEVICE_PROPERTIES = 0x1

zes_device_properties_t

ZES_STRUCTURE_TYPE_PCI_PROPERTIES = 0x2

zes_pci_properties_t

ZES_STRUCTURE_TYPE_PCI_BAR_PROPERTIES = 0x3

zes_pci_bar_properties_t

ZES_STRUCTURE_TYPE_DIAG_PROPERTIES = 0x4

zes_diag_properties_t

ZES_STRUCTURE_TYPE_ENGINE_PROPERTIES = 0x5

zes_engine_properties_t

ZES_STRUCTURE_TYPE_FABRIC_PORT_PROPERTIES = 0x6

zes_fabric_port_properties_t

ZES_STRUCTURE_TYPE_FAN_PROPERTIES = 0x7

zes_fan_properties_t

ZES_STRUCTURE_TYPE_FIRMWARE_PROPERTIES = 0x8

zes_firmware_properties_t

ZES_STRUCTURE_TYPE_FREQ_PROPERTIES = 0x9

zes_freq_properties_t

ZES_STRUCTURE_TYPE_LED_PROPERTIES = 0xa

zes_led_properties_t

ZES_STRUCTURE_TYPE_MEM_PROPERTIES = 0xb

zes_mem_properties_t

ZES_STRUCTURE_TYPE_PERF_PROPERTIES = 0xc

zes_perf_properties_t

ZES_STRUCTURE_TYPE_POWER_PROPERTIES = 0xd

zes_power_properties_t

ZES_STRUCTURE_TYPE_PSU_PROPERTIES = 0xe

zes_psu_properties_t

ZES_STRUCTURE_TYPE_RAS_PROPERTIES = 0xf

zes_ras_properties_t

ZES_STRUCTURE_TYPE_SCHED_PROPERTIES = 0x10

zes_sched_properties_t

ZES_STRUCTURE_TYPE_SCHED_TIMEOUT_PROPERTIES = 0x11

zes_sched_timeout_properties_t

ZES_STRUCTURE_TYPE_SCHED_TIMESLICE_PROPERTIES = 0x12

zes_sched_timeslice_properties_t

ZES_STRUCTURE_TYPE_STANDBY_PROPERTIES = 0x13

zes_standby_properties_t

ZES_STRUCTURE_TYPE_TEMP_PROPERTIES = 0x14

zes_temp_properties_t

ZES_STRUCTURE_TYPE_DEVICE_STATE = 0x15

zes_device_state_t

ZES_STRUCTURE_TYPE_PROCESS_STATE = 0x16

zes_process_state_t

ZES_STRUCTURE_TYPE_PCI_STATE = 0x17

zes_pci_state_t

ZES_STRUCTURE_TYPE_FABRIC_PORT_CONFIG = 0x18

zes_fabric_port_config_t

ZES_STRUCTURE_TYPE_FABRIC_PORT_STATE = 0x19

zes_fabric_port_state_t

ZES_STRUCTURE_TYPE_FAN_CONFIG = 0x1a

zes_fan_config_t

ZES_STRUCTURE_TYPE_FREQ_STATE = 0x1b

zes_freq_state_t

ZES_STRUCTURE_TYPE_OC_CAPABILITIES = 0x1c

zes_oc_capabilities_t

ZES_STRUCTURE_TYPE_LED_STATE = 0x1d

zes_led_state_t

ZES_STRUCTURE_TYPE_MEM_STATE = 0x1e

zes_mem_state_t

ZES_STRUCTURE_TYPE_PSU_STATE = 0x1f

zes_psu_state_t

ZES_STRUCTURE_TYPE_BASE_STATE = 0x20

zes_base_state_t

ZES_STRUCTURE_TYPE_RAS_CONFIG = 0x21

zes_ras_config_t

ZES_STRUCTURE_TYPE_RAS_STATE = 0x22

zes_ras_state_t

ZES_STRUCTURE_TYPE_TEMP_CONFIG = 0x23

zes_temp_config_t

ZES_STRUCTURE_TYPE_PCI_BAR_PROPERTIES_1_2 = 0x24

zes_pci_bar_properties_1_2_t

ZES_STRUCTURE_TYPE_FORCE_UINT32 = 0x7fffffff

Common Structures

zes_base_properties_t

struct zes_base_properties_t

Base for all properties types.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_base_desc_t

struct zes_base_desc_t

Base for all descriptor types.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_base_state_t

struct zes_base_state_t

Base for all state types.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_base_config_t

struct zes_base_config_t

Base for all config types.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_base_capability_t

struct zes_base_capability_t

Base for all capability types.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

Device

Device Functions

zesDeviceGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceGetProperties(zes_device_handle_t hDevice, zes_device_properties_t *pProperties)

Get properties about the device.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pProperties: [in,out] Structure that will contain information about the device.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDeviceGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceGetState(zes_device_handle_t hDevice, zes_device_state_t *pState)

Get information about the state of the device - if a reset is required, reasons for the reset and if the device has been repaired.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pState: [in,out] Structure that will contain information about the device.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDeviceReset

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceReset(zes_device_handle_t hDevice, ze_bool_t force)

Reset device.

Parameters

  • hDevice: [in] Sysman handle for the device

  • force: [in] If set to true, all applications that are currently using the device will be forcibly killed.

  • Performs a PCI bus reset of the device. This will result in all current device state being lost.

  • All applications using the device should be stopped before calling this function.

  • If the force argument is specified, all applications using the device will be forcibly killed.

  • The function will block until the device has restarted or a timeout occurred waiting for the reset to complete.

Return

zesDeviceProcessesGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceProcessesGetState(zes_device_handle_t hDevice, uint32_t *pCount, zes_process_state_t *pProcesses)

Get information about host processes using the device.

Parameters

  • hDevice: [in] Sysman handle for the device

  • pCount: [in,out] pointer to the number of processes. if count is zero, then the driver shall update the value with the total number of processes currently attached to the device. if count is greater than the number of processes currently attached to the device, then the driver shall update the value with the correct number of processes.

  • pProcesses: [in,out][optional][range(0, *pCount)] array of process information. if count is less than the number of processes currently attached to the device, then the driver shall only retrieve information about that number of processes. In this case, the return code will ZE_RESULT_ERROR_INVALID_SIZE.

  • The number of processes connected to the device is dynamic. This means that between a call to determine the value of pCount and the subsequent call, the number of processes may have increased or decreased. It is recommended that a large array be passed in so as to avoid receiving the error ZE_RESULT_ERROR_INVALID_SIZE. Also, always check the returned value in pCount since it may be less than the earlier call to get the required array size.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDevicePciGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesDevicePciGetProperties(zes_device_handle_t hDevice, zes_pci_properties_t *pProperties)

Get PCI properties - address, max speed.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pProperties: [in,out] Will contain the PCI properties.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDevicePciGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesDevicePciGetState(zes_device_handle_t hDevice, zes_pci_state_t *pState)

Get current PCI state - current speed.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pState: [in,out] Will contain the PCI properties.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDevicePciGetBars

ZE_APIEXPORT ze_result_t ZE_APICALL zesDevicePciGetBars(zes_device_handle_t hDevice, uint32_t *pCount, zes_pci_bar_properties_t *pProperties)

Get information about each configured bar.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of PCI bars. if count is zero, then the driver shall update the value with the total number of PCI bars that are setup. if count is greater than the number of PCI bars that are setup, then the driver shall update the value with the correct number of PCI bars.

  • pProperties: [in,out][optional][range(0, *pCount)] array of information about setup PCI bars. if count is less than the number of PCI bars that are setup, then the driver shall only retrieve information about that number of PCI bars.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDevicePciGetStats

ZE_APIEXPORT ze_result_t ZE_APICALL zesDevicePciGetStats(zes_device_handle_t hDevice, zes_pci_stats_t *pStats)

Get PCI stats - bandwidth, number of packets, number of replays.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pStats: [in,out] Will contain a snapshot of the latest stats.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Device Enums

zes_engine_type_flags_t

enum zes_engine_type_flag_t

Values:

ZES_ENGINE_TYPE_FLAG_OTHER = ZE_BIT(0)

Undefined types of accelerators.

ZES_ENGINE_TYPE_FLAG_COMPUTE = ZE_BIT(1)

Engines that process compute kernels only (no 3D content).

ZES_ENGINE_TYPE_FLAG_3D = ZE_BIT(2)

Engines that process 3D content only (no compute kernels).

ZES_ENGINE_TYPE_FLAG_MEDIA = ZE_BIT(3)

Engines that process media workloads.

ZES_ENGINE_TYPE_FLAG_DMA = ZE_BIT(4)

Engines that copy blocks of data.

ZES_ENGINE_TYPE_FLAG_RENDER = ZE_BIT(5)

Engines that can process both 3D content and compute kernels.

ZES_ENGINE_TYPE_FLAG_FORCE_UINT32 = 0x7fffffff

zes_repair_status_t

enum zes_repair_status_t

Device repair status.

Values:

ZES_REPAIR_STATUS_UNSUPPORTED = 0

The device does not support in-field repairs.

ZES_REPAIR_STATUS_NOT_PERFORMED = 1

The device has never been repaired.

ZES_REPAIR_STATUS_PERFORMED = 2

The device has been repaired.

ZES_REPAIR_STATUS_FORCE_UINT32 = 0x7fffffff

zes_reset_reason_flags_t

enum zes_reset_reason_flag_t

Values:

ZES_RESET_REASON_FLAG_WEDGED = ZE_BIT(0)

The device needs to be reset because one or more parts of the hardware is wedged

ZES_RESET_REASON_FLAG_REPAIR = ZE_BIT(1)

The device needs to be reset in order to complete in-field repairs.

ZES_RESET_REASON_FLAG_FORCE_UINT32 = 0x7fffffff

zes_pci_bar_type_t

enum zes_pci_bar_type_t

PCI bar types.

Values:

ZES_PCI_BAR_TYPE_MMIO = 0

MMIO registers.

ZES_PCI_BAR_TYPE_ROM = 1

ROM aperture.

ZES_PCI_BAR_TYPE_MEM = 2

Device memory.

ZES_PCI_BAR_TYPE_FORCE_UINT32 = 0x7fffffff

Device Structures

zes_device_state_t

struct zes_device_state_t

Device state.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_reset_reason_flags_t reset

[out] Indicates if the device needs to be reset and for what reasons. returns 0 (none) or combination of zes_reset_reason_flag_t

zes_repair_status_t repaired

[out] Indicates if the device has been repaired

zes_device_properties_t

struct zes_device_properties_t

Device properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_device_properties_t core

[out] Core device properties

uint32_t numSubdevices

[out] Number of sub-devices. A value of 0 indicates that this device doesn’t have sub-devices.

char serialNumber[ZES_STRING_PROPERTY_SIZE]

[out] Manufacturing serial number (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

char boardNumber[ZES_STRING_PROPERTY_SIZE]

[out] Manufacturing board number (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

char brandName[ZES_STRING_PROPERTY_SIZE]

[out] Brand name of the device (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

char modelName[ZES_STRING_PROPERTY_SIZE]

[out] Model name of the device (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

char vendorName[ZES_STRING_PROPERTY_SIZE]

[out] Vendor name of the device (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

char driverVersion[ZES_STRING_PROPERTY_SIZE]

[out] Installed driver version (NULL terminated string value). Will be set to the string “unkown” if this cannot be determined for the device.

zes_process_state_t

struct zes_process_state_t

Contains information about a process that has an open connection with this device.

  • The application can use the process ID to query the OS for the owner and the path to the executable.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

uint32_t processId

[out] Host OS process ID.

uint64_t memSize

[out] Device memory size in bytes allocated by this process (may not necessarily be resident on the device at the time of reading).

uint64_t sharedSize

[out] The size of shared device memory mapped into this process (may not necessarily be resident on the device at the time of reading).

zes_engine_type_flags_t engines

[out] Bitfield of accelerator engine types being used by this process.

zes_pci_address_t

struct zes_pci_address_t

PCI address.

