CUDA provides a separate CUDA Driver and Runtime APIs. The two APIs have significant overlap in functionality:
- Both APIs support events, streams, memory management, memory copy, and error handling.
- Both APIs deliver similar performance.
- Driver APIs calls begin with the prefix
cu
while Runtime APIs begin with the prefixcuda
. For example, the Driver API API containscuEventCreate
while the Runtime API containscudaEventCreate
, with similar functionality. - The Driver API defines a different but largely overlapping error code space than the Runtime API, and uses a different coding convention. For example, Driver API defines
CUDA_ERROR_INVALID_VALUE
while the Runtime API definescudaErrorInvalidValue
The Driver API offers two additional pieces of functionality not provided by the Runtime API: cuModule and cuCtx APIs.
The Module section of the Driver API provides additional control over how and when accelerator code objects are loaded. For example, the driver API allows code objects to be loaded from files or memory pointers. Symbols for kernels or global data can be extracted from the loaded code objects. In contrast, the Runtime API automatically loads and (if necessary) compiles all of the kernels from an executable binary when run. In this mode, NVCC must be used to compile kernel code so the automatic loading can function correctly.
Both Driver and Runtime APIs define a function for launching kernels (called cuLaunchKernel
or cudaLaunchKernel
.
The kernel arguments and the execution configuration (grid dimensions, group dimensions, dynamic shared memory, and stream) are passed as arguments to the launch function.
The Runtime additionally provides the <<< >>>
syntax for launching kernels, which resembles a special function call and is easier to use than explicit launch API (in particular with respect to handling of kernel arguments).
However, this syntax is not standard C++ and is available only when NVCC is used to compile the host code.
The Module features are useful in an environment which generates the code objects directly, such as a new accelerator language front-end. Here, NVCC is not used. Instead, the environment may have a different kernel language or different compilation flow. Other environments have many kernels and do not want them to be all loaded automatically. The Module functions can be used to load the generated code objects and launch kernels. As we will see below, HIP defines a Module API which provides similar explicit control over code object management.
The Driver API defines "Context" and "Devices" as separate entities.
Contexts contain a single device, and a device can theoretically have multiple contexts.
Each context contains a set of streams and events specific to the context.
Historically contexts also defined a unique address space for the GPU, though this may no longer be the case in Unified Memory platforms (since the CPU and all the devices in the same process share a single unified address space).
The Context APIs also provide a mechanism to switch between devices, which allowed a single CPU thread to send commands to different GPUs.
HIP as well as a recent versions of CUDA Runtime provide other mechanisms to accomplish this feat - for example using streams or cudaSetDevice
.
The CUDA Runtime API unifies the Context API with the Device API. This simplifies the APIs and has little loss of functionality since each Context can contain a single device, and the benefits of multiple contexts has been replaced with other interfaces. HIP provides a context API to facilitate easy porting from existing Driver codes. In HIP, the Ctx functions largely provide an alternate syntax for changing the active device.
Most new applications will prefer to use hipSetDevice
or the stream APIs , therefore HIP has marked hipCtx APIs as deprecated. Support for these APIs may not be available in future releases. For more details on deprecated APIs please refer HIP deprecated APIs.
Rather than present two separate APIs, HIP extends the HIP API with new APIs for Modules and Ctx control.
Like the CUDA Driver API, the Module API provides additional control over how code is loaded, including options to load code from files or from in-memory pointers.
NVCC and HCC target different architectures and use different code object formats: NVCC is cubin
or ptx
files, while the HCC path is the hsaco
format.
The external compilers which generate these code objects are responsible for generating and loading the correct code object for each platform.
Notably, there is not a fat binary format that can contain code for both NVCC and HCC platforms. The following table summarizes the formats used on each platform:
Format | APIs | NVCC | HCC | HIP-CLANG |
---|---|---|---|---|
Code Object | hipModuleLoad, hipModuleLoadData | .cubin or PTX text | .hsaco | .hsaco |
Fat Binary | hipModuleLoadFatBin | .fatbin | Under Development | .hip_fatbin |
hipcc
uses NVCC and HCC to compile host codes. Both of these may embed code objects into the final executable, and these code objects will be automatically loaded when the application starts.
The hipModule API can be used to load additional code objects, and in this way provides an extended capability to the automatically loaded code objects.
HCC allows both of these capabilities to be used together, if desired. Of course it is possible to create a program with no kernels and thus no automatic loading.
HIP provides a Ctx
API as a thin layer over the existing Device functions. This Ctx API can be used to set the current context, or to query properties of the device associated with the context.
The current context is implicitly used by other APIs such as hipStreamCreate
.
The HIPIFY tools convert CUDA Driver APIs for streams, events, modules, devices, memory management, context, profiler to the equivalent HIP driver calls. For example, cuEventCreate
will be translated to hipEventCreate
.
HIPIFY tools also convert error codes from the Driver namespace and coding convention to the equivalent HIP error code. Thus, HIP unifies the APIs for these common functions.
