/* Copyright (c) 2014-2015 Intel Corporation. All Rights Reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Intel Corporation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #if defined(LINUX) || defined(FREEBSD) #include #endif #include "offload_myo_host.h" #include #include #include "offload_host.h" //#include "offload_util.h" #define MYO_VERSION1 "MYO_1.0" extern "C" void __cilkrts_cilk_for_32(void*, void*, uint32_t, int32_t); extern "C" void __cilkrts_cilk_for_64(void*, void*, uint64_t, int32_t); #ifndef TARGET_WINNT #pragma weak __cilkrts_cilk_for_32 #pragma weak __cilkrts_cilk_for_64 #endif // TARGET_WINNT static void __offload_myoProcessDeferredTables(); class MyoWrapper { public: MyoWrapper() : m_lib_handle(0), m_is_available(false) {} bool is_available() const { return m_is_available; } bool LoadLibrary(void); // unloads the library void UnloadLibrary(void) { // if (m_lib_handle != 0) { // DL_close(m_lib_handle); // m_lib_handle = 0; // } } // Wrappers for MYO client functions void LibInit(void *arg, void *func) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myoinit, "%s(%p, %p)\n", __func__, arg, func); CheckResult(__func__, m_lib_init(arg, func)); } void LibFini(void) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myofini, "%s()\n", __func__); m_lib_fini(); } void* SharedMalloc(size_t size) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedmalloc, "%s(%lld)\n", __func__, size); return m_shared_malloc(size); } void SharedFree(void *ptr) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedfree, "%s(%p)\n", __func__, ptr); m_shared_free(ptr); } void* SharedAlignedMalloc(size_t size, size_t align) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedalignedmalloc, "%s(%lld, %lld)\n", __func__, size, align); return m_shared_aligned_malloc(size, align); } void SharedAlignedFree(void *ptr) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedalignedfree, "%s(%p)\n", __func__, ptr); m_shared_aligned_free(ptr); } void Acquire(void) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myoacquire, "%s()\n", __func__); CheckResult(__func__, m_acquire()); } void Release(void) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myorelease, "%s()\n", __func__); CheckResult(__func__, m_release()); } void HostVarTablePropagate(void *table, int num_entries) const { OFFLOAD_DEBUG_TRACE(4, "%s(%p, %d)\n", __func__, table, num_entries); CheckResult(__func__, m_host_var_table_propagate(table, num_entries)); } void HostFptrTableRegister(void *table, int num_entries, int ordered) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myoregister, "%s(%p, %d, %d)\n", __func__, table, num_entries, ordered); CheckResult(__func__, m_host_fptr_table_register(table, num_entries, ordered)); } void RemoteThunkCall(void *thunk, void *args, int device) { OFFLOAD_DEBUG_TRACE(4, "%s(%p, %p, %d)\n", __func__, thunk, args, device); CheckResult(__func__, m_remote_thunk_call(thunk, args, device)); } MyoiRFuncCallHandle RemoteCall(const char *func, void *args, int device) const { OFFLOAD_DEBUG_TRACE(4, "%s(%s, %p, %d)\n", __func__, func, args, device); return m_remote_call(func, args, device); } void GetResult(MyoiRFuncCallHandle handle) const { OFFLOAD_DEBUG_TRACE(4, "%s(%p)\n", __func__, handle); CheckResult(__func__, m_get_result(handle)); } bool PostInitFuncSupported() const { OFFLOAD_DEBUG_TRACE(4, "%s()\n", __func__); if (m_feature_available) { return m_feature_available(MYO_FEATURE_POST_LIB_INIT) == MYO_SUCCESS; } else { return false; } } void CreateVtableArena(); MyoArena GetVtableArena()const { return m_vtable_arena; } void ArenaCreate( MyoOwnershipType ownership, int consistency, MyoArena* arena ) const { OFFLOAD_DEBUG_TRACE(4, "%s(%d, %d, %p)\n", __func__, ownership, consistency, arena); CheckResult(__func__, m_arena_create(ownership, consistency, arena)); } void* SharedAlignedArenaMalloc( MyoArena