Files
rocm-systems/rocclr/runtime/device/rocm/rocdevice.cpp
T
foreman 324486b2ec P4 to Git Change 1761023 by wchau@wchau_OCL_boltzmann on 2019/03/25 11:21:37
SWDEV-168145 - Add ECC target feature to OpenCL runtime
	- hard coded SRAM ECC target feature for now since ROCr disable sram-ecc reporting via ISA until HCC is fixed

Affected files ...

... //depot/stg/opencl/drivers/opencl/runtime/device/rocm/rocdevice.cpp#123 edit
2019-03-25 20:32:28 -04:00

1767 строки
54 KiB
C++

//
// Copyright (c) 2008 Advanced Micro Devices, Inc. All rights reserved.
//
#ifndef WITHOUT_HSA_BACKEND
#include "platform/program.hpp"
#include "platform/kernel.hpp"
#include "os/os.hpp"
#include "utils/debug.hpp"
#include "utils/flags.hpp"
#include "utils/options.hpp"
#include "utils/versions.hpp"
#include "thread/monitor.hpp"
#include "CL/cl_ext.h"
#include "amdocl/cl_common.hpp"
#include "device/rocm/rocdevice.hpp"
#include "device/rocm/rocblit.hpp"
#include "device/rocm/rocvirtual.hpp"
#include "device/rocm/rocprogram.hpp"
#if defined(WITH_LIGHTNING_COMPILER) && ! defined(USE_COMGR_LIBRARY)
#include "driver/AmdCompiler.h"
#endif // defined(WITH_LIGHTNING_COMPILER) && ! defined(USE_COMGR_LIBRARY)
#include "device/rocm/rocmemory.hpp"
#include "device/rocm/rocglinterop.hpp"
#ifdef WITH_AMDGPU_PRO
#include "pro/prodriver.hpp"
#endif
#include "platform/sampler.hpp"
#include <cstring>
#include <fstream>
#include <sstream>
#include <iostream>
#include <vector>
#include <algorithm>
#endif // WITHOUT_HSA_BACKEND
#define OPENCL_VERSION_STR XSTR(OPENCL_MAJOR) "." XSTR(OPENCL_MINOR)
#define OPENCL_C_VERSION_STR XSTR(OPENCL_C_MAJOR) "." XSTR(OPENCL_C_MINOR)
#ifndef WITHOUT_HSA_BACKEND
namespace device {
extern const char* BlitSourceCode;
}
namespace roc {
amd::Device::Compiler* NullDevice::compilerHandle_;
bool roc::Device::isHsaInitialized_ = false;
hsa_agent_t roc::Device::cpu_agent_ = {0};
std::vector<hsa_agent_t> roc::Device::gpu_agents_;
amd::Monitor* roc::Device::p2p_stage_ops_ = nullptr;
std::vector<Memory*> roc::Device::p2p_stages_;
const bool roc::Device::offlineDevice_ = false;
const bool roc::NullDevice::offlineDevice_ = true;
static HsaDeviceId getHsaDeviceId(hsa_agent_t device, uint32_t& pci_id) {
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(device, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_CHIP_ID, &pci_id)) {
return HSA_INVALID_DEVICE_ID;
}
char agent_name[64] = {0};
if (HSA_STATUS_SUCCESS != hsa_agent_get_info(device, HSA_AGENT_INFO_NAME, agent_name)) {
return HSA_INVALID_DEVICE_ID;
}
if (strncmp(agent_name, "gfx", 3) != 0) {
return HSA_INVALID_DEVICE_ID;
}
uint gfxipVersion = atoi(&agent_name[3]);
if (gfxipVersion < 900 && GPU_VEGA10_ONLY) {
return HSA_INVALID_DEVICE_ID;
}
switch (gfxipVersion) {
case 701:
return HSA_HAWAII_ID;
case 801:
return HSA_CARRIZO_ID;
case 802:
return HSA_TONGA_ID;
case 803:
return HSA_FIJI_ID;
case 900:
return HSA_VEGA10_ID;
case 901:
return HSA_VEGA10_HBCC_ID;
case 902:
return HSA_RAVEN_ID;
case 904:
return HSA_VEGA12_ID;
case 906:
return HSA_VEGA20_ID;
case 908:
return HSA_MI100_ID;
case 1000:
return HSA_ARIEL_ID;
case 1010:
return HSA_NAVI10_ID;
default:
return HSA_INVALID_DEVICE_ID;
}
}
bool NullDevice::create(const AMDDeviceInfo& deviceInfo) {
online_ = false;
deviceInfo_ = deviceInfo;
// Mark the device as GPU type
info_.type_ = CL_DEVICE_TYPE_GPU;
info_.vendorId_ = 0x1002;
settings_ = new Settings();
roc::Settings* hsaSettings = static_cast<roc::Settings*>(settings_);
if ((hsaSettings == nullptr) || !hsaSettings->create(false, deviceInfo_.gfxipVersion_)) {
LogError("Error creating settings for nullptr HSA device");
return false;
}
if (!ValidateComgr()) {
LogError("Code object manager initialization failed!");
return false;
}
// Report the device name
::strcpy(info_.name_, "AMD HSA Device");
info_.extensions_ = getExtensionString();
info_.maxWorkGroupSize_ = hsaSettings->maxWorkGroupSize_;
::strcpy(info_.vendor_, "Advanced Micro Devices, Inc.");
info_.oclcVersion_ = "OpenCL C " OPENCL_C_VERSION_STR " ";
info_.spirVersions_ = "";
strcpy(info_.driverVersion_, "1.0 Provisional (hsa)");
info_.version_ = "OpenCL " OPENCL_VERSION_STR " ";
return true;
}
Device::Device(hsa_agent_t bkendDevice)
: mapCacheOps_(nullptr)
, mapCache_(nullptr)
, _bkendDevice(bkendDevice)
, gpuvm_segment_max_alloc_(0)
, alloc_granularity_(0)
, context_(nullptr)
, xferQueue_(nullptr)
, xferRead_(nullptr)
, xferWrite_(nullptr)
, pro_device_(nullptr)
, pro_ena_(false)
, freeMem_(0)
, numOfVgpus_(0) {
group_segment_.handle = 0;
system_segment_.handle = 0;
system_coarse_segment_.handle = 0;
gpuvm_segment_.handle = 0;
}
Device::~Device() {
#ifdef WITH_AMDGPU_PRO
delete pro_device_;
#endif
// Release cached map targets
for (uint i = 0; mapCache_ != nullptr && i < mapCache_->size(); ++i) {
if ((*mapCache_)[i] != nullptr) {
(*mapCache_)[i]->release();
}
}
delete mapCache_;
delete mapCacheOps_;
delete p2p_stage_ops_;
p2p_stage_ops_ = nullptr;
for (auto buf: p2p_stages_) {
delete buf;
}
p2p_stages_.clear();
// Destroy temporary buffers for read/write
delete xferRead_;
delete xferWrite_;
// Destroy transfer queue
if (xferQueue_ && xferQueue_->terminate()) {
delete xferQueue_;
xferQueue_ = nullptr;
}
if (blitProgram_) {
delete blitProgram_;
blitProgram_ = nullptr;
}
if (context_ != nullptr) {
context_->release();
}
if (info_.extensions_) {
delete[] info_.extensions_;
info_.extensions_ = nullptr;
}
if (settings_) {
delete settings_;
settings_ = nullptr;
}
}
bool NullDevice::initCompiler(bool isOffline) {
#if defined(WITH_COMPILER_LIB)
// Initialize the compiler handle if has already not been initialized
// This is destroyed in Device::teardown
acl_error error;
if (!compilerHandle_) {
aclCompilerOptions opts = {
sizeof(aclCompilerOptions_0_8),
IF(IS_LIGHTNING, "libamdoclcl64.so", NULL),
NULL, NULL, NULL, NULL, NULL, NULL
};
compilerHandle_ = aclCompilerInit(&opts, &error);
if (!GPU_ENABLE_LC && error != ACL_SUCCESS) {
LogError("Error initializing the compiler handle");
return false;
}
}
#endif // defined(WITH_COMPILER_LIB)
return true;
}