The memory copy API requires additional explanation. The CUDA driver includes the memory direction in the name of the API (ie cuMemcpyH2D
) while the CUDA driver API provides a single memory copy API with a parameter that specifies the direction and additionally supports a "default" direction where the runtime determines the direction automatically.
HIP provides APIs with both styles: for example, hipMemcpyH2D
as well as hipMemcpy
.
The first flavor may be faster in some cases since they avoid host overhead to detect the different memory directions.
HIP defines a single error space, and uses camel-case for all errors (i.e. hipErrorInvalidValue
).
The .hsaco format used by HCC is described in more detail here. An example and blog that show how to use the format is here. hsaco can be generated by hcc + extractkernel tool, cloc, the GCN assembler, or other tools.
HCC defines a process-wide address space where the CPU and all devices allocate addresses from a single unified pool. Thus addresses may be shared between contexts, and unlike the original CUDA definition a new context does not create a new address space for the device.
hipModuleLaunchKernel
is cuLaunchKernel
in HIP world. It takes the same arguments as cuLaunchKernel
. The argument kernelParams
is not fully implemented for HCC. The workaround for it is, to use platform specific macros for each target. Or, extra
argument can be used which works on both the platforms.
- HCC allocates staging buffers (used for unpinned copies) on a per-device basis.
- HCC creates a primary context when the HIP API is called. So in a pure driver API code, HIP/HCC will create a primary context while HIP/NVCC will have empty context stack. HIP/HCC will push primary context to context stack when it is empty. This can have subtle differences on applications which mix the runtime and driver APIs.
hip-clang links device code from different translation units together. For each device target, a code object is generated. Code objects for different device targets are bundled by clang-offload-bundler as one fatbinary, which is embeded as a global symbol __hip_fatbin
in the .hip_fatbin section of the ELF file of the executable or shared object.
hip-clang generates initializatiion and termination functions for each translation unit for host code compilation. The initialization functions call __hipRegisterFatBinary
to register the fatbinary embeded in the ELF file. They also call __hipRegisterFunction
and __hipRegisterVar
to register kernel functions and device side global variables. The termination functions call __hipUnregisterFatBinary
.
hip-clang emits a global variable __hip_gpubin_handle
of void** type with linkonce linkage and inital value 0 for each host translation unit. Each initialization function checks __hip_gpubin_handle
and register the fatbinary only if __hip_gpubin_handle
is 0 and saves the return value of __hip_gpubin_handle
to __hip_gpubin_handle
. This is to guarantee that the fatbinary is only registered once. Similar check is done in the termination functions.
hip-clang supports kernel launching by CUDA <<<>>>
syntax, hipLaunchKernel, and hipLaunchKernelGGL. The latter two are macros which expand to CUDA <<<>>>
syntax.
When the executable or shared library is loaded by the dynamic linker, the initilization functions are called. In the initialization functions, when __hipRegisterFatBinary
is called, the code objects containing all kernels are loaded; when __hipRegisterFunction
is called, the stub functions are associated with the corresponding kernels in code objects.
hip-clang implements two sets of kernel launching APIs.
By default, in the host code, for the <<<>>>
statement, hip-clang first emits call of hipConfigureCall to set up the threads and grids, then emits call of the stub function with the given arguments. In the stub function, hipSetupArgument is called for each kernel argument, then hipLaunchByPtr is called with a function pointer to the stub function. In hipLaunchByPtr, the real kernel associated with the stub function is launched.
If HIP program is compiled with -fhip-new-launch-api, in the host code, for the <<<>>>
statement, hip-clang first emits call of __hipPushCallConfiguration
to save the grid dimension, block dimension, shared memory usage and stream to a stack, then emits call of the stub function with the given arguments. In the stub function, __hipPopCallConfiguration
is called to get the saved grid dimension, block dimension, shared memory usage and stream, then hipLaunchKernel is called with a function pointer to the stub function. In hipLaunchKernel, the real kernel associated with the stub function is launched.
CUDA applications may want to mix CUDA driver code with HIP code (see example below). This table shows the type equivalence to enable this interaction.
HIP Type | CU Driver Type | CUDA Runtime Type |
---|---|---|
hipModule_t | CUmodule | |
hipFunction_t | CUfunction | |
hipCtx_t | CUcontext | |
hipDevice_t | CUdevice | |
hipStream_t | CUstream | cudaStream_t |
hipEvent_t | CUevent | cudaEvent_t |
hipArray | CUarray | cudaArray |
The hipModule_t
interface does not support cuModuleLoadDataEx
function, which is used to control PTX compilation options.
HCC does not use PTX and does not support these compilation options.
In fact, HCC code objects always contain fully compiled ISA and do not require additional compilation as a part of the load step.
The corresponding HIP function hipModuleLoadDataEx
behaves as hipModuleLoadData
on HCC path (compilation options are not used) and as cuModuleLoadDataEx
on NVCC path.
