/* Copyright (c) 2014 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. */ #include "offload_engine.h" #include #include #include #include #include "offload_host.h" #include "offload_table.h" const char* Engine::m_func_names[Engine::c_funcs_total] = { "server_compute", #ifdef MYO_SUPPORT "server_myoinit", "server_myofini", #endif // MYO_SUPPORT "server_init", "server_var_table_size", "server_var_table_copy" }; // Symbolic representation of system signals. Fix for CQ233593 const char* Engine::c_signal_names[Engine::c_signal_max] = { "Unknown SIGNAL", "SIGHUP", /* 1, Hangup (POSIX). */ "SIGINT", /* 2, Interrupt (ANSI). */ "SIGQUIT", /* 3, Quit (POSIX). */ "SIGILL", /* 4, Illegal instruction (ANSI). */ "SIGTRAP", /* 5, Trace trap (POSIX). */ "SIGABRT", /* 6, Abort (ANSI). */ "SIGBUS", /* 7, BUS error (4.2 BSD). */ "SIGFPE", /* 8, Floating-point exception (ANSI). */ "SIGKILL", /* 9, Kill, unblockable (POSIX). */ "SIGUSR1", /* 10, User-defined signal 1 (POSIX). */ "SIGSEGV", /* 11, Segmentation violation (ANSI). */ "SIGUSR2", /* 12, User-defined signal 2 (POSIX). */ "SIGPIPE", /* 13, Broken pipe (POSIX). */ "SIGALRM", /* 14, Alarm clock (POSIX). */ "SIGTERM", /* 15, Termination (ANSI). */ "SIGSTKFLT", /* 16, Stack fault. */ "SIGCHLD", /* 17, Child status has changed (POSIX). */ "SIGCONT", /* 18, Continue (POSIX). */ "SIGSTOP", /* 19, Stop, unblockable (POSIX). */ "SIGTSTP", /* 20, Keyboard stop (POSIX). */ "SIGTTIN", /* 21, Background read from tty (POSIX). */ "SIGTTOU", /* 22, Background write to tty (POSIX). */ "SIGURG", /* 23, Urgent condition on socket (4.2 BSD). */ "SIGXCPU", /* 24, CPU limit exceeded (4.2 BSD). */ "SIGXFSZ", /* 25, File size limit exceeded (4.2 BSD). */ "SIGVTALRM", /* 26, Virtual alarm clock (4.2 BSD). */ "SIGPROF", /* 27, Profiling alarm clock (4.2 BSD). */ "SIGWINCH", /* 28, Window size change (4.3 BSD, Sun). */ "SIGIO", /* 29, I/O now possible (4.2 BSD). */ "SIGPWR", /* 30, Power failure restart (System V). */ "SIGSYS" /* 31, Bad system call. */ }; void Engine::init(void) { if (!m_ready) { mutex_locker_t locker(m_lock); if (!m_ready) { // start process if not done yet if (m_process == 0) { init_process(); } // load penging images load_libraries(); // and (re)build pointer table init_ptr_data(); // it is ready now m_ready = true; } } } void Engine::init_process(void) { COIENGINE engine; COIRESULT res; const char **environ; // create environment for the target process environ = (const char**) mic_env_vars.create_environ_for_card(m_index); if (environ != 0) { for (const char **p = environ; *p != 0; p++) { OFFLOAD_DEBUG_TRACE(3, "Env Var for card %d: %s\n", m_index, *p); } } // Create execution context in the specified device OFFLOAD_DEBUG_TRACE(2, "Getting device %d (engine %d) handle\n", m_index, m_physical_index); res = COI::EngineGetHandle(COI_ISA_KNC, m_physical_index, &engine); check_result(res, c_get_engine_handle, m_index, res); // Target executable should be available by the time when we // attempt to initialize the device if (__target_exe == 0) { LIBOFFLOAD_ERROR(c_no_target_exe); exit(1); } OFFLOAD_DEBUG_TRACE(2, "Loading target executable \"%s\" from %p, size %lld\n", __target_exe->name, __target_exe->data, __target_exe->size); res = COI::ProcessCreateFromMemory( engine, // in_Engine __target_exe->name, // in_pBinaryName __target_exe->data, // in_pBinaryBuffer __target_exe->size, // in_BinaryBufferLength, 0, // in_Argc 0, // in_ppArgv environ == 0, // in_DupEnv environ, // in_ppAdditionalEnv mic_proxy_io, // in_ProxyActive mic_proxy_fs_root, // in_ProxyfsRoot mic_buffer_size, // in_BufferSpace mic_library_path, // in_LibrarySearchPath __target_exe->origin, // in_FileOfOrigin __target_exe->offset, // in_FileOfOriginOffset &m_process // out_pProcess ); check_result(res, c_process_create, m_index, res); // get function handles res = COI::ProcessGetFunctionHandles(m_process, c_funcs_total, m_func_names, m_funcs); check_result(res, c_process_get_func_handles, m_index, res); // initialize device side pid_t pid = init_device(); // For IDB if (__dbg_is_attached) { // TODO: we