bool NullDevice::destroyCompiler() {
#if defined(WITH_COMPILER_LIB)
if (compilerHandle_ != nullptr) {
acl_error error = aclCompilerFini(compilerHandle_);
if (error != ACL_SUCCESS) {
LogError("Error closing the compiler");
return false;
}
}
#endif // defined(WITH_COMPILER_LIB)
return true;
}
void NullDevice::tearDown() { destroyCompiler(); }
bool NullDevice::init() {
// Initialize the compiler
if (!initCompiler(offlineDevice_)) {
return false;
}
// Return without initializing offline device list
return true;
#if defined(WITH_COMPILER_LIB)
// If there is an HSA enabled device online then skip any offline device
std::vector<Device*> devices;
devices = getDevices(CL_DEVICE_TYPE_GPU, false);
// Load the offline devices
// Iterate through the set of available offline devices
for (uint id = 0; id < sizeof(DeviceInfo) / sizeof(AMDDeviceInfo); id++) {
bool isOnline = false;
// Check if the particular device is online
for (unsigned int i = 0; i < devices.size(); i++) {
if (static_cast<NullDevice*>(devices[i])->deviceInfo_.hsaDeviceId_ ==
DeviceInfo[id].hsaDeviceId_) {
isOnline = true;
}
}
if (isOnline) {
continue;
}
NullDevice* nullDevice = new NullDevice();
if (!nullDevice->create(DeviceInfo[id])) {
LogError("Error creating new instance of Device.");
delete nullDevice;
return false;
}
nullDevice->registerDevice();
}
#endif // defined(WITH_COMPILER_LIB)
return true;
}
NullDevice::~NullDevice() {
if (info_.extensions_) {
delete[] info_.extensions_;
info_.extensions_ = nullptr;
}
if (settings_) {
delete settings_;
settings_ = nullptr;
}
}
hsa_status_t Device::iterateAgentCallback(hsa_agent_t agent, void* data) {
hsa_device_type_t dev_type = HSA_DEVICE_TYPE_CPU;
hsa_status_t stat = hsa_agent_get_info(agent, HSA_AGENT_INFO_DEVICE, &dev_type);
if (stat != HSA_STATUS_SUCCESS) {
return stat;
}
if (dev_type == HSA_DEVICE_TYPE_CPU) {
Device::cpu_agent_ = agent;
} else if (dev_type == HSA_DEVICE_TYPE_GPU) {
gpu_agents_.push_back(agent);
}
return HSA_STATUS_SUCCESS;
}
hsa_ven_amd_loader_1_00_pfn_t Device::amd_loader_ext_table = {nullptr};
hsa_status_t Device::loaderQueryHostAddress(const void* device, const void** host) {
return amd_loader_ext_table.hsa_ven_amd_loader_query_host_address
? amd_loader_ext_table.hsa_ven_amd_loader_query_host_address(device, host)
: HSA_STATUS_ERROR;
}
Device::XferBuffers::~XferBuffers() {
// Destroy temporary buffer for reads
for (const auto& buf : freeBuffers_) {
delete buf;
}
freeBuffers_.clear();
}
bool Device::XferBuffers::create() {
Memory* xferBuf = nullptr;
bool result = false;
// Create a buffer object
xferBuf = new Buffer(dev(), bufSize_);
// Try to allocate memory for the transfer buffer
if ((nullptr == xferBuf) || !xferBuf->create()) {
delete xferBuf;
xferBuf = nullptr;
LogError("Couldn't allocate a transfer buffer!");
} else {
result = true;
freeBuffers_.push_back(xferBuf);
}
return result;
}
Memory& Device::XferBuffers::acquire() {
Memory* xferBuf = nullptr;
size_t listSize;
// Lock the operations with the staged buffer list
amd::ScopedLock l(lock_);
listSize = freeBuffers_.size();
// If the list is empty, then attempt to allocate a staged buffer
if (listSize == 0) {
// Allocate memory
xferBuf = new Buffer(dev(), bufSize_);
// Allocate memory for the transfer buffer
if ((nullptr == xferBuf) || !xferBuf->create()) {
delete xferBuf;
xferBuf = nullptr;
LogError("Couldn't allocate a transfer buffer!");
} else {
++acquiredCnt_;
}
}
if (xferBuf == nullptr) {
xferBuf = *(freeBuffers_.begin());
freeBuffers_.erase(freeBuffers_.begin());
++acquiredCnt_;
}
return *xferBuf;
}
void Device::XferBuffers::release(VirtualGPU& gpu, Memory& buffer) {
// Make sure buffer isn't busy on the current VirtualGPU, because
// the next aquire can come from different queue
// buffer.wait(gpu);
// Lock the operations with the staged buffer list
amd::ScopedLock l(lock_);
freeBuffers_.push_back(&buffer);
--acquiredCnt_;
}
bool Device::init() {
LogInfo("Initializing HSA stack.");
// Initialize the compiler
if (!initCompiler(offlineDevice_)) {
return false;
}
if (HSA_STATUS_SUCCESS != hsa_init()) {
LogError("hsa_init failed.");
return false;
}
hsa_system_get_major_extension_table(HSA_EXTENSION_AMD_LOADER, 1, sizeof(amd_loader_ext_table),
&amd_loader_ext_table);
if (HSA_STATUS_SUCCESS != hsa_iterate_agents(iterateAgentCallback, nullptr)) {
return false;
}
std::unordered_map<int, bool> selectedDevices;
bool useDeviceList = false;
std::string ordinals = amd::IS_HIP ? ((HIP_VISIBLE_DEVICES[0] != '\0') ?
HIP_VISIBLE_DEVICES : CUDA_VISIBLE_DEVICES)
: GPU_DEVICE_ORDINAL;
if (ordinals[0] != '\0') {
useDeviceList = true;
size_t end, pos = 0;
do {
bool deviceIdValid = true;
end = ordinals.find_first_of(',', pos);
int index = atoi(ordinals.substr(pos, end - pos).c_str());
if (index < 0 || static_cast<size_t>(index) >= gpu_agents_.size()) {
deviceIdValid = false;
}
if (!deviceIdValid) {
// Exit the loop as anything to the right of invalid deviceId
// has to be discarded
break;
}
selectedDevices[index] = deviceIdValid;
pos = end + 1;
} while (end != std::string::npos);
}
size_t ordinal = 0;
for (auto agent : gpu_agents_) {
std::unique_ptr<Device> roc_device(new Device(agent));
if (!roc_device) {
LogError("Error creating new instance of Device on then heap.");
return false;
}
uint32_t pci_id;
HsaDeviceId deviceId = getHsaDeviceId(agent, pci_id);
if (deviceId == HSA_INVALID_DEVICE_ID) {
LogPrintfError("Invalid HSA device %x", pci_id);
continue;
}
// Find device id in the table
uint id = HSA_INVALID_DEVICE_ID;
for (uint i = 0; i < sizeof(DeviceInfo) / sizeof(AMDDeviceInfo); ++i) {
if (DeviceInfo[i].hsaDeviceId_ == deviceId) {
id = i;
break;
}
}
// If the AmdDeviceInfo for the HsaDevice Id could not be found return false
if (id == HSA_INVALID_DEVICE_ID) {
LogPrintfWarning("Could not find a DeviceInfo entry for %d", deviceId);
continue;
}
roc_device->deviceInfo_ = DeviceInfo[id];
roc_device->deviceInfo_.pciDeviceId_ = pci_id;
// Query the agent's ISA name to fill deviceInfo.gfxipVersion_. We can't
// have a static mapping as some marketing names cover multiple gfxip.