Public Members

uint32_t domain

[out] BDF domain

uint32_t bus

[out] BDF bus

uint32_t device

[out] BDF device

uint32_t function

[out] BDF function

zes_pci_speed_t

struct zes_pci_speed_t

PCI speed.

Public Members

int32_t gen

[out] The link generation. A value of -1 means that this property is unknown.

int32_t width

[out] The number of lanes. A value of -1 means that this property is unknown.

int64_t maxBandwidth

[out] The maximum bandwidth in bytes/sec (sum of all lanes). A value of -1 means that this property is unknown.

zes_pci_properties_t

struct zes_pci_properties_t

Static PCI properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_pci_address_t address

[out] The BDF address

zes_pci_speed_t maxSpeed

[out] Fastest port configuration supported by the device (sum of all lanes)

ze_bool_t haveBandwidthCounters

[out] Indicates if zes_pci_stats_t.rxCounter and zes_pci_stats_t.txCounter will have valid values

ze_bool_t havePacketCounters

[out] Indicates if zes_pci_stats_t.packetCounter will have valid values

ze_bool_t haveReplayCounters

[out] Indicates if zes_pci_stats_t.replayCounter will have valid values

zes_pci_state_t

struct zes_pci_state_t

Dynamic PCI state.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_pci_link_status_t status

[out] The current status of the port

zes_pci_link_qual_issue_flags_t qualityIssues

[out] If status is ZES_PCI_LINK_STATUS_QUALITY_ISSUES, then this gives a combination of zes_pci_link_qual_issue_flag_t for quality issues that have been detected; otherwise, 0 indicates there are no quality issues with the link at this time.”

zes_pci_link_stab_issue_flags_t stabilityIssues

[out] If status is ZES_PCI_LINK_STATUS_STABILITY_ISSUES, then this gives a combination of zes_pci_link_stab_issue_flag_t for reasons for the connection instability; otherwise, 0 indicates there are no connection stability issues at this time.”

zes_pci_speed_t speed

[out] The current port configure speed

zes_pci_bar_properties_t

struct zes_pci_bar_properties_t

Properties of a pci bar.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_pci_bar_type_t type

[out] The type of bar

uint32_t index

[out] The index of the bar

uint64_t base

[out] Base address of the bar.

uint64_t size

[out] Size of the bar.

zes_pci_bar_properties_1_2_t

struct zes_pci_bar_properties_1_2_t

Properties of a pci bar, including the resizable bar.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_pci_bar_type_t type

[out] The type of bar

uint32_t index

[out] The index of the bar

uint64_t base

[out] Base address of the bar.

uint64_t size

[out] Size of the bar.

ze_bool_t resizableBarSupported

[out] Support for Resizable Bar on this device.

ze_bool_t resizableBarEnabled

[out] Resizable Bar enabled on this device

zes_pci_stats_t

struct zes_pci_stats_t

PCI stats counters.

  • Percent replays is calculated by taking two snapshots (s1, s2) and using the equation: replay = 10^6 * (s2.replayCounter - s1.replayCounter) / (s2.maxBandwidth * (s2.timestamp - s1.timestamp))

  • Percent throughput is calculated by taking two snapshots (s1, s2) and using the equation: bw = 10^6 * ((s2.rxCounter - s1.rxCounter) + (s2.txCounter - s1.txCounter)) / (s2.maxBandwidth * (s2.timestamp - s1.timestamp))

Public Members

uint64_t timestamp

[out] Monotonic timestamp counter in microseconds when the measurement was made. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

uint64_t replayCounter

[out] Monotonic counter for the number of replay packets (sum of all lanes). Will always be 0 if zes_pci_properties_t.haveReplayCounters is FALSE.

uint64_t packetCounter

[out] Monotonic counter for the number of packets (sum of all lanes). Will always be 0 if zes_pci_properties_t.havePacketCounters is FALSE.

uint64_t rxCounter

[out] Monotonic counter for the number of bytes received (sum of all lanes). Will always be 0 if zes_pci_properties_t.haveBandwidthCounters is FALSE.

uint64_t txCounter

[out] Monotonic counter for the number of bytes transmitted (including replays) (sum of all lanes). Will always be 0 if zes_pci_properties_t.haveBandwidthCounters is FALSE.

zes_pci_speed_t speed

[out] The current speed of the link (sum of all lanes)

Diagnostics

Diagnostics Functions

zesDeviceEnumDiagnosticTestSuites

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumDiagnosticTestSuites(zes_device_handle_t hDevice, uint32_t *pCount, zes_diag_handle_t *phDiagnostics)

Get handle of diagnostics test suites.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phDiagnostics: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDiagnosticsGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesDiagnosticsGetProperties(zes_diag_handle_t hDiagnostics, zes_diag_properties_t *pProperties)

Get properties of a diagnostics test suite.

Parameters

  • hDiagnostics: [in] Handle for the component.

  • pProperties: [in,out] Structure describing the properties of a diagnostics test suite

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDiagnosticsGetTests

ZE_APIEXPORT ze_result_t ZE_APICALL zesDiagnosticsGetTests(zes_diag_handle_t hDiagnostics, uint32_t *pCount, zes_diag_test_t *pTests)

Get individual tests that can be run separately. Not all test suites permit running individual tests - check zes_diag_properties_t.haveTests.

Parameters

  • hDiagnostics: [in] Handle for the component.

  • pCount: [in,out] pointer to the number of tests. if count is zero, then the driver shall update the value with the total number of tests that are available. if count is greater than the number of tests that are available, then the driver shall update the value with the correct number of tests.

  • pTests: [in,out][optional][range(0, *pCount)] array of information about individual tests sorted by increasing value of zes_diag_test_t.index. if count is less than the number of tests that are available, then the driver shall only retrieve that number of tests.

  • The list of available tests is returned in order of increasing test index zes_diag_test_t.index.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDiagnosticsRunTests

ZE_APIEXPORT ze_result_t ZE_APICALL zesDiagnosticsRunTests(zes_diag_handle_t hDiagnostics, uint32_t start, uint32_t end, zes_diag_result_t *pResult)

Run a diagnostics test suite, either all tests or a subset of tests.

Parameters

  • hDiagnostics: [in] Handle for the component.

  • start: [in] The index of the first test to run. Set to ZES_DIAG_FIRST_TEST_INDEX to start from the beginning.

  • end: [in] The index of the last test to run. Set to ZES_DIAG_LAST_TEST_INDEX to complete all tests after the start test.

  • pResult: [in,out] The result of the diagnostics

  • WARNING: Performancing diagnostics may destroy current device state information. Gracefully close any running workloads before initiating.

  • To run all tests in a test suite, set start = ZES_DIAG_FIRST_TEST_INDEX and end = ZES_DIAG_LAST_TEST_INDEX.

  • If the test suite permits running individual tests, zes_diag_properties_t.haveTests will be true. In this case, the function zesDiagnosticsGetTests() can be called to get the list of tests and corresponding indices that can be supplied to the arguments start and end in this function.

  • This function will block until the diagnostics have completed.

Return

Diagnostics Enums

zes_diag_result_t

enum zes_diag_result_t

Diagnostic results.

Values:

ZES_DIAG_RESULT_NO_ERRORS = 0

Diagnostic completed without finding errors to repair.

ZES_DIAG_RESULT_ABORT = 1

Diagnostic had problems running tests.

ZES_DIAG_RESULT_FAIL_CANT_REPAIR = 2

Diagnostic had problems setting up repairs.

ZES_DIAG_RESULT_REBOOT_FOR_REPAIR = 3

Diagnostics found errors, setup for repair and reboot is required to complete the process

ZES_DIAG_RESULT_FORCE_UINT32 = 0x7fffffff

Diagnostics Structures

zes_diag_test_t

struct zes_diag_test_t

Diagnostic test.

Public Members

uint32_t index

[out] Index of the test

char name[ZES_STRING_PROPERTY_SIZE]

[out] Name of the test

zes_diag_properties_t

struct zes_diag_properties_t

Diagnostics test suite properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

char name[ZES_STRING_PROPERTY_SIZE]

[out] Name of the diagnostics test suite

ze_bool_t haveTests

[out] Indicates if this test suite has individual tests which can be run separately (use the function zesDiagnosticsGetTests() to get the list of these tests)

Engine

Engine Functions

zesDeviceEnumEngineGroups

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumEngineGroups(zes_device_handle_t hDevice, uint32_t *pCount, zes_engine_handle_t *phEngine)

Get handle of engine groups.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phEngine: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesEngineGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesEngineGetProperties(zes_engine_handle_t hEngine, zes_engine_properties_t *pProperties)

Get engine group properties.

Parameters

  • hEngine: [in] Handle for the component.

  • pProperties: [in,out] The properties for the specified engine group.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesEngineGetActivity

ZE_APIEXPORT ze_result_t ZE_APICALL zesEngineGetActivity(zes_engine_handle_t hEngine, zes_engine_stats_t *pStats)

Get the activity stats for an engine group.

Parameters

  • hEngine: [in] Handle for the component.

  • pStats: [in,out] Will contain a snapshot of the engine group activity counters.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Engine Enums

zes_engine_group_t

enum zes_engine_group_t

Accelerator engine groups.

Values:

ZES_ENGINE_GROUP_ALL = 0

Access information about all engines combined.

ZES_ENGINE_GROUP_COMPUTE_ALL = 1

Access information about all compute engines combined. Compute engines can only process compute kernels (no 3D content).

ZES_ENGINE_GROUP_MEDIA_ALL = 2

Access information about all media engines combined.

ZES_ENGINE_GROUP_COPY_ALL = 3

Access information about all copy (blitter) engines combined.

ZES_ENGINE_GROUP_COMPUTE_SINGLE = 4

Access information about a single compute engine - this is an engine that can process compute kernels. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_3D_RENDER_COMPUTE_ALL for that.

ZES_ENGINE_GROUP_RENDER_SINGLE = 5

Access information about a single render engine - this is an engine that can process both 3D content and compute kernels. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_3D_RENDER_COMPUTE_ALL for that.

ZES_ENGINE_GROUP_MEDIA_DECODE_SINGLE = 6

Access information about a single media decode engine. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_MEDIA_ALL for that.

ZES_ENGINE_GROUP_MEDIA_ENCODE_SINGLE = 7

Access information about a single media encode engine. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_MEDIA_ALL for that.

ZES_ENGINE_GROUP_COPY_SINGLE = 8

Access information about a single media encode engine. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_COPY_ALL for that.

ZES_ENGINE_GROUP_MEDIA_ENHANCEMENT_SINGLE = 9

Access information about a single media enhancement engine. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_MEDIA_ALL for that.

ZES_ENGINE_GROUP_3D_SINGLE = 10

Access information about a single 3D engine - this is an engine that can process 3D content only. Note that single engines may share the same underlying accelerator resources as other engines so activity of such an engine may not be indicative of the underlying resource utilization - use ZES_ENGINE_GROUP_3D_RENDER_COMPUTE_ALL for that.

ZES_ENGINE_GROUP_3D_RENDER_COMPUTE_ALL = 11

Access information about all 3D/render/compute engines combined.

ZES_ENGINE_GROUP_RENDER_ALL = 12

Access information about all render engines combined. Render engines are those than process both 3D content and compute kernels.

ZES_ENGINE_GROUP_3D_ALL = 13

Access information about all 3D engines combined. 3D engines can process 3D content only (no compute kernels).

ZES_ENGINE_GROUP_FORCE_UINT32 = 0x7fffffff

Engine Structures

zes_engine_properties_t

struct zes_engine_properties_t

Engine group properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_engine_group_t type

[out] The engine group

ze_bool_t onSubdevice

[out] True if this resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

zes_engine_stats_t

struct zes_engine_stats_t

Engine activity counters.