arena, size_t size, size_t align ) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedalignedarenamalloc, "%s(%u, %lld, %lld)\n", __func__, arena, size, align); return m_arena_aligned_malloc(arena, size, align); } void* SharedAlignedArenaFree( MyoArena arena, void* ptr ) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myosharedalignedarenafree, "%s(%u, %p)\n", __func__, arena, ptr); return m_arena_aligned_free(arena, ptr); } void ArenaAcquire( MyoArena arena ) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myoarenaacquire, "%s()\n", __func__); CheckResult(__func__, m_arena_acquire(arena)); } void ArenaRelease( MyoArena arena ) const { OFFLOAD_DEBUG_TRACE_1(4, 0, c_offload_myoarenarelease, "%s()\n", __func__); CheckResult(__func__, m_arena_release(arena)); } private: void CheckResult(const char *func, MyoError error) const { if (error != MYO_SUCCESS) { LIBOFFLOAD_ERROR(c_myowrapper_checkresult, func, error); exit(1); } } private: void* m_lib_handle; bool m_is_available; int m_post_init_func; MyoArena m_vtable_arena; // pointers to functions from myo library MyoError (*m_lib_init)(void*, void*); void (*m_lib_fini)(void); void* (*m_shared_malloc)(size_t); void (*m_shared_free)(void*); void* (*m_shared_aligned_malloc)(size_t, size_t); void (*m_shared_aligned_free)(void*); MyoError (*m_acquire)(void); MyoError (*m_release)(void); MyoError (*m_host_var_table_propagate)(void*, int); MyoError (*m_host_fptr_table_register)(void*, int, int); MyoError (*m_remote_thunk_call)(void*, void*, int); MyoiRFuncCallHandle (*m_remote_call)(const char*, void*, int); MyoError (*m_get_result)(MyoiRFuncCallHandle); MyoError (*m_arena_create)(MyoOwnershipType, int, MyoArena*); void* (*m_arena_aligned_malloc)(MyoArena, size_t, size_t); void* (*m_arena_aligned_free)(MyoArena, void*); MyoError (*m_arena_acquire)(MyoArena); MyoError (*m_arena_release)(MyoArena); // Placeholder until MYO headers support enum type for feature MyoError (*m_feature_available)(int feature); }; DLL_LOCAL bool MyoWrapper::LoadLibrary(void) { #ifndef TARGET_WINNT const char *lib_name = "libmyo-client.so"; #else // TARGET_WINNT const char *lib_name = "myo-client.dll"; #endif // TARGET_WINNT OFFLOAD_DEBUG_TRACE(2, "Loading MYO library %s ...\n", lib_name); m_lib_handle = DL_open(lib_name); if (m_lib_handle == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to load the library. errno = %d\n", errno); return false; } m_lib_init = (MyoError (*)(void*, void*)) DL_sym(m_lib_handle, "myoiLibInit", MYO_VERSION1); if (m_lib_init == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiLibInit"); UnloadLibrary(); return false; } m_lib_fini = (void (*)(void)) DL_sym(m_lib_handle, "myoiLibFini", MYO_VERSION1); if (m_lib_fini == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiLibFini"); UnloadLibrary(); return false; } m_shared_malloc = (void* (*)(size_t)) DL_sym(m_lib_handle, "myoSharedMalloc", MYO_VERSION1); if (m_shared_malloc == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoSharedMalloc"); UnloadLibrary(); return false; } m_shared_free = (void (*)(void*)) DL_sym(m_lib_handle, "myoSharedFree", MYO_VERSION1); if (m_shared_free == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoSharedFree"); UnloadLibrary(); return false; } m_shared_aligned_malloc = (void* (*)(size_t, size_t)) DL_sym(m_lib_handle, "myoSharedAlignedMalloc", MYO_VERSION1); if (m_shared_aligned_malloc == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoSharedAlignedMalloc"); UnloadLibrary(); return false; } m_shared_aligned_free = (void (*)(void*)) DL_sym(m_lib_handle, "myoSharedAlignedFree", MYO_VERSION1); if (m_shared_aligned_free == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoSharedAlignedFree"); UnloadLibrary(); return false; } m_acquire = (MyoError (*)(void)) DL_sym(m_lib_handle, "myoAcquire", MYO_VERSION1); if (m_acquire == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoAcquire"); UnloadLibrary(); return false; } m_release = (MyoError (*)(void)) DL_sym(m_lib_handle, "myoRelease", MYO_VERSION1); if (m_release == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoRelease"); UnloadLibrary(); return false; } m_host_var_table_propagate = (MyoError (*)(void*, int)) DL_sym(m_lib_handle, "myoiHostVarTablePropagate", MYO_VERSION1); if (m_host_var_table_propagate == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiHostVarTablePropagate"); UnloadLibrary(); return false; } m_host_fptr_table_register = (MyoError (*)(void*, int, int)) DL_sym(m_lib_handle, "myoiHostFptrTableRegister", MYO_VERSION1); if (m_host_fptr_table_register == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiHostFptrTableRegister"); UnloadLibrary(); return false; } m_remote_thunk_call = (MyoError (*)(void*, void*, int)) DL_sym(m_lib_handle, "myoiRemoteThunkCall", MYO_VERSION1); if (m_remote_thunk_call == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiRemoteThunkCall"); UnloadLibrary(); return false; } m_remote_call = (MyoiRFuncCallHandle (*)(const char*, void*, int)) DL_sym(m_lib_handle, "myoiRemoteCall", MYO_VERSION1); if (m_remote_call == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiRemoteCall"); UnloadLibrary(); return false; } m_get_result = (MyoError (*)(MyoiRFuncCallHandle)) DL_sym(m_lib_handle, "myoiGetResult", MYO_VERSION1); if (m_get_result == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiGetResult"); UnloadLibrary(); return false; } m_arena_create = (MyoError (*)(MyoOwnershipType, int, MyoArena*)) DL_sym(m_lib_handle, "myoArenaCreate", MYO_VERSION1); if (m_arena_create == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoArenaCreate"); UnloadLibrary(); return false; } m_arena_aligned_malloc = (void* (*)(MyoArena, size_t, size_t)) DL_sym(m_lib_handle, "myoArenaAlignedMalloc", MYO_VERSION1); if (m_arena_aligned_malloc == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoArenaAlignedMalloc"); UnloadLibrary(); return false; } m_arena_aligned_free = (void* (*)(MyoArena, void*)) DL_sym(m_lib_handle, "myoArenaAlignedFree", MYO_VERSION1); if (m_arena_aligned_free == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoArenaAlignedFree"); UnloadLibrary(); return false; } m_arena_acquire = (MyoError (*)(MyoArena)) DL_sym(m_lib_handle, "myoArenaAcquire", MYO_VERSION1); if (m_acquire == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoArenaAcquire"); UnloadLibrary(); return false; } m_arena_release = (MyoError (*)(MyoArena)) DL_sym(m_lib_handle, "myoArenaRelease", MYO_VERSION1); if (m_release == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoArenaRelease"); UnloadLibrary(); return false; } // Check for "feature-available" API added in MPSS 3.3. // Not finding it is not an error. m_feature_available = (MyoError (*)(int)) DL_sym(m_lib_handle, "myoiSupportsFeature", MYO_VERSION1); if (m_feature_available == 0) { OFFLOAD_DEBUG_TRACE(2, "Failed to find %s in MYO library\n", "myoiSupportsFeature"); } OFFLOAD_DEBUG_TRACE(2, "The library was successfully loaded\n"); // Create arena if supported CreateVtableArena(); OFFLOAD_DEBUG_TRACE(3, "Vtable arena created\n"); m_is_available = true; return true; } static bool myo_is_available; static MyoWrapper myo_wrapper; void MyoWrapper::CreateVtableArena() { MyoArena* vtable_arena; // Check if this MYO supports arenas for vtables if (myo_wrapper.PostInitFuncSupported()) { // Create arena for vtables vtable_arena = (MyoArena *)myo_wrapper.SharedMalloc(sizeof(MyoArena)); myo_wrapper.ArenaCreate( MYO_ARENA_OURS, MYO_NO_CONSISTENCY, vtable_arena); m_vtable_arena = *vtable_arena; OFFLOAD_DEBUG_TRACE(4, "created arena = %d\n", m_vtable_arena); } else { m_vtable_arena = 0; } } struct MyoTable { MyoTable(SharedTableEntry *tab, int