have in-memory executable now. // Check with IDB team what should we provide them now? if (strlen(__target_exe->name) < MAX_TARGET_NAME) { strcpy(__dbg_target_exe_name, __target_exe->name); } __dbg_target_so_pid = pid; __dbg_target_id = m_physical_index; __dbg_target_so_loaded(); } } void Engine::fini_process(bool verbose) { if (m_process != 0) { uint32_t sig; int8_t ret; // destroy target process OFFLOAD_DEBUG_TRACE(2, "Destroying process on the device %d\n", m_index); COIRESULT res = COI::ProcessDestroy(m_process, -1, 0, &ret, &sig); m_process = 0; if (res == COI_SUCCESS) { OFFLOAD_DEBUG_TRACE(3, "Device process: signal %d, exit code %d\n", sig, ret); if (verbose) { if (sig != 0) { LIBOFFLOAD_ERROR( c_mic_process_exit_sig, m_index, sig, c_signal_names[sig >= c_signal_max ? 0 : sig]); } else { LIBOFFLOAD_ERROR(c_mic_process_exit_ret, m_index, ret); } } // for idb if (__dbg_is_attached) { __dbg_target_so_unloaded(); } } else { if (verbose) { LIBOFFLOAD_ERROR(c_mic_process_exit, m_index); } } } } void Engine::load_libraries() { // load libraries collected so far for (TargetImageList::iterator it = m_images.begin(); it != m_images.end(); it++) { OFFLOAD_DEBUG_TRACE(2, "Loading library \"%s\" from %p, size %llu\n", it->name, it->data, it->size); // load library to the device COILIBRARY lib; COIRESULT res; res = COI::ProcessLoadLibraryFromMemory(m_process, it->data, it->size, it->name, mic_library_path, it->origin, it->offset, COI_LOADLIBRARY_V1_FLAGS, &lib); if (res != COI_SUCCESS && res != COI_ALREADY_EXISTS) { check_result(res, c_load_library, m_index, res); } } m_images.clear(); } static bool target_entry_cmp( const VarList::BufEntry &l, const VarList::BufEntry &r ) { const char *l_name = reinterpret_cast(l.name); const char *r_name = reinterpret_cast(r.name); return strcmp(l_name, r_name) < 0; } static bool host_entry_cmp( const VarTable::Entry *l, const VarTable::Entry *r ) { return strcmp(l->name, r->name) < 0; } void Engine::init_ptr_data(void) { COIRESULT res; COIEVENT event; // Prepare table of host entries std::vector host_table(__offload_vars.begin(), __offload_vars.end()); // no need to do anything further is host table is empty if (host_table.size() <= 0) { return; } // Get var table entries from the target. // First we need to get size for the buffer to copy data struct { int64_t nelems; int64_t length; } params; res = COI::PipelineRunFunction(get_pipeline(), m_funcs[c_func_var_table_size], 0, 0, 0, 0, 0, 0, 0, ¶ms, sizeof(params), &event); check_result(res, c_pipeline_run_func, m_index, res); res = COI::EventWait(1, &event, -1, 1, 0, 0); check_result(res, c_event_wait, res); if (params.length == 0) { return; } // create buffer for target entries and copy data to host COIBUFFER buffer; res = COI::BufferCreate(params.length, COI_BUFFER_NORMAL, 0, 0, 1, &m_process, &buffer); check_result(res, c_buf_create, m_index, res); COI_ACCESS_FLAGS flags = COI_SINK_WRITE; res = COI::PipelineRunFunction(get_pipeline(), m_funcs[c_func_var_table_copy], 1, &buffer, &flags, 0, 0, ¶ms.nelems, sizeof(params.nelems), 0, 0, &event); check_result(res, c_pipeline_run_func, m_index, res); res = COI::EventWait(1, &event, -1, 1, 0, 0); check_result(res, c_event_wait, res); // patch names in target data VarList::BufEntry *target_table; COIMAPINSTANCE map_inst; res = COI::BufferMap(buffer, 0, params.length, COI_MAP_READ_ONLY, 0, 0, 0, &map_inst, reinterpret_cast(&target_table)); check_result(res, c_buf_map, res); VarList::table_patch_names(target_table, params.nelems); // and sort entries std::sort(target_table, target_table + params.nelems, target_entry_cmp); std::sort(host_table.begin(), host_table.end(), host_entry_cmp); // merge host and target entries and enter matching vars map std::vector::const_iterator hi = host_table.begin(); std::vector::const_iterator he = host_table.end(); const VarList::BufEntry *ti = target_table; const VarList::BufEntry *te = target_table + params.nelems; while (hi != he && ti != te) { int res = strcmp((*hi)->name, reinterpret_cast(ti->name)); if (res == 0) { // add matching entry to var