  • Percent utilization is calculated by taking two snapshots (s1, s2) and using the equation: util = (s2.activeTime - s1.activeTime) / (s2.timestamp - s1.timestamp)

Public Members

uint64_t activeTime

[out] Monotonic counter for time in microseconds that this resource is actively running workloads.

uint64_t timestamp

[out] Monotonic timestamp counter in microseconds when activeTime counter was sampled. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

Events

Events Functions

zesDeviceEventRegister

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEventRegister(zes_device_handle_t hDevice, zes_event_type_flags_t events)

Specify the list of events to listen to for a given device.

Parameters

  • hDevice: [in] The device handle.

  • events: [in] List of events to listen to.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDriverEventListen

ZE_APIEXPORT ze_result_t ZE_APICALL zesDriverEventListen(ze_driver_handle_t hDriver, uint32_t timeout, uint32_t count, zes_device_handle_t *phDevices, uint32_t *pNumDeviceEvents, zes_event_type_flags_t *pEvents)

Wait for events to be received from a one or more devices.

Parameters

  • hDriver: [in] handle of the driver instance

  • timeout: [in] if non-zero, then indicates the maximum time (in milliseconds) to yield before returning ZE_RESULT_SUCCESS or ZE_RESULT_NOT_READY; if zero, then will check status and return immediately; if UINT32_MAX, then function will not return until events arrive.

  • count: [in] Number of device handles in phDevices.

  • phDevices: [in][range(0, count)] Device handles to listen to for events. Only devices from the provided driver handle can be specified in this list.

  • pNumDeviceEvents: [in,out] Will contain the actual number of devices in phDevices that generated events. If non-zero, check pEvents to determine the devices and events that were received.

  • pEvents: [in,out] An array that will continue the list of events for each device listened in phDevices. This array must be at least as big as count. For every device handle in phDevices, this will provide the events that occurred for that device at the same position in this array. If no event was received for a given device, the corresponding array entry will be zero.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesDriverEventListenEx

ZE_APIEXPORT ze_result_t ZE_APICALL zesDriverEventListenEx(ze_driver_handle_t hDriver, uint64_t timeout, uint32_t count, zes_device_handle_t *phDevices, uint32_t *pNumDeviceEvents, zes_event_type_flags_t *pEvents)

Wait for events to be received from a one or more devices.

Parameters

  • hDriver: [in] handle of the driver instance

  • timeout: [in] if non-zero, then indicates the maximum time (in milliseconds) to yield before returning ZE_RESULT_SUCCESS or ZE_RESULT_NOT_READY; if zero, then will check status and return immediately; if UINT64_MAX, then function will not return until events arrive.

  • count: [in] Number of device handles in phDevices.

  • phDevices: [in][range(0, count)] Device handles to listen to for events. Only devices from the provided driver handle can be specified in this list.

  • pNumDeviceEvents: [in,out] Will contain the actual number of devices in phDevices that generated events. If non-zero, check pEvents to determine the devices and events that were received.

  • pEvents: [in,out] An array that will continue the list of events for each device listened in phDevices. This array must be at least as big as count. For every device handle in phDevices, this will provide the events that occurred for that device at the same position in this array. If no event was received for a given device, the corresponding array entry will be zero.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Events Enums

zes_event_type_flags_t

enum zes_event_type_flag_t

Values:

ZES_EVENT_TYPE_FLAG_DEVICE_DETACH = ZE_BIT(0)

Event is triggered when the device is no longer available (due to a reset or being disabled).

ZES_EVENT_TYPE_FLAG_DEVICE_ATTACH = ZE_BIT(1)

Event is triggered after the device is available again.

ZES_EVENT_TYPE_FLAG_DEVICE_SLEEP_STATE_ENTER = ZE_BIT(2)

deep sleep state

Event is triggered when the driver is about to put the device into a

ZES_EVENT_TYPE_FLAG_DEVICE_SLEEP_STATE_EXIT = ZE_BIT(3)

sleep state

Event is triggered when the driver is waking the device up from a deep

ZES_EVENT_TYPE_FLAG_FREQ_THROTTLED = ZE_BIT(4)

Event is triggered when the frequency starts being throttled.

ZES_EVENT_TYPE_FLAG_ENERGY_THRESHOLD_CROSSED = ZE_BIT(5)

(use zesPowerSetEnergyThreshold() to configure).

Event is triggered when the energy consumption threshold is reached

ZES_EVENT_TYPE_FLAG_TEMP_CRITICAL = ZE_BIT(6)

Event is triggered when the critical temperature is reached (use zesTemperatureSetConfig() to configure - disabled by default).

ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD1 = ZE_BIT(7)

Event is triggered when the temperature crosses threshold 1 (use zesTemperatureSetConfig() to configure - disabled by default).

ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD2 = ZE_BIT(8)

Event is triggered when the temperature crosses threshold 2 (use zesTemperatureSetConfig() to configure - disabled by default).

ZES_EVENT_TYPE_FLAG_MEM_HEALTH = ZE_BIT(9)

Event is triggered when the health of device memory changes.

ZES_EVENT_TYPE_FLAG_FABRIC_PORT_HEALTH = ZE_BIT(10)

Event is triggered when the health of fabric ports change.

ZES_EVENT_TYPE_FLAG_PCI_LINK_HEALTH = ZE_BIT(11)

Event is triggered when the health of the PCI link changes.

ZES_EVENT_TYPE_FLAG_RAS_CORRECTABLE_ERRORS = ZE_BIT(12)

Event is triggered when accelerator RAS correctable errors cross thresholds (use zesRasSetConfig() to configure - disabled by default).

ZES_EVENT_TYPE_FLAG_RAS_UNCORRECTABLE_ERRORS = ZE_BIT(13)

Event is triggered when accelerator RAS uncorrectable errors cross thresholds (use zesRasSetConfig() to configure - disabled by default).

ZES_EVENT_TYPE_FLAG_DEVICE_RESET_REQUIRED = ZE_BIT(14)

zesDeviceGetState() to determine the reasons for the reset).

Event is triggered when the device needs to be reset (use

ZES_EVENT_TYPE_FLAG_FORCE_UINT32 = 0x7fffffff

Fabric

Fabric Functions

zesDeviceEnumFabricPorts

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumFabricPorts(zes_device_handle_t hDevice, uint32_t *pCount, zes_fabric_port_handle_t *phPort)

Get handle of Fabric ports in a device.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phPort: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortGetProperties(zes_fabric_port_handle_t hPort, zes_fabric_port_properties_t *pProperties)

Get Fabric port properties.

Parameters

  • hPort: [in] Handle for the component.

  • pProperties: [in,out] Will contain properties of the Fabric Port.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortGetLinkType

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortGetLinkType(zes_fabric_port_handle_t hPort, zes_fabric_link_type_t *pLinkType)

Get Fabric port link type.

Parameters

  • hPort: [in] Handle for the component.

  • pLinkType: [in,out] Will contain details about the link attached to the Fabric port.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortGetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortGetConfig(zes_fabric_port_handle_t hPort, zes_fabric_port_config_t *pConfig)

Get Fabric port configuration.

Parameters

  • hPort: [in] Handle for the component.

  • pConfig: [in,out] Will contain configuration of the Fabric Port.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortSetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortSetConfig(zes_fabric_port_handle_t hPort, const zes_fabric_port_config_t *pConfig)

Set Fabric port configuration.

Parameters

  • hPort: [in] Handle for the component.

  • pConfig: [in] Contains new configuration of the Fabric Port.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortGetState(zes_fabric_port_handle_t hPort, zes_fabric_port_state_t *pState)

Get Fabric port state - status (health/degraded/failed/disabled), reasons for link degradation or instability, current rx/tx speed.

Parameters

  • hPort: [in] Handle for the component.

  • pState: [in,out] Will contain the current state of the Fabric Port

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFabricPortGetThroughput

ZE_APIEXPORT ze_result_t ZE_APICALL zesFabricPortGetThroughput(zes_fabric_port_handle_t hPort, zes_fabric_port_throughput_t *pThroughput)

Get Fabric port throughput.

Parameters

  • hPort: [in] Handle for the component.

  • pThroughput: [in,out] Will contain the Fabric port throughput counters.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Fabric Enums

zes_fabric_port_status_t

enum zes_fabric_port_status_t

Fabric port status.

Values:

ZES_FABRIC_PORT_STATUS_UNKNOWN = 0

The port status cannot be determined.

ZES_FABRIC_PORT_STATUS_HEALTHY = 1

The port is up and operating as expected.

ZES_FABRIC_PORT_STATUS_DEGRADED = 2

The port is up but has quality and/or speed degradation.

ZES_FABRIC_PORT_STATUS_FAILED = 3

Port connection instabilities are preventing workloads making forward progress

ZES_FABRIC_PORT_STATUS_DISABLED = 4

The port is configured down.

ZES_FABRIC_PORT_STATUS_FORCE_UINT32 = 0x7fffffff

zes_fabric_port_qual_issue_flags_t

enum zes_fabric_port_qual_issue_flag_t

Values:

ZES_FABRIC_PORT_QUAL_ISSUE_FLAG_LINK_ERRORS = ZE_BIT(0)

Excessive link errors are occurring.

ZES_FABRIC_PORT_QUAL_ISSUE_FLAG_SPEED = ZE_BIT(1)

There is a degradation in the bitrate and/or width of the link.

ZES_FABRIC_PORT_QUAL_ISSUE_FLAG_FORCE_UINT32 = 0x7fffffff

zes_fabric_port_failure_flags_t

enum zes_fabric_port_failure_flag_t

Values:

ZES_FABRIC_PORT_FAILURE_FLAG_FAILED = ZE_BIT(0)

A previously operating link has failed. Hardware will automatically retrain this port. This state will persist until either the physical connection is removed or the link trains successfully.

ZES_FABRIC_PORT_FAILURE_FLAG_TRAINING_TIMEOUT = ZE_BIT(1)

A connection has not been established within an expected time. Hardware will continue to attempt port training. This status will persist until either the physical connection is removed or the link successfully trains.

ZES_FABRIC_PORT_FAILURE_FLAG_FLAPPING = ZE_BIT(2)

Port has excessively trained and then transitioned down for some period of time. Driver will allow port to continue to train, but will not enable the port for use until the port has been disabled and subsequently re-enabled using zesFabricPortSetConfig().

ZES_FABRIC_PORT_FAILURE_FLAG_FORCE_UINT32 = 0x7fffffff

Fabric Structures

zes_fabric_port_id_t

struct zes_fabric_port_id_t

Unique identifier for a fabric port.

  • This not a universal identifier. The identified is garanteed to be unique for the current hardware configuration of the system. Changes in the hardware may result in a different identifier for a given port.

  • The main purpose of this identifier to build up an instantaneous topology map of system connectivity. An application should enumerate all fabric ports and match zes_fabric_port_state_t.remotePortId to zes_fabric_port_properties_t.portId.

Public Members

uint32_t fabricId

[out] Unique identifier for the fabric end-point

uint32_t attachId

[out] Unique identifier for the device attachment point

uint8_t portNumber

[out] The logical port number (this is typically marked somewhere on the physical device)

zes_fabric_port_speed_t

struct zes_fabric_port_speed_t

Fabric port speed in one direction.

