/*===- InstrProfilingWriter.c - Write instrumentation to a file or buffer -===*\ |* |* Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. |* See https://llvm.org/LICENSE.txt for license information. |* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception |* \*===----------------------------------------------------------------------===*/ // Note: This is linked into the Darwin kernel, and must remain compatible // with freestanding compilation. See `darwin_add_builtin_libraries`. #ifdef _MSC_VER /* For _alloca */ #include #endif #include "InstrProfiling.h" #include "InstrProfilingInternal.h" #include "InstrProfilingPort.h" #define INSTR_PROF_VALUE_PROF_DATA #include "profile/InstrProfData.inc" COMPILER_RT_VISIBILITY void (*FreeHook)(void *) = NULL; static ProfBufferIO TheBufferIO; #define VP_BUFFER_SIZE 8 * 1024 static uint8_t BufferIOBuffer[VP_BUFFER_SIZE]; static InstrProfValueData VPDataArray[16]; static uint32_t VPDataArraySize = sizeof(VPDataArray) / sizeof(*VPDataArray); COMPILER_RT_VISIBILITY uint8_t *DynamicBufferIOBuffer = 0; COMPILER_RT_VISIBILITY uint32_t VPBufferSize = 0; /* The buffer writer is responsible in keeping writer state * across the call. */ COMPILER_RT_VISIBILITY uint32_t lprofBufferWriter(ProfDataWriter *This, ProfDataIOVec *IOVecs, uint32_t NumIOVecs) { uint32_t I; char **Buffer = (char **)&This->WriterCtx; for (I = 0; I < NumIOVecs; I++) { size_t Length = IOVecs[I].ElmSize * IOVecs[I].NumElm; if (IOVecs[I].Data) memcpy(*Buffer, IOVecs[I].Data, Length); else if (IOVecs[I].UseZeroPadding) { /* Allocating the buffer should zero fill. */ } *Buffer += Length; } return 0; } static void llvmInitBufferIO(ProfBufferIO *BufferIO, ProfDataWriter *FileWriter, uint8_t *Buffer, uint32_t BufferSz) { BufferIO->FileWriter = FileWriter; BufferIO->OwnFileWriter = 0; BufferIO->BufferStart = Buffer; BufferIO->BufferSz = BufferSz; BufferIO->CurOffset = 0; } COMPILER_RT_VISIBILITY ProfBufferIO * lprofCreateBufferIO(ProfDataWriter *FileWriter) { uint8_t *Buffer = DynamicBufferIOBuffer; uint32_t BufferSize = VPBufferSize; if (!Buffer) { Buffer = &BufferIOBuffer[0]; BufferSize = sizeof(BufferIOBuffer); } llvmInitBufferIO(&TheBufferIO, FileWriter, Buffer, BufferSize); return &TheBufferIO; } COMPILER_RT_VISIBILITY void lprofDeleteBufferIO(ProfBufferIO *BufferIO) { if (BufferIO->OwnFileWriter) FreeHook(BufferIO->FileWriter); if (DynamicBufferIOBuffer) { FreeHook(DynamicBufferIOBuffer); DynamicBufferIOBuffer = 0; VPBufferSize = 0; } } COMPILER_RT_VISIBILITY int lprofBufferIOWrite(ProfBufferIO *BufferIO, const uint8_t *Data, uint32_t Size) { /* Buffer is not large enough, it is time to flush. */ if (Size + BufferIO->CurOffset > BufferIO->BufferSz) { if (lprofBufferIOFlush(BufferIO) != 0) return -1; } /* Special case, bypass the buffer completely. */ ProfDataIOVec IO[] = {{Data, sizeof(uint8_t), Size, 0}}; if (Size > BufferIO->BufferSz) { if (BufferIO->FileWriter->Write(BufferIO->FileWriter, IO, 1)) return -1; } else { /* Write the data to buffer */ uint8_t *Buffer = BufferIO->BufferStart + BufferIO->CurOffset; ProfDataWriter BufferWriter; initBufferWriter(&BufferWriter, (char *)Buffer); lprofBufferWriter(&BufferWriter, IO, 