len) : var_tab(tab), var_tab_len(len) {} SharedTableEntry* var_tab; int var_tab_len; }; typedef std::list MyoTableList; static MyoTableList __myo_table_list; static mutex_t __myo_table_lock; static bool __myo_tables = false; static void __offload_myo_shared_vtable_process(SharedTableEntry *entry); static void __offload_myo_shared_table_process(SharedTableEntry *entry); static void __offload_myo_shared_init_table_process(InitTableEntry* entry); static void __offload_myo_fptr_table_process(FptrTableEntry *entry); static void __offload_propagate_shared_vars(); static void __offload_myoLoadLibrary_once(void) { if (__offload_init_library()) { myo_wrapper.LoadLibrary(); } } static bool __offload_myoLoadLibrary(void) { OFFLOAD_DEBUG_TRACE(4, "__offload_myoLoadLibrary\n"); static OffloadOnceControl ctrl = OFFLOAD_ONCE_CONTROL_INIT; __offload_run_once(&ctrl, __offload_myoLoadLibrary_once); return myo_wrapper.is_available(); } static void __offload_myoInit_once(void) { if (!__offload_myoLoadLibrary()) { return; } // initialize all devices for (int i = 0; i < mic_engines_total; i++) { mic_engines[i].init(); } // load and initialize MYO library OFFLOAD_DEBUG_TRACE(2, "Initializing MYO library ...\n"); COIEVENT events[MIC_ENGINES_MAX]; // One entry per device + // A pair of entries for the Host postInit func + // A pair of entries for the MIC postInit func + // end marker MyoiUserParams params[MIC_ENGINES_MAX+5]; // Load target library to all devices and // create libinit parameters for all devices for (int i = 0; i < mic_engines_total; i++) { mic_engines[i].init_myo(&events[i]); params[i].type = MYOI_USERPARAMS_DEVID; params[i].nodeid = mic_engines[i].get_physical_index() + 1; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %d, %d }\n", i, params[i].type, params[i].nodeid); } // Check if V2 myoLibInit is available if (myo_wrapper.PostInitFuncSupported()) { // Set the host post libInit function indicator params[mic_engines_total].type = MYOI_USERPARAMS_POST_MYO_LIB_INIT_FUNC; params[mic_engines_total].nodeid = MYOI_USERPARAMS_POST_MYO_LIB_INIT_FUNC_HOST_NODE; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %d, %d }\n", mic_engines_total, params[mic_engines_total].type, params[mic_engines_total].nodeid); // Set the host post libInit host function address ((MyoiUserParamsPostLibInit*)(¶ms[mic_engines_total+1]))-> postLibInitHostFuncAddress = (void (*)())&__offload_propagate_shared_vars; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %p }\n", mic_engines_total+1, ((MyoiUserParamsPostLibInit*)(¶ms[mic_engines_total+1]))-> postLibInitHostFuncAddress); // Set the target post libInit function indicator params[mic_engines_total+2].type = MYOI_USERPARAMS_POST_MYO_LIB_INIT_FUNC; params[mic_engines_total+2].nodeid = MYOI_USERPARAMS_POST_MYO_LIB_INIT_FUNC_ALL_NODES; // Set the target post libInit target function name ((MyoiUserParamsPostLibInit*)(¶ms[mic_engines_total+3]))-> postLibInitRemoveFuncName = "--vtable_initializer--"; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %s }\n", mic_engines_total+3, ((MyoiUserParamsPostLibInit*)(¶ms[mic_engines_total+1]))-> postLibInitRemoveFuncName); params[mic_engines_total+4].type = MYOI_USERPARAMS_LAST_MSG; params[mic_engines_total+4].nodeid = 0; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %d, %d }\n", mic_engines_total+4, params[mic_engines_total+4].type, params[mic_engines_total+4].nodeid); } else { params[mic_engines_total].type = MYOI_USERPARAMS_LAST_MSG; params[mic_engines_total].nodeid = 0; OFFLOAD_DEBUG_TRACE(2, "params[%d] = { %d, %d }\n", mic_engines_total, params[mic_engines_total].type, params[mic_engines_total].nodeid); } // initialize myo runtime on host myo_wrapper.LibInit(params, 0); // wait for the target init calls to finish COIRESULT res; res = COI::EventWait(mic_engines_total, events, -1, 1, 0, 0); if (res != COI_SUCCESS) { LIBOFFLOAD_ERROR(c_event_wait, res); exit(1); } myo_is_available = true; OFFLOAD_DEBUG_TRACE(2, "setting myo_is_available=%d\n", myo_is_available); OFFLOAD_DEBUG_TRACE(2, "Initializing MYO library ... done\n"); } static bool __offload_myoInit(void) { static OffloadOnceControl ctrl = OFFLOAD_ONCE_CONTROL_INIT; __offload_run_once(&ctrl, __offload_myoInit_once); // Check if using V1 myoLibInit if (!myo_wrapper.PostInitFuncSupported()) { __offload_propagate_shared_vars(); } return myo_is_available; } static void __offload_propagate_shared_vars() { // Propagate pending shared var tables if (__myo_tables) { mutex_locker_t locker(__myo_table_lock); if (__myo_tables) { // Give tables with MYO so it can propagate to target for(MyoTableList::const_iterator it = __myo_table_list.begin(); it != __myo_table_list.end(); ++it) { #ifdef TARGET_WINNT for (SharedTableEntry *entry = it->var_tab; entry->varName != MYO_TABLE_END_MARKER(); entry++) { if (entry->varName == 0) { continue; } myo_wrapper.HostVarTablePropagate(entry, 1); OFFLOAD_DEBUG_TRACE(2, "HostVarTablePropagate(%s, 1)\n", entry->varName); } #else // TARGET_WINNT myo_wrapper.HostVarTablePropagate(it->var_tab, it->var_tab_len); #endif // TARGET_WINNT } __myo_table_list.clear(); __myo_tables = false; } } } static bool shared_table_entries( SharedTableEntry *entry ) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); for (; entry->varName != MYO_TABLE_END_MARKER(); entry++) { #ifdef TARGET_WINNT if (entry->varName == 0) { continue; } #endif // TARGET_WINNT return true; } return false; } static bool fptr_table_entries( FptrTableEntry *entry ) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); for (; entry->funcName != MYO_TABLE_END_MARKER(); entry++) { #ifdef TARGET_WINNT if (entry->funcName == 0) { continue; } #endif // TARGET_WINNT return true; } return false; } extern "C" void __offload_myoRegisterTables( InitTableEntry* init_table, SharedTableEntry *shared_table, FptrTableEntry *fptr_table ) { // check whether we need to initialize MYO library. It is // initialized only if at least one myo table is not empty if (shared_table_entries(shared_table) || fptr_table_entries(fptr_table)) { // make sure myo library is loaded __offload_myoLoadLibrary(); // register tables __offload_myo_shared_table_process(shared_table); __offload_myo_fptr_table_process(fptr_table); __offload_myo_shared_init_table_process(init_table); } } extern "C" bool __offload_myoProcessTables( const void* image, MYOInitTableList::Node *init_table, MYOVarTableList::Node *shared_table, MYOVarTableList::Node *shared_vtable, MYOFuncTableList::Node *fptr_table ) { OFFLOAD_DEBUG_TRACE(3, "%s\n", __func__); // Collect the tables in this .dll/.so __offload_myoRegisterTables1( init_table, shared_table, shared_vtable, fptr_table); // Now check what type of module we are dealing with if (__offload_target_image_is_executable(image)) { OFFLOAD_DEBUG_TRACE(2, "Main encountered\n"); OFFLOAD_DEBUG_TRACE(2, "MYO initialization not deferred\n"); // MYO tables across dlls have been collected // Now init MYO and process the tables __offload_myoProcessDeferredTables(); // Return true to indicate that atexit needs to be calld by ofldbegin return true; } else { // This is a shared library, either auto-loaded or dynamically loaded // If __target_exe is set, then main has started running if (__target_exe != 0) { // Main is running: this is a dynamic load of a shared library // Finish processing the tables in this library OFFLOAD_DEBUG_TRACE(2, "Dynamically loaded shared library encountered\n"); OFFLOAD_DEBUG_TRACE(2, "MYO initialization not deferred\n"); __offload_myoProcessDeferredTables(); } else { // Main is not running: this is an auto-loaded shared library // Tables have been collected, nothing else to do OFFLOAD_DEBUG_TRACE(2, "Auto-loaded shared library encountered\n"); OFFLOAD_DEBUG_TRACE(2, "Deferring initialization of MYO\n"); } return false; } } // Process contents of all Var tables void MYOVarTableList::process() { OFFLOAD_DEBUG_TRACE(2, "Process MYO Var tables:\n"); m_lock.lock(); for (Node *n = m_head; n != 0; n = n->next) { __offload_myo_shared_table_process( (SharedTableEntry*)n->table.entries); } for (Node *n = m_head; n != 0; n = n->next) { remove_table(n); } m_lock.unlock(); } // Process contents of all Var tables void MYOVarTableList::process_vtable() { OFFLOAD_DEBUG_TRACE(2, "Process MYO Vtable tables:\n"); m_lock.lock(); for (Node *n = m_head; n != 0; n = n->next) { __offload_myo_shared_vtable_process( (SharedTableEntry*)n->table.entries); } for (Node *n = m_head; n != 0; n = n->next) { remove_table(n); } m_lock.unlock(); } // Process contents of all Func tables void MYOFuncTableList::process() { OFFLOAD_DEBUG_TRACE(2, "Process MYO Func tables:\n"); m_lock.lock(); for (Node *n = m_head; n != 0; n = n->next) { __offload_myo_fptr_table_process( (FptrTableEntry*)n->table.entries); } for (Node *n = m_head; n != 0; n = n->next) { remove_table(n); } m_lock.unlock(); } // Process contents of all Init tables void MYOInitTableList::process() { OFFLOAD_DEBUG_TRACE(2, "Process MYO Init tables:\n"); m_lock.lock(); for (Node *n = m_head; n != 0; n = n->next) { __offload_myo_shared_init_table_process( (InitTableEntry*)n->table.entries); } for (Node *n = m_head; n != 0; n = n->next) { remove_table(n); } m_lock.unlock(); } static void __offload_myoProcessDeferredTables() { OFFLOAD_DEBUG_TRACE(3, "%s()\n", __func__); // Debug dumps of MYO tables if (console_enabled >= 2) { __offload_myo_var_tables.dump(); __offload_myo_vtable_tables.dump(); __offload_myo_func_tables.dump(); __offload_myo_init_tables.dump(); } if (!__offload_myo_var_tables.is_empty() || !__offload_myo_vtable_tables.is_empty() || !__offload_myo_func_tables.is_empty() || !__offload_myo_init_tables.is_empty()) { OFFLOAD_DEBUG_TRACE(3, "MYO usage detected in program\n"); // Make sure myo library is loaded __offload_myoLoadLibrary(); OFFLOAD_DEBUG_TRACE(3, "Initialized MYO\n"); __offload_myo_var_tables.process(); __offload_myo_vtable_tables.process_vtable(); __offload_myo_func_tables.process(); __offload_myo_init_tables.process(); OFFLOAD_DEBUG_TRACE(3, "Finished processing MYO tables\n"); } else { OFFLOAD_DEBUG_TRACE(3, "MYO tables are empty; Will not initialize MYO\n"); } } DLL_LOCAL void __offload_myoFini(void) { if (myo_is_available) { OFFLOAD_DEBUG_TRACE(3, "%s\n", __func__); COIEVENT events[MIC_ENGINES_MAX]; // kick off myoiLibFini calls on all devices for (int i = 0; i < mic_engines_total; i++) { mic_engines[i].fini_myo(&events[i]); } // cleanup myo runtime on host myo_wrapper.LibFini(); // wait for the target fini calls to finish COIRESULT res; res = COI::EventWait(mic_engines_total, events, -1, 1, 0, 0); if (res != COI_SUCCESS) { LIBOFFLOAD_ERROR(c_event_wait, res); exit(1); } } } static void __offload_myo_shared_table_process( SharedTableEntry *entry ) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); SharedTableEntry *start = entry; int entries = 0; // allocate shared memory for vars for (; entry->varName != MYO_TABLE_END_MARKER(); entry++) { #ifdef TARGET_WINNT if (entry->varName == 0) { OFFLOAD_DEBUG_TRACE(4, "skip registering a NULL MyoSharedTable entry\n"); continue; } #endif // TARGET_WINNT OFFLOAD_DEBUG_TRACE(4, "registering MyoSharedTable entry for %s @%p\n", entry->varName, entry); // Invoke the function to create shared memory reinterpret_cast(entry->sharedAddr)(); entries++; } // and table to the list if it is not empty if (entries > 0) { mutex_locker_t locker(__myo_table_lock); __myo_table_list.push_back(MyoTable(start, entries)); __myo_tables = true; } } static void __offload_myo_shared_vtable_process( SharedTableEntry *entry ) { SharedTableEntry *start = entry; int entries = 0; OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); // allocate shared memory for vtables for (; entry->varName != MYO_TABLE_END_MARKER(); entry++) { #ifdef TARGET_WINNT if (entry->varName == 0) { OFFLOAD_DEBUG_TRACE(4, "skip registering a NULL MyoSharedVTable entry\n"); continue; } #endif // TARGET_WINNT OFFLOAD_DEBUG_TRACE(4, "registering MyoSharedVTable entry for %s @%p\n", entry->varName, entry); // Invoke the function to create shared memory reinterpret_cast(entry->sharedAddr)( myo_wrapper.GetVtableArena()); entries++; } // add table to the list if it is not empty if (entries > 0) { mutex_locker_t locker(__myo_table_lock); __myo_table_list.push_back(MyoTable(start, entries)); __myo_tables = true; } } void __offload_myo_shared_init_table_process(InitTableEntry* entry) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); #ifdef TARGET_WINNT for (; entry->funcName != MYO_TABLE_END_MARKER(); entry++) { if (entry->funcName == 0) { OFFLOAD_DEBUG_TRACE(4, "skip registering a NULL MyoSharedInit entry\n"); continue; } // Invoke the function to init the shared memory OFFLOAD_DEBUG_TRACE(4, "execute MyoSharedInit routine for %s\n", entry->funcName); entry->func(myo_wrapper.GetVtableArena()); } #else // TARGET_WINNT for (; entry->func != 0; entry++) { // Invoke the function to init the shared memory entry->func(myo_wrapper.GetVtableArena()); } #endif // TARGET_WINNT } static void __offload_myo_fptr_table_process( FptrTableEntry *entry ) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, entry); FptrTableEntry *start = entry; int entries = 0; for (; entry->funcName != MYO_TABLE_END_MARKER(); entry++) { #ifdef TARGET_WINNT if (entry->funcName == 0) { OFFLOAD_DEBUG_TRACE(4, "skip registering a NULL MyoFptrTable entry\n"); continue; } #endif // TARGET_WINNT if (!myo_wrapper.is_available()) { *(static_cast(entry->localThunkAddr)) = entry->funcAddr; } OFFLOAD_DEBUG_TRACE(4, "registering MyoFptrTable entry for %s @%p\n", entry->funcName, entry); #ifdef TARGET_WINNT if (myo_wrapper.is_available()) { myo_wrapper.HostFptrTableRegister(entry, 1, false); } #endif // TARGET_WINNT entries++; } #ifndef TARGET_WINNT if (myo_wrapper.is_available() && entries > 0) { myo_wrapper.HostFptrTableRegister(start, entries, false); } #endif // TARGET_WINNT } extern "C" int __offload_myoIsAvailable(int target_number) { OFFLOAD_DEBUG_TRACE(3, "%s(%d)\n", __func__, target_number); if (target_number >= -2) { bool is_default_number = (target_number == -2); if (__offload_myoInit()) { if (target_number >= 0) { // User provided the device number int num = target_number % mic_engines_total; // reserve device in ORSL target_number = ORSL::reserve(num) ? num : -1; } else { // try to use device 0 target_number = ORSL::reserve(0) ? 0 : -1; } // make sure device is initialized if (target_number >= 0) { mic_engines[target_number].init(); } } else { // fallback to CPU target_number = -1; } if (target_number < 0 && !is_default_number) { LIBOFFLOAD_ERROR(c_device_is_not_available); exit(1); } } else { LIBOFFLOAD_ERROR(c_invalid_device_number); exit(1); } return target_number; } extern "C" void __offload_myoiRemoteIThunkCall( void *thunk, void *arg, int target_number ) { OFFLOAD_DEBUG_TRACE(3, "%s(%p, %p, %d)\n", __func__, thunk, arg, target_number); myo_wrapper.Release(); myo_wrapper.RemoteThunkCall(thunk, arg, target_number); myo_wrapper.Acquire(); ORSL::release(target_number); } extern "C" void* _Offload_shared_malloc(size_t size) { OFFLOAD_DEBUG_TRACE(3, "%s(%lld)\n", __func__, size); if (__offload_myoLoadLibrary()) { return myo_wrapper.SharedMalloc(size); } else { return malloc(size); } } extern "C" void _Offload_shared_free(void *ptr) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, ptr); if (__offload_myoLoadLibrary()) { myo_wrapper.SharedFree(ptr); } else { free(ptr); } } extern "C" void* _Offload_shared_aligned_malloc(size_t size, size_t align) { OFFLOAD_DEBUG_TRACE(3, "%s(%lld, %lld)\n", __func__, size, align); if (__offload_myoLoadLibrary()) { return myo_wrapper.SharedAlignedMalloc(size, align); } else { if (align < sizeof(void*)) { align = sizeof(void*); } return _mm_malloc(size, align); } } extern "C" void _Offload_shared_aligned_free(void *ptr) { OFFLOAD_DEBUG_TRACE(3, "%s(%p)\n", __func__, ptr); if (__offload_myoLoadLibrary()) { myo_wrapper.SharedAlignedFree(ptr); } else { _mm_free(ptr); } } extern "C" void _Offload_shared_arena_create( MyoOwnershipType ownership, int consistency, MyoArena* arena ) { OFFLOAD_DEBUG_TRACE(3, "%s(%d, %d, %p)\n", __func__, ownership, consistency, arena); if (__offload_myoLoadLibrary()) { myo_wrapper.ArenaCreate(ownership, consistency, arena); } } extern "C" void* _Offload_shared_aligned_arena_malloc( MyoArena arena, size_t size, size_t align ) { OFFLOAD_DEBUG_TRACE(3, "%s(%u, %lld, %lld)\n", __func__, arena, size, align); if (__offload_myoLoadLibrary()) { void *p = myo_wrapper.SharedAlignedArenaMalloc(arena, size, align); OFFLOAD_DEBUG_TRACE(3, "%s(%u, %lld, %lld)->%p\n", __func__, arena, size, align, p); return p; } else { if (align < sizeof(void*)) { align = sizeof(void*); } return _mm_malloc(size, align); } } extern "C" void _Offload_shared_aligned_arena_free( MyoArena arena, void *ptr ) { OFFLOAD_DEBUG_TRACE(3, "%s(%u, %p)\n", __func__, arena, ptr); if (__offload_myoLoadLibrary()) { myo_wrapper.SharedAlignedArenaFree(arena, ptr); } else { _mm_free(ptr); } } extern "C" void _Offload_shared_arena_acquire( MyoArena arena ) { OFFLOAD_DEBUG_TRACE(3, "%s(%u)\n", __func__, arena); if (__offload_myoLoadLibrary()) { myo_wrapper.ArenaAcquire(arena); } } extern "C" void _Offload_shared_arena_release( MyoArena arena ) { OFFLOAD_DEBUG_TRACE(3, "%s(%u)\n", __func__, arena); if (__offload_myoLoadLibrary()) { myo_wrapper.ArenaRelease(arena); } } extern "C" void __intel_cilk_for_32_offload( int size, void (*copy_constructor)(void*, void*), int target_number, void *raddr, void *closure_object, unsigned int iters, unsigned int grain_size) { OFFLOAD_DEBUG_TRACE(3, "%s\n", __func__); target_number = __offload_myoIsAvailable(target_number); if (target_number >= 0) { struct S { void *M1; unsigned int M2; unsigned int M3; char closure[]; } *args; args = (struct S*) _Offload_shared_malloc(sizeof(struct S) + size); if (args == NULL) LIBOFFLOAD_ERROR(c_malloc); args->M1 = raddr; args->M2 = iters; args->M3 = grain_size; if (copy_constructor == 0) { memcpy(args->closure, closure_object, size); } else { copy_constructor(args->closure, closure_object); } myo_wrapper.Release(); myo_wrapper.GetResult( myo_wrapper.RemoteCall("__intel_cilk_for_32_offload", args, target_number) ); myo_wrapper.Acquire(); _Offload_shared_free(args); ORSL::release(target_number); } else { __cilkrts_cilk_for_32(raddr, closure_object, iters, grain_size); } } extern "C" void __intel_cilk_for_64_offload( int size, void (*copy_constructor)(void*, void*), int target_number, void *raddr, void *closure_object, uint64_t iters, uint64_t grain_size) { OFFLOAD_DEBUG_TRACE(3, "%s\n", __func__); target_number = __offload_myoIsAvailable(target_number); if (target_number >= 0) { struct S { void *M1; uint64_t M2; uint64_t M3; char closure[]; } *args; args = (struct S*) _Offload_shared_malloc(sizeof(struct S) + size); if (args == NULL) LIBOFFLOAD_ERROR(c_malloc); args->M1 = raddr; args->M2 = iters; args->M3 = grain_size; if (copy_constructor == 0) { memcpy(args->closure, closure_object, size); } else { copy_constructor(args->closure, closure_object); } myo_wrapper.Release(); myo_wrapper.GetResult( myo_wrapper.RemoteCall("__intel_cilk_for_64_offload", args, target_number) ); myo_wrapper.Acquire(); _Offload_shared_free(args); ORSL::release(target_number); } else { __cilkrts_cilk_for_64(raddr, closure_object, iters, grain_size); } }