// Copyright (c) 2015 The Khronos Group Inc. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and/or associated documentation files (the // "Materials"), to deal in the Materials without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Materials, and to // permit persons to whom the Materials are furnished to do so, subject to // the following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Materials. // // MODIFICATIONS TO THIS FILE MAY MEAN IT NO LONGER ACCURATELY REFLECTS // KHRONOS STANDARDS. THE UNMODIFIED, NORMATIVE VERSIONS OF KHRONOS // SPECIFICATIONS AND HEADER INFORMATION ARE LOCATED AT // https://www.khronos.org/registry/ // // THE MATERIALS ARE PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. // IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY // CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, // TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE // MATERIALS OR THE USE OR OTHER DEALINGS IN THE MATERIALS. #include "text_handler.h" #include #include #include #include #include "assembly_grammar.h" #include "binary.h" #include "ext_inst.h" #include "instruction.h" #include "opcode.h" #include "text.h" #include "util/bitutils.h" #include "util/hex_float.h" namespace { using spvutils::BitwiseCast; using spvutils::FloatProxy; using spvutils::HexFloat; /// @brief Advance text to the start of the next line /// /// @param[in] text to be parsed /// @param[in,out] position position text has been advanced to /// /// @return result code spv_result_t advanceLine(spv_text text, spv_position position) { while (true) { switch (text->str[position->index]) { case '\0': return SPV_END_OF_STREAM; case '\n': position->column = 0; position->line++; position->index++; return SPV_SUCCESS; default: position->column++; position->index++; break; } } } /// @brief Advance text to first non white space character /// If a null terminator is found during the text advance SPV_END_OF_STREAM is /// returned, SPV_SUCCESS otherwise. No error checking is performed on the /// parameters, its the users responsibility to ensure these are non null. /// /// @param[in] text to be parsed /// @param[in,out] position text has been advanced to /// /// @return result code spv_result_t advance(spv_text text, spv_position position) { // NOTE: Consume white space, otherwise don't advance. if (position->index >= text->length) return SPV_END_OF_STREAM; switch (text->str[position->index]) { case '\0': return SPV_END_OF_STREAM; case ';': if (spv_result_t error = advanceLine(text, position)) return error; return advance(text, position); case ' ': case '\t': position->column++; position->index++; return advance(text, position); case '\n': position->column = 0; position->line++; position->index++; return advance(text, position); default: break; } return SPV_SUCCESS; } /// @brief Fetch the next word from the text stream. /// /// A word ends at the next comment or whitespace. However, double-quoted /// strings remain intact, and a backslash always escapes the next character. /// /// @param[in] text stream to read from /// @param[in] position current position in text stream /// @param[out] word returned word /// @param[out] endPosition one past the end of the returned word /// /// @return result code spv_result_t getWord(spv_text text, spv_position position, std::string& word, spv_position endPosition) { if (!text->str || !text->length) return SPV_ERROR_INVALID_TEXT; if (!position || !endPosition) return SPV_ERROR_INVALID_POINTER; *endPosition = *position; bool quoting = false; bool escaping = false; // NOTE: Assumes first character is not white space! while (true) { const char ch = text->str[endPosition->index]; if (ch == '\\') escaping = !escaping; else { switch (ch) { case '"': if (!escaping) quoting = !quoting; break; case ' ': case ';': case '\t': case '\n': if (escaping || quoting) break; // Fall through. case '\0': { // NOTE: End of word found! word.assign(text->str + position->index, (size_t)(endPosition->index - position->index)); return SPV_SUCCESS; } default: break; } escaping = false; } endPosition->column++; endPosition->index++; } } // Returns true if the characters in the text as position represent // the start of an Opcode. bool startsWithOp(spv_text text, spv_position position) { if (text->length < position->index + 3) return false; char ch0 = text->str[position->index]; char ch1 = text->str[position->index + 1]; char ch2 = text->str[position->index + 2]; return ('O' == ch0 && 'p' == ch1 && ('A' <= ch2 && ch2 <= 'Z')); } } // anonymous namespace namespace libspirv { const IdType kUnknownType = {0, false, IdTypeClass::kBottom}; // TODO(dneto): Reorder AssemblyContext definitions to match declaration order. // This represents all of the data that is only valid for the duration of // a single compilation. uint32_t AssemblyContext::spvNamedIdAssignOrGet(const char* textValue) { if (named_ids_.end() == named_ids_.find(textValue)) { named_ids_[std::string(textValue)] = bound_++; } return named_ids_[textValue]; } uint32_t AssemblyContext::getBound() const { return bound_; } spv_result_t AssemblyContext::advance() { return ::advance(text_, ¤t_position_); } spv_result_t AssemblyContext::getWord(std::string& word, spv_position endPosition) { return ::getWord(text_, ¤t_position_, word, endPosition); } bool AssemblyContext::startsWithOp() { return ::startsWithOp(text_, ¤t_position_); } bool AssemblyContext::isStartOfNewInst() { spv_position_t nextPosition = current_position_; if (::advance(text_, &nextPosition)) return false; if (::startsWithOp(text_, &nextPosition)) return true; std::string word; spv_position_t startPosition = current_position_; if (::getWord(text_, &startPosition, word, &nextPosition)) return false; if ('%' != word.front()) return false; if (::advance(text_, &nextPosition)) return false; startPosition = nextPosition; if (::getWord(text_, &startPosition, word, &nextPosition)) return false; if ("=" != word) return false; if (::advance(text_, &nextPosition)) return false; startPosition = nextPosition; if (::startsWithOp(text_, &startPosition)) return true; return false; } char AssemblyContext::peek() const { return text_->str[current_position_.index]; } bool AssemblyContext::hasText() const { return text_->length > current_position_.index; } std::string AssemblyContext::getWord() const { uint64_t index = current_position_.index; while (true) { switch (text_->str[index]) { case '\0': case '\t': case '\v': case '\r': case '\n': case ' ': return std::string(text_->str, text_->str + index); default: index++; } } assert(0 && "Unreachable"); return ""; // Make certain compilers happy. } void AssemblyContext::seekForward(uint32_t size) { current_position_.index += size; current_position_.column += size; } spv_result_t AssemblyContext::binaryEncodeU32(const uint32_t value, spv_instruction_t* pInst) { spvInstructionAddWord(pInst, value); return SPV_SUCCESS; } spv_result_t AssemblyContext::binaryEncodeU64(const uint64_t value, spv_instruction_t* pInst) { uint32_t low = uint32_t(0x00000000ffffffff & value); uint32_t high = uint32_t((0xffffffff00000000 & value) >> 32); binaryEncodeU32(low, pInst); binaryEncodeU32(high, pInst); return SPV_SUCCESS; } spv_result_t AssemblyContext::binaryEncodeNumericLiteral( const char* val, spv_result_t error_code, const IdType& type, spv_instruction_t* pInst) { const bool is_bottom = type.type_class == libspirv::IdTypeClass::kBottom; const bool is_floating = libspirv::isScalarFloating(type); const bool is_integer = libspirv::isScalarIntegral(type); if (!is_bottom && !is_floating && !is_integer) { return diagnostic(SPV_ERROR_INTERNAL) << "The expected type is not a scalar integer