1); BufferIO->CurOffset = (uint8_t *)BufferWriter.WriterCtx - BufferIO->BufferStart; } return 0; } COMPILER_RT_VISIBILITY int lprofBufferIOFlush(ProfBufferIO *BufferIO) { if (BufferIO->CurOffset) { ProfDataIOVec IO[] = { {BufferIO->BufferStart, sizeof(uint8_t), BufferIO->CurOffset, 0}}; if (BufferIO->FileWriter->Write(BufferIO->FileWriter, IO, 1)) return -1; BufferIO->CurOffset = 0; } return 0; } /* Write out value profile data for function specified with \c Data. * The implementation does not use the method \c serializeValueProfData * which depends on dynamic memory allocation. In this implementation, * value profile data is written out to \c BufferIO piecemeal. */ static int writeOneValueProfData(ProfBufferIO *BufferIO, VPDataReaderType *VPDataReader, const __llvm_profile_data *Data) { unsigned I, NumValueKinds = 0; ValueProfData VPHeader; uint8_t *SiteCountArray[IPVK_Last + 1]; for (I = 0; I <= IPVK_Last; I++) { if (!Data->NumValueSites[I]) SiteCountArray[I] = 0; else { uint32_t Sz = VPDataReader->GetValueProfRecordHeaderSize(Data->NumValueSites[I]) - offsetof(ValueProfRecord, SiteCountArray); /* Only use alloca for this small byte array to avoid excessive * stack growth. */ SiteCountArray[I] = (uint8_t *)COMPILER_RT_ALLOCA(Sz); memset(SiteCountArray[I], 0, Sz); } } /* If NumValueKinds returned is 0, there is nothing to write, report success and return. This should match the raw profile reader's behavior. */ if (!(NumValueKinds = VPDataReader->InitRTRecord(Data, SiteCountArray))) return 0; /* First write the header structure. */ VPHeader.TotalSize = VPDataReader->GetValueProfDataSize(); VPHeader.NumValueKinds = NumValueKinds; if (lprofBufferIOWrite(BufferIO, (const uint8_t *)&VPHeader, sizeof(ValueProfData))) return -1; /* Make sure nothing else needs to be written before value profile * records. */ if ((void *)VPDataReader->GetFirstValueProfRecord(&VPHeader) != (void *)(&VPHeader + 1)) return -1; /* Write out the value profile record for each value kind * one by one. */ for (I = 0; I <= IPVK_Last; I++) { uint32_t J; ValueProfRecord RecordHeader; /* The size of the value prof record header without counting the * site count array .*/ uint32_t RecordHeaderSize = offsetof(ValueProfRecord, SiteCountArray); uint32_t SiteCountArraySize; if (!Data->NumValueSites[I]) continue; /* Write out the record header. */ RecordHeader.Kind = I; RecordHeader.NumValueSites = Data->NumValueSites[I]; if (lprofBufferIOWrite(BufferIO, (const uint8_t *)&RecordHeader, RecordHeaderSize)) return -1; /* Write out the site value count array including padding space. */ SiteCountArraySize = VPDataReader->GetValueProfRecordHeaderSize(Data->NumValueSites[I]) - RecordHeaderSize; if (lprofBufferIOWrite(BufferIO, SiteCountArray[I], SiteCountArraySize)) return -1; /* Write out the value profile data for each value site. */ for (J = 0; J < Data->NumValueSites[I]; J++) { uint32_t NRead, NRemain; ValueProfNode *NextStartNode = 0; NRemain = VPDataReader->GetNumValueDataForSite(I, J); if (!NRemain) continue; /* Read and write out value data in small chunks till it is done. */ do { NRead = (NRemain > VPDataArraySize ? VPDataArraySize : NRemain); NextStartNode = VPDataReader->GetValueData(I, /* ValueKind */ J, /* Site */ &VPDataArray[0], NextStartNode, NRead); if (lprofBufferIOWrite(BufferIO, (const uint8_t *)&VPDataArray[0], NRead * sizeof(InstrProfValueData))) return -1; NRemain -= NRead; } while (NRemain != 0); } } /* All done report success. */ return 0; } static int writeValueProfData(ProfDataWriter *Writer, VPDataReaderType *VPDataReader, const __llvm_profile_data *DataBegin, const __llvm_profile_data *DataEnd) { ProfBufferIO *BufferIO; const __llvm_profile_data *DI = 0; if (!VPDataReader) return 0; BufferIO = lprofCreateBufferIO(Writer); for (DI = DataBegin; DI < DataEnd; DI++) { if (writeOneValueProfData(BufferIO, VPDataReader, DI)) return -1; } if (lprofBufferIOFlush(BufferIO) != 0) return -1; lprofDeleteBufferIO(BufferIO); return 0; } COMPILER_RT_VISIBILITY int lprofWriteData(ProfDataWriter *Writer, VPDataReaderType *VPDataReader, int SkipNameDataWrite) { /* Match logic in __llvm_profile_write_buffer(). */ const __llvm_profile_data *DataBegin = __llvm_profile_begin_data(); const __llvm_profile_data *DataEnd = __llvm_profile_end_data(); const char *CountersBegin = __llvm_profile_begin_counters(); const char *CountersEnd = __llvm_profile_end_counters(); const char *BitmapBegin = __llvm_profile_begin_bitmap(); const char *BitmapEnd = __llvm_profile_end_bitmap(); const char *NamesBegin = __llvm_profile_begin_names(); const char *NamesEnd = __llvm_profile_end_names(); const VTableProfData *VTableBegin = __llvm_profile_begin_vtables(); const VTableProfData *VTableEnd = __llvm_profile_end_vtables(); const char *VNamesBegin = __llvm_profile_begin_vtabnames(); const char *VNamesEnd = __llvm_profile_end_vtabnames(); return lprofWriteDataImpl(Writer, DataBegin, DataEnd, CountersBegin, CountersEnd, BitmapBegin, BitmapEnd, VPDataReader, NamesBegin, NamesEnd, VTableBegin, VTableEnd, VNamesBegin, VNamesEnd, SkipNameDataWrite); } COMPILER_RT_VISIBILITY int lprofWriteDataImpl(ProfDataWriter *Writer, const __llvm_profile_data *DataBegin, const __llvm_profile_data *DataEnd, const char *CountersBegin, const char *CountersEnd, const char *BitmapBegin, const char *BitmapEnd, VPDataReaderType *VPDataReader, const char *NamesBegin, const char *NamesEnd, const VTableProfData *VTableBegin, const VTableProfData *VTableEnd, const char *VNamesBegin, const char *VNamesEnd, int SkipNameDataWrite) { /* Calculate size of sections. */ const uint64_t DataSectionSize = __llvm_profile_get_data_size(DataBegin, DataEnd); const uint64_t NumData = __llvm_profile_get_num_data(DataBegin, DataEnd); const uint64_t CountersSectionSize = __llvm_profile_get_counters_size(CountersBegin, CountersEnd); const uint64_t NumCounters = __llvm_profile_get_num_counters(CountersBegin, CountersEnd); const uint64_t NumBitmapBytes = __llvm_profile_get_num_bitmap_bytes(BitmapBegin, BitmapEnd); const uint64_t NamesSize = __llvm_profile_get_name_size(NamesBegin, NamesEnd); const uint64_t NumVTables = __llvm_profile_get_num_vtable(VTableBegin, VTableEnd); const uint64_t VTableSectionSize = __llvm_profile_get_vtable_section_size(VTableBegin, VTableEnd); const uint64_t VNamesSize = __llvm_profile_get_name_size(VNamesBegin, VNamesEnd); /* Create the header. */ __llvm_profile_header Header; /* Determine how much padding is needed before/after the counters and after * the names. */ uint64_t PaddingBytesBeforeCounters, PaddingBytesAfterCounters, PaddingBytesAfterBitmapBytes, PaddingBytesAfterNames, PaddingBytesAfterVTable, PaddingBytesAfterVNames; if (__llvm_profile_get_padding_sizes_for_counters( DataSectionSize, CountersSectionSize, NumBitmapBytes, NamesSize, VTableSectionSize, VNamesSize, &PaddingBytesBeforeCounters, &PaddingBytesAfterCounters, &PaddingBytesAfterBitmapBytes, &PaddingBytesAfterNames, &PaddingBytesAfterVTable, &PaddingBytesAfterVNames) == -1) return -1; { /* Initialize header structure. */ #define INSTR_PROF_RAW_HEADER(Type, Name, Init) Header.Name = Init; #include "profile/InstrProfData.inc" } /* On WIN64, label differences are truncated 32-bit values. Truncate * CountersDelta to match. */ #ifdef _WIN64 Header.CountersDelta = (uint32_t)Header.CountersDelta; Header.BitmapDelta = (uint32_t)Header.BitmapDelta; #endif /* The data and names sections are omitted in lightweight mode. */ if (NumData == 0 && NamesSize == 0) { Header.CountersDelta = 0; Header.NamesDelta = 0; } /* Write the profile header. */ ProfDataIOVec IOVec[] = {{&Header, sizeof(__llvm_profile_header), 1, 0}}; if (Writer->Write(Writer, IOVec, sizeof(IOVec) / sizeof(*IOVec))) return -1; /* Write the binary id lengths and data. */ if (__llvm_write_binary_ids(Writer) == -1) return -1; /* Write the profile data. */ ProfDataIOVec IOVecData[] = { {DataBegin, sizeof(uint8_t), DataSectionSize, 0}, {NULL, sizeof(uint8_t), PaddingBytesBeforeCounters, 1}, {CountersBegin, sizeof(uint8_t), CountersSectionSize, 0}, {NULL, sizeof(uint8_t), PaddingBytesAfterCounters, 1}, {BitmapBegin, sizeof(uint8_t), NumBitmapBytes, 0}, {NULL, sizeof(uint8_t), PaddingBytesAfterBitmapBytes, 1}, {SkipNameDataWrite ? NULL : NamesBegin, sizeof(uint8_t), NamesSize, 0}, {NULL, sizeof(uint8_t), PaddingBytesAfterNames, 1}, {VTableBegin, sizeof(uint8_t), VTableSectionSize, 0}, {NULL, sizeof(uint8_t), PaddingBytesAfterVTable, 1}, {SkipNameDataWrite ? NULL : VNamesBegin, sizeof(uint8_t), VNamesSize, 0}, {NULL, sizeof(uint8_t), PaddingBytesAfterVNames, 1}}; if (Writer->Write(Writer, IOVecData, sizeof(IOVecData) / sizeof(*IOVecData))) return -1; /* Value profiling is not yet supported in continuous mode and profile * correlation mode. */ if (__llvm_profile_is_continuous_mode_enabled() || (NumData == 0 && NamesSize == 0)) return 0; return writeValueProfData(Writer, VPDataReader, DataBegin, DataEnd); } /* * Write binary id length and then its data, because binary id does not * have a fixed length. */ COMPILER_RT_VISIBILITY int lprofWriteOneBinaryId(ProfDataWriter *Writer, uint64_t BinaryIdLen, const uint8_t *BinaryIdData, uint64_t BinaryIdPadding) { ProfDataIOVec BinaryIdIOVec[] = { {&BinaryIdLen, sizeof(uint64_t), 1, 0}, {BinaryIdData, sizeof(uint8_t), BinaryIdLen, 0}, {NULL, sizeof(uint8_t), BinaryIdPadding, 1}, }; if (Writer->Write(Writer, BinaryIdIOVec, sizeof(BinaryIdIOVec) / sizeof(*BinaryIdIOVec))) return -1; /* Successfully wrote binary id, report success. */ return 0; }