import copy import hashlib import math import os import platform import re import shutil import subprocess import sys import tempfile from typing import Optional import warnings from cupy.cuda import device from cupy.cuda import function from cupy.cuda import get_rocm_path from cupy_backends.cuda.api import driver from cupy_backends.cuda.api import runtime from cupy_backends.cuda.libs import nvrtc from cupy import _environment from cupy import _util _cuda_hip_version = driver.get_build_version() _nvrtc_version = None _win32 = sys.platform.startswith('win32') _rdc_flags = ('--device-c', '-dc', '-rdc=true', '--relocatable-device-code=true') _cudadevrt = None class NVCCException(Exception): pass class HIPCCException(Exception): pass class JitifyException(Exception): pass def _run_cc(cmd, cwd, backend, log_stream=None): # backend in ('nvcc', 'hipcc') try: # Inherit the environment variable as NVCC refers to PATH, TMPDIR/TMP, # NVCC_PREPEND_FLAGS, NVCC_APPEND_FLAGS. env = os.environ if _win32: # Adds the extra PATH for NVCC invocation. # When running NVCC, a host compiler must be available in PATH, # but this is not true in general Windows environment unless # running inside the SDK Tools command prompt. # To mitigate the situation CuPy automatically adds a path to # the VC++ compiler (cl.exe) found via setuptools, if it is not # on the PATH. extra_path = _get_extra_path_for_msvc() if extra_path is not None: path = extra_path + os.pathsep + os.environ.get('PATH', '') env = copy.deepcopy(env) env['PATH'] = path log = subprocess.check_output( cmd, cwd=cwd, env=env, stderr=subprocess.STDOUT, universal_newlines=True, creationflags=(subprocess.CREATE_NO_WINDOW if _win32 else 0)) if log_stream is not None: log_stream.write(log) return log except subprocess.CalledProcessError as e: msg = ('`{0}` command returns non-zero exit status. \n' 'command: {1}\n' 'return-code: {2}\n' 'stdout/stderr: \n' '{3}'.format(backend, e.cmd, e.returncode, e.output)) if backend == 'nvcc': raise NVCCException(msg) elif backend == 'hipcc': raise HIPCCException(msg) else: raise RuntimeError(msg) except OSError as e: msg = 'Failed to run `{0}` command. ' \ 'Check PATH environment variable: ' \ + str(e) raise OSError(msg.format(backend)) @_util.memoize() def _get_extra_path_for_msvc(): cl_exe = shutil.which('cl.exe') if cl_exe: # The compiler is already on PATH, no extra path needed. return None cl_exe_dir = _get_cl_exe_dir() if cl_exe_dir: return cl_exe_dir cl_exe_dir = _get_cl_exe_dir_fallback() if cl_exe_dir: return cl_exe_dir return None def _get_cl_exe_dir() -> Optional[str]: try: try: # setuptools.msvc is missing in setuptools v74.0.0. # setuptools.msvc requires explicit import in setuptools v74.1.0+. import setuptools.msvc except Exception: return None vctools = setuptools.msvc.EnvironmentInfo(platform.machine()).VCTools for path in vctools: cl_exe = os.path.join(path, 'cl.exe') if os.path.exists(cl_exe): return path warnings.warn(f'cl.exe could not be found in {vctools}') except Exception as e: warnings.warn( f'Failed to find cl.exe with setuptools.msvc: {type(e)}: {e}') return None def _get_cl_exe_dir_fallback() -> Optional[str]: # Discover cl.exe without relying on undocumented setuptools.msvc API. # As of now this code path exists only for setuptools 74.0.0 (see #8583). # N.B. This takes few seconds as this incurs cmd.exe (vcvarsall.bat) # invocation. try: from setuptools import Distribution from setuptools.command.build_ext import build_ext ext = build_ext(Distribution({'name': 'cupy_cl_exe_discover'})) ext.setup_shlib_compiler() ext.shlib_compiler.initialize() # MSVCCompiler only return os.path.dirname(ext.shlib_compiler.cc) except Exception as e: warnings.warn( f'Failed to find cl.exe with setuptools: {type(e)}: {e}') return None def _get_nvrtc_version(): global _nvrtc_version if _nvrtc_version is None: _nvrtc_version = nvrtc.getVersion() return _nvrtc_version @_util.memoize() def _get_cupy_cache_key(): from cupy._core import core return core.CUPY_CACHE_KEY # Known archs for Tegra/Jetson/Xavier/etc _tegra_archs = ('32', '53', '62', '72', '87') @_util.memoize() def _get_max_compute_capability(): major, minor = _get_nvrtc_version() if major < 11: # CUDA 10.2 nvrtc_max_compute_capability = '75' elif major == 11 and minor == 0: # CUDA 11.0 nvrtc_max_compute_capability = '80' elif major == 11 and minor < 8: # CUDA 11.1 - 11.7 # Note: 87 is for Jetson Orin nvrtc_max_compute_capability = '86' elif (major == 11 and minor == 8) or (major == 12 and minor < 8): # CUDA 11.8, 12.0 - 12.7 nvrtc_max_compute_capability = '90' else: # CUDA 12.8+ nvrtc_max_compute_capability = '120' return nvrtc_max_compute_capability @_util.memoize() def _get_extra_include_dir_opts(): major, minor = _get_nvrtc_version() return tuple( f'-I{d}' for d in _environment._get_include_dir_from_conda_or_wheel( major, minor ) ) @_util.memoize(for_each_device=True) def _get_arch(): # See Supported Compile Options section of NVRTC User Guide for # the maximum value allowed for `--gpu-architecture`. nvrtc_max_compute_capability = _get_max_compute_capability() arch = device.Device().compute_capability if arch in _tegra_archs: return arch else: return min(arch, nvrtc_max_compute_capability, key=int) @_util.memoize(for_each_device=True) def _get_arch_for_options_for_nvrtc(arch=None): # NVRTC in CUDA 11.3+ generates PTX that cannot be run an earlier driver # version than the one included in the used CUDA version, as # documented in: # https://docs.nvidia.com/cuda/archive/11.3.0/nvrtc/index.html#versioning # Here we use `-arch=sm_*` instead of `-arch=compute_*` to directly # generate cubin (SASS) instead of PTX. See #5097 for details. if arch is None: arch = _get_arch() if ( not _use_ptx and int(arch) <= int(_get_max_compute_capability()) ): return f'-arch=sm_{arch}', 'cubin' return f'-arch=compute_{arch}', 'ptx' def _is_cudadevrt_needed(options): return any(o for o in options if o in _rdc_flags) def _get_cudadevrt_path(): global _cudadevrt if _cudadevrt is not None: return _cudadevrt # defer import to here to avoid circular dependency from cupy.cuda import get_cuda_path global _win32 cudadevrt = get_cuda_path() if cudadevrt is None: raise RuntimeError('CUDA is not found.') if _win32: # rely on os.altsep cudadevrt += '/lib/x64/cudadevrt.lib' else: # linux & osx: search twice as in cupy/install/build.py cudadevrt64 = cudadevrt + '/lib64/libcudadevrt.a' if not os.path.isfile(cudadevrt64): cudadevrt += '/lib/libcudadevrt.a' else: cudadevrt = cudadevrt64 if not os.path.isfile(cudadevrt): raise RuntimeError( 'Relocatable PTX code is requested, but cudadevrt ' 'is not found.') return cudadevrt def _remove_rdc_option(options): return tuple(o for o in options if o not in _rdc_flags) def _get_bool_env_variable(name, default): val = os.environ.get(name) if val is None or len(val) == 0: return default try: return int(val) == 1 except ValueError: return False _use_ptx = _get_bool_env_variable('CUPY_COMPILE_WITH_PTX', False) _jitify_header_source_map_populated = False def _jitify_prep(source, options, cu_path): from cupy.cuda import jitify # TODO(leofang): refactor this? global _jitify_header_source_map_populated if not _jitify_header_source_map_populated: from cupy._core import core jitify._init_module() jitify._add_sources(core._get_header_source_map()) _jitify_header_source_map_populated = True # jitify requires the 1st line to be the program name old_source = source source = cu_path + '\n' + source # Upon failure, in addition to throw an error Jitify also prints the log # to stdout. In principle we could intercept that by hijacking stdout's # file descriptor (tested locally), but the problem is pytest also does # the same thing internally, causing strange errors when running the tests. # As a result, we currently maintain Jitify's default behavior for easy # debugging, and