hsa_isa_t isa = {0};
if (hsa_agent_get_info(agent, HSA_AGENT_INFO_ISA, &isa) != HSA_STATUS_SUCCESS) {
continue;
}
uint32_t isaNameLength = 0;
if (hsa_isa_get_info_alt(isa, HSA_ISA_INFO_NAME_LENGTH, &isaNameLength) != HSA_STATUS_SUCCESS) {
continue;
}
char* isaName = (char*)alloca((size_t)isaNameLength + 1);
if (hsa_isa_get_info_alt(isa, HSA_ISA_INFO_NAME, isaName) != HSA_STATUS_SUCCESS) {
continue;
}
isaName[isaNameLength] = '\0';
std::string str(isaName);
unsigned gfxipVersionNum = (unsigned)-1;
if (str.find("amdgcn-") == 0) {
// New way.
std::vector<std::string> tokens;
size_t end, pos = 0;
do {
end = str.find_first_of('-', pos);
tokens.push_back(str.substr(pos, end - pos));
pos = end + 1;
} while (end != std::string::npos);
if (tokens.size() != 5 && tokens.size() != 6) {
LogError("Not an amdgcn name");
continue;
}
if (tokens[4].find("gfx") != 0) {
LogError("Invalid ISA string");
continue;
}
std::string gfxipVersionStr = tokens[4].substr(tokens[4].find("gfx") + 3);
gfxipVersionNum = std::atoi(gfxipVersionStr.c_str());
} else {
// FIXME(kzhuravl): Old way. Remove.
std::vector<std::string> tokens;
size_t end, pos = 0;
do {
end = str.find_first_of(':', pos);
tokens.push_back(str.substr(pos, end - pos));
pos = end + 1;
} while (end != std::string::npos);
if (tokens.size() != 5 || tokens[0] != "AMD" || tokens[1] != "AMDGPU") {
LogError("Not an AMD:AMDGPU ISA name");
continue;
}
uint major = atoi(tokens[2].c_str());
uint minor = atoi(tokens[3].c_str());
uint stepping = atoi(tokens[4].c_str());
if (minor >= 10 && stepping >= 10) {
LogError("Invalid ISA string");
continue;
}
gfxipVersionNum = major * 100 + minor * 10 + stepping;
}
assert(gfxipVersionNum != (unsigned)-1);
roc_device->deviceInfo_.gfxipVersion_ = gfxipVersionNum;
// TODO: set sramEccEnabled flag based on target string suffix
// when ROCr resumes reporting sram-ecc support
bool sramEccEnabled = (gfxipVersionNum == 906 || gfxipVersionNum == 908) ? true : false;
if (!roc_device->create(sramEccEnabled)) {
LogError("Error creating new instance of Device.");
continue;
}
// Setup System Memory to be Non-Coherent per user
// request via environment variable. By default the
// System Memory is setup to be Coherent
if (roc_device->settings().enableNCMode_) {
hsa_status_t err = hsa_amd_coherency_set_type(agent, HSA_AMD_COHERENCY_TYPE_NONCOHERENT);
if (err != HSA_STATUS_SUCCESS) {
LogError("Unable to set NC memory policy!");
continue;
}
}
if (!useDeviceList && (flagIsDefault(GPU_DEVICE_NAME) || GPU_DEVICE_NAME == 0
|| GPU_DEVICE_NAME[0] == '\0' || !strcmp(GPU_DEVICE_NAME, roc_device->info_.name_))) {
roc_device.release()->registerDevice();
} else if (useDeviceList && selectedDevices[ordinal++]) {
roc_device.release()->registerDevice();
}
}
if (0 != Device::numDevices(CL_DEVICE_TYPE_GPU, false)) {
// Loop through all available devices
for (auto device1: Device::devices()) {
// Find all agents that can have access to the current device
for (auto agent: static_cast<Device*>(device1)->p2pAgents()) {
// Find cl_device_id associated with the current agent
for (auto device2: Device::devices()) {
if (agent.handle == static_cast<Device*>(device2)->getBackendDevice().handle) {
// Device2 can have access to device1
device2->p2pDevices_.push_back(as_cl(device1));
}
}
}
}
}
return true;
}
extern const char* SchedulerSourceCode;
void Device::tearDown() {
NullDevice::tearDown();
hsa_shut_down();
}
bool Device::create(bool sramEccEnabled) {
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_PROFILE, &agent_profile_)) {
return false;
}
// Create HSA settings
settings_ = new Settings();
roc::Settings* hsaSettings = static_cast<roc::Settings*>(settings_);
if ((hsaSettings == nullptr) ||
!hsaSettings->create((agent_profile_ == HSA_PROFILE_FULL), deviceInfo_.gfxipVersion_)) {
return false;
}
if (!ValidateComgr()) {
LogError("Code object manager initialization failed!");
return false;
}
if (!amd::Device::create()) {
return false;
}
uint32_t hsa_bdf_id = 0;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_BDFID, &hsa_bdf_id)) {
return false;
}
info_.deviceTopology_.pcie.type = CL_DEVICE_TOPOLOGY_TYPE_PCIE_AMD;
info_.deviceTopology_.pcie.bus = (hsa_bdf_id & (0xFF << 8)) >> 8;
info_.deviceTopology_.pcie.device = (hsa_bdf_id & (0x1F << 3)) >> 3;
info_.deviceTopology_.pcie.function = (hsa_bdf_id & 0x07);
info_.sramEccEnabled_ = sramEccEnabled;
#ifdef WITH_AMDGPU_PRO
// Create amdgpu-pro device interface for SSG support
pro_device_ = IProDevice::Init(
info_.deviceTopology_.pcie.bus,
info_.deviceTopology_.pcie.device,
info_.deviceTopology_.pcie.function);
if (pro_device_ != nullptr) {
pro_ena_ = true;
settings_->enableExtension(ClAMDLiquidFlash);
pro_device_->GetAsicIdAndRevisionId(&info_.pcieDeviceId_, &info_.pcieRevisionId_);
}
#endif
if (populateOCLDeviceConstants() == false) {
return false;
}
const char* scheduler = nullptr;
#if defined(WITH_LIGHTNING_COMPILER) || defined(USE_COMGR_LIBRARY)
std::string sch = SchedulerSourceCode;
if (settings().useLightning_) {
scheduler = sch.c_str();
}
#ifndef USE_COMGR_LIBRARY
// create compilation object with cache support
int gfxipMajor = deviceInfo_.gfxipVersion_ / 100;
int gfxipMinor = deviceInfo_.gfxipVersion_ / 10 % 10;
int gfxipStepping = deviceInfo_.gfxipVersion_ % 10;
// Use compute capability as target (AMD:AMDGPU:major:minor:stepping)
// with dash as delimiter to be compatible with Windows directory name
std::ostringstream cacheTarget;
