/* * Copyright 2012, The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "bcc/Renderscript/RSCompilerDriver.h" #include #include #include #include #include "bcinfo/BitcodeWrapper.h" #include "bcc/Compiler.h" #include "bcc/Renderscript/RSExecutable.h" #include "bcc/Renderscript/RSScript.h" #include "bcc/Support/CompilerConfig.h" #include "bcc/Support/TargetCompilerConfigs.h" #include "bcc/Source.h" #include "bcc/Support/FileMutex.h" #include "bcc/Support/Log.h" #include "bcc/Support/InputFile.h" #include "bcc/Support/Initialization.h" #include "bcc/Support/Sha1Util.h" #include "bcc/Support/OutputFile.h" #ifdef HAVE_ANDROID_OS #include #endif #include #include using namespace bcc; RSCompilerDriver::RSCompilerDriver(bool pUseCompilerRT) : mConfig(NULL), mCompiler(), mCompilerRuntime(NULL), mDebugContext(false), mEnableGlobalMerge(true) { init::Initialize(); // Chain the symbol resolvers for compiler_rt and RS runtimes. if (pUseCompilerRT) { mCompilerRuntime = new CompilerRTSymbolResolver(); mResolver.chainResolver(*mCompilerRuntime); } mResolver.chainResolver(mRSRuntime); } RSCompilerDriver::~RSCompilerDriver() { delete mCompilerRuntime; delete mConfig; } RSExecutable * RSCompilerDriver::loadScript(const char *pCacheDir, const char *pResName, const char *pBitcode, size_t pBitcodeSize) { //android::StopWatch load_time("bcc: RSCompilerDriver::loadScript time"); if ((pCacheDir == NULL) || (pResName == NULL)) { ALOGE("Missing pCacheDir and/or pResName"); return NULL; } if ((pBitcode == NULL) || (pBitcodeSize <= 0)) { ALOGE("No bitcode supplied! (bitcode: %p, size of bitcode: %zu)", pBitcode, pBitcodeSize); return NULL; } RSInfo::DependencyTableTy dep_info; uint8_t bitcode_sha1[20]; Sha1Util::GetSHA1DigestFromBuffer(bitcode_sha1, pBitcode, pBitcodeSize); // {pCacheDir}/{pResName}.o llvm::SmallString<80> output_path(pCacheDir); llvm::sys::path::append(output_path, pResName); llvm::sys::path::replace_extension(output_path, ".o"); dep_info.push(std::make_pair(output_path.c_str(), bitcode_sha1)); //===--------------------------------------------------------------------===// // Acquire the read lock for reading the Script object file. //===--------------------------------------------------------------------===// FileMutex read_output_mutex(output_path.c_str()); if (read_output_mutex.hasError() || !read_output_mutex.lock()) { ALOGE("Unable to acquire the read lock for %s! (%s)", output_path.c_str(), read_output_mutex.getErrorMessage().c_str()); return NULL; } //===--------------------------------------------------------------------===// // Read the output object file. //===--------------------------------------------------------------------===// InputFile *object_file = new (std::nothrow) InputFile(output_path.c_str()); if ((object_file == NULL) || object_file->hasError()) { // ALOGE("Unable to open the %s for read! (%s)", output_path.c_str(), // object_file->getErrorMessage().c_str()); delete object_file; return NULL; } //===--------------------------------------------------------------------===// // Acquire the read lock on object_file for reading its RS info file. //===--------------------------------------------------------------------===// android::String8 info_path = RSInfo::GetPath(output_path.c_str()); if (!object_file->lock()) { ALOGE("Unable to acquire the read lock on %s for reading %s! (%s)", output_path.c_str(), info_path.string(), object_file->getErrorMessage().c_str()); delete object_file; return NULL; } //===---------------------------------------------------------------------===// // Open and load the RS info file. //===--------------------------------------------------------------------===// InputFile info_file(info_path.string()); RSInfo *info = RSInfo::ReadFromFile(info_file, dep_info); // Release the lock on object_file. object_file->unlock(); if (info == NULL) { delete object_file; return NULL; } //===--------------------------------------------------------------------===// // Create the RSExecutable. //===--------------------------------------------------------------------===// RSExecutable *result = RSExecutable::Create(*info, *object_file, mResolver); if (result == NULL) { delete object_file; delete info; return NULL; } return result; } #if defined(DEFAULT_ARM_CODEGEN) extern llvm::cl::opt EnableGlobalMerge; #endif bool RSCompilerDriver::setupConfig(const RSScript &pScript) { bool changed = false; const llvm::CodeGenOpt::Level script_opt_level = static_cast(pScript.getOptimizationLevel()); if (mConfig != NULL) { // Renderscript bitcode may have their optimization flag configuration // different than the previous run of RS compilation. if (mConfig->getOptimizationLevel() != script_opt_level) { mConfig->setOptimizationLevel(script_opt_level); changed = true; } } else { // Haven't run the compiler ever. mConfig = new (std::nothrow) DefaultCompilerConfig(); if (mConfig == NULL) { // Return false since mConfig remains NULL and out-of-memory. return false; } mConfig->setOptimizationLevel(script_opt_level); #if defined(DEFAULT_ARM_CODEGEN) EnableGlobalMerge = mEnableGlobalMerge; #endif changed = true; } #if defined(DEFAULT_ARM_CODEGEN) // NEON should be disable when full-precision floating point is required. assert((pScript.getInfo() != NULL) && "NULL RS info!"); if (pScript.getInfo()->getFloatPrecisionRequirement() == RSInfo::FP_Full) { // Must be ARMCompilerConfig. ARMCompilerConfig *arm_config = static_cast(mConfig); changed |= arm_config->enableNEON(/* pEnable */false); } #endif return changed; } Compiler::ErrorCode RSCompilerDriver::compileScript(RSScript &pScript, const char* pScriptName, const char *pOutputPath, const char *pRuntimePath, const RSInfo::DependencyTableTy &pDeps, bool pSkipLoad, bool pDumpIR) { //android::StopWatch compile_time("bcc: RSCompilerDriver::compileScript time"); RSInfo *info = NULL; //===--------------------------------------------------------------------===// // Extract RS-specific information from source bitcode. //===--------------------------------------------------------------------===// // RS info may contains configuration (such as #optimization_level) to the // compiler therefore it should be extracted before compilation. info = RSInfo::ExtractFromSource(pScript.getSource(), pDeps); if (info == NULL) { return Compiler::kErrInvalidSource; } //===--------------------------------------------------------------------===// // Associate script with its info //===--------------------------------------------------------------------===// // This is required since RS compiler may need information in the info file // to do some transformation (e.g., expand foreach-able function.) pScript.setInfo(info); //===--------------------------------------------------------------------===// // Link RS script with Renderscript runtime. //===--------------------------------------------------------------------===// if (!RSScript::LinkRuntime(pScript, pRuntimePath)) { ALOGE("Failed to link script '%s' with Renderscript runtime!", pScriptName); return Compiler::kErrInvalidSource; } { // FIXME(srhines): Windows compilation can't use locking like this, but // we also don't need to worry about concurrent writers of the same file. #ifndef USE_MINGW //===------------------------------------------------------------------===// // Acquire the write lock for writing output object file. //===------------------------------------------------------------------===// FileMutex write_output_mutex(pOutputPath); if (write_output_mutex.hasError() || !write_output_mutex.lock()) { ALOGE("Unable to acquire the lock for writing %s! (%s)", pOutputPath, write_output_mutex.getErrorMessage().c_str()); return Compiler::kErrInvalidSource; } #endif // Open the output file for write. OutputFile output_file(pOutputPath, FileBase::kTruncate | FileBase::kBinary); if (output_file.hasError()) { ALOGE("Unable to open %s for write! (%s)", pOutputPath, output_file.getErrorMessage().c_str()); return Compiler::kErrInvalidSource; } // Setup the config to the compiler. bool compiler_need_reconfigure = setupConfig(pScript); if (mConfig == NULL) { ALOGE("Failed to setup config for RS compiler to compile %s!", pOutputPath); return Compiler::kErrInvalidSource; } if (compiler_need_reconfigure) { Compiler::ErrorCode err = mCompiler.config(*mConfig); if (err != Compiler::kSuccess) { ALOGE("Failed to config the RS compiler for %s! (%s)",pOutputPath, Compiler::GetErrorString(err)); return Compiler::kErrInvalidSource; } } OutputFile *ir_file = NULL; llvm::raw_fd_ostream *IRStream = NULL; if (pDumpIR) { android::String8 path(pOutputPath); path.append(".ll"); ir_file = new OutputFile(path.string(), FileBase::kTruncate); IRStream = ir_file->dup(); } // Run the compiler. Compiler::ErrorCode compile_result = mCompiler.compile(pScript, output_file, IRStream); if (ir_file) { ir_file->close(); delete ir_file; } if (compile_result != Compiler::kSuccess) { ALOGE("Unable to compile the source to file %s! (%s)", pOutputPath, Compiler::GetErrorString(compile_result)); return Compiler::kErrInvalidSource; } } // No need to produce an RSExecutable in this case. // TODO: Error handling in this case is nonexistent. if (pSkipLoad) { return Compiler::kSuccess; } { android::String8 info_path = RSInfo::GetPath(pOutputPath); OutputFile info_file(info_path.string(), FileBase::kTruncate); if (info_file.hasError()) { ALOGE("Failed to open the info file %s for write! (%s)", info_path.string(), info_file.getErrorMessage().c_str()); return Compiler::kErrInvalidSource; } FileMutex write_info_mutex(info_path.string()); if (write_info_mutex.hasError() || !write_info_mutex.lock()) { ALOGE("Unable to acquire the lock for writing %s! (%s)", info_path.string(), write_info_mutex.getErrorMessage().c_str()); return Compiler::kErrInvalidSource; } // Perform the write. if (!info->write(info_file)) { ALOGE("Failed to sync the RS info file %s!", info_path.string()); return Compiler::kErrInvalidSource; } } return Compiler::kSuccess; } bool RSCompilerDriver::build(BCCContext &pContext, const char *pCacheDir, const char *pResName, const char *pBitcode, size_t pBitcodeSize, const char *pRuntimePath, RSLinkRuntimeCallback pLinkRuntimeCallback, bool pDumpIR) { // android::StopWatch build_time("bcc: RSCompilerDriver::build time"); //===--------------------------------------------------------------------===// // Check parameters. //===--------------------------------------------------------------------===// if ((pCacheDir == NULL) || (pResName == NULL)) { ALOGE("Invalid parameter passed to RSCompilerDriver::build()! (cache dir: " "%s, resource name: %s)", ((pCacheDir) ? pCacheDir : "(null)"), ((pResName) ? pResName : "(null)")); return false; } if ((pBitcode == NULL) || (pBitcodeSize <= 0)) { ALOGE("No bitcode supplied! (bitcode: %p, size of bitcode: %u)", pBitcode, static_cast(pBitcodeSize)); return false; } //===--------------------------------------------------------------------===// // Prepare dependency information. //===--------------------------------------------------------------------===// RSInfo::DependencyTableTy dep_info; uint8_t bitcode_sha1[20]; Sha1Util::GetSHA1DigestFromBuffer(bitcode_sha1, pBitcode, pBitcodeSize); //===--------------------------------------------------------------------===// // Construct output path. // {pCacheDir}/{pResName}.o //===--------------------------------------------------------------------===// llvm::SmallString<80> output_path(pCacheDir); llvm::sys::path::append(output_path, pResName); llvm::sys::path::replace_extension(output_path, ".o"); dep_info.push(std::make_pair(output_path.c_str(), bitcode_sha1)); //===--------------------------------------------------------------------===// // Load the bitcode and create script. //===--------------------------------------------------------------------===// Source *source = Source::CreateFromBuffer(pContext, pResName, pBitcode, pBitcodeSize); if (source == NULL) { return false; } RSScript *script = new (std::nothrow) RSScript(*source); if (script == NULL) { ALOGE("Out of memory when create Script object for '%s'! (output: %s)", pResName, output_path.c_str()); delete source; return false; } script->setLinkRuntimeCallback(pLinkRuntimeCallback); // Read information from bitcode wrapper. bcinfo::BitcodeWrapper wrapper(pBitcode, pBitcodeSize); script->setCompilerVersion(wrapper.getCompilerVersion()); script->setOptimizationLevel(static_cast( wrapper.getOptimizationLevel())); //===--------------------------------------------------------------------===// // Compile the script //===--------------------------------------------------------------------===// Compiler::ErrorCode status = compileScript(*script, pResName, output_path.c_str(), pRuntimePath, dep_info, false, pDumpIR); // Script is no longer used. Free it to get more memory. delete script; if (status != Compiler::kSuccess) { return false; } return true; } bool RSCompilerDriver::build(RSScript &pScript, const char *pOut, const char *pRuntimePath) { RSInfo::DependencyTableTy dep_info; RSInfo *info = RSInfo::ExtractFromSource(pScript.getSource(), dep_info); if (info == NULL) { return false; } pScript.setInfo(info); // Embed the info string directly in the ELF, since this path is for an // offline (host) compilation. pScript.setEmbedInfo(true); Compiler::ErrorCode status = compileScript(pScript, pOut, pOut, pRuntimePath, dep_info, true); if (status != Compiler::kSuccess) { return false; } return true; }