/*===- InstrProfilingValue.c - Support library for PGO instrumentation ----===*\ |* |* The LLVM Compiler Infrastructure |* |* This file is distributed under the University of Illinois Open