cacheTarget << "AMD-AMDGPU-" << gfxipMajor << "-" << gfxipMinor << "-" << gfxipStepping;
if (settings().enableXNACK_) {
cacheTarget << "+xnack";
}
if (info_.sramEccEnabled_) {
cacheTarget << "+sram-ecc";
}
amd::CacheCompilation* compObj = new amd::CacheCompilation(
cacheTarget.str(), "_rocm", OCL_CODE_CACHE_ENABLE, OCL_CODE_CACHE_RESET);
if (!compObj) {
LogError("Unable to create cache compilation object!");
return false;
}
cacheCompilation_.reset(compObj);
#endif // USE_COMGR_LIBRARY
#endif
amd::Context::Info info = {0};
std::vector<amd::Device*> devices;
devices.push_back(this);
// Create a dummy context
context_ = new amd::Context(devices, info);
if (context_ == nullptr) {
return false;
}
blitProgram_ = new BlitProgram(context_);
// Create blit programs
if (blitProgram_ == nullptr || !blitProgram_->create(this, scheduler)) {
delete blitProgram_;
blitProgram_ = nullptr;
LogError("Couldn't create blit kernels!");
return false;
}
mapCacheOps_ = new amd::Monitor("Map Cache Lock", true);
if (nullptr == mapCacheOps_) {
return false;
}
mapCache_ = new std::vector<amd::Memory*>();
if (mapCache_ == nullptr) {
return false;
}
// Use just 1 entry by default for the map cache
mapCache_->push_back(nullptr);
if (p2p_stage_ops_ == nullptr) {
p2p_stage_ops_ = new amd::Monitor("P2P Staging Lock", true);
if (nullptr == p2p_stage_ops_) {
return false;
}
for (uint i = 0; i < 2; i++) {
Memory* buf = new Buffer(*this, kP2PStagingSize);
if ((buf != nullptr) && buf->create()) {
p2p_stages_.push_back(buf);
} else {
delete buf;
return false;
}
}
}
if (settings().stagedXferSize_ != 0) {
// Initialize staged write buffers
if (settings().stagedXferWrite_) {
xferWrite_ = new XferBuffers(*this, amd::alignUp(settings().stagedXferSize_, 4 * Ki));
if ((xferWrite_ == nullptr) || !xferWrite_->create()) {
LogError("Couldn't allocate transfer buffer objects for read");
return false;
}
}
// Initialize staged read buffers
if (settings().stagedXferRead_) {
xferRead_ = new XferBuffers(*this, amd::alignUp(settings().stagedXferSize_, 4 * Ki));
if ((xferRead_ == nullptr) || !xferRead_->create()) {
LogError("Couldn't allocate transfer buffer objects for write");
return false;
}
}
}
xferQueue();
return true;
}
device::Program* NullDevice::createProgram(amd::option::Options* options) {
device::Program* program;
if (settings().useLightning_) {
program = new LightningProgram(*this);
} else {
program = new HSAILProgram(*this);
}
if (program == nullptr) {
LogError("Memory allocation has failed!");
}
return program;
}
device::Program* Device::createProgram(amd::option::Options* options) {
device::Program* program;
if (settings().useLightning_) {
program = new LightningProgram(*this);
} else {
program = new HSAILProgram(*this);
}
if (program == nullptr) {
LogError("Memory allocation has failed!");
}
return program;
}
hsa_status_t Device::iterateGpuMemoryPoolCallback(hsa_amd_memory_pool_t pool, void* data) {
if (data == nullptr) {
return HSA_STATUS_ERROR_INVALID_ARGUMENT;
}
hsa_region_segment_t segment_type = (hsa_region_segment_t)0;
hsa_status_t stat =
hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_SEGMENT, &segment_type);
if (stat != HSA_STATUS_SUCCESS) {
return stat;
}
// TODO: system and device local segment
Device* dev = reinterpret_cast<Device*>(data);
switch (segment_type) {
case HSA_REGION_SEGMENT_GLOBAL: {
if (dev->settings().enableLocalMemory_) {
dev->gpuvm_segment_ = pool;
}
break;
}
case HSA_REGION_SEGMENT_GROUP:
dev->group_segment_ = pool;
break;
default:
break;
}
return HSA_STATUS_SUCCESS;
}
hsa_status_t Device::iterateCpuMemoryPoolCallback(hsa_amd_memory_pool_t pool, void* data) {
if (data == nullptr) {
return HSA_STATUS_ERROR_INVALID_ARGUMENT;
}
hsa_region_segment_t segment_type = (hsa_region_segment_t)0;
hsa_status_t stat =
hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_SEGMENT, &segment_type);
if (stat != HSA_STATUS_SUCCESS) {
return stat;
}
Device* dev = reinterpret_cast<Device*>(data);
switch (segment_type) {
case HSA_REGION_SEGMENT_GLOBAL: {
uint32_t global_flag = 0;
hsa_status_t stat =
hsa_amd_memory_pool_get_info(pool, HSA_AMD_MEMORY_POOL_INFO_GLOBAL_FLAGS, &global_flag);
if (stat != HSA_STATUS_SUCCESS) {
return stat;
}
if ((global_flag & HSA_REGION_GLOBAL_FLAG_FINE_GRAINED) != 0) {
dev->system_segment_ = pool;
} else {
dev->system_coarse_segment_ = pool;
}
break;
}
default:
break;
}
return HSA_STATUS_SUCCESS;
}
bool Device::createSampler(const amd::Sampler& owner, device::Sampler** sampler) const {
*sampler = nullptr;
Sampler* gpuSampler = new Sampler(*this);
if ((nullptr == gpuSampler) || !gpuSampler->create(owner)) {
delete gpuSampler;
return false;
}
*sampler = gpuSampler;
return true;
}
void Sampler::fillSampleDescriptor(hsa_ext_sampler_descriptor_t& samplerDescriptor,
const amd::Sampler& sampler) const {
samplerDescriptor.filter_mode = sampler.filterMode() == CL_FILTER_NEAREST
? HSA_EXT_SAMPLER_FILTER_MODE_NEAREST
: HSA_EXT_SAMPLER_FILTER_MODE_LINEAR;
samplerDescriptor.coordinate_mode = sampler.normalizedCoords()
? HSA_EXT_SAMPLER_COORDINATE_MODE_NORMALIZED
: HSA_EXT_SAMPLER_COORDINATE_MODE_UNNORMALIZED;
switch (sampler.addressingMode()) {
case CL_ADDRESS_CLAMP_TO_EDGE:
samplerDescriptor.address_mode = HSA_EXT_SAMPLER_ADDRESSING_MODE_CLAMP_TO_EDGE;
break;
case CL_ADDRESS_REPEAT:
samplerDescriptor.address_mode = HSA_EXT_SAMPLER_ADDRESSING_MODE_REPEAT;
break;
case CL_ADDRESS_CLAMP:
samplerDescriptor.address_mode = HSA_EXT_SAMPLER_ADDRESSING_MODE_CLAMP_TO_BORDER;
break;
case CL_ADDRESS_MIRRORED_REPEAT:
samplerDescriptor.address_mode = HSA_EXT_SAMPLER_ADDRESSING_MODE_MIRRORED_REPEAT;
break;
case CL_ADDRESS_NONE:
samplerDescriptor.address_mode = HSA_EXT_SAMPLER_ADDRESSING_MODE_UNDEFINED;
break;
default:
return;
}
}
bool Sampler::create(const amd::Sampler& owner) {
hsa_ext_sampler_descriptor_t samplerDescriptor;
fillSampleDescriptor(samplerDescriptor, owner);
hsa_status_t status = hsa_ext_sampler_create(dev_.getBackendDevice(), &samplerDescriptor, &hsa_sampler);
if (HSA_STATUS_SUCCESS != status) {
return false;
}
hwSrd_ = reinterpret_cast<uint64_t>(hsa_sampler.handle);
hwState_ = reinterpret_cast<address>(hsa_sampler.handle);
return true;
}
Sampler::~Sampler() {
hsa_ext_sampler_destroy(dev_.getBackendDevice(), hsa_sampler);
}
bool Device::populateOCLDeviceConstants() {
info_.available_ = true;
roc::Settings* hsa_settings = static_cast<roc::Settings*>(settings_);
int gfxipMajor = deviceInfo_.gfxipVersion_ / 100;
int gfxipMinor = deviceInfo_.gfxipVersion_ / 10 % 10;
int gfxipStepping = deviceInfo_.gfxipVersion_ % 10;
std::ostringstream oss;
oss << "gfx" << gfxipMajor << gfxipMinor << gfxipStepping;
if (settings().useLightning_ && hsa_settings->enableXNACK_) {
oss << "+xnack";
}
if (info_.sramEccEnabled_) {
oss << "+sram-ecc";
}
::strcpy(info_.name_, oss.str().c_str());
char device_name[64] = {0};
if (HSA_STATUS_SUCCESS == hsa_agent_get_info(_bkendDevice,
(hsa_agent_info_t)HSA_AMD_AGENT_INFO_PRODUCT_NAME,
device_name)) {
::strcpy(info_.boardName_, device_name);
}
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_COMPUTE_UNIT_COUNT,
&info_.maxComputeUnits_)) {
return false;
}
assert(info_.maxComputeUnits_ > 0);
if (HSA_STATUS_SUCCESS != hsa_agent_get_info(_bkendDevice,
(hsa_agent_info_t)HSA_AMD_AGENT_INFO_CACHELINE_SIZE,
&info_.globalMemCacheLineSize_)) {
return false;
}
assert(info_.globalMemCacheLineSize_ > 0);
uint32_t cachesize[4] = {0};
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_CACHE_SIZE, cachesize)) {
return false;
}
assert(cachesize[0] > 0);
info_.globalMemCacheSize_ = cachesize[0];
info_.globalMemCacheType_ = CL_READ_WRITE_CACHE;
info_.type_ = CL_DEVICE_TYPE_GPU;
info_.extensions_ = getExtensionString();
info_.nativeVectorWidthDouble_ = info_.preferredVectorWidthDouble_ =
(settings().doublePrecision_) ? 1 : 0;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_MAX_CLOCK_FREQUENCY,
&info_.maxEngineClockFrequency_)) {
return false;
}
//TODO: add the assert statement for Raven
if (deviceInfo_.gfxipVersion_ != 902) {
assert(info_.maxEngineClockFrequency_ > 0);
}
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_MEMORY_MAX_FREQUENCY,
&info_.maxMemoryClockFrequency_)) {
return false;
}
if (HSA_STATUS_SUCCESS !=
hsa_amd_agent_iterate_memory_pools(cpu_agent_, Device::iterateCpuMemoryPoolCallback, this)) {
return false;
}
assert(system_segment_.handle != 0);
if (HSA_STATUS_SUCCESS != hsa_amd_agent_iterate_memory_pools(
_bkendDevice, Device::iterateGpuMemoryPoolCallback, this)) {
return false;
}
assert(group_segment_.handle != 0);
for (auto agent: gpu_agents_) {
if (agent.handle != _bkendDevice.handle) {
hsa_status_t err;
// Can current GPU have access to another GPU memory pool
hsa_amd_memory_pool_access_t access;
err = hsa_amd_agent_memory_pool_get_info(agent, gpuvm_segment_, HSA_AMD_AGENT_MEMORY_POOL_INFO_ACCESS, &access);
if (err != HSA_STATUS_SUCCESS) {
continue;
}
// Find accessible p2p agents - i.e != HSA_AMD_MEMORY_POOL_ACCESS_NEVER_ALLOWED
if (HSA_AMD_MEMORY_POOL_ACCESS_ALLOWED_BY_DEFAULT == access ||
HSA_AMD_MEMORY_POOL_ACCESS_DISALLOWED_BY_DEFAULT == access) {
p2p_agents_.push_back(agent);
}
}
}
size_t group_segment_size = 0;
if (HSA_STATUS_SUCCESS != hsa_amd_memory_pool_get_info(group_segment_,
HSA_AMD_MEMORY_POOL_INFO_SIZE,
&group_segment_size)) {
return false;
}
assert(group_segment_size > 0);
info_.localMemSizePerCU_ = group_segment_size;
info_.localMemSize_ = group_segment_size;
info_.maxWorkItemDimensions_ = 3;
if (settings().enableLocalMemory_ && gpuvm_segment_.handle != 0) {
size_t global_segment_size = 0;
if (HSA_STATUS_SUCCESS != hsa_amd_memory_pool_get_info(gpuvm_segment_,
HSA_AMD_MEMORY_POOL_INFO_SIZE,
&global_segment_size)) {
return false;
}
assert(global_segment_size > 0);
info_.globalMemSize_ = static_cast<cl_ulong>(global_segment_size);
gpuvm_segment_max_alloc_ =
cl_ulong(info_.globalMemSize_ * std::min(GPU_SINGLE_ALLOC_PERCENT, 100u) / 100u);
assert(gpuvm_segment_max_alloc_ > 0);
info_.maxMemAllocSize_ = static_cast<cl_ulong>(gpuvm_segment_max_alloc_);
if (HSA_STATUS_SUCCESS !=
hsa_amd_memory_pool_get_info(gpuvm_segment_, HSA_AMD_MEMORY_POOL_INFO_RUNTIME_ALLOC_GRANULE,
&alloc_granularity_)) {
return false;
}
assert(alloc_granularity_ > 0);
} else {
// We suppose half of physical memory can be used by GPU in APU system
info_.globalMemSize_ =
cl_ulong(sysconf(_SC_PAGESIZE)) * cl_ulong(sysconf(_SC_PHYS_PAGES)) / 2;
info_.globalMemSize_ = std::max(info_.globalMemSize_, cl_ulong(1 * Gi));
info_.maxMemAllocSize_ =
cl_ulong(info_.globalMemSize_ * std::min(GPU_SINGLE_ALLOC_PERCENT, 100u) / 100u);
if (HSA_STATUS_SUCCESS !=
hsa_amd_memory_pool_get_info(
system_segment_, HSA_AMD_MEMORY_POOL_INFO_RUNTIME_ALLOC_GRANULE, &alloc_granularity_)) {
return false;
}
}
freeMem_ = info_.globalMemSize_;
// Make sure the max allocation size is not larger than the available
// memory size.