Public Members

int64_t bitRate

[out] Bits/sec that the link is operating at. A value of -1 means that this property is unknown.

int32_t width

[out] The number of lanes. A value of -1 means that this property is unknown.

zes_fabric_port_properties_t

struct zes_fabric_port_properties_t

Fabric port properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

char model[ZES_MAX_FABRIC_PORT_MODEL_SIZE]

[out] Description of port technology. Will be set to the string “unkown” if this cannot be determined for this port.

ze_bool_t onSubdevice

[out] True if the port is located on a sub-device; false means that the port is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

zes_fabric_port_id_t portId

[out] The unique port identifier

zes_fabric_port_speed_t maxRxSpeed

[out] Maximum speed supported by the receive side of the port (sum of all lanes)

zes_fabric_port_speed_t maxTxSpeed

[out] Maximum speed supported by the transmit side of the port (sum of all lanes)

zes_fabric_port_config_t

struct zes_fabric_port_config_t

Fabric port configuration.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

ze_bool_t enabled

[in,out] Port is configured up/down

ze_bool_t beaconing

[in,out] Beaconing is configured on/off

zes_fabric_port_state_t

struct zes_fabric_port_state_t

Fabric port state.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_fabric_port_status_t status

[out] The current status of the port

zes_fabric_port_qual_issue_flags_t qualityIssues

[out] If status is ZES_FABRIC_PORT_STATUS_DEGRADED,

then this gives a combination of

zes_fabric_port_qual_issue_flag_t for quality issues that have been detected; otherwise, 0 indicates there are no quality issues with the link at this time.

zes_fabric_port_failure_flags_t failureReasons

[out] If status is ZES_FABRIC_PORT_STATUS_FAILED, then this gives a combination of zes_fabric_port_failure_flag_t for reasons for the connection instability; otherwise, 0 indicates there are no connection stability issues at this time.

zes_fabric_port_id_t remotePortId

[out] The unique port identifier for the remote connection point if status is ZES_FABRIC_PORT_STATUS_HEALTHY, ZES_FABRIC_PORT_STATUS_DEGRADED or ZES_FABRIC_PORT_STATUS_FAILED

zes_fabric_port_speed_t rxSpeed

[out] Current maximum receive speed (sum of all lanes)

zes_fabric_port_speed_t txSpeed

[out] Current maximum transmit speed (sum of all lanes)

zes_fabric_port_throughput_t

struct zes_fabric_port_throughput_t

Fabric port throughput.

Public Members

uint64_t timestamp

[out] Monotonic timestamp counter in microseconds when the measurement was made. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

uint64_t rxCounter

[out] Monotonic counter for the number of bytes received (sum of all lanes). This includes all protocol overhead, not only the GPU traffic.

uint64_t txCounter

[out] Monotonic counter for the number of bytes transmitted (sum of all lanes). This includes all protocol overhead, not only the GPU traffic.

Fan

Fan Functions

zesDeviceEnumFans

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumFans(zes_device_handle_t hDevice, uint32_t *pCount, zes_fan_handle_t *phFan)

Get handle of fans.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phFan: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanGetProperties(zes_fan_handle_t hFan, zes_fan_properties_t *pProperties)

Get fan properties.

Parameters

  • hFan: [in] Handle for the component.

  • pProperties: [in,out] Will contain the properties of the fan.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanGetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanGetConfig(zes_fan_handle_t hFan, zes_fan_config_t *pConfig)

Get fan configurations and the current fan speed mode (default, fixed, temp-speed table)

Parameters

  • hFan: [in] Handle for the component.

  • pConfig: [in,out] Will contain the current configuration of the fan.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanSetDefaultMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanSetDefaultMode(zes_fan_handle_t hFan)

Configure the fan to run with hardware factory settings (set mode to ZES_FAN_SPEED_MODE_DEFAULT)

Parameters

  • hFan: [in] Handle for the component.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanSetFixedSpeedMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanSetFixedSpeedMode(zes_fan_handle_t hFan, const zes_fan_speed_t *speed)

Configure the fan to rotate at a fixed speed (set mode to ZES_FAN_SPEED_MODE_FIXED)

Parameters

  • hFan: [in] Handle for the component.

  • speed: [in] The fixed fan speed setting

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanSetSpeedTableMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanSetSpeedTableMode(zes_fan_handle_t hFan, const zes_fan_speed_table_t *speedTable)

Configure the fan to adjust speed based on a temperature/speed table (set mode to ZES_FAN_SPEED_MODE_TABLE)

Parameters

  • hFan: [in] Handle for the component.

  • speedTable: [in] A table containing temperature/speed pairs.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFanGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesFanGetState(zes_fan_handle_t hFan, zes_fan_speed_units_t units, int32_t *pSpeed)

Get current state of a fan - current mode and speed.

Parameters

  • hFan: [in] Handle for the component.

  • units: [in] The units in which the fan speed should be returned.

  • pSpeed: [in,out] Will contain the current speed of the fan in the units requested. A value of -1 indicates that the fan speed cannot be measured.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Fan Enums

zes_fan_speed_mode_t

enum zes_fan_speed_mode_t

Fan resource speed mode.

Values:

ZES_FAN_SPEED_MODE_DEFAULT = 0

The fan speed is operating using the hardware default settings.

ZES_FAN_SPEED_MODE_FIXED = 1

The fan speed is currently set to a fixed value.

ZES_FAN_SPEED_MODE_TABLE = 2

The fan speed is currently controlled dynamically by hardware based on a temp/speed table

ZES_FAN_SPEED_MODE_FORCE_UINT32 = 0x7fffffff

zes_fan_speed_units_t

enum zes_fan_speed_units_t

Fan speed units.

Values:

ZES_FAN_SPEED_UNITS_RPM = 0

The fan speed is in units of revolutions per minute (rpm)

ZES_FAN_SPEED_UNITS_PERCENT = 1

The fan speed is a percentage of the maximum speed of the fan.

ZES_FAN_SPEED_UNITS_FORCE_UINT32 = 0x7fffffff

Fan Structures

zes_fan_speed_t

struct zes_fan_speed_t

Fan speed.

Public Members

int32_t speed

[in,out] The speed of the fan. On output, a value of -1 indicates that there is no fixed fan speed setting.

zes_fan_speed_units_t units

[in,out] The units that the fan speed is expressed in. On output, if fan speed is -1 then units should be ignored.

zes_fan_temp_speed_t

struct zes_fan_temp_speed_t

Fan temperature/speed pair.

Public Members

uint32_t temperature

[in,out] Temperature in degrees Celsius.

zes_fan_speed_t speed

[in,out] The speed of the fan

zes_fan_speed_table_t

struct zes_fan_speed_table_t

Fan speed table.

Public Members

int32_t numPoints

[in,out] The number of valid points in the fan speed table. 0 means that there is no fan speed table configured. -1 means that a fan speed table is not supported by the hardware.

zes_fan_temp_speed_t table[ZES_FAN_TEMP_SPEED_PAIR_COUNT]

based on temperature from lowest to highest.

[in,out] Array of temperature/fan speed pairs. The table is ordered

zes_fan_properties_t

struct zes_fan_properties_t

Fan properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Indicates if software can control the fan speed assuming the user has permissions

uint32_t supportedModes

[out] Bitfield of supported fan configuration modes (1<<zes_fan_speed_mode_t)

uint32_t supportedUnits

[out] Bitfield of supported fan speed units (1<<zes_fan_speed_units_t)

int32_t maxRPM

[out] The maximum RPM of the fan. A value of -1 means that this property is unknown.

int32_t maxPoints

[out] The maximum number of points in the fan temp/speed table. A value of -1 means that this fan doesn’t support providing a temp/speed table.

zes_fan_config_t

struct zes_fan_config_t

Fan configuration.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_fan_speed_mode_t mode

[in,out] The fan speed mode (fixed, temp-speed table)

zes_fan_speed_t speedFixed

[in,out] The current fixed fan speed setting

zes_fan_speed_table_t speedTable

[out] A table containing temperature/speed pairs

Firmware

Firmware Functions

zesDeviceEnumFirmwares

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumFirmwares(zes_device_handle_t hDevice, uint32_t *pCount, zes_firmware_handle_t *phFirmware)

Get handle of firmwares.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phFirmware: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFirmwareGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesFirmwareGetProperties(zes_firmware_handle_t hFirmware, zes_firmware_properties_t *pProperties)

Get firmware properties.

Parameters

  • hFirmware: [in] Handle for the component.

  • pProperties: [in,out] Pointer to an array that will hold the properties of the firmware

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFirmwareFlash

ZE_APIEXPORT ze_result_t ZE_APICALL zesFirmwareFlash(zes_firmware_handle_t hFirmware, void *pImage, uint32_t size)

Flash a new firmware image.

Parameters

  • hFirmware: [in] Handle for the component.

  • pImage: [in] Image of the new firmware to flash.

  • size: [in] Size of the flash image.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Firmware Structures

zes_firmware_properties_t

struct zes_firmware_properties_t

Firmware properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Indicates if software can flash the firmware assuming the user has permissions

char name[ZES_STRING_PROPERTY_SIZE]

[out] NULL terminated string value. The string “unknown” will be returned if this property cannot be determined.

char version[ZES_STRING_PROPERTY_SIZE]

[out] NULL terminated string value. The string “unknown” will be returned if this property cannot be determined.

Frequency

Frequency Functions

zesDeviceEnumFrequencyDomains

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumFrequencyDomains(zes_device_handle_t hDevice, uint32_t *pCount, zes_freq_handle_t *phFrequency)

Get handle of frequency domains.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phFrequency: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyGetProperties(zes_freq_handle_t hFrequency, zes_freq_properties_t *pProperties)

Get frequency properties - available frequencies.

Parameters

  • hFrequency: [in] Handle for the component.

  • pProperties: [in,out] The frequency properties for the specified domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyGetAvailableClocks

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyGetAvailableClocks(zes_freq_handle_t hFrequency, uint32_t *pCount, double *phFrequency)

Get available non-overclocked hardware clock frequencies for the frequency domain.

Parameters

  • hFrequency: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of frequencies. if count is zero, then the driver shall update the value with the total number of frequencies that are available. if count is greater than the number of frequencies that are available, then the driver shall update the value with the correct number of frequencies.

  • phFrequency: [in,out][optional][range(0, *pCount)] array of frequencies in units of MHz and sorted from slowest to fastest. if count is less than the number of frequencies that are available, then the driver shall only retrieve that number of frequencies.

  • The list of available frequencies is returned in order of slowest to fastest.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyGetRange

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyGetRange(zes_freq_handle_t hFrequency, zes_freq_range_t *pLimits)

Get current frequency limits.

Parameters

  • hFrequency: [in] Handle for the component.

  • pLimits: [in,out] The range between which the hardware can operate for the specified domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencySetRange

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencySetRange(zes_freq_handle_t hFrequency, const zes_freq_range_t *pLimits)

Set frequency range between which the hardware can operate.

Parameters

  • hFrequency: [in] Handle for the component.

  • pLimits: [in] The limits between which the hardware can operate for the specified domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyGetState(zes_freq_handle_t hFrequency, zes_freq_state_t *pState)

Get current frequency state - frequency request, actual frequency, TDP limits.

Parameters

  • hFrequency: [in] Handle for the component.

  • pState: [in,out] Frequency state for the specified domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyGetThrottleTime

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyGetThrottleTime(zes_freq_handle_t hFrequency, zes_freq_throttle_time_t *pThrottleTime)

Get frequency throttle time.

Parameters

  • hFrequency: [in] Handle for the component.

  • pThrottleTime: [in,out] Will contain a snapshot of the throttle time counters for the specified domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetCapabilities

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetCapabilities(zes_freq_handle_t hFrequency, zes_oc_capabilities_t *pOcCapabilities)

Get the overclocking capabilities.

Parameters

  • hFrequency: [in] Handle for the component.

  • pOcCapabilities: [in,out] Pointer to the capabilities structure zes_oc_capabilities_t.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetFrequencyTarget

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetFrequencyTarget(zes_freq_handle_t hFrequency, double *pCurrentOcFrequency)

Get the current overclocking frequency target, if extended moded is supported, will returned in 1 Mhz granularity.

Parameters

  • hFrequency: [in] Handle for the component.

  • pCurrentOcFrequency: [out] Overclocking Frequency in MHz, if extended moded is supported, will returned in 1 Mhz granularity, else, in multiples of 50 Mhz. This cannot be greater than zes_oc_capabilities_t.maxOcFrequency.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcSetFrequencyTarget

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcSetFrequencyTarget(zes_freq_handle_t hFrequency, double CurrentOcFrequency)

Set the current overclocking frequency target, if extended moded is supported, can be set in 1 Mhz granularity.

Parameters

  • hFrequency: [in] Handle for the component.

