// Copyright 2009 the V8 project authors. 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 Google Inc. 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 // OWNER 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 "v8.h" #include "log-utils.h" namespace v8 { namespace internal { #ifdef ENABLE_LOGGING_AND_PROFILING LogDynamicBuffer::LogDynamicBuffer( int block_size, int max_size, const char* seal, int seal_size) : block_size_(block_size), max_size_(max_size - (max_size % block_size_)), seal_(seal), seal_size_(seal_size), blocks_(max_size_ / block_size_ + 1), write_pos_(0), block_index_(0), block_write_pos_(0), is_sealed_(false) { ASSERT(BlocksCount() > 0); AllocateBlock(0); for (int i = 1; i < BlocksCount(); ++i) { blocks_[i] = NULL; } } LogDynamicBuffer::~LogDynamicBuffer() { for (int i = 0; i < BlocksCount(); ++i) { DeleteArray(blocks_[i]); } } int LogDynamicBuffer::Read(int from_pos, char* dest_buf, int buf_size) { if (buf_size == 0) return 0; int read_pos = from_pos; int block_read_index = BlockIndex(from_pos); int block_read_pos = PosInBlock(from_pos); int dest_buf_pos = 0; // Read until dest_buf is filled, or write_pos_ encountered. while (read_pos < write_pos_ && dest_buf_pos < buf_size) { const int read_size = Min(write_pos_ - read_pos, Min(buf_size - dest_buf_pos, block_size_ - block_read_pos)); memcpy(dest_buf + dest_buf_pos, blocks_[block_read_index] + block_read_pos, read_size); block_read_pos += read_size; dest_buf_pos += read_size; read_pos += read_size; if (block_read_pos == block_size_) { block_read_pos = 0; ++block_read_index; } } return dest_buf_pos; } int LogDynamicBuffer::Seal() { WriteInternal(seal_, seal_size_); is_sealed_ = true; return 0; } int LogDynamicBuffer::Write(const char* data, int data_size) { if (is_sealed_) { return 0; } if ((write_pos_ + data_size) <= (max_size_ - seal_size_)) { return WriteInternal(data, data_size); } else { return Seal(); } } int LogDynamicBuffer::WriteInternal(const char* data, int data_size) { int data_pos = 0; while (data_pos < data_size) { const int write_size = Min(data_size - data_pos, block_size_ - block_write_pos_); memcpy(blocks_[block_index_] + block_write_pos_, data + data_pos, write_size); block_write_pos_ += write_size; data_pos += write_size; if (block_write_pos_ == block_size_) { block_write_pos_ = 0; AllocateBlock(++block_index_); } } write_pos_ += data_size; return data_size; } bool Log::is_stopped_ = false; Log::WritePtr Log::Write = NULL; FILE* Log::output_handle_ = NULL; LogDynamicBuffer* Log::output_buffer_ = NULL; // Must be the same message as in Logger::PauseProfiler. const char* Log::kDynamicBufferSeal = "profiler,\"pause\"\n"; Mutex* Log::mutex_ = NULL; char* Log::message_buffer_ = NULL; void Log::Init() { mutex_ = OS::CreateMutex(); message_buffer_ = NewArray(kMessageBufferSize); } void Log::OpenStdout() { ASSERT(!IsEnabled()); output_handle_ = stdout; Write = WriteToFile; Init(); } void Log::OpenFile(const char* name) { ASSERT(!IsEnabled()); output_handle_ = OS::FOpen(name, OS::LogFileOpenMode); Write = WriteToFile; Init(); } void Log::OpenMemoryBuffer() { ASSERT(!IsEnabled()); output_buffer_ = new LogDynamicBuffer( kDynamicBufferBlockSize, kMaxDynamicBufferSize, kDynamicBufferSeal, strlen(kDynamicBufferSeal)); Write = WriteToMemory; Init(); } void Log::Close() { if (Write == WriteToFile) { fclose(output_handle_); output_handle_ = NULL; } else if (Write == WriteToMemory) { delete output_buffer_; output_buffer_ = NULL; } else { ASSERT(Write == NULL); } Write = NULL; DeleteArray(message_buffer_); message_buffer_ = NULL; delete mutex_; mutex_ = NULL; is_stopped_ = false; } int Log::GetLogLines(int from_pos, char* dest_buf, int max_size) { if (Write != WriteToMemory) return 0; ASSERT(output_buffer_ != NULL); ASSERT(from_pos >= 0); ASSERT(max_size >= 0); int actual_size = output_buffer_->Read(from_pos, dest_buf, max_size); ASSERT(actual_size <= max_size); if (actual_size == 0) return 0; // Find previous log line boundary. char* end_pos = dest_buf + actual_size - 1; while (end_pos >= dest_buf && *end_pos != '\n') --end_pos; actual_size = end_pos - dest_buf + 1; ASSERT(actual_size <= max_size); return actual_size; } LogMessageBuilder::WriteFailureHandler LogMessageBuilder::write_failure_handler = NULL; LogMessageBuilder::LogMessageBuilder(): sl(Log::mutex_), pos_(0) { ASSERT(Log::message_buffer_ != NULL); } void LogMessageBuilder::Append(const char* format, ...) { Vector buf(Log::message_buffer_ + pos_, Log::kMessageBufferSize - pos_); va_list args; va_start(args, format); AppendVA(format, args); va_end(args); ASSERT(pos_ <= Log::kMessageBufferSize); } void LogMessageBuilder::AppendVA(const char* format, va_list args) { Vector buf(Log::message_buffer_ + pos_, Log::kMessageBufferSize - pos_); int result = v8::internal::OS::VSNPrintF(buf, format, args); // Result is -1 if output was truncated. if (result >= 0) { pos_ += result; } else { pos_ = Log::kMessageBufferSize; } ASSERT(pos_ <= Log::kMessageBufferSize); } void LogMessageBuilder::Append(const char c) { if (pos_ < Log::kMessageBufferSize) { Log::message_buffer_[pos_++] = c; } ASSERT(pos_ <= Log::kMessageBufferSize); } void LogMessageBuilder::Append(String* str) { AssertNoAllocation no_heap_allocation; // Ensure string stay valid. int length = str->length(); for (int i = 0; i < length; i++) { Append(static_cast(str->Get(i))); } } void LogMessageBuilder::AppendAddress(Address addr) { static Address last_address_ = NULL; AppendAddress(addr, last_address_); last_address_ = addr; } void LogMessageBuilder::AppendAddress(Address addr, Address bias) { if (!FLAG_compress_log) { Append("0x%" V8PRIxPTR, addr); } else if (bias == NULL) { Append("%" V8PRIxPTR, addr); } else { uintptr_t delta; char sign; if (addr >= bias) { delta = addr - bias; sign = '+'; } else { delta = bias - addr; sign = '-'; } Append("%c%" V8PRIxPTR, sign, delta); } } void LogMessageBuilder::AppendDetailed(String* str, bool show_impl_info) { AssertNoAllocation no_heap_allocation; // Ensure string stay valid. int len = str->length(); if (len > 0x1000) len = 0x1000; if (show_impl_info) { Append(str->IsAsciiRepresentation() ? 'a' : '2'); if (StringShape(str).IsExternal()) Append('e'); if (StringShape(str).IsSymbol()) Append('#'); Append(":%i:", str->length()); } for (int i = 0; i < len; i++) { uc32 c = str->Get(i); if (c > 0xff) { Append("\\u%04x", c); } else if (c < 32 || c > 126) { Append("\\x%02x", c); } else if (c == ',') { Append("\\,"); } else if (c == '\\') { Append("\\\\"); } else { Append("%lc", c); } } } bool LogMessageBuilder::StoreInCompressor(LogRecordCompressor* compressor) { return compressor->Store(Vector(Log::message_buffer_, pos_)); } bool LogMessageBuilder::RetrieveCompressedPrevious( LogRecordCompressor* compressor, const char* prefix) { pos_ = 0; if (prefix[0] != '\0') Append(prefix); Vector prev_record(Log::message_buffer_ + pos_, Log::kMessageBufferSize - pos_); const bool has_prev = compressor->RetrievePreviousCompressed(&prev_record); if (!has_prev) return false; pos_ += prev_record.length(); return true; } void LogMessageBuilder::WriteToLogFile() { ASSERT(pos_ <= Log::kMessageBufferSize); const int written = Log::Write(Log::message_buffer_, pos_); if (written != pos_ && write_failure_handler != NULL) { write_failure_handler(); } } void LogMessageBuilder::WriteCStringToLogFile(const char* str) { const int len = strlen(str); const int written = Log::Write(str, len); if (written != len && write_failure_handler != NULL) { write_failure_handler(); } } // Formatting string for back references to the whole line. E.g. "#2" means // "the second line above". const char* LogRecordCompressor::kLineBackwardReferenceFormat = "#%d"; // Formatting string for back references. E.g. "#2:10" means // "the second line above, start from char 10 (0-based)". const char* LogRecordCompressor::kBackwardReferenceFormat = "#%d:%d"; LogRecordCompressor::~LogRecordCompressor() { for (int i = 0; i < buffer_.length(); ++i) { buffer_[i].Dispose(); } } static int GetNumberLength(int number) { ASSERT(number >= 0); ASSERT(number < 10000); if (number < 10) return 1; if (number < 100) return 2; if (number < 1000) return 3; return 4; } int LogRecordCompressor::GetBackwardReferenceSize(int distance, int pos) { // See kLineBackwardReferenceFormat and kBackwardReferenceFormat. return pos == 0 ? GetNumberLength(distance) + 1 : GetNumberLength(distance) + GetNumberLength(pos) + 2; } void LogRecordCompressor::PrintBackwardReference(Vector dest, int distance, int pos) { if (pos == 0) { OS::SNPrintF(dest, kLineBackwardReferenceFormat, distance); } else { OS::SNPrintF(dest, kBackwardReferenceFormat, distance, pos); } } bool LogRecordCompressor::Store(const Vector& record) { // Check if the record is the same as the last stored one. if (curr_ != -1) { Vector& curr = buffer_[curr_]; if (record.length() == curr.length() && strncmp(record.start(), curr.start(), record.length()) == 0) { return false; } } // buffer_ is circular. prev_ = curr_++; curr_ %= buffer_.length(); Vector record_copy = Vector::New(record.length()); memcpy(record_copy.start(), record.start(), record.length()); buffer_[curr_].Dispose(); buffer_[curr_] = Vector(record_copy.start(), record_copy.length()); return true; } bool LogRecordCompressor::RetrievePreviousCompressed( Vector* prev_record) { if (prev_ == -1) return false; int index = prev_; // Distance from prev_. int distance = 0; // Best compression result among records in the buffer. struct { intptr_t truncated_len; int distance; int copy_from_pos; int backref_size; } best = {-1, 0, 0, 0}; Vector& prev = buffer_[prev_]; const char* const prev_start = prev.start(); const char* const prev_end = prev.start() + prev.length(); do { // We're moving backwards until we reach the current record. // Remember that buffer_ is circular. if (--index == -1) index = buffer_.length() - 1; ++distance; if (index == curr_) break; Vector& data = buffer_[index]; if (data.start() == NULL) break; const char* const data_end = data.start() + data.length(); const char* prev_ptr = prev_end; const char* data_ptr = data_end; // Compare strings backwards, stop on the last matching character. while (prev_ptr != prev_start && data_ptr != data.start() && *(prev_ptr - 1) == *(data_ptr - 1)) { --prev_ptr; --data_ptr; } const intptr_t truncated_len = prev_end - prev_ptr; const int copy_from_pos = data_ptr - data.start(); // Check if the length of compressed tail is enough. if (truncated_len <= kMaxBackwardReferenceSize && truncated_len <= GetBackwardReferenceSize(distance, copy_from_pos)) { continue; } // Record compression results. if (truncated_len > best.truncated_len) { best.truncated_len = truncated_len; best.distance = distance; best.copy_from_pos = copy_from_pos; best.backref_size = GetBackwardReferenceSize(distance, copy_from_pos); } } while (true); if (best.distance == 0) { // Can't compress the previous record. Return as is. ASSERT(prev_record->length() >= prev.length()); memcpy(prev_record->start(), prev.start(), prev.length()); prev_record->Truncate(prev.length()); } else { // Copy the uncompressible part unchanged. const intptr_t unchanged_len = prev.length() - best.truncated_len; // + 1 for '\0'. ASSERT(prev_record->length() >= unchanged_len + best.backref_size + 1); memcpy(prev_record->start(), prev.start(), unchanged_len); // Append the backward reference. Vector backref( prev_record->start() + unchanged_len, best.backref_size + 1); PrintBackwardReference(backref, best.distance, best.copy_from_pos); ASSERT(strlen(backref.start()) - best.backref_size == 0); prev_record->Truncate(unchanged_len + best.backref_size); } return true; } #endif // ENABLE_LOGGING_AND_PROFILING } } // namespace v8::internal