info_.maxMemAllocSize_ = std::min(info_.maxMemAllocSize_, info_.globalMemSize_);
/*make sure we don't run anything over 8 params for now*/
info_.maxParameterSize_ = 1024; // [TODO]: CAL stack values: 1024*
// constant
uint32_t max_work_group_size = 0;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_WORKGROUP_MAX_SIZE, &max_work_group_size)) {
return false;
}
assert(max_work_group_size > 0);
max_work_group_size =
std::min(max_work_group_size, static_cast<uint32_t>(settings().maxWorkGroupSize_));
info_.maxWorkGroupSize_ = max_work_group_size;
uint16_t max_workgroup_size[3] = {0, 0, 0};
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_WORKGROUP_MAX_DIM, &max_workgroup_size)) {
return false;
}
assert(max_workgroup_size[0] != 0 && max_workgroup_size[1] != 0 && max_workgroup_size[2] != 0);
uint16_t max_work_item_size = static_cast<uint16_t>(max_work_group_size);
info_.maxWorkItemSizes_[0] = std::min(max_workgroup_size[0], max_work_item_size);
info_.maxWorkItemSizes_[1] = std::min(max_workgroup_size[1], max_work_item_size);
info_.maxWorkItemSizes_[2] = std::min(max_workgroup_size[2], max_work_item_size);
info_.preferredWorkGroupSize_ = settings().preferredWorkGroupSize_;
info_.nativeVectorWidthChar_ = info_.preferredVectorWidthChar_ = 4;
info_.nativeVectorWidthShort_ = info_.preferredVectorWidthShort_ = 2;
info_.nativeVectorWidthInt_ = info_.preferredVectorWidthInt_ = 1;
info_.nativeVectorWidthLong_ = info_.preferredVectorWidthLong_ = 1;
info_.nativeVectorWidthFloat_ = info_.preferredVectorWidthFloat_ = 1;
if (agent_profile_ == HSA_PROFILE_FULL) { // full-profile = participating in coherent memory,
// base-profile = NUMA based non-coherent memory
info_.hostUnifiedMemory_ = CL_TRUE;
}
info_.memBaseAddrAlign_ =
8 * (flagIsDefault(MEMOBJ_BASE_ADDR_ALIGN) ? sizeof(cl_long16) : MEMOBJ_BASE_ADDR_ALIGN);
info_.minDataTypeAlignSize_ = sizeof(cl_long16);
info_.maxConstantArgs_ = 8;
info_.preferredConstantBufferSize_ = 16 * Ki;
info_.maxConstantBufferSize_ = info_.maxMemAllocSize_;
info_.localMemType_ = CL_LOCAL;
info_.errorCorrectionSupport_ = false;
info_.profilingTimerResolution_ = 1;
info_.littleEndian_ = true;
info_.compilerAvailable_ = true;
info_.executionCapabilities_ = CL_EXEC_KERNEL;
info_.queueProperties_ = CL_QUEUE_PROFILING_ENABLE;
info_.platform_ = AMD_PLATFORM;
info_.profile_ = "FULL_PROFILE";
strcpy(info_.vendor_, "Advanced Micro Devices, Inc.");
info_.addressBits_ = LP64_SWITCH(32, 64);
info_.maxSamplers_ = 16;
info_.bufferFromImageSupport_ = CL_FALSE;
info_.oclcVersion_ = "OpenCL C " OPENCL_C_VERSION_STR " ";
info_.spirVersions_ = "";
uint16_t major, minor;
if (hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_VERSION_MAJOR, &major) !=
HSA_STATUS_SUCCESS ||
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_VERSION_MINOR, &minor) !=
HSA_STATUS_SUCCESS) {
return false;
}
std::stringstream ss;
ss << AMD_BUILD_STRING " (HSA" << major << "." << minor << "," << (settings().useLightning_ ? "LC" : "HSAIL");
ss << ")";
strcpy(info_.driverVersion_, ss.str().c_str());
// Enable OpenCL 2.0 for Vega10+
if (deviceInfo_.gfxipVersion_ >= 900) {
info_.version_ = "OpenCL " /*OPENCL_VERSION_STR*/"2.0" " ";
} else {
info_.version_ = "OpenCL " /*OPENCL_VERSION_STR*/"1.2" " ";
}
info_.builtInKernels_ = "";
info_.linkerAvailable_ = true;
info_.preferredInteropUserSync_ = true;
info_.printfBufferSize_ = PrintfDbg::WorkitemDebugSize * info().maxWorkGroupSize_;
info_.vendorId_ = 0x1002; // AMD's PCIe vendor id
info_.maxGlobalVariableSize_ = static_cast<size_t>(info_.maxMemAllocSize_);
info_.globalVariablePreferredTotalSize_ = static_cast<size_t>(info_.globalMemSize_);
// Populate the single config setting.
info_.singleFPConfig_ =
CL_FP_ROUND_TO_NEAREST | CL_FP_ROUND_TO_ZERO | CL_FP_ROUND_TO_INF | CL_FP_INF_NAN | CL_FP_FMA;
if (hsa_settings->doublePrecision_) {
info_.doubleFPConfig_ = info_.singleFPConfig_ | CL_FP_DENORM;
info_.singleFPConfig_ |= CL_FP_CORRECTLY_ROUNDED_DIVIDE_SQRT;
}
if (hsa_settings->singleFpDenorm_) {
info_.singleFPConfig_ |= CL_FP_DENORM;
}
info_.preferredPlatformAtomicAlignment_ = 0;
info_.preferredGlobalAtomicAlignment_ = 0;
info_.preferredLocalAtomicAlignment_ = 0;
uint8_t hsa_extensions[128];
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_EXTENSIONS, hsa_extensions)) {
return false;
}
assert(HSA_EXTENSION_IMAGES < 8);
const bool image_is_supported = ((hsa_extensions[0] & (1 << HSA_EXTENSION_IMAGES)) != 0);
if (image_is_supported) {
// Images
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_MAX_SAMPLER_HANDLERS),
&info_.maxSamplers_)) {
return false;
}
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_MAX_IMAGE_RD_HANDLES),
&info_.maxReadImageArgs_)) {
return false;
}
// TODO: no attribute for write image.
info_.maxWriteImageArgs_ = 8;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_MAX_IMAGE_RORW_HANDLES),
&info_.maxReadWriteImageArgs_)) {
return false;
}
uint32_t image_max_dim[3];
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_IMAGE_2D_MAX_ELEMENTS),
&image_max_dim)) {
return false;
}
info_.image2DMaxWidth_ = image_max_dim[0];
info_.image2DMaxHeight_ = image_max_dim[1];
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_IMAGE_3D_MAX_ELEMENTS),
&image_max_dim)) {
return false;
}
info_.image3DMaxWidth_ = image_max_dim[0];
info_.image3DMaxHeight_ = image_max_dim[1];
info_.image3DMaxDepth_ = image_max_dim[2];
uint32_t max_array_size = 0;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_IMAGE_ARRAY_MAX_LAYERS),
&max_array_size)) {
return false;
}
info_.imageMaxArraySize_ = max_array_size;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice,
static_cast<hsa_agent_info_t>(HSA_EXT_AGENT_INFO_IMAGE_1DB_MAX_ELEMENTS),
&image_max_dim)) {
return false;
}
info_.imageMaxBufferSize_ = image_max_dim[0];
info_.imagePitchAlignment_ = 256;
info_.imageBaseAddressAlignment_ = 256;
info_.bufferFromImageSupport_ = CL_FALSE;
info_.imageSupport_ = (info_.maxReadWriteImageArgs_ > 0) ? CL_TRUE : CL_FALSE;
}
// Enable SVM Capabilities of Hsa device. Ensure
// user has not setup memory to be non-coherent
info_.svmCapabilities_ = 0;
if (hsa_settings->enableNCMode_ == false) {
info_.svmCapabilities_ = CL_DEVICE_SVM_COARSE_GRAIN_BUFFER;
info_.svmCapabilities_ |= CL_DEVICE_SVM_FINE_GRAIN_BUFFER;
// Report fine-grain system only on full profile
if (agent_profile_ == HSA_PROFILE_FULL) {
info_.svmCapabilities_ |= CL_DEVICE_SVM_FINE_GRAIN_SYSTEM;
}
if (!settings().useLightning_) {
// Report atomics capability based on GFX IP, control on Hawaii
// and Vega10.