For example (CUDA):
CUmodule module;
void *imagePtr = ...; // Somehow populate data pointer with code object
const int numOptions = 1;
CUJit_option options[numOptions];
void * optionValues[numOptions];
options[0] = CU_JIT_MAX_REGISTERS;
unsigned maxRegs = 15;
optionValues[0] = (void*)(&maxRegs);
cuModuleLoadDataEx(module, imagePtr, numOptions, options, optionValues);
CUfunction k;
cuModuleGetFunction(&k, module, "myKernel");
HIP:
hipModule_t module;
void *imagePtr = ...; // Somehow populate data pointer with code object
const int numOptions = 1;
hipJitOption options[numOptions];
void * optionValues[numOptions];
options[0] = hipJitOptionMaxRegisters;
unsigned maxRegs = 15;
optionValues[0] = (void*)(&maxRegs);
// hipModuleLoadData(module, imagePtr) will be called on HCC path, JIT options will not be used, and
// cupModuleLoadDataEx(module, imagePtr, numOptions, options, optionValues) will be called on NVCC path
hipModuleLoadDataEx(module, imagePtr, numOptions, options, optionValues);
hipFunction_t k;
hipModuleGetFunction(&k, module, "myKernel");
The below sample shows how to use hipModuleGetFunction
.
#include<hip_runtime.h>
#include<hip_runtime_api.h>
#include<iostream>
#include<fstream>
#include<vector>
#define LEN 64
#define SIZE LEN<<2
#ifdef __HIP_PLATFORM_HCC__
#define fileName "vcpy_isa.co"
#endif
#ifdef __HIP_PLATFORM_NVCC__
#define fileName "vcpy_isa.ptx"
#endif
#define kernel_name "hello_world"
int main(){
float *A, *B;
hipDeviceptr_t Ad, Bd;
A = new float[LEN];
B = new float[LEN];
for(uint32_t i=0;i<LEN;i++){
A[i] = i*1.0f;
B[i] = 0.0f;
std::cout<<A[i] << " "<<B[i]<<std::endl;
}
#ifdef __HIP_PLATFORM_NVCC__
hipInit(0);
hipDevice_t device;
hipCtx_t context;
hipDeviceGet(&device, 0);
hipCtxCreate(&context, 0, device);
#endif
hipMalloc((void**)&Ad, SIZE);
hipMalloc((void**)&Bd, SIZE);
hipMemcpyHtoD(Ad, A, SIZE);
hipMemcpyHtoD(Bd, B, SIZE);
hipModule_t Module;
hipFunction_t Function;
hipModuleLoad(&Module, fileName);
hipModuleGetFunction(&Function, Module, kernel_name);
std::vector<void*>argBuffer(2);
memcpy(&argBuffer[0], &Ad, sizeof(void*));
memcpy(&argBuffer[1], &Bd, sizeof(void*));
size_t size = argBuffer.size()*sizeof(void*);
void *config[] = {
HIP_LAUNCH_PARAM_BUFFER_POINTER, &argBuffer[0],
HIP_LAUNCH_PARAM_BUFFER_SIZE, &size,
HIP_LAUNCH_PARAM_END
};
hipModuleLaunchKernel(Function, 1, 1, 1, LEN, 1, 1, 0, 0, NULL, (void**)&config);
hipMemcpyDtoH(B, Bd, SIZE);
for(uint32_t i=0;i<LEN;i++){
std::cout<<A[i]<<" - "<<B[i]<<std::endl;
}
#ifdef __HIP_PLATFORM_NVCC__
hipCtxDetach(context);
#endif
return 0;
}
HIP supports texture driver APIs however texture reference should be declared in host scope. Following code explains the use of texture reference for HIP_PLATFORM_HCC platform.
// Code to generate code object
#include "hip/hip_runtime.h"
extern texture<float, 2, hipReadModeElementType> tex;
__global__ void tex2dKernel(hipLaunchParm lp, float* outputData,
int width,
int height)
{
int x = hipBlockIdx_x*hipBlockDim_x + hipThreadIdx_x;
int y = hipBlockIdx_y*hipBlockDim_y + hipThreadIdx_y;
outputData[y*width + x] = tex2D(tex, x, y);
}
// Host code:
texture<float, 2, hipReadModeElementType> tex;
void myFunc ()
{
// ...
textureReference* texref;
hipModuleGetTexRef(&texref, Module1, "tex");
hipTexRefSetAddressMode(texref, 0, hipAddressModeWrap);
hipTexRefSetAddressMode(texref, 1, hipAddressModeWrap);
hipTexRefSetFilterMode(texref, hipFilterModePoint);
hipTexRefSetFlags(texref, 0);
hipTexRefSetFormat(texref, HIP_AD_FORMAT_FLOAT, 1);
hipTexRefSetArray(texref, array, HIP_TRSA_OVERRIDE_FORMAT);
// ...
}