/* * Copyright (C) 2015 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 #include #include #include #include #include "Generator.h" #include "Specification.h" #include "Utilities.h" using namespace std; const unsigned int kMinimumApiLevelForTests = 11; const unsigned int kApiLevelWithFirst64Bit = 21; // Used to map the built-in types to their mangled representations struct BuiltInMangling { const char* token[3]; // The last two entries can be nullptr const char* equivalence; // The mangled equivalent }; BuiltInMangling builtInMangling[] = { {{"long", "long"}, "x"}, {{"unsigned", "long", "long"}, "y"}, {{"long"}, "l"}, {{"unsigned", "long"}, "m"}, {{"int"}, "i"}, {{"unsigned", "int"}, "j"}, {{"short"}, "s"}, {{"unsigned", "short"}, "t"}, {{"char"}, "c"}, {{"unsigned", "char"}, "h"}, {{"signed", "char"}, "a"}, {{"void"}, "v"}, {{"wchar_t"}, "w"}, {{"bool"}, "b"}, {{"__fp16"}, "Dh"}, {{"float"}, "f"}, {{"double"}, "d"}, }; /* For the given API level and bitness (e.g. 32 or 64 bit), try to find a * substitution for the provided type name, as would be done (mostly) by a * preprocessor. Returns empty string if there's no substitution. */ static string findSubstitute(const string& typeName, unsigned int apiLevel, int intSize) { const auto& types = systemSpecification.getTypes(); const auto type = types.find(typeName); if (type != types.end()) { for (TypeSpecification* spec : type->second->getSpecifications()) { // Verify this specification applies const VersionInfo info = spec->getVersionInfo(); if (!info.includesVersion(apiLevel) || (info.intSize != 0 && info.intSize != intSize)) { continue; } switch (spec->getKind()) { case SIMPLE: { return spec->getSimpleType(); } case RS_OBJECT: { // Do nothing for RS object types. break; } case STRUCT: { return spec->getStructName(); } case ENUM: // Do nothing break; } } } return ""; } /* Expand the typedefs found in 'type' into their equivalents and tokenize * the resulting list. 'apiLevel' and 'intSize' specifies the API level and bitness * we are currently processing. */ list expandTypedefs(const string type, unsigned int apiLevel, int intSize, string& vectorSize) { // Split the string in tokens. istringstream stream(type); list tokens{istream_iterator{stream}, istream_iterator{}}; // Try to substitue each token. for (auto i = tokens.begin(); i != tokens.end();) { const string substitute = findSubstitute(*i, apiLevel, intSize); if (substitute.empty()) { // No substitution possible, just go to the next token. i++; } else { // Split the replacement string in tokens. /* Get the new vector size. This is for the case of the type being for example * rs_quaternion* == float4*, where we need the vector size to be 4 for the * purposes of mangling, although the parameter itself is not determined to be * a vector. */ string unused; string newVectorSize; getVectorSizeAndBaseType(*i, newVectorSize, unused); istringstream vectorSizeBuf(vectorSize); int vectorSizeVal; vectorSizeBuf >> vectorSizeVal; istringstream newVectorSizeBuf(newVectorSize); int newVectorSizeVal; newVectorSizeBuf >> newVectorSizeVal; if (newVectorSizeVal > vectorSizeVal) vectorSize = newVectorSize; istringstream stream(substitute); list newTokens{istream_iterator{stream}, istream_iterator{}}; // Replace the token with the substitution. Don't advance, as the new substitution // might itself be replaced. // hold previous node auto prev = i; // insert new nodes after node i tokens.splice(++i, std::move(newTokens)); // remove previous node and set i to beginning of inserted nodes i = tokens.erase(prev); } } return tokens; } // Remove the first element of the list if it equals 'prefix'. Return true in that case. static bool eatFront(list* tokens, const char* prefix) { if (tokens->front() == prefix) { tokens->pop_front(); return true; } return false; } /* Search the table of translations for the built-ins for the mangling that * corresponds to this list of tokens. If a match is found, consume these tokens * and return a pointer to the string. If not, return nullptr. */ static const char* findManglingOfBuiltInType(list* tokens) { for (const BuiltInMangling& a : builtInMangling) { auto t = tokens->begin(); auto end = tokens->end(); bool match = true; // We match up to three tokens. for (int i = 0; i < 3; i++) { if (!a.token[i]) { // No more tokens break; } if (t == end || *t++ != a.token[i]) { match = false; } } if (match) { tokens->erase(tokens->begin(), t); return a.equivalence; } } return nullptr; } // Mangle a long name by prefixing it with its length, e.g. "13rs_allocation". static inline string mangleLongName(const string& name) { return to_string(name.size()) + name; } /* Mangle the type name that's represented by the vector size and list of tokens. * The mangling will be returned in full form in 'mangling'. 