  • CurrentOcFrequency: [in] Overclocking Frequency in MHz, if extended moded is supported, it could be set in 1 Mhz granularity, else, in multiples of 50 Mhz. This cannot be greater than zes_oc_capabilities_t.maxOcFrequency.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetVoltageTarget

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetVoltageTarget(zes_freq_handle_t hFrequency, double *pCurrentVoltageTarget, double *pCurrentVoltageOffset)

Get the current overclocking voltage settings.

Parameters

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcSetVoltageTarget

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcSetVoltageTarget(zes_freq_handle_t hFrequency, double CurrentVoltageTarget, double CurrentVoltageOffset)

Set the current overclocking voltage settings.

Parameters

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcSetMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcSetMode(zes_freq_handle_t hFrequency, zes_oc_mode_t CurrentOcMode)

Set the current overclocking mode.

Parameters

  • hFrequency: [in] Handle for the component.

  • CurrentOcMode: [in] Current Overclocking Mode zes_oc_mode_t.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetMode(zes_freq_handle_t hFrequency, zes_oc_mode_t *pCurrentOcMode)

Get the current overclocking mode.

Parameters

  • hFrequency: [in] Handle for the component.

  • pCurrentOcMode: [out] Current Overclocking Mode zes_oc_mode_t.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetIccMax

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetIccMax(zes_freq_handle_t hFrequency, double *pOcIccMax)

Get the maximum current limit setting.

Parameters

  • hFrequency: [in] Handle for the component.

  • pOcIccMax: [in,out] Will contain the maximum current limit in Amperes on successful return.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcSetIccMax

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcSetIccMax(zes_freq_handle_t hFrequency, double ocIccMax)

Change the maximum current limit setting.

Parameters

  • hFrequency: [in] Handle for the component.

  • ocIccMax: [in] The new maximum current limit in Amperes.

  • Setting ocIccMax to 0.0 will return the value to the factory default.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcGetTjMax

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcGetTjMax(zes_freq_handle_t hFrequency, double *pOcTjMax)

Get the maximum temperature limit setting.

Parameters

  • hFrequency: [in] Handle for the component.

  • pOcTjMax: [in,out] Will contain the maximum temperature limit in degrees Celsius on successful return.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesFrequencyOcSetTjMax

ZE_APIEXPORT ze_result_t ZE_APICALL zesFrequencyOcSetTjMax(zes_freq_handle_t hFrequency, double ocTjMax)

Change the maximum temperature limit setting.

Parameters

  • hFrequency: [in] Handle for the component.

  • ocTjMax: [in] The new maximum temperature limit in degrees Celsius.

  • Setting ocTjMax to 0.0 will return the value to the factory default.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Frequency Enums

zes_freq_domain_t

enum zes_freq_domain_t

Frequency domains.

Values:

ZES_FREQ_DOMAIN_GPU = 0

GPU Core Domain.

ZES_FREQ_DOMAIN_MEMORY = 1

Local Memory Domain.

ZES_FREQ_DOMAIN_FORCE_UINT32 = 0x7fffffff

zes_freq_throttle_reason_flags_t

enum zes_freq_throttle_reason_flag_t

Values:

ZES_FREQ_THROTTLE_REASON_FLAG_AVE_PWR_CAP = ZE_BIT(0)

frequency throttled due to average power excursion (PL1)

ZES_FREQ_THROTTLE_REASON_FLAG_BURST_PWR_CAP = ZE_BIT(1)

frequency throttled due to burst power excursion (PL2)

ZES_FREQ_THROTTLE_REASON_FLAG_CURRENT_LIMIT = ZE_BIT(2)

frequency throttled due to current excursion (PL4)

ZES_FREQ_THROTTLE_REASON_FLAG_THERMAL_LIMIT = ZE_BIT(3)

frequency throttled due to thermal excursion (T > TjMax)

ZES_FREQ_THROTTLE_REASON_FLAG_PSU_ALERT = ZE_BIT(4)

frequency throttled due to power supply assertion

ZES_FREQ_THROTTLE_REASON_FLAG_SW_RANGE = ZE_BIT(5)

frequency throttled due to software supplied frequency range

ZES_FREQ_THROTTLE_REASON_FLAG_HW_RANGE = ZE_BIT(6)

range when it receives clocks

frequency throttled due to a sub block that has a lower frequency

ZES_FREQ_THROTTLE_REASON_FLAG_FORCE_UINT32 = 0x7fffffff

zes_oc_mode_t

enum zes_oc_mode_t

Overclocking modes.

Values:

ZES_OC_MODE_OFF = 0

Overclocking if off - hardware is running using factory default voltages/frequencies.

ZES_OC_MODE_OVERRIDE = 1

Overclock override mode - In this mode, a fixed user-supplied voltage is applied independent of the frequency request. The maximum permitted frequency can also be increased. This mode disables INTERPOLATIVE and FIXED modes.

ZES_OC_MODE_INTERPOLATIVE = 2

Overclock interpolative mode - In this mode, the voltage/frequency curve can be extended with a new voltage/frequency point that will be interpolated. The existing voltage/frequency points can also be offset (up or down) by a fixed voltage. This mode disables FIXED and OVERRIDE modes.

ZES_OC_MODE_FIXED = 3

Overclocking fixed Mode - In this mode, hardware will disable most frequency throttling and lock the frequency and voltage at the specified overclock values. This mode disables OVERRIDE and INTERPOLATIVE modes. This mode can damage the part, most of the protections are disabled on this mode.

ZES_OC_MODE_FORCE_UINT32 = 0x7fffffff

Frequency Structures

zes_freq_properties_t

struct zes_freq_properties_t

Frequency properties.

  • Indicates if this frequency domain can be overclocked (if true, functions such as zesFrequencyOcSetFrequencyTarget() are supported).

  • The min/max hardware frequencies are specified for non-overclock configurations. For overclock configurations, use zesFrequencyOcGetFrequencyTarget() to determine the maximum frequency that can be requested.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_freq_domain_t type

[out] The hardware block that this frequency domain controls (GPU, memory, …)

ze_bool_t onSubdevice

[out] True if this resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Indicates if software can control the frequency of this domain assuming the user has permissions

ze_bool_t isThrottleEventSupported

[out] Indicates if software can register to receive event ZES_EVENT_TYPE_FLAG_FREQ_THROTTLED

double min

[out] The minimum hardware clock frequency in units of MHz.

double max

[out] The maximum non-overclock hardware clock frequency in units of MHz.

zes_freq_range_t

struct zes_freq_range_t

Frequency range between which the hardware can operate. The limits can be above or below the hardware limits - the hardware will clamp appropriately.

Public Members

double min

[in,out] The min frequency in MHz below which hardware frequency management will not request frequencies. On input, setting to 0 will permit the frequency to go down to the hardware minimum. On output, a negative value indicates that no external minimum frequency limit is in effect.

double max

[in,out] The max frequency in MHz above which hardware frequency management will not request frequencies. On input, setting to 0 or a very big number will permit the frequency to go all the way up to the hardware maximum. On output, a negative number indicates that no external maximum frequency limit is in effect.

zes_freq_state_t

struct zes_freq_state_t

Frequency state.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

double currentVoltage

[out] Current voltage in Volts. A negative value indicates that this property is not known.

double request

[out] The current frequency request in MHz. A negative value indicates that this property is not known.

double tdp

[out] The maximum frequency in MHz supported under the current TDP conditions. This fluctuates dynamically based on the power and thermal limits of the part. A negative value indicates that this property is not known.

double efficient

[out] The efficient minimum frequency in MHz. A negative value indicates that this property is not known.

double actual

[out] The resolved frequency in MHz. A negative value indicates that this property is not known.

zes_freq_throttle_reason_flags_t throttleReasons

Returns 0 (frequency not throttled) or a combination of zes_freq_throttle_reason_flag_t.

[out] The reasons that the frequency is being limited by the hardware.

zes_freq_throttle_time_t

struct zes_freq_throttle_time_t

Frequency throttle time snapshot.

  • Percent time throttled is calculated by taking two snapshots (s1, s2) and using the equation: throttled = (s2.throttleTime - s1.throttleTime) / (s2.timestamp - s1.timestamp)

Public Members

uint64_t throttleTime

[out] The monotonic counter of time in microseconds that the frequency has been limited by the hardware.

uint64_t timestamp

[out] Microsecond timestamp when throttleTime was captured. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

zes_oc_capabilities_t

struct zes_oc_capabilities_t

Overclocking properties.

  • Provides all the overclocking capabilities and properties supported by the device for the frequency domain.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

ze_bool_t isOcSupported

[out] Indicates if any overclocking features are supported on this frequency domain.

double maxFactoryDefaultFrequency

[out] Factory default non-overclock maximum frequency in Mhz.

double maxFactoryDefaultVoltage

[out] Factory default voltage used for the non-overclock maximum frequency in MHz.

double maxOcFrequency

[out] Maximum hardware overclocking frequency limit in Mhz.

double minOcVoltageOffset

[out] The minimum voltage offset that can be applied to the voltage/frequency curve. Note that this number can be negative.

double maxOcVoltageOffset

[out] The maximum voltage offset that can be applied to the voltage/frequency curve.

double maxOcVoltage

[out] The maximum overclock voltage that hardware supports.

ze_bool_t isTjMaxSupported

[out] Indicates if the maximum temperature limit (TjMax) can be changed for this frequency domain.

ze_bool_t isIccMaxSupported

[out] Indicates if the maximum current (IccMax) can be changed for this frequency domain.

ze_bool_t isHighVoltModeCapable

[out] Indicates if this frequency domains supports a feature to set very high voltages.

ze_bool_t isHighVoltModeEnabled

[out] Indicates if very high voltages are permitted on this frequency domain.

ze_bool_t isExtendedModeSupported

[out] Indicates if the extended overclocking features are supported. If this is supported, increments are on 1 Mhz basis.

ze_bool_t isFixedModeSupported

[out] Indicates if the fixed mode is supported. In this mode, hardware will disable most frequency throttling and lock the frequency and voltage at the specified overclock values.

Led

Led Functions

zesDeviceEnumLeds

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumLeds(zes_device_handle_t hDevice, uint32_t *pCount, zes_led_handle_t *phLed)

Get handle of LEDs.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phLed: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesLedGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesLedGetProperties(zes_led_handle_t hLed, zes_led_properties_t *pProperties)

Get LED properties.

Parameters

  • hLed: [in] Handle for the component.

  • pProperties: [in,out] Will contain the properties of the LED.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesLedGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesLedGetState(zes_led_handle_t hLed, zes_led_state_t *pState)

Get current state of a LED - on/off, color.

Parameters

  • hLed: [in] Handle for the component.

  • pState: [in,out] Will contain the current state of the LED.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesLedSetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesLedSetState(zes_led_handle_t hLed, ze_bool_t enable)

Turn the LED on/off.

Parameters

  • hLed: [in] Handle for the component.

  • enable: [in] Set to TRUE to turn the LED on, FALSE to turn off.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesLedSetColor

ZE_APIEXPORT ze_result_t ZE_APICALL zesLedSetColor(zes_led_handle_t hLed, const zes_led_color_t *pColor)

Set the color of the LED.

Parameters

  • hLed: [in] Handle for the component.

  • pColor: [in] New color of the LED.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Led Structures

zes_led_properties_t

struct zes_led_properties_t

LED properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Indicates if software can control the LED assuming the user has permissions

ze_bool_t haveRGB

[out] Indicates if the LED is RGB capable

zes_led_color_t

struct zes_led_color_t

LED color.

Public Members

double red

[in,out][range(0.0, 1.0)] The LED red value. On output, a value less than 0.0 indicates that the color is not known.

double green

[in,out][range(0.0, 1.0)] The LED green value. On output, a value less than 0.0 indicates that the color is not known.

double blue

[in,out][range(0.0, 1.0)] The LED blue value. On output, a value less than 0.0 indicates that the color is not known.

zes_led_state_t

struct zes_led_state_t

LED state.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

ze_bool_t isOn

[out] Indicates if the LED is on or off

zes_led_color_t color

[out] Color of the LED

Memory

Memory Functions

zesDeviceEnumMemoryModules

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumMemoryModules(zes_device_handle_t hDevice, uint32_t *pCount, zes_mem_handle_t *phMemory)

Get handle of memory modules.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phMemory: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesMemoryGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesMemoryGetProperties(zes_mem_handle_t hMemory, zes_mem_properties_t *pProperties)

Get memory properties.