if (info_.hostUnifiedMemory_ ||
((deviceInfo_.gfxipVersion_ >= 800) && (deviceInfo_.gfxipVersion_ < 900))) {
info_.svmCapabilities_ |= CL_DEVICE_SVM_ATOMICS;
}
}
}
if (settings().checkExtension(ClAmdDeviceAttributeQuery)) {
info_.simdPerCU_ = deviceInfo_.simdPerCU_;
info_.simdWidth_ = deviceInfo_.simdWidth_;
info_.simdInstructionWidth_ = deviceInfo_.simdInstructionWidth_;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, HSA_AGENT_INFO_WAVEFRONT_SIZE, &info_.wavefrontWidth_)) {
return false;
}
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_MEMORY_WIDTH, &info_.vramBusBitWidth_)) {
return false;
}
uint32_t max_waves_per_cu;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_MAX_WAVES_PER_CU, &max_waves_per_cu)) {
return false;
}
info_.maxThreadsPerCU_ = info_.wavefrontWidth_ * max_waves_per_cu;
uint32_t cache_sizes[4];
/* FIXIT [skudchad] - Seems like hardcoded in HSA backend so 0*/
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AGENT_INFO_CACHE_SIZE, cache_sizes)) {
return false;
}
info_.l2CacheSize_ = cache_sizes[1];
info_.timeStampFrequency_ = 1000000;
info_.globalMemChannelBanks_ = 4;
info_.globalMemChannelBankWidth_ = deviceInfo_.memChannelBankWidth_;
info_.localMemSizePerCU_ = deviceInfo_.localMemSizePerCU_;
info_.localMemBanks_ = deviceInfo_.localMemBanks_;
info_.gfxipVersion_ = deviceInfo_.gfxipVersion_;
info_.numAsyncQueues_ = kMaxAsyncQueues;
info_.numRTQueues_ = info_.numAsyncQueues_;
if (HSA_STATUS_SUCCESS !=
hsa_agent_get_info(_bkendDevice, (hsa_agent_info_t)HSA_AMD_AGENT_INFO_COMPUTE_UNIT_COUNT, &info_.numRTCUs_)) {
return false;
}
//TODO: set to true once thread trace support is available
info_.threadTraceEnable_ = false;
info_.pcieDeviceId_ = deviceInfo_.pciDeviceId_;
}
info_.maxPipePacketSize_ = info_.maxMemAllocSize_;
info_.maxPipeActiveReservations_ = 16;
info_.maxPipeArgs_ = 16;
info_.queueOnDeviceProperties_ =
CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE | CL_QUEUE_PROFILING_ENABLE;
info_.queueOnDevicePreferredSize_ = 256 * Ki;
info_.queueOnDeviceMaxSize_ = 8 * Mi;
info_.maxOnDeviceQueues_ = 1;
info_.maxOnDeviceEvents_ = settings().numDeviceEvents_;
return true;
}
device::VirtualDevice* Device::createVirtualDevice(amd::CommandQueue* queue) {
bool profiling = (queue != nullptr) && queue->properties().test(CL_QUEUE_PROFILING_ENABLE);
// Initialization of heap and other resources occur during the command
// queue creation time.
VirtualGPU* virtualDevice = new VirtualGPU(*this);
if (!virtualDevice->create(profiling)) {
delete virtualDevice;
return nullptr;
}
if (profiling) {
hsa_amd_profiling_set_profiler_enabled(virtualDevice->gpu_queue(), 1);
}
return virtualDevice;
}
bool Device::globalFreeMemory(size_t* freeMemory) const {
const uint TotalFreeMemory = 0;
const uint LargestFreeBlock = 1;
freeMemory[TotalFreeMemory] = freeMem_ / Ki;
// since there is no memory heap on ROCm, the biggest free block is
// equal to total free local memory
freeMemory[LargestFreeBlock] = freeMemory[TotalFreeMemory];
return true;
}
bool Device::bindExternalDevice(uint flags, void* const gfxDevice[], void* gfxContext,
bool validateOnly) {
#if defined(_WIN32)
return false;
#else
if ((flags & amd::Context::GLDeviceKhr) == 0) return false;
MesaInterop::MESA_INTEROP_KIND kind = MesaInterop::MESA_INTEROP_NONE;
MesaInterop::DisplayHandle display;
MesaInterop::ContextHandle context;
if ((flags & amd::Context::EGLDeviceKhr) != 0) {
kind = MesaInterop::MESA_INTEROP_EGL;
display.eglDisplay = reinterpret_cast<EGLDisplay>(gfxDevice[amd::Context::GLDeviceKhrIdx]);
context.eglContext = reinterpret_cast<EGLContext>(gfxContext);
} else {
kind = MesaInterop::MESA_INTEROP_GLX;
display.glxDisplay = reinterpret_cast<Display*>(gfxDevice[amd::Context::GLDeviceKhrIdx]);
context.glxContext = reinterpret_cast<GLXContext>(gfxContext);
}
mesa_glinterop_device_info info;
info.version = MESA_GLINTEROP_DEVICE_INFO_VERSION;
if (!MesaInterop::Init(kind)) {
return false;
}
if (!MesaInterop::GetInfo(info, kind, display, context)) {
return false;
}
bool match = true;
match &= info_.deviceTopology_.pcie.bus == info.pci_bus;
match &= info_.deviceTopology_.pcie.device == info.pci_device;
match &= info_.deviceTopology_.pcie.function == info.pci_function;
match &= info_.vendorId_ == info.vendor_id;
match &= deviceInfo_.pciDeviceId_ == info.device_id;
return match;
#endif
}
bool Device::unbindExternalDevice(uint flags, void* const gfxDevice[], void* gfxContext,
bool validateOnly) {
#if defined(_WIN32)
return false;
#else
if ((flags & amd::Context::GLDeviceKhr) == 0) return false;
return true;
#endif
}
amd::Memory* Device::findMapTarget(size_t size) const {
// Must be serialised for access
amd::ScopedLock lk(*mapCacheOps_);
amd::Memory* map = nullptr;
size_t minSize = 0;
size_t maxSize = 0;
uint mapId = mapCache_->size();
uint releaseId = mapCache_->size();
// Find if the list has a map target of appropriate size
for (uint i = 0; i < mapCache_->size(); i++) {
if ((*mapCache_)[i] != nullptr) {
// Requested size is smaller than the entry size
if (size < (*mapCache_)[i]->getSize()) {
if ((minSize == 0) || (minSize > (*mapCache_)[i]->getSize())) {
minSize = (*mapCache_)[i]->getSize();
mapId = i;
}
}
// Requeted size matches the entry size
else if (size == (*mapCache_)[i]->getSize()) {
mapId = i;
break;
} else {
// Find the biggest map target in the list
if (maxSize < (*mapCache_)[i]->getSize()) {
maxSize = (*mapCache_)[i]->getSize();
releaseId = i;
}
}
}
}
// Check if we found any map target
if (mapId < mapCache_->size()) {
map = (*mapCache_)[mapId];
(*mapCache_)[mapId] = nullptr;
}
// If cache is full, then release the biggest map target
else if (releaseId < mapCache_->size()) {
(*mapCache_)[releaseId]->release();
(*mapCache_)[releaseId] = nullptr;
}
return map;
}
bool Device::addMapTarget(amd::Memory* memory) const {
// Must be serialised for access
amd::ScopedLock lk(*mapCacheOps_);
// the svm memory shouldn't be cached
if (!memory->canBeCached()) {
return false;
}
// Find if the list has a map target of appropriate size
for (uint i = 0; i < mapCache_->size(); ++i) {
if ((*mapCache_)[i] == nullptr) {
(*mapCache_)[i] = memory;
return true;
}
}
// Add a new entry
mapCache_->push_back(memory);
return true;
}
Memory* Device::getRocMemory(amd::Memory* mem) const {
return static_cast<roc::Memory*>(mem->getDeviceMemory(*this));
}
device::Memory* Device::createMemory(amd::Memory& owner) const {
roc::Memory* memory = nullptr;
if (owner.asBuffer()) {
memory = new roc::Buffer(*this, owner);
} else if (owner.asImage()) {
memory = new roc::Image(*this, owner);
} else {
LogError("Unknown memory type");
}
if (memory == nullptr) {
return nullptr;
}
bool result = memory->create();
if (!result) {
LogError("Failed creating memory");
delete memory;
return nullptr;
}
// Initialize if the memory is a pipe object
if (owner.getType() == CL_MEM_OBJECT_PIPE) {
// Pipe initialize in order read_idx, write_idx, end_idx. Refer clk_pipe_t structure.
// Init with 3 DWORDS for 32bit addressing and 6 DWORDS for 64bit
size_t pipeInit[3] = { 0, 0, owner.asPipe()->getMaxNumPackets() };
xferMgr().writeBuffer((void *)pipeInit, *memory, amd::Coord3D(0), amd::Coord3D(sizeof(pipeInit)));
}
// Transfer data only if OCL context has one device.