'compressedMangling' * will have the compressed equivalent. This is built using the 'previousManglings' * list. false is returned if an error is encountered. * * This function is recursive because compression is possible at each level of the definition. * See http://mentorembedded.github.io/cxx-abi/abi.html#mangle.type for a description * of the Itanium mangling used by llvm. * * This function mangles correctly the types currently used by RenderScript. It does * not currently mangle more complicated types like function pointers, namespaces, * or other C++ types. In particular, we don't deal correctly with parenthesis. */ static bool mangleType(string vectorSize, list* tokens, vector* previousManglings, string* mangling, string* compressedMangling) { string delta; // The part of the mangling we're generating for this recursion. bool isTerminal = false; // True if this iteration parses a terminal node in the production. bool canBeCompressed = true; // Will be false for manglings of builtins. if (tokens->back() == "*") { delta = "P"; tokens->pop_back(); } else if (eatFront(tokens, "const")) { delta = "K"; } else if (eatFront(tokens, "volatile")) { delta = "V"; } else if (vectorSize != "1" && vectorSize != "") { // For vector, prefix with the abbreviation for a vector, including the size. delta = "Dv" + vectorSize + "_"; vectorSize.clear(); // Reset to mark the size as consumed. } else if (eatFront(tokens, "struct")) { // For a structure, we just use the structure name if (tokens->size() == 0) { cerr << "Expected a name after struct\n"; return false; } delta = mangleLongName(tokens->front()); isTerminal = true; tokens->pop_front(); } else if (eatFront(tokens, "...")) { delta = "z"; isTerminal = true; } else { const char* c = findManglingOfBuiltInType(tokens); if (c) { // It's a basic type. We don't use those directly for compression. delta = c; isTerminal = true; canBeCompressed = false; } else if (tokens->size() > 0) { // It's a complex type name. delta = mangleLongName(tokens->front()); isTerminal = true; tokens->pop_front(); } } if (isTerminal) { // If we're the terminal node, there should be nothing left to mangle. if (tokens->size() > 0) { cerr << "Expected nothing else but found"; for (const auto& t : *tokens) { cerr << " " << t; } cerr << "\n"; return false; } *mangling = delta; *compressedMangling = delta; } else { // We're not terminal. Recurse and prefix what we've translated this pass. if (tokens->size() == 0) { cerr << "Expected a more complete type\n"; return false; } string rest, compressedRest; if (!mangleType(vectorSize, tokens, previousManglings, &rest, &compressedRest)) { return false; } *mangling = delta + rest; *compressedMangling = delta + compressedRest; } /* If it's a built-in type, we don't look at previously emitted ones and we * don't keep track of it. */ if (!canBeCompressed) { return true; } // See if we've encountered this mangling before. for (size_t i = 0; i < previousManglings->size(); ++i) { if ((*previousManglings)[i] == *mangling) { // We have a match, construct an index reference to that previously emitted mangling. ostringstream stream2; stream2 << 'S'; if (i > 0) { stream2 << (char)('0' + i - 1); } stream2 << '_'; *compressedMangling = stream2.str(); return true; } } // We have not encountered this before. Add it to the list. previousManglings->push_back(*mangling); return true; } // Write to the stream the mangled representation of each parameter. static bool writeParameters(ostringstream* stream, const std::vector& params, unsigned int apiLevel, int intSize) { if (params.empty()) { *stream << "v"; return true; } /* We keep track of the previously generated parameter types, as type mangling * is compressed by reusing previous manglings. */ vector previousManglings; for (ParameterDefinition* p : params) { // Expand the typedefs and create a tokenized list. string vectorSize = p->mVectorSize; list tokens = expandTypedefs(p->rsType, apiLevel, intSize, vectorSize); if (p->isOutParameter) { tokens.push_back("*"); } string mangling, compressedMangling; if (!mangleType(vectorSize, &tokens, &previousManglings, &mangling, &compressedMangling)) { return false; } *stream << compressedMangling; } return true; } /* Add the mangling for this permutation of the function. apiLevel and intSize is used * to select the correct type when expanding complex type. */ static bool addFunctionManglingToSet(const FunctionPermutation& permutation, bool overloadable, unsigned int apiLevel, int intSize, set* allManglings) { const string& functionName = permutation.getName(); string mangling; if (overloadable) { ostringstream stream; stream << "_Z" << mangleLongName(functionName); if (!writeParameters(&stream, permutation.getParams(), apiLevel, intSize)) { cerr << "Error mangling " << functionName << ". See above message.\n"; return false; } mangling = stream.str(); } else { mangling = functionName; } allManglings->insert(mangling); return true; } /* Add to the set the mangling of each function prototype that can be generated from this * specification, i.e. for all the versions covered and for 32/64 bits. We call this * for each API level because the implementation of a type may have changed in the range * of API levels covered. */ static bool addManglingsForSpecification(const FunctionSpecification& spec, unsigned int lastApiLevel, set* allManglings) { // If the function is inlined, we won't generate an unresolved external for that. if (spec.hasInline()) { return true; } const VersionInfo info = spec.getVersionInfo(); unsigned int minApiLevel, maxApiLevel; minApiLevel = info.minVersion ? info.minVersion : kMinimumApiLevelForTests; maxApiLevel = info.maxVersion ? info.maxVersion : lastApiLevel; const bool overloadable = spec.isOverloadable(); /* We track success rather than aborting early in case of failure so that we * generate all the error messages. */ bool success = true; // Use 64-bit integer here for the loop count to avoid overflow // (minApiLevel == maxApiLevel == UINT_MAX for unreleased API) for (int64_t apiLevel = minApiLevel; apiLevel <= maxApiLevel; ++apiLevel) { for (auto permutation : spec.getPermutations()) { if (info.intSize == 0 || info.intSize == 32) { if (!addFunctionManglingToSet(*permutation, overloadable, apiLevel, 32, allManglings)) { success = false; } } if (apiLevel >= kApiLevelWithFirst64Bit && (info.intSize == 0 || info.intSize == 64)) { if (!addFunctionManglingToSet(*permutation, overloadable, apiLevel, 64, allManglings)) { success = false; } } } } return success; } /* Generate the white list file of the mangled function prototypes. This generated list is used * to validate unresolved external references. 'lastApiLevel' is the largest api level found in * all spec files. */ static bool generateWhiteListFile(unsigned int lastApiLevel) { bool success = true; // We generate all the manglings in a set to remove duplicates and to order them. set allManglings; for (auto f : systemSpecification.getFunctions()) { const Function* function = f.second; for (auto spec : function->getSpecifications()) { // Compiler intrinsics are not runtime APIs. Do not include them in the whitelist. if (spec->isIntrinsic()) { continue; } if (!addManglingsForSpecification(*spec, lastApiLevel, &allManglings)) { success = false; // We continue so we can generate all errors. } } } if (success) { GeneratedFile file; if (!file.start(".", "RSStubsWhiteList.cpp")) { return false; } file.writeNotices(); file << "#include \"RSStubsWhiteList.h\"\n\n"; file << "std::vector stubList = {\n"; for (const auto& e : allManglings) { file << "\"" << e << "\",\n"; } file << "};\n"; } return success; } // Add a uniquely named variable definition to the file and return its name. static const string addVariable(GeneratedFile* file, unsigned int* variableNumber) { const string name = "buf" + to_string((*variableNumber)++); /* Some data structures like rs_tm can't be exported. We'll just use a dumb buffer * and cast its address later on. */ *file << "char " << name << "[200];\n"; return name; } /* Write to the file