Parameters

  • hMemory: [in] Handle for the component.

  • pProperties: [in,out] Will contain memory properties.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesMemoryGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesMemoryGetState(zes_mem_handle_t hMemory, zes_mem_state_t *pState)

Get memory state - health, allocated.

Parameters

  • hMemory: [in] Handle for the component.

  • pState: [in,out] Will contain the current health and allocated memory.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesMemoryGetBandwidth

ZE_APIEXPORT ze_result_t ZE_APICALL zesMemoryGetBandwidth(zes_mem_handle_t hMemory, zes_mem_bandwidth_t *pBandwidth)

Get memory bandwidth.

Parameters

  • hMemory: [in] Handle for the component.

  • pBandwidth: [in,out] Will contain the current health, free memory, total memory size.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Memory Enums

zes_mem_type_t

enum zes_mem_type_t

Memory module types.

Values:

ZES_MEM_TYPE_HBM = 0

HBM memory.

ZES_MEM_TYPE_DDR = 1

DDR memory.

ZES_MEM_TYPE_DDR3 = 2

DDR3 memory.

ZES_MEM_TYPE_DDR4 = 3

DDR4 memory.

ZES_MEM_TYPE_DDR5 = 4

DDR5 memory.

ZES_MEM_TYPE_LPDDR = 5

LPDDR memory.

ZES_MEM_TYPE_LPDDR3 = 6

LPDDR3 memory.

ZES_MEM_TYPE_LPDDR4 = 7

LPDDR4 memory.

ZES_MEM_TYPE_LPDDR5 = 8

LPDDR5 memory.

ZES_MEM_TYPE_SRAM = 9

SRAM memory.

ZES_MEM_TYPE_L1 = 10

L1 cache.

ZES_MEM_TYPE_L3 = 11

L3 cache.

ZES_MEM_TYPE_GRF = 12

Execution unit register file.

ZES_MEM_TYPE_SLM = 13

Execution unit shared local memory.

ZES_MEM_TYPE_FORCE_UINT32 = 0x7fffffff

zes_mem_loc_t

enum zes_mem_loc_t

Memory module location.

Values:

ZES_MEM_LOC_SYSTEM = 0

System memory.

ZES_MEM_LOC_DEVICE = 1

On board local device memory.

ZES_MEM_LOC_FORCE_UINT32 = 0x7fffffff

zes_mem_health_t

enum zes_mem_health_t

Memory health.

Values:

ZES_MEM_HEALTH_UNKNOWN = 0

The memory health cannot be determined.

ZES_MEM_HEALTH_OK = 1

All memory channels are healthy.

ZES_MEM_HEALTH_DEGRADED = 2

Excessive correctable errors have been detected on one or more channels. Device should be reset.

ZES_MEM_HEALTH_CRITICAL = 3

Operating with reduced memory to cover banks with too many uncorrectable errors.

ZES_MEM_HEALTH_REPLACE = 4

Device should be replaced due to excessive uncorrectable errors.

ZES_MEM_HEALTH_FORCE_UINT32 = 0x7fffffff

Memory Structures

zes_mem_properties_t

struct zes_mem_properties_t

Memory properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_mem_type_t type

[out] The memory type

ze_bool_t onSubdevice

[out] True if this resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

zes_mem_loc_t location

[out] Location of this memory (system, device)

uint64_t physicalSize

[out] Physical memory size in bytes. A value of 0 indicates that this property is not known. However, a call to zesMemoryGetState() will correctly return the total size of usable memory.

int32_t busWidth

[out] Width of the memory bus. A value of -1 means that this property is unknown.

int32_t numChannels

[out] The number of memory channels. A value of -1 means that this property is unknown.

zes_mem_state_t

struct zes_mem_state_t

Memory state - health, allocated.

  • Percent allocation is given by 100 * (size - free / size.

  • Percent free is given by 100 * free / size.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_mem_health_t health

[out] Indicates the health of the memory

uint64_t free

[out] The free memory in bytes

uint64_t size

[out] The total allocatable memory in bytes (can be less than zes_mem_properties_t.physicalSize)

zes_mem_bandwidth_t

struct zes_mem_bandwidth_t

Memory bandwidth.

  • Percent bandwidth is calculated by taking two snapshots (s1, s2) and using the equation: bw = 10^6 * ((s2.readCounter - s1.readCounter) + (s2.writeCounter - s1.writeCounter)) / (s2.maxBandwidth * (s2.timestamp - s1.timestamp))

Public Members

uint64_t readCounter

[out] Total bytes read from memory

uint64_t writeCounter

[out] Total bytes written to memory

uint64_t maxBandwidth

[out] Current maximum bandwidth in units of bytes/sec

uint64_t timestamp

[out] The timestamp when these measurements were sampled. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

Performance

Performance Functions

zesDeviceEnumPerformanceFactorDomains

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumPerformanceFactorDomains(zes_device_handle_t hDevice, uint32_t *pCount, zes_perf_handle_t *phPerf)

Get handles to accelerator domains whose performance can be optimized via a Performance Factor.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phPerf: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • A Performance Factor should be tuned for each workload.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPerformanceFactorGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesPerformanceFactorGetProperties(zes_perf_handle_t hPerf, zes_perf_properties_t *pProperties)

Get properties about a Performance Factor domain.

Parameters

  • hPerf: [in] Handle for the Performance Factor domain.

  • pProperties: [in,out] Will contain information about the specified Performance Factor domain.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPerformanceFactorGetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesPerformanceFactorGetConfig(zes_perf_handle_t hPerf, double *pFactor)

Get current Performance Factor for a given domain.

Parameters

  • hPerf: [in] Handle for the Performance Factor domain.

  • pFactor: [in,out] Will contain the actual Performance Factor being used by the hardware (may not be the same as the requested Performance Factor).

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPerformanceFactorSetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesPerformanceFactorSetConfig(zes_perf_handle_t hPerf, double factor)

Change the performance factor for a domain.

Parameters

  • hPerf: [in] Handle for the Performance Factor domain.

  • factor: [in] The new Performance Factor.

  • The Performance Factor is a number between 0 and 100.

  • A Performance Factor is a hint to the hardware. Depending on the hardware, the request may not be granted. Follow up this function with a call to zesPerformanceFactorGetConfig() to determine the actual factor being used by the hardware.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Performance Structures

zes_perf_properties_t

struct zes_perf_properties_t

Static information about a Performance Factor domain.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if this Performance Factor affects accelerators located on a sub-device

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

zes_engine_type_flags_t engines

[out] Bitfield of accelerator engine types that are affected by this Performance Factor.

Power

Power Functions

zesDeviceEnumPowerDomains

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumPowerDomains(zes_device_handle_t hDevice, uint32_t *pCount, zes_pwr_handle_t *phPower)

Get handle of power domains.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phPower: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerGetProperties(zes_pwr_handle_t hPower, zes_power_properties_t *pProperties)

Get properties related to a power domain.

Parameters

  • hPower: [in] Handle for the component.

  • pProperties: [in,out] Structure that will contain property data.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerGetEnergyCounter

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerGetEnergyCounter(zes_pwr_handle_t hPower, zes_power_energy_counter_t *pEnergy)

Get energy counter.

Parameters

  • hPower: [in] Handle for the component.

  • pEnergy: [in,out] Will contain the latest snapshot of the energy counter and timestamp when the last counter value was measured.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerGetLimits

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerGetLimits(zes_pwr_handle_t hPower, zes_power_sustained_limit_t *pSustained, zes_power_burst_limit_t *pBurst, zes_power_peak_limit_t *pPeak)

Get power limits.

Parameters

  • hPower: [in] Handle for the component.

  • pSustained: [in,out][optional] The sustained power limit. If this is null, the current sustained power limits will not be returned.

  • pBurst: [in,out][optional] The burst power limit. If this is null, the current peak power limits will not be returned.

  • pPeak: [in,out][optional] The peak power limit. If this is null, the peak power limits will not be returned.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerSetLimits

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerSetLimits(zes_pwr_handle_t hPower, const zes_power_sustained_limit_t *pSustained, const zes_power_burst_limit_t *pBurst, const zes_power_peak_limit_t *pPeak)

Set power limits.

Parameters

  • hPower: [in] Handle for the component.

  • pSustained: [in][optional] The sustained power limit. If this is null, no changes will be made to the sustained power limits.

  • pBurst: [in][optional] The burst power limit. If this is null, no changes will be made to the burst power limits.

  • pPeak: [in][optional] The peak power limit. If this is null, no changes will be made to the peak power limits.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerGetEnergyThreshold

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerGetEnergyThreshold(zes_pwr_handle_t hPower, zes_energy_threshold_t *pThreshold)

Get energy threshold.

Parameters

  • hPower: [in] Handle for the component.

  • pThreshold: [in,out] Returns information about the energy threshold setting - enabled/energy threshold/process ID.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPowerSetEnergyThreshold

ZE_APIEXPORT ze_result_t ZE_APICALL zesPowerSetEnergyThreshold(zes_pwr_handle_t hPower, double threshold)

Set energy threshold.

Parameters

  • hPower: [in] Handle for the component.

  • threshold: [in] The energy threshold to be set in joules.

  • An event ZES_EVENT_TYPE_FLAG_ENERGY_THRESHOLD_CROSSED will be generated when the delta energy consumed starting from this call exceeds the specified threshold. Use the function zesDeviceEventRegister() to start receiving the event.

  • Only one running process can control the energy threshold at a given time. If another process attempts to change the energy threshold, the error ZE_RESULT_ERROR_NOT_AVAILABLE will be returned. The function zesPowerGetEnergyThreshold() to determine the process ID currently controlling this setting.

  • Calling this function will remove any pending energy thresholds and start counting from the time of this call.

  • Once the energy threshold has been reached and the event generated, the threshold is automatically removed. It is up to the application to request a new threshold.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Power Structures

zes_power_properties_t

struct zes_power_properties_t

Properties related to device power settings.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if this resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Software can change the power limits of this domain assuming the user has permissions.

ze_bool_t isEnergyThresholdSupported

[out] Indicates if this power domain supports the energy threshold event (ZES_EVENT_TYPE_FLAG_ENERGY_THRESHOLD_CROSSED).

int32_t defaultLimit

[out] The factory default TDP power limit of the part in milliwatts. A value of -1 means that this is not known.

int32_t minLimit

[out] The minimum power limit in milliwatts that can be requested.

int32_t maxLimit

[out] The maximum power limit in milliwatts that can be requested.

zes_power_energy_counter_t

struct zes_power_energy_counter_t

Energy counter snapshot.

  • Average power is calculated by taking two snapshots (s1, s2) and using the equation: PowerWatts = (s2.energy - s1.energy) / (s2.timestamp - s1.timestamp)

Public Members

uint64_t energy

[out] The monotonic energy counter in microjoules.

uint64_t timestamp

[out] Microsecond timestamp when energy was captured. This timestamp should only be used to calculate delta time between snapshots of this structure. Never take the delta of this timestamp with the timestamp from a different structure since they are not guaranteed to have the same base. The absolute value of the timestamp is only valid during within the application and may be different on the next execution.

zes_power_sustained_limit_t

struct zes_power_sustained_limit_t

Sustained power limits.

  • The power controller (Punit) will throttle the operating frequency if the power averaged over a window (typically seconds) exceeds this limit.

Public Members

ze_bool_t enabled

[in,out] indicates if the limit is enabled (true) or ignored (false)

int32_t power

[in,out] power limit in milliwatts

int32_t interval

[in,out] power averaging window (Tau) in milliseconds

zes_power_burst_limit_t

struct zes_power_burst_limit_t

Burst power limit.

  • The power controller (Punit) will throttle the operating frequency of the device if the power averaged over a few milliseconds exceeds a limit known as PL2. Typically PL2 > PL1 so that it permits the frequency to burst higher for short periods than would be otherwise permitted by PL1.