// Cache coherency layer will update data for multiple devices
if (!memory->isHostMemDirectAccess() && owner.asImage() && (owner.parent() == nullptr) &&
(owner.getMemFlags() & CL_MEM_COPY_HOST_PTR) && (owner.getContext().devices().size() == 1)) {
// To avoid recurssive call to Device::createMemory, we perform
// data transfer to the view of the image.
amd::Image* imageView = owner.asImage()->createView(
owner.getContext(), owner.asImage()->getImageFormat(), xferQueue());
if (imageView == nullptr) {
LogError("[OCL] Fail to allocate view of image object");
return nullptr;
}
Image* devImageView = new roc::Image(static_cast<const Device&>(*this), *imageView);
if (devImageView == nullptr) {
LogError("[OCL] Fail to allocate device mem object for the view");
imageView->release();
return nullptr;
}
if (devImageView != nullptr && !devImageView->createView(static_cast<roc::Image&>(*memory))) {
LogError("[OCL] Fail to create device mem object for the view");
delete devImageView;
imageView->release();
return nullptr;
}
imageView->replaceDeviceMemory(this, devImageView);
result = xferMgr().writeImage(owner.getHostMem(), *devImageView, amd::Coord3D(0, 0, 0),
imageView->getRegion(), 0, 0, true);
// Release host memory, since runtime copied data
owner.setHostMem(nullptr);
imageView->release();
}
// Prepin sysmem buffer for possible data synchronization between CPU and GPU
if (!memory->isHostMemDirectAccess() &&
(owner.getHostMem() != nullptr) &&
(owner.getSvmPtr() == nullptr)) {
memory->pinSystemMemory(owner.getHostMem(), owner.getSize());
}
if (!result) {
delete memory;
return nullptr;
}
return memory;
}
void* Device::hostAlloc(size_t size, size_t alignment, bool atomics) const {
void* ptr = nullptr;
const hsa_amd_memory_pool_t segment = (!atomics)
? (system_coarse_segment_.handle != 0) ? system_coarse_segment_ : system_segment_
: system_segment_;
assert(segment.handle != 0);
hsa_status_t stat = hsa_amd_memory_pool_allocate(segment, size, 0, &ptr);
if (stat != HSA_STATUS_SUCCESS) {
LogError("Fail allocation host memory");
return nullptr;
}
stat = hsa_amd_agents_allow_access(gpu_agents_.size(), &gpu_agents_[0], nullptr, ptr);
if (stat != HSA_STATUS_SUCCESS) {
LogError("Fail hsa_amd_agents_allow_access");
return nullptr;
}
return ptr;
}
void Device::hostFree(void* ptr, size_t size) const { memFree(ptr, size); }
void* Device::deviceLocalAlloc(size_t size) const {
if (gpuvm_segment_.handle == 0 || gpuvm_segment_max_alloc_ == 0) {
return nullptr;
}
void* ptr = nullptr;
hsa_status_t stat = hsa_amd_memory_pool_allocate(gpuvm_segment_, size, 0, &ptr);
if (stat != HSA_STATUS_SUCCESS) {
LogError("Fail allocation local memory");
return nullptr;
}
if (p2pAgents().size() > 0) {
stat = hsa_amd_agents_allow_access(p2pAgents().size(), p2pAgents().data(), nullptr, ptr);
if (stat != HSA_STATUS_SUCCESS) {
LogError("Allow p2p acces for memory allocation");
memFree(ptr, size);
return nullptr;
}
}
return ptr;
}
void Device::memFree(void* ptr, size_t size) const {
hsa_status_t stat = hsa_amd_memory_pool_free(ptr);
if (stat != HSA_STATUS_SUCCESS) {
LogError("Fail freeing local memory");
}
}
void Device::updateFreeMemory(size_t size, bool free) {
if (free) {
freeMem_ += size;
}
else {
freeMem_ -= size;
}
}
amd::Memory *Device::IpcAttach(const void* handle, size_t mem_size, unsigned int flags, void** dev_ptr) const {
amd::Memory* amd_mem_obj = nullptr;
hsa_status_t hsa_status = HSA_STATUS_SUCCESS;
/* Retrieve the devPtr from the handle */
hsa_agent_t hsa_agent = getBackendDevice();
hsa_status
= hsa_amd_ipc_memory_attach(reinterpret_cast<const hsa_amd_ipc_memory_t*>(handle),
mem_size, 1, &hsa_agent, dev_ptr);
if (hsa_status != HSA_STATUS_SUCCESS) {
LogError("[OCL] HSA failed to attach IPC memory");
return nullptr;
}
/* Create an amd Memory object for the pointer */
amd_mem_obj = new (context()) amd::Buffer(context(), flags, mem_size, *dev_ptr);
if (amd_mem_obj == nullptr) {
LogError("[OCL] failed to create a mem object!");
return nullptr;
}
if (!amd_mem_obj->create(nullptr)) {
LogError("[OCL] failed to create a svm hidden buffer!");
amd_mem_obj->release();
return nullptr;
}
return amd_mem_obj;
}
void Device::IpcDetach (amd::Memory& memory) const {
void* dev_ptr = nullptr;
hsa_status_t hsa_status = HSA_STATUS_SUCCESS;
if(memory.getSvmPtr() != nullptr) {
dev_ptr = memory.getSvmPtr();
} else if (memory.getHostMem() != nullptr) {
dev_ptr = memory.getHostMem();
} else {
ShouldNotReachHere();
}
/*Detach the memory from HSA */
hsa_status = hsa_amd_ipc_memory_detach(dev_ptr);
if (hsa_status != HSA_STATUS_SUCCESS) {
LogError("[OCL] HSA failed to detach memory !");
return;
}
memory.release();
}
void* Device::svmAlloc(amd::Context& context, size_t size, size_t alignment, cl_svm_mem_flags flags,
void* svmPtr) const {
amd::Memory* mem = nullptr;
if (nullptr == svmPtr) {
// create a hidden buffer, which will allocated on the device later
mem = new (context) amd::Buffer(context, flags, size, reinterpret_cast<void*>(1));
if (mem == nullptr) {
LogError("failed to create a svm mem object!");
return nullptr;
}
if (!mem->create(nullptr)) {
LogError("failed to create a svm hidden buffer!");
mem->release();
return nullptr;
}
// if the device supports SVM FGS, return the committed CPU address directly.
Memory* gpuMem = getRocMemory(mem);
// add the information to context so that we can use it later.
amd::MemObjMap::AddMemObj(mem->getSvmPtr(), mem);
svmPtr = mem->getSvmPtr();
} else {
// Find the existing amd::mem object
mem = amd::MemObjMap::FindMemObj(svmPtr);
if (nullptr == mem) {
return nullptr;
}
svmPtr = mem->getSvmPtr();
}
return svmPtr;
}
void Device::svmFree(void* ptr) const {
amd::Memory* svmMem = nullptr;
svmMem = amd::MemObjMap::FindMemObj(ptr);
if (nullptr != svmMem) {
svmMem->release();
amd::MemObjMap::RemoveMemObj(ptr);
}
}
VirtualGPU* Device::xferQueue() const {
if (!xferQueue_) {
// Create virtual device for internal memory transfer
Device* thisDevice = const_cast<Device*>(this);
thisDevice->xferQueue_ = reinterpret_cast<VirtualGPU*>(thisDevice->createVirtualDevice());
if (!xferQueue_) {
LogError("Couldn't create the device transfer manager!");
}
}
xferQueue_->enableSyncBlit();
return xferQueue_;
}
bool Device::SetClockMode(const cl_set_device_clock_mode_input_amd setClockModeInput, cl_set_device_clock_mode_output_amd* pSetClockModeOutput) {
bool result = true;
return result;
}
}
#endif // WITHOUT_HSA_BACKEND