or float type"; } // If this is bottom, but looks like a float, we should treat it like a // float. const bool looks_like_float = is_bottom && strchr(val, '.'); // If we explicitly expect a floating-point number, we should handle that // first. if (is_floating || looks_like_float) return binaryEncodeFloatingPointLiteral(val, error_code, type, pInst); return binaryEncodeIntegerLiteral(val, error_code, type, pInst); } spv_result_t AssemblyContext::binaryEncodeString(const char* value, spv_instruction_t* pInst) { const size_t length = strlen(value); const size_t wordCount = (length / 4) + 1; const size_t oldWordCount = pInst->words.size(); const size_t newWordCount = oldWordCount + wordCount; // TODO(dneto): We can just defer this check until later. if (newWordCount > SPV_LIMIT_INSTRUCTION_WORD_COUNT_MAX) { return diagnostic() << "Instruction too long: more than " << SPV_LIMIT_INSTRUCTION_WORD_COUNT_MAX << " words."; } pInst->words.resize(newWordCount); // Make sure all the bytes in the last word are 0, in case we only // write a partial word at the end. pInst->words.back() = 0; char* dest = (char*)&pInst->words[oldWordCount]; strncpy(dest, value, length); return SPV_SUCCESS; } spv_result_t AssemblyContext::recordTypeDefinition( const spv_instruction_t* pInst) { uint32_t value = pInst->words[1]; if (types_.find(value) != types_.end()) { return diagnostic() << "Value " << value << " has already been used to generate a type"; } if (pInst->opcode == SpvOpTypeInt) { if (pInst->words.size() != 4) return diagnostic() << "Invalid OpTypeInt instruction"; types_[value] = {pInst->words[2], pInst->words[3] != 0, IdTypeClass::kScalarIntegerType}; } else if (pInst->opcode == SpvOpTypeFloat) { if (pInst->words.size() != 3) return diagnostic() << "Invalid OpTypeFloat instruction"; types_[value] = {pInst->words[2], false, IdTypeClass::kScalarFloatType}; } else { types_[value] = {0, false, IdTypeClass::kOtherType}; } return SPV_SUCCESS; } IdType AssemblyContext::getTypeOfTypeGeneratingValue(uint32_t value) const { auto type = types_.find(value); if (type == types_.end()) { return kUnknownType; } return std::get<1>(*type); } IdType AssemblyContext::getTypeOfValueInstruction(uint32_t value) const { auto type_value = value_types_.find(value); if (type_value == value_types_.end()) { return {0, false, IdTypeClass::kBottom}; } return getTypeOfTypeGeneratingValue(std::get<1>(*type_value)); } spv_result_t AssemblyContext::recordTypeIdForValue(uint32_t value, uint32_t type) { bool successfully_inserted = false; std::tie(std::ignore, successfully_inserted) = value_types_.insert(std::make_pair(value, type)); if (!successfully_inserted) return diagnostic() << "Value is being defined a second time"; return SPV_SUCCESS; } spv_result_t AssemblyContext::recordIdAsExtInstImport( uint32_t id, spv_ext_inst_type_t type) { bool successfully_inserted = false; std::tie(std::ignore, successfully_inserted) = import_id_to_ext_inst_type_.insert(std::make_pair(id, type)); if (!successfully_inserted) return diagnostic() << "Import Id is being defined a second time"; return SPV_SUCCESS; } spv_ext_inst_type_t AssemblyContext::getExtInstTypeForId(uint32_t id) const { auto type = import_id_to_ext_inst_type_.find(id); if (type == import_id_to_ext_inst_type_.end()) { return SPV_EXT_INST_TYPE_NONE; } return std::get<1>(*type); } spv_result_t AssemblyContext::binaryEncodeFloatingPointLiteral( const char* val, spv_result_t error_code, const IdType& type, spv_instruction_t* pInst) { const auto bit_width = assumedBitWidth(type); switch (bit_width) { case 16: return diagnostic(SPV_ERROR_INTERNAL) << "Unsupported yet: 16-bit float constants."; case 32: { spvutils::HexFloat> fVal(0.0f); if (auto error = parseNumber(val, error_code, &fVal, "Invalid 32-bit float literal: ")) return error; return