Public Members

ze_bool_t enabled

[in,out] indicates if the limit is enabled (true) or ignored (false)

int32_t power

[in,out] power limit in milliwatts

zes_power_peak_limit_t

struct zes_power_peak_limit_t

Peak power limit.

  • The power controller (Punit) will preemptively throttle the operating frequency of the device when the instantaneous power exceeds this limit. The limit is known as PL4. It expresses the maximum power that can be drawn from the power supply.

  • If this power limit is removed or set too high, the power supply will generate an interrupt when it detects an overcurrent condition and the power controller will throttle the device frequencies down to min. It is thus better to tune the PL4 value in order to avoid such excursions.

Public Members

int32_t powerAC

[in,out] power limit in milliwatts for the AC power source.

int32_t powerDC

[in,out] power limit in milliwatts for the DC power source. On input, this is ignored if the product does not have a battery. On output, this will be -1 if the product does not have a battery.

zes_energy_threshold_t

struct zes_energy_threshold_t

Energy threshold.

  • .

Public Members

ze_bool_t enable

[in,out] Indicates if the energy threshold is enabled.

double threshold

[in,out] The energy threshold in Joules. Will be 0.0 if no threshold has been set.

uint32_t processId

[in,out] The host process ID that set the energy threshold. Will be 0xFFFFFFFF if no threshold has been set.

Psu

Psu Functions

zesDeviceEnumPsus

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumPsus(zes_device_handle_t hDevice, uint32_t *pCount, zes_psu_handle_t *phPsu)

Get handle of power supplies.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phPsu: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPsuGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesPsuGetProperties(zes_psu_handle_t hPsu, zes_psu_properties_t *pProperties)

Get power supply properties.

Parameters

  • hPsu: [in] Handle for the component.

  • pProperties: [in,out] Will contain the properties of the power supply.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesPsuGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesPsuGetState(zes_psu_handle_t hPsu, zes_psu_state_t *pState)

Get current power supply state.

Parameters

  • hPsu: [in] Handle for the component.

  • pState: [in,out] Will contain the current state of the power supply.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Psu Enums

zes_psu_voltage_status_t

enum zes_psu_voltage_status_t

PSU voltage status.

Values:

ZES_PSU_VOLTAGE_STATUS_UNKNOWN = 0

The status of the power supply voltage controllers cannot be determined

ZES_PSU_VOLTAGE_STATUS_NORMAL = 1

No unusual voltages have been detected.

ZES_PSU_VOLTAGE_STATUS_OVER = 2

Over-voltage has occurred.

ZES_PSU_VOLTAGE_STATUS_UNDER = 3

Under-voltage has occurred.

ZES_PSU_VOLTAGE_STATUS_FORCE_UINT32 = 0x7fffffff

Psu Structures

zes_psu_properties_t

struct zes_psu_properties_t

Static properties of the power supply.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t haveFan

[out] True if the power supply has a fan

int32_t ampLimit

[out] The maximum electrical current in milliamperes that can be drawn. A value of -1 indicates that this property cannot be determined.

zes_psu_state_t

struct zes_psu_state_t

Dynamic state of the power supply.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

zes_psu_voltage_status_t voltStatus

[out] The current PSU voltage status

ze_bool_t fanFailed

[out] Indicates if the fan has failed

int32_t temperature

[out] Read the current heatsink temperature in degrees Celsius. A value of -1 indicates that this property cannot be determined.

int32_t current

[out] The amps being drawn in milliamperes. A value of -1 indicates that this property cannot be determined.

Ras

Ras Functions

zesDeviceEnumRasErrorSets

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumRasErrorSets(zes_device_handle_t hDevice, uint32_t *pCount, zes_ras_handle_t *phRas)

Get handle of all RAS error sets on a device.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phRas: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • A RAS error set is a collection of RAS error counters of a given type (correctable/uncorrectable) from hardware blocks contained within a sub-device or within the device.

  • A device without sub-devices will typically return two handles, one for correctable errors sets and one for uncorrectable error sets.

  • A device with sub-devices will return RAS error sets for each sub-device and possibly RAS error sets for hardware blocks outside the sub-devices.

  • If the function completes successfully but pCount is set to 0, RAS features are not available/enabled on this device.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesRasGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesRasGetProperties(zes_ras_handle_t hRas, zes_ras_properties_t *pProperties)

Get RAS properties of a given RAS error set - this enables discovery of the type of RAS error set (correctable/uncorrectable) and if located on a sub-device.

Parameters

  • hRas: [in] Handle for the component.

  • pProperties: [in,out] Structure describing RAS properties

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesRasGetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesRasGetConfig(zes_ras_handle_t hRas, zes_ras_config_t *pConfig)

Get RAS error thresholds that control when RAS events are generated.

Parameters

  • hRas: [in] Handle for the component.

  • pConfig: [in,out] Will be populed with the current RAS configuration - thresholds used to trigger events

  • The driver maintains counters for all RAS error sets and error categories. Events are generated when errors occur. The configuration enables setting thresholds to limit when events are sent.

  • When a particular RAS correctable error counter exceeds the configured threshold, the event ZES_EVENT_TYPE_FLAG_RAS_CORRECTABLE_ERRORS will be triggered.

  • When a particular RAS uncorrectable error counter exceeds the configured threshold, the event ZES_EVENT_TYPE_FLAG_RAS_UNCORRECTABLE_ERRORS will be triggered.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesRasSetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesRasSetConfig(zes_ras_handle_t hRas, const zes_ras_config_t *pConfig)

Set RAS error thresholds that control when RAS events are generated.

Parameters

  • hRas: [in] Handle for the component.

  • pConfig: [in] Change the RAS configuration - thresholds used to trigger events

  • The driver maintains counters for all RAS error sets and error categories. Events are generated when errors occur. The configuration enables setting thresholds to limit when events are sent.

  • When a particular RAS correctable error counter exceeds the specified threshold, the event ZES_EVENT_TYPE_FLAG_RAS_CORRECTABLE_ERRORS will be generated.

  • When a particular RAS uncorrectable error counter exceeds the specified threshold, the event ZES_EVENT_TYPE_FLAG_RAS_UNCORRECTABLE_ERRORS will be generated.

  • Call zesRasGetState() and set the clear flag to true to restart event generation once counters have exceeded thresholds.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesRasGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesRasGetState(zes_ras_handle_t hRas, ze_bool_t clear, zes_ras_state_t *pState)

Get the current value of RAS error counters for a particular error set.

Parameters

  • hRas: [in] Handle for the component.

  • clear: [in] Set to 1 to clear the counters of this type

  • pState: [in,out] Breakdown of where errors have occurred

  • Clearing errors will affect other threads/applications - the counter values will start from zero.

  • Clearing errors requires write permissions.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Ras Enums

zes_ras_error_type_t

enum zes_ras_error_type_t

RAS error type.

Values:

ZES_RAS_ERROR_TYPE_CORRECTABLE = 0

Errors were corrected by hardware.

ZES_RAS_ERROR_TYPE_UNCORRECTABLE = 1

Error were not corrected.

ZES_RAS_ERROR_TYPE_FORCE_UINT32 = 0x7fffffff

zes_ras_error_cat_t

enum zes_ras_error_cat_t

RAS error categories.

Values:

ZES_RAS_ERROR_CAT_RESET = 0

The number of accelerator engine resets attempted by the driver.

ZES_RAS_ERROR_CAT_PROGRAMMING_ERRORS = 1

The number of hardware exceptions generated by the way workloads have programmed the hardware

ZES_RAS_ERROR_CAT_DRIVER_ERRORS = 2

The number of low level driver communication errors have occurred.

ZES_RAS_ERROR_CAT_COMPUTE_ERRORS = 3

The number of errors that have occurred in the compute accelerator hardware

ZES_RAS_ERROR_CAT_NON_COMPUTE_ERRORS = 4

The number of errors that have occurred in the fixed-function accelerator hardware

ZES_RAS_ERROR_CAT_CACHE_ERRORS = 5

The number of errors that have occurred in caches (L1/L3/register file/shared local memory/sampler)

ZES_RAS_ERROR_CAT_DISPLAY_ERRORS = 6

The number of errors that have occurred in the display.

ZES_RAS_ERROR_CAT_FORCE_UINT32 = 0x7fffffff

Ras Structures

zes_ras_properties_t

struct zes_ras_properties_t

RAS properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_ras_error_type_t type

[out] The type of RAS error

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

zes_ras_state_t

struct zes_ras_state_t

RAS error details.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

uint64_t category[ZES_MAX_RAS_ERROR_CATEGORY_COUNT]

[in][out] Breakdown of error by category

zes_ras_config_t

struct zes_ras_config_t

RAS error configuration - thresholds used for triggering RAS events (ZES_EVENT_TYPE_FLAG_RAS_CORRECTABLE_ERRORS, ZES_EVENT_TYPE_FLAG_RAS_UNCORRECTABLE_ERRORS)

  • The driver maintains a total counter which is updated every time a hardware block covered by the corresponding RAS error set notifies that an error has occurred. When this total count goes above the totalThreshold specified below, a RAS event is triggered.

  • The driver also maintains a counter for each category of RAS error (see zes_ras_state_t for a breakdown). Each time a hardware block of that category notifies that an error has occurred, that corresponding category counter is updated. When it goes above the threshold specified in detailedThresholds, a RAS event is triggered.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

uint64_t totalThreshold

[in,out] If the total RAS errors exceeds this threshold, the event will be triggered. A value of 0ULL disables triggering the event based on the total counter.

zes_ras_state_t detailedThresholds

[in,out] If the RAS errors for each category exceed the threshold for that category, the event will be triggered. A value of 0ULL will disable an event being triggered for that category.

Scheduler

Scheduler Functions

zesDeviceEnumSchedulers

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumSchedulers(zes_device_handle_t hDevice, uint32_t *pCount, zes_sched_handle_t *phScheduler)

Returns handles to scheduler components.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phScheduler: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • Each scheduler component manages the distribution of work across one or more accelerator engines.

  • If an application wishes to change the scheduler behavior for all accelerator engines of a specific type (e.g. compute), it should select all the handles where the structure member zes_sched_properties_t.engines contains that type.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerGetProperties(zes_sched_handle_t hScheduler, zes_sched_properties_t *pProperties)

Get properties related to a scheduler component.

Parameters

  • hScheduler: [in] Handle for the component.

  • pProperties: [in,out] Structure that will contain property data.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerGetCurrentMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerGetCurrentMode(zes_sched_handle_t hScheduler, zes_sched_mode_t *pMode)

Get current scheduling mode in effect on a scheduler component.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • pMode: [in,out] Will contain the current scheduler mode.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerGetTimeoutModeProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerGetTimeoutModeProperties(zes_sched_handle_t hScheduler, ze_bool_t getDefaults, zes_sched_timeout_properties_t *pConfig)

Get scheduler config for mode ZES_SCHED_MODE_TIMEOUT.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • getDefaults: [in] If TRUE, the driver will return the system default properties for this mode, otherwise it will return the current properties.

  • pConfig: [in,out] Will contain the current parameters for this mode.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerGetTimesliceModeProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerGetTimesliceModeProperties(zes_sched_handle_t hScheduler, ze_bool_t getDefaults, zes_sched_timeslice_properties_t *pConfig)

Get scheduler config for mode ZES_SCHED_MODE_TIMESLICE.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • getDefaults: [in] If TRUE, the driver will return the system default properties for this mode, otherwise it will return the current properties.

  • pConfig: [in,out] Will contain the current parameters for this mode.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerSetTimeoutMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerSetTimeoutMode(zes_sched_handle_t hScheduler, zes_sched_timeout_properties_t *pProperties, ze_bool_t *pNeedReload)

Change scheduler mode to ZES_SCHED_MODE_TIMEOUT or update scheduler mode parameters if already running in this mode.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • pProperties: [in] The properties to use when configurating this mode.