wait for the upstream to address this issue # (NVIDIA/jitify#79). try: name, options, headers, include_names = jitify.jitify(source, options) except Exception as e: # C++ could throw all kinds of errors cex = CompileException(str(e), old_source, cu_path, options, 'jitify') dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: cex.dump(sys.stderr) raise JitifyException(str(cex)) from e assert name == cu_path return options, headers, include_names _has_usedforsecurity = (sys.version_info >= (3, 9)) def _hash_hexdigest(value): if _has_usedforsecurity: hashobj = hashlib.sha1(value, usedforsecurity=False) else: hashobj = hashlib.sha1(value) return hashobj.hexdigest() _hash_length = len(_hash_hexdigest(b'')) # 40 for SHA1 def compile_using_nvrtc(source, options=(), arch=None, filename='kern.cu', name_expressions=None, log_stream=None, cache_in_memory=False, jitify=False): def _compile( source, options, cu_path, name_expressions, log_stream, jitify): if not runtime.is_hip: arch_opt, method = _get_arch_for_options_for_nvrtc(arch) options += (arch_opt,) else: method = 'ptx' if jitify: options, headers, include_names = _jitify_prep( source, options, cu_path) else: headers = include_names = () major_version, minor_version = _get_nvrtc_version() if major_version >= 12: # Starting with CUDA 12.0, even without using jitify, some # tests cause an error if the following option is not included. options += ('--device-as-default-execution-space',) prog = _NVRTCProgram(source, cu_path, headers, include_names, name_expressions=name_expressions, method=method) try: compiled_obj, mapping = prog.compile(options, log_stream) except CompileException as e: dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: e.dump(sys.stderr) raise return compiled_obj, mapping if not cache_in_memory: with tempfile.TemporaryDirectory() as root_dir: cu_path = os.path.join(root_dir, filename) with open(cu_path, 'w') as cu_file: cu_file.write(source) return _compile(source, options, cu_path, name_expressions, log_stream, jitify) else: cu_path = '' if not jitify else filename return _compile(source, options, cu_path, name_expressions, log_stream, jitify) def compile_using_nvcc(source, options=(), arch=None, filename='kern.cu', code_type='cubin', separate_compilation=False, log_stream=None): # defer import to here to avoid circular dependency from cupy.cuda import get_nvcc_path if not arch: arch = _get_arch() if code_type not in ('cubin', 'ptx'): raise ValueError('Invalid code_type %s. Should be cubin or ptx') if code_type == 'ptx': assert not separate_compilation arch_str = '-gencode=arch=compute_{cc},code=sm_{cc}'.format(cc=arch) _nvcc = get_nvcc_path() # split() is needed because _nvcc could come from the env var NVCC cmd = _nvcc.split() cmd.append(arch_str) with tempfile.TemporaryDirectory() as root_dir: first_part = filename.split('.')[0] path = os.path.join(root_dir, first_part) cu_path = '%s.cu' % path result_path = '%s.%s' % (path, code_type) with open(cu_path, 'w') as cu_file: cu_file.write(source) if not separate_compilation: # majority cases cmd.append('--%s' % code_type) cmd += list(options) cmd.append(cu_path) try: _run_cc(cmd, root_dir, 'nvcc', log_stream) except NVCCException as e: cex = CompileException(str(e), source, cu_path, options, 'nvcc') dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: cex.dump(sys.stderr) raise cex else: # two steps: compile to object and device-link cmd_partial = cmd.copy() cmd_partial.append('--cubin') obj = path + '.o' cmd += list(options + ('-o', obj)) cmd.append(cu_path) try: _run_cc(cmd, root_dir, 'nvcc', log_stream) except NVCCException as e: cex = CompileException(str(e), source, cu_path, options, 'nvcc') dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: cex.dump(sys.stderr) raise cex options = _remove_rdc_option(options) options += ('--device-link', obj, '-o', path + '.cubin') cmd = cmd_partial + list(options) try: _run_cc(cmd, root_dir, 'nvcc', log_stream) except NVCCException as e: cex = CompileException(str(e), '', '', options, 'nvcc') raise cex if code_type == 'ptx': with open(result_path, 'rb') as ptx_file: return ptx_file.read() elif code_type == 'cubin': with open(result_path, 'rb') as bin_file: return bin_file.read() else: assert False, code_type def _preprocess(source, options, arch, backend): if backend == 'nvrtc': # For the preprocess it is enough to use PTX method # we don't need to explicitly obtain a CUBIN file. options += ('-arch=compute_{}'.format(arch),) prog = _NVRTCProgram(source) try: result, _ = prog.compile(options) except CompileException as e: dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: e.dump(sys.stderr) raise elif backend == 'nvcc': try: result = compile_using_nvcc(source, options, arch, 'preprocess.cu', code_type='ptx') except CompileException as e: dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: e.dump(sys.stderr) raise else: raise ValueError('Invalid backend %s' % backend) assert isinstance(result, bytes) # Extract the part containing version information. return '\n'.join( x for x in result.decode().splitlines() if x.startswith('//')) _default_cache_dir = os.path.expanduser('~/.cupy/kernel_cache') def get_cache_dir(): return os.environ.get('CUPY_CACHE_DIR', _default_cache_dir) _empty_file_preprocess_cache: dict = {} def _compile_module_with_cache( source, options=(), arch=None, cache_dir=None, extra_source=None, backend='nvrtc', *, enable_cooperative_groups=False, name_expressions=None, log_stream=None, jitify=False): if enable_cooperative_groups: if runtime.is_hip: raise ValueError( 'Cooperative groups is not supported in HIP.') if name_expressions is not None and backend != 'nvrtc': raise NotImplementedError # We silently ignore CUPY_CACHE_IN_MEMORY if nvcc/hipcc are in use, because # they must dump files to disk. cache_in_memory = ( _get_bool_env_variable('CUPY_CACHE_IN_MEMORY', False) and backend == 'nvrtc') if runtime.is_hip: backend = 'hiprtc' if backend == 'nvrtc' else 'hipcc' return _compile_with_cache_hip( source, options, arch, cache_dir, extra_source, backend, name_expressions, log_stream, cache_in_memory) else: return _compile_with_cache_cuda( source, options, arch, cache_dir, extra_source, backend, enable_cooperative_groups, name_expressions, log_stream, cache_in_memory, jitify) def _compile_with_cache_cuda( source, options, arch, cache_dir, extra_source=None, backend='nvrtc', enable_cooperative_groups=False, name_expressions=None, log_stream=None, cache_in_memory=False, jitify=False): # NVRTC does not use extra_source. extra_source is used for cache key. global _empty_file_preprocess_cache if cache_dir is None: cache_dir = get_cache_dir() if arch is None: arch = _get_arch() options += ('-ftz=true',) if enable_cooperative_groups: # `cooperative_groups` requires relocatable device code. options += ('--device-c',) if _get_bool_env_variable('CUPY_CUDA_COMPILE_WITH_DEBUG', False): options += ('--device-debug', '--generate-line-info') is_jitify_requested = ('-DCUPY_USE_JITIFY' in options) if jitify and not is_jitify_requested: # jitify is set in RawKernel/RawModule, translate it to an option # that is useless to the compiler, but can be used as part of the # hash key options += ('-DCUPY_USE_JITIFY',) elif is_jitify_requested and not jitify: # jitify is requested internally, just set the flag jitify = True if jitify and backend != 'nvrtc': raise ValueError('jitify only works with NVRTC') options += _get_extra_include_dir_opts() env = ((arch, options, _get_nvrtc_version(), backend) + _get_arch_for_options_for_nvrtc(arch)) base = _empty_file_preprocess_cache.get(env, None) if base is None: # This is for checking NVRTC/NVCC compiler internal version base = _preprocess('', options, arch, backend) _empty_file_preprocess_cache[env] = base key_src = '%s %s %s %s %s' % ( env, base, source, extra_source, _get_cupy_cache_key()) key_src = key_src.encode('utf-8') name = _hash_hexdigest(key_src) + '.cubin' mod = function.Module() if not cache_in_memory: # Read from disk cache if not os.path.isdir(cache_dir): os.makedirs(cache_dir, exist_ok=True) # To handle conflicts in concurrent situation, we adopt lock-free # method to avoid performance degradation. # We force recompiling to retrieve C++ mangled names if so desired. path = os.path.join(cache_dir, name) if os.path.exists(path) and not name_expressions: with open(path, 'rb') as file: data = file.read() if len(data) >= _hash_length: hash = data[:_hash_length] cubin = data[_hash_length:] cubin_hash = _hash_hexdigest(cubin).encode('ascii') if hash == cubin_hash: mod.load(cubin) return mod else: # Enforce compiling -- the resulting kernel will be cached elsewhere, # so we do nothing pass if backend == 'nvrtc': cu_name = '' if cache_in_memory else name + '.cu' ptx, mapping = compile_using_nvrtc( source, options, arch, cu_name, name_expressions, log_stream, cache_in_memory, jitify) if _is_cudadevrt_needed(options): # for separate compilation ls = function.LinkState() ls.add_ptr_data(ptx, 'cupy.ptx') _cudadevrt = _get_cudadevrt_path() ls.add_ptr_file(_cudadevrt) cubin = ls.complete() else: cubin = ptx mod._set_mapping(mapping) elif backend == 'nvcc': rdc = _is_cudadevrt_needed(options) cubin = compile_using_nvcc(source, options, arch, name + '.cu', code_type='cubin', separate_compilation=rdc, log_stream=log_stream) else: raise ValueError('Invalid backend %s' % backend) if not cache_in_memory: # Write to disk cache cubin_hash = _hash_hexdigest(cubin).encode('ascii') # shutil.move is not atomic operation, so it could result in a # corrupted file. We detect it by appending a hash at the beginning # of each cache file. If the file is corrupted, it will be ignored # next time it is read. with tempfile.NamedTemporaryFile(dir=cache_dir, delete=False) as tf: tf.write(cubin_hash) tf.write(cubin) temp_path = tf.name shutil.move(temp_path, path) # Save .cu source file along with .cubin if _get_bool_env_variable('CUPY_CACHE_SAVE_CUDA_SOURCE', False): with open(path + '.cu', 'w') as f: f.write(source) else: # we don't do any disk I/O pass mod.load(cubin) return mod class CompileException(Exception): def __init__(self, msg, source, name, options, backend='nvrtc'): self._msg = msg self.source = source self.name = name self.options = options self.backend = backend super(CompileException, self).__init__() def __reduce__(self): return (type(self), (self._msg, self.source, self.name, self.options, self.backend)) def __repr__(self): return str(self) def __str__(self): return self.get_message() def get_message(self): return self._msg def dump(self, f): lines = self.source.split('\n') digits = int(math.floor(math.log10(len(lines)))) + 1 linum_fmt = '{{:0{}d}} '.format(digits) f.write('{} '.format(self.backend.upper())) f.write('compilation error: {}\n'.format(self)) f.write('-----\n') f.write('Name: {}\n'.format(self.name)) f.write('Options: {}\n'.format(' '.join(self.options))) f.write('CUDA source:\n') for i, line in enumerate(lines): f.write(linum_fmt.format(i + 1) + line.rstrip() + '\n') f.write('-----\n') f.flush() class _NVRTCProgram(object): def __init__(self, src, name='default_program', headers=(), include_names=(), name_expressions=None, method='ptx'): self.ptr = None if isinstance(src, bytes): src = src.decode('UTF-8') if isinstance(name, bytes): name = name.decode('UTF-8') self.src = src self.name = name self.ptr = nvrtc.createProgram(src, name, headers, include_names) self.name_expressions = name_expressions self.method = method def __del__(self, is_shutting_down=_util.is_shutting_down): if is_shutting_down(): return if self.ptr: nvrtc.destroyProgram(self.ptr) def compile(self, options=(), log_stream=None): try: if self.name_expressions: for ker in self.name_expressions: nvrtc.addNameExpression(self.ptr, ker) nvrtc.compileProgram(self.ptr, options) mapping = None if self.name_expressions: mapping = {} for ker in self.name_expressions: mapping[ker] = nvrtc.getLoweredName(self.ptr, ker) if log_stream is not None: log_stream.write(nvrtc.getProgramLog(self.ptr)) # This is to ensure backwards compatibility with nvrtc if self.method == 'cubin': return nvrtc.getCUBIN(self.ptr), mapping elif self.method == 'ptx': return nvrtc.getPTX(self.ptr), mapping # TODO(leofang): support JIT LTO using nvrtc.getNVVM()? # need -dlto and -arch=compute_XX else: raise RuntimeError('Unknown NVRTC compile method') except nvrtc.NVRTCError: log = nvrtc.getProgramLog(self.ptr) raise CompileException(log, self.src, self.name, options, 'nvrtc' if not runtime.is_hip else 'hiprtc') def is_valid_kernel_name(name): return re.match('^[a-zA-Z_][a-zA-Z_0-9]*$', name) is not None def compile_using_hipcc(source, options, arch, log_stream=None): # As of ROCm 3.5.0 hiprtc/hipcc can automatically pick up the # right arch without setting HCC_AMDGPU_TARGET, so we don't need # to set arch here cmd = ['hipcc', '--genco'] + list(options) with tempfile.TemporaryDirectory() as root_dir: path = os.path.join(root_dir, 'kern') in_path = path + '.cpp' out_path = path + '.hsaco' with open(in_path, 'w') as f: f.write(source) cmd += [in_path, '-o', out_path] try: output = _run_cc(cmd, root_dir, 'hipcc', log_stream) except HIPCCException as e: cex = CompileException(str(e), source, in_path, options, 'hipcc') dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: cex.dump(sys.stderr) raise cex if not os.path.isfile(out_path): raise HIPCCException( '`hipcc` command does not generate output file. \n' 'command: {0}\n' 'stdout/stderr: \n' '{1}'.format(cmd, output)) with open(out_path, 'rb') as f: return f.read() # TODO(leofang): consider merge _preprocess_hipcc with _preprocess_hiprtc, # perhaps also with _preprocess? def _preprocess_hipcc(source, options): cmd = ['hipcc', '--preprocess'] + list(options) with tempfile.TemporaryDirectory() as root_dir: path = os.path.join(root_dir, 'kern') cu_path = '%s.cpp' % path with open(cu_path, 'w') as cu_file: cu_file.write(source) cmd.append(cu_path) pp_src = _run_cc(cmd, root_dir, 'hipcc') assert isinstance(pp_src, str) return re.sub('(?m)^#.*$', '', pp_src) def _preprocess_hiprtc(source, options): # source is ignored if _cuda_hip_version >= 40400000: # HIP runtime headers can be no longer explicitly included on ROCm 4.5+ code = ''' // hiprtc segfaults if the input code is empty __global__ void _cupy_preprocess_dummy_kernel_() { } ''' else: code = ''' // hiprtc segfaults if the input code is empty #include __global__ void _cupy_preprocess_dummy_kernel_() { } ''' prog = _NVRTCProgram(code) try: result, _ = prog.compile(options) except CompileException as e: dump = _get_bool_env_variable( 'CUPY_DUMP_CUDA_SOURCE_ON_ERROR', False) if dump: e.dump(sys.stderr) raise assert isinstance(result, bytes) return result _hip_extra_source = None def _convert_to_hip_source(source, extra_source, is_hiprtc): if not is_hiprtc: return '#include \n' + source if _cuda_hip_version >= 40400000: # HIP runtime headers can be no longer explicitly included on ROCm 4.5+ return source if _cuda_hip_version >= 402: # "-I" is fixed on ROCm 4.2.0+ return '#include \n' + source # Workaround for hiprtc: it does not follow the -I option to search # headers (as of ROCm 3.5.0), so we must prepend all CuPy's headers global _hip_extra_source if _hip_extra_source is None: if extra_source is not None: extra_source = extra_source.split('\n') extra_source = [line for line in extra_source if ( not line.startswith('#include') and not line.startswith('#pragma once'))] _hip_extra_source = extra_source = '\n'.join(extra_source) source = source.split('\n') source = [line for line in source if not line.startswith('#include')] source = ('#include \n#include \n' + _hip_extra_source + '\n'.join(source)) return source # TODO(leofang): evaluate if