binaryEncodeU32(BitwiseCast(fVal), pInst); } break; case 64: { spvutils::HexFloat> dVal(0.0); if (auto error = parseNumber(val, error_code, &dVal, "Invalid 64-bit float literal: ")) return error; return binaryEncodeU64(BitwiseCast(dVal), pInst); } break; default: break; } return diagnostic() << "Unsupported " << bit_width << "-bit float literals"; } spv_result_t AssemblyContext::binaryEncodeIntegerLiteral( const char* val, spv_result_t error_code, const IdType& type, spv_instruction_t* pInst) { const bool is_bottom = type.type_class == libspirv::IdTypeClass::kBottom; const auto bit_width = assumedBitWidth(type); if (bit_width > 64) return diagnostic(SPV_ERROR_INTERNAL) << "Unsupported " << bit_width << "-bit integer literals"; // Either we are expecting anything or integer. bool is_negative = val[0] == '-'; bool can_be_signed = is_bottom || type.isSigned; if (is_negative && !can_be_signed) { return diagnostic() << "Cannot put a negative number in an unsigned literal"; } const bool is_hex = val[0] == '0' && (val[1] == 'x' || val[1] == 'X'); uint64_t decoded_bits; if (is_negative) { int64_t decoded_signed = 0; if (auto error = parseNumber(val, error_code, &decoded_signed, "Invalid signed integer literal: ")) return error; if (auto error = checkRangeAndIfHexThenSignExtend( decoded_signed, error_code, type, is_hex, &decoded_signed)) return error; decoded_bits = decoded_signed; } else { // There's no leading minus sign, so parse it as an unsigned integer. if (auto error = parseNumber(val, error_code, &decoded_bits, "Invalid unsigned integer literal: ")) return error; if (auto error = checkRangeAndIfHexThenSignExtend( decoded_bits, error_code, type, is_hex, &decoded_bits)) return error; } if (bit_width > 32) { return binaryEncodeU64(decoded_bits, pInst); } else { return binaryEncodeU32(uint32_t(decoded_bits), pInst); } } template spv_result_t AssemblyContext::checkRangeAndIfHexThenSignExtend( T value, spv_result_t error_code, const IdType& type, bool is_hex, T* updated_value_for_hex) { // The encoded result has three regions of bits that are of interest, from // least to most significant: // - magnitude bits, where the magnitude of the number would be stored if // we were using a signed-magnitude representation. // - an optional sign bit // - overflow bits, up to bit 63 of a 64-bit number // For example: // Type Overflow Sign Magnitude // --------------- -------- ---- --------- // unsigned 8 bit 8-63 n/a 0-7 // signed 8 bit 8-63 7 0-6 // unsigned 16 bit 16-63 n/a 0-15 // signed 16 bit 16-63 15 0-14 // We'll use masks to define the three regions. // At first we'll assume the number is unsigned. const uint32_t bit_width = assumedBitWidth(type); uint64_t magnitude_mask = (bit_width == 64) ? -1 : ((uint64_t(1) << bit_width) - 1); uint64_t sign_mask = 0; uint64_t overflow_mask = ~magnitude_mask; if (value < 0 || type.isSigned) { // Accommodate the sign bit. magnitude_mask >>= 1; sign_mask = magnitude_mask + 1; } bool failed = false; if (value < 0) { // The top bits must all be 1 for a negative signed value. failed = ((value & overflow_mask) != overflow_mask) || ((value & sign_mask) != sign_mask); } else { if (is_hex) { // Hex values are a bit special. They decode as unsigned values, but // may represent a negative number. In this case, the overflow bits // should be zero. failed = (value & overflow_mask); } else { // Check overflow in the ordinary case. failed = (value & magnitude_mask) != value; } } if (failed) { return diagnostic(error_code) << "Integer " << (is_hex ? std::hex : std::dec) << std::showbase << value << " does not fit in a " << std::dec << bit_width << "-bit " << (type.isSigned ? "signed" : "unsigned") << " integer"; } // Sign extend hex the number. if (is_hex && (value & sign_mask)) *updated_value_for_hex = (value | overflow_mask); return SPV_SUCCESS; } } // namespace libspirv