the globals needed to make the call for this permutation. The actual * call is stored in 'calls', as we'll need to generate all the global variable declarations * before the function definition. */ static void generateTestCall(GeneratedFile* file, ostringstream* calls, unsigned int* variableNumber, const FunctionPermutation& permutation) { *calls << " "; // Handle the return type. const auto ret = permutation.getReturn(); if (ret && ret->rsType != "void" && ret->rsType != "const void") { *calls << "*(" << ret->rsType << "*)" << addVariable(file, variableNumber) << " = "; } *calls << permutation.getName() << "("; // Generate the arguments. const char* separator = ""; for (auto p : permutation.getParams()) { *calls << separator; if (p->rsType == "rs_kernel_context") { // Special case for the kernel context, as it has a special existence. *calls << "context"; } else if (p->rsType == "...") { // Special case for varargs. No need for casting. *calls << addVariable(file, variableNumber); } else if (p->isOutParameter) { *calls << "(" << p->rsType << "*) " << addVariable(file, variableNumber); } else { *calls << "*(" << p->rsType << "*)" << addVariable(file, variableNumber); } separator = ", "; } *calls << ");\n"; } /* Generate a test file that will be used in the frameworks/compile/slang/tests unit tests. * This file tests that all RenderScript APIs can be called for the specified API level. * To avoid the compiler agressively pruning out our calls, we use globals as inputs and outputs. * * Since some structures can't be defined at the global level, we use casts of simple byte * buffers to get around that restriction. * * This file can be used to verify the white list that's also generated in this file. To do so, * run "llvm-nm -undefined-only -just-symbol-name" on the resulting bit code. */ static bool generateApiTesterFile(const string& slangTestDirectory, unsigned int apiLevel) { GeneratedFile file; if (!file.start(slangTestDirectory, "all" + to_string(apiLevel) + ".rs")) { return false; } /* This unusual comment is used by slang/tests/test.py to know which parameter to pass * to llvm-rs-cc when compiling the test. */ file << "// -target-api " << apiLevel << " -Wno-deprecated-declarations\n"; file.writeNotices(); file << "#pragma version(1)\n"; file << "#pragma rs java_package_name(com.example.renderscript.testallapi)\n\n"; if (apiLevel < 23) { // All rs_graphics APIs were deprecated in api level 23. file << "#include \"rs_graphics.rsh\"\n\n"; } /* The code below emits globals and calls to functions in parallel. We store * the calls in a stream so that we can emit them in the file in the proper order. */ ostringstream calls; unsigned int variableNumber = 0; // Used to generate unique names. for (auto f : systemSpecification.getFunctions()) { const Function* function = f.second; for (auto spec : function->getSpecifications()) { // Do not include internal APIs in the API tests. if (spec->isInternal()) { continue; } VersionInfo info = spec->getVersionInfo(); if (!info.includesVersion(apiLevel)) { continue; } if (info.intSize == 32) { calls << "#ifndef __LP64__\n"; } else if (info.intSize == 64) { calls << "#ifdef __LP64__\n"; } for (auto permutation : spec->getPermutations()) { // http://b/27358969 Do not test rsForEach in the all-api test. if (apiLevel >= 24 && permutation->getName().compare(0, 9, "rsForEach") == 0) continue; generateTestCall(&file, &calls, &variableNumber, *permutation); } if (info.intSize != 0) { calls << "#endif\n"; } } } file << "\n"; // Modify the style of kernel as required by the API level. if (apiLevel >= 23) { file << "void RS_KERNEL test(int in, rs_kernel_context context) {\n"; } else if (apiLevel >= 17) { file << "void RS_KERNEL test(int in) {\n"; } else { file << "void root(const int* in) {\n"; } file << calls.str(); file << "}\n"; return true; } bool generateStubsWhiteList(const string& slangTestDirectory, unsigned int maxApiLevel) { unsigned int lastApiLevel = min(systemSpecification.getMaximumApiLevel(), maxApiLevel); if (!generateWhiteListFile(lastApiLevel)) { return false; } // Generate a test file for each apiLevel. for (unsigned int i = kMinimumApiLevelForTests; i <= lastApiLevel; ++i) { if (!generateApiTesterFile(slangTestDirectory, i)) { return false; } } return true; }