this can be merged with _compile_with_cache_cuda() def _compile_with_cache_hip(source, options, arch, cache_dir, extra_source, backend='hiprtc', name_expressions=None, log_stream=None, cache_in_memory=False, use_converter=True): global _empty_file_preprocess_cache # TODO(leofang): this might be possible but is currently undocumented if _is_cudadevrt_needed(options): raise ValueError('separate compilation is not supported in HIP') # HIP's equivalent of -ftz=true, see ROCm-Developer-Tools/HIP#2252 # Notes: # - For hipcc, this should just work, as invalid options would cause errors # See https://clang.llvm.org/docs/ClangCommandLineReference.html. # - For hiprtc, this is a no-op until the compiler options like -D and -I # are accepted, see ROCm-Developer-Tools/HIP#2182 and # ROCm-Developer-Tools/HIP#2248 options += ('-fcuda-flush-denormals-to-zero',) # Workaround ROCm 4.3 LLVM_PATH issue in hipRTC #5689 rocm_build_version = driver.get_build_version() if rocm_build_version >= 40300000 and rocm_build_version < 40500000: options += ( '-I' + get_rocm_path() + '/llvm/lib/clang/13.0.0/include/',) if cache_dir is None: cache_dir = get_cache_dir() # As of ROCm 3.5.0 hiprtc/hipcc can automatically pick up the # right arch without setting HCC_AMDGPU_TARGET, so we don't need # to tell the compiler which arch we are targeting. But, we still # need to know arch as part of the cache key: if arch is None: # On HIP, gcnArch is computed from "compute capability": # https://github.com/ROCm-Developer-Tools/HIP/blob/rocm-4.0.0/rocclr/hip_device.cpp#L202 arch = device.Device().compute_capability if use_converter: source = _convert_to_hip_source(source, extra_source, is_hiprtc=(backend == 'hiprtc')) env = (arch, options, _get_nvrtc_version(), backend) base = _empty_file_preprocess_cache.get(env, None) if base is None: # This is for checking HIPRTC/HIPCC compiler internal version if backend == 'hiprtc': base = _preprocess_hiprtc('', options) else: base = _preprocess_hipcc('', options) _empty_file_preprocess_cache[env] = base key_src = '%s %s %s %s' % (env, base, source, extra_source) key_src = key_src.encode('utf-8') name = _hash_hexdigest(key_src) + '.hsaco' mod = function.Module() if not cache_in_memory: # Read from disk cache if not os.path.isdir(cache_dir): os.makedirs(cache_dir, exist_ok=True) # To handle conflicts in concurrent situation, we adopt lock-free # method to avoid performance degradation. # We force recompiling to retrieve C++ mangled names if so desired. path = os.path.join(cache_dir, name) if os.path.exists(path) and not name_expressions: with open(path, 'rb') as f: data = f.read() if len(data) >= _hash_length: hash_value = data[:_hash_length] binary = data[_hash_length:] binary_hash = _hash_hexdigest(binary).encode('ascii') if hash_value == binary_hash: mod.load(binary) return mod else: # Enforce compiling -- the resulting kernel will be cached elsewhere, # so we do nothing pass if backend == 'hiprtc': # compile_using_nvrtc calls hiprtc for hip builds binary, mapping = compile_using_nvrtc( source, options, arch, name + '.cu', name_expressions, log_stream, cache_in_memory) mod._set_mapping(mapping) else: binary = compile_using_hipcc(source, options, arch, log_stream) if not cache_in_memory: # Write to disk cache binary_hash = _hash_hexdigest(binary).encode('ascii') # shutil.move is not atomic operation, so it could result in a # corrupted file. We detect it by appending a hash at the beginning # of each cache file. If the file is corrupted, it will be ignored # next time it is read. with tempfile.NamedTemporaryFile(dir=cache_dir, delete=False) as tf: tf.write(binary_hash) tf.write(binary) temp_path = tf.name shutil.move(temp_path, path) # Save .cu source file along with .hsaco if _get_bool_env_variable('CUPY_CACHE_SAVE_CUDA_SOURCE', False): with open(path + '.cpp', 'w') as f: f.write(source) else: # we don't do any disk I/O pass mod.load(binary) return mod