  • pNeedReload: [in,out] Will be set to TRUE if a device driver reload is needed to apply the new scheduler mode.

  • This mode is optimized for multiple applications or contexts submitting work to the hardware. When higher priority work arrives, the scheduler attempts to pause the current executing work within some timeout interval, then submits the other work.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerSetTimesliceMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerSetTimesliceMode(zes_sched_handle_t hScheduler, zes_sched_timeslice_properties_t *pProperties, ze_bool_t *pNeedReload)

Change scheduler mode to ZES_SCHED_MODE_TIMESLICE or update scheduler mode parameters if already running in this mode.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • pProperties: [in] The properties to use when configurating this mode.

  • pNeedReload: [in,out] Will be set to TRUE if a device driver reload is needed to apply the new scheduler mode.

  • This mode is optimized to provide fair sharing of hardware execution time between multiple contexts submitting work to the hardware concurrently.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerSetExclusiveMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerSetExclusiveMode(zes_sched_handle_t hScheduler, ze_bool_t *pNeedReload)

Change scheduler mode to ZES_SCHED_MODE_EXCLUSIVE.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • pNeedReload: [in,out] Will be set to TRUE if a device driver reload is needed to apply the new scheduler mode.

  • This mode is optimized for single application/context use-cases. It permits a context to run indefinitely on the hardware without being preempted or terminated. All pending work for other contexts must wait until the running context completes with no further submitted work.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesSchedulerSetComputeUnitDebugMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesSchedulerSetComputeUnitDebugMode(zes_sched_handle_t hScheduler, ze_bool_t *pNeedReload)

Change scheduler mode to ZES_SCHED_MODE_COMPUTE_UNIT_DEBUG.

Parameters

  • hScheduler: [in] Sysman handle for the component.

  • pNeedReload: [in,out] Will be set to TRUE if a device driver reload is needed to apply the new scheduler mode.

  • This is a special mode that must ben enabled when debugging an application that uses this device e.g. using the Level0 Debug API.

  • It ensures that only one command queue can execute work on the hardware at a given time. Work is permitted to run as long as needed without enforcing any scheduler fairness policies.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Scheduler Enums

zes_sched_mode_t

enum zes_sched_mode_t

Scheduler mode.

Values:

ZES_SCHED_MODE_TIMEOUT = 0

Multiple applications or contexts are submitting work to the hardware. When higher priority work arrives, the scheduler attempts to pause the current executing work within some timeout interval, then submits the other work.

ZES_SCHED_MODE_TIMESLICE = 1

The scheduler attempts to fairly timeslice hardware execution time between multiple contexts submitting work to the hardware concurrently.

ZES_SCHED_MODE_EXCLUSIVE = 2

Any application or context can run indefinitely on the hardware without being preempted or terminated. All pending work for other contexts must wait until the running context completes with no further submitted work.

ZES_SCHED_MODE_COMPUTE_UNIT_DEBUG = 3

This is a special mode that must ben enabled when debugging an application that uses this device e.g. using the Level0 Debug API. It has the effect of disabling any timeouts on workload execution time and will change workload scheduling to ensure debug accuracy.

ZES_SCHED_MODE_FORCE_UINT32 = 0x7fffffff

Scheduler Structures

zes_sched_properties_t

struct zes_sched_properties_t

Properties related to scheduler component.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

ze_bool_t onSubdevice

[out] True if this resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

ze_bool_t canControl

[out] Software can change the scheduler component configuration assuming the user has permissions.

zes_engine_type_flags_t engines

[out] Bitfield of accelerator engine types that are managed by this scheduler component. Note that there can be more than one scheduler component for the same type of accelerator engine.

uint32_t supportedModes

[out] Bitfield of scheduler modes that can be configured for this scheduler component (bitfield of 1<<zes_sched_mode_t).

zes_sched_timeout_properties_t

struct zes_sched_timeout_properties_t

Configuration for timeout scheduler mode (ZES_SCHED_MODE_TIMEOUT)

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

uint64_t watchdogTimeout

[in,out] The maximum time in microseconds that the scheduler will wait for a batch of work submitted to a hardware engine to complete or to be preempted so as to run another context. If this time is exceeded, the hardware engine is reset and the context terminated. If set to ZES_SCHED_WATCHDOG_DISABLE, a running workload can run as long as it wants without being terminated, but preemption attempts to run other contexts are permitted but not enforced.

zes_sched_timeslice_properties_t

struct zes_sched_timeslice_properties_t

Configuration for timeslice scheduler mode (ZES_SCHED_MODE_TIMESLICE)

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

uint64_t interval

[in,out] The average interval in microseconds that a submission for a context will run on a hardware engine before being preempted out to run a pending submission for another context.

uint64_t yieldTimeout

[in,out] The maximum time in microseconds that the scheduler will wait to preempt a workload running on an engine before deciding to reset the hardware engine and terminating the associated context.

Standby

Standby Functions

zesDeviceEnumStandbyDomains

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumStandbyDomains(zes_device_handle_t hDevice, uint32_t *pCount, zes_standby_handle_t *phStandby)

Get handle of standby controls.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phStandby: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesStandbyGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesStandbyGetProperties(zes_standby_handle_t hStandby, zes_standby_properties_t *pProperties)

Get standby hardware component properties.

Parameters

  • hStandby: [in] Handle for the component.

  • pProperties: [in,out] Will contain the standby hardware properties.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesStandbyGetMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesStandbyGetMode(zes_standby_handle_t hStandby, zes_standby_promo_mode_t *pMode)

Get the current standby promotion mode.

Parameters

  • hStandby: [in] Handle for the component.

  • pMode: [in,out] Will contain the current standby mode.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesStandbySetMode

ZE_APIEXPORT ze_result_t ZE_APICALL zesStandbySetMode(zes_standby_handle_t hStandby, zes_standby_promo_mode_t mode)

Set standby promotion mode.

Parameters

  • hStandby: [in] Handle for the component.

  • mode: [in] New standby mode.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Standby Enums

zes_standby_type_t

enum zes_standby_type_t

Standby hardware components.

Values:

ZES_STANDBY_TYPE_GLOBAL = 0

Control the overall standby policy of the device/sub-device.

ZES_STANDBY_TYPE_FORCE_UINT32 = 0x7fffffff

zes_standby_promo_mode_t

enum zes_standby_promo_mode_t

Standby promotion modes.

Values:

ZES_STANDBY_PROMO_MODE_DEFAULT = 0

Best compromise between performance and energy savings.

ZES_STANDBY_PROMO_MODE_NEVER = 1

The device/component will never shutdown. This can improve performance but uses more energy.

ZES_STANDBY_PROMO_MODE_FORCE_UINT32 = 0x7fffffff

Standby Structures

zes_standby_properties_t

struct zes_standby_properties_t

Standby hardware component properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_standby_type_t type

[out] Which standby hardware component this controls

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

Temperature

Temperature Functions

zesDeviceEnumTemperatureSensors

ZE_APIEXPORT ze_result_t ZE_APICALL zesDeviceEnumTemperatureSensors(zes_device_handle_t hDevice, uint32_t *pCount, zes_temp_handle_t *phTemperature)

Get handle of temperature sensors.

Parameters

  • hDevice: [in] Sysman handle of the device.

  • pCount: [in,out] pointer to the number of components of this type. if count is zero, then the driver shall update the value with the total number of components of this type that are available. if count is greater than the number of components of this type that are available, then the driver shall update the value with the correct number of components.

  • phTemperature: [in,out][optional][range(0, *pCount)] array of handle of components of this type. if count is less than the number of components of this type that are available, then the driver shall only retrieve that number of component handles.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesTemperatureGetProperties

ZE_APIEXPORT ze_result_t ZE_APICALL zesTemperatureGetProperties(zes_temp_handle_t hTemperature, zes_temp_properties_t *pProperties)

Get temperature sensor properties.

Parameters

  • hTemperature: [in] Handle for the component.

  • pProperties: [in,out] Will contain the temperature sensor properties.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesTemperatureGetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesTemperatureGetConfig(zes_temp_handle_t hTemperature, zes_temp_config_t *pConfig)

Get temperature configuration for this sensor - which events are triggered and the trigger conditions.

Parameters

  • hTemperature: [in] Handle for the component.

  • pConfig: [in,out] Returns current configuration.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

zesTemperatureSetConfig

ZE_APIEXPORT ze_result_t ZE_APICALL zesTemperatureSetConfig(zes_temp_handle_t hTemperature, const zes_temp_config_t *pConfig)

Set temperature configuration for this sensor - indicates which events are triggered and the trigger conditions.

Parameters

  • hTemperature: [in] Handle for the component.

  • pConfig: [in] New configuration.

Return

zesTemperatureGetState

ZE_APIEXPORT ze_result_t ZE_APICALL zesTemperatureGetState(zes_temp_handle_t hTemperature, double *pTemperature)

Get the temperature from a specified sensor.

Parameters

  • hTemperature: [in] Handle for the component.

  • pTemperature: [in,out] Will contain the temperature read from the specified sensor in degrees Celsius.

  • The application may call this function from simultaneous threads.

  • The implementation of this function should be lock-free.

Return

Temperature Enums

zes_temp_sensors_t

enum zes_temp_sensors_t

Temperature sensors.

Values:

ZES_TEMP_SENSORS_GLOBAL = 0

The maximum temperature across all device sensors.

ZES_TEMP_SENSORS_GPU = 1

The maximum temperature across all sensors in the GPU.

ZES_TEMP_SENSORS_MEMORY = 2

The maximum temperature across all sensors in the local memory.

ZES_TEMP_SENSORS_GLOBAL_MIN = 3

The minimum temperature across all device sensors.

ZES_TEMP_SENSORS_GPU_MIN = 4

The minimum temperature across all sensors in the GPU.

ZES_TEMP_SENSORS_MEMORY_MIN = 5

The minimum temperature across all sensors in the local device memory.

ZES_TEMP_SENSORS_FORCE_UINT32 = 0x7fffffff

Temperature Structures

zes_temp_properties_t

struct zes_temp_properties_t

Temperature sensor properties.

Public Members

zes_structure_type_t stype

[in] type of this structure

void *pNext

[in,out][optional] pointer to extension-specific structure

zes_temp_sensors_t type

[out] Which part of the device the temperature sensor measures

ze_bool_t onSubdevice

[out] True if the resource is located on a sub-device; false means that the resource is on the device of the calling Sysman handle

uint32_t subdeviceId

[out] If onSubdevice is true, this gives the ID of the sub-device

double maxTemperature

[out] Will contain the maximum temperature for the specific device in degrees Celsius.

ze_bool_t isCriticalTempSupported

[out] Indicates if the critical temperature event ZES_EVENT_TYPE_FLAG_TEMP_CRITICAL is supported

ze_bool_t isThreshold1Supported

[out] Indicates if the temperature threshold 1 event ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD1 is supported

ze_bool_t isThreshold2Supported

[out] Indicates if the temperature threshold 2 event ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD2 is supported

zes_temp_threshold_t

struct zes_temp_threshold_t

Temperature sensor threshold.

Public Members

ze_bool_t enableLowToHigh

[in,out] Trigger an event when the temperature crosses from below the threshold to above.

ze_bool_t enableHighToLow

[in,out] Trigger an event when the temperature crosses from above the threshold to below.

double threshold

[in,out] The threshold in degrees Celsius.

zes_temp_config_t

struct zes_temp_config_t

Temperature configuration - which events should be triggered and the trigger conditions.

Public Members

zes_structure_type_t stype

[in] type of this structure

const void *pNext

[in][optional] pointer to extension-specific structure

ze_bool_t enableCritical

[in,out] Indicates if event ZES_EVENT_TYPE_FLAG_TEMP_CRITICAL should be triggered by the driver.

zes_temp_threshold_t threshold1

[in,out] Configuration controlling if and when event ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD1 should be triggered by the driver.

zes_temp_threshold_t threshold2

[in,out] Configuration controlling if and when event ZES_EVENT_TYPE_FLAG_TEMP_THRESHOLD2 should be triggered by the driver.