map std::pair res = m_ptr_set.insert(PtrData((*hi)->addr, (*hi)->size)); // store address for new entries if (res.second) { PtrData *ptr = const_cast(res.first.operator->()); ptr->mic_addr = ti->addr; ptr->is_static = true; } hi++; ti++; } else if (res < 0) { hi++; } else { ti++; } } // cleanup res = COI::BufferUnmap(map_inst, 0, 0, 0); check_result(res, c_buf_unmap, res); res = COI::BufferDestroy(buffer); check_result(res, c_buf_destroy, res); } COIRESULT Engine::compute( const std::list &buffers, const void* data, uint16_t data_size, void* ret, uint16_t ret_size, uint32_t num_deps, const COIEVENT* deps, COIEVENT* event ) /* const */ { COIBUFFER *bufs; COI_ACCESS_FLAGS *flags; COIRESULT res; // convert buffers list to array int num_bufs = buffers.size(); if (num_bufs > 0) { bufs = (COIBUFFER*) alloca(num_bufs * sizeof(COIBUFFER)); flags = (COI_ACCESS_FLAGS*) alloca(num_bufs * sizeof(COI_ACCESS_FLAGS)); int i = 0; for (std::list::const_iterator it = buffers.begin(); it != buffers.end(); it++) { bufs[i] = *it; // TODO: this should be fixed flags[i++] = COI_SINK_WRITE; } } else { bufs = 0; flags = 0; } // start computation res = COI::PipelineRunFunction(get_pipeline(), m_funcs[c_func_compute], num_bufs, bufs, flags, num_deps, deps, data, data_size, ret, ret_size, event); return res; } pid_t Engine::init_device(void) { struct init_data { int device_index; int devices_total; int console_level; int offload_report_level; } data; COIRESULT res; COIEVENT event; pid_t pid; OFFLOAD_DEBUG_TRACE_1(2, 0, c_offload_init, "Initializing device with logical index %d " "and physical index %d\n", m_index, m_physical_index); // setup misc data data.device_index = m_index; data.devices_total = mic_engines_total; data.console_level = console_enabled; data.offload_report_level = offload_report_level; res = COI::PipelineRunFunction(get_pipeline(), m_funcs[c_func_init], 0, 0, 0, 0, 0, &data, sizeof(data), &pid, sizeof(pid), &event); check_result(res, c_pipeline_run_func, m_index, res); res = COI::EventWait(1, &event, -1, 1, 0, 0); check_result(res, c_event_wait, res); OFFLOAD_DEBUG_TRACE(2, "Device process pid is %d\n", pid); return pid; } // data associated with each thread struct Thread { Thread(long* addr_coipipe_counter) { m_addr_coipipe_counter = addr_coipipe_counter; memset(m_pipelines, 0, sizeof(m_pipelines)); } ~Thread() { #ifndef TARGET_WINNT __sync_sub_and_fetch(m_addr_coipipe_counter, 1); #else // TARGET_WINNT _InterlockedDecrement(m_addr_coipipe_counter); #endif // TARGET_WINNT for (int i = 0; i < mic_engines_total; i++) { if (m_pipelines[i] != 0) { COI::PipelineDestroy(m_pipelines[i]); } } } COIPIPELINE get_pipeline(int index) const { return m_pipelines[index]; } void set_pipeline(int index, COIPIPELINE pipeline) { m_pipelines[index] = pipeline; } AutoSet& get_auto_vars() { return m_auto_vars; } private: long* m_addr_coipipe_counter; AutoSet m_auto_vars; COIPIPELINE m_pipelines[MIC_ENGINES_MAX]; }; COIPIPELINE Engine::get_pipeline(void) { Thread* thread = (Thread*) thread_getspecific(mic_thread_key); if (thread == 0) { thread = new Thread(&m_proc_number); thread_setspecific(mic_thread_key, thread); } COIPIPELINE pipeline = thread->get_pipeline(m_index); if (pipeline == 0) { COIRESULT res; int proc_num; #ifndef TARGET_WINNT proc_num = __sync_fetch_and_add(&m_proc_number, 1); #else // TARGET_WINNT proc_num = _InterlockedIncrement(&m_proc_number); #endif // TARGET_WINNT if (proc_num > COI_PIPELINE_MAX_PIPELINES) { LIBOFFLOAD_ERROR(c_coipipe_max_number, COI_PIPELINE_MAX_PIPELINES); LIBOFFLOAD_ABORT; } // create pipeline for this thread res = COI::PipelineCreate(m_process, 0, mic_stack_size, &pipeline); check_result(res, c_pipeline_create, m_index, res); thread->set_pipeline(m_index, pipeline); } return pipeline; } AutoSet& Engine::get_auto_vars(void) { Thread* thread = (Thread*) thread_getspecific(mic_thread_key); if (thread == 0) { thread = new Thread(&m_proc_number); thread_setspecific(mic_thread_key, thread); } return thread->get_auto_vars(); } void Engine::destroy_thread_data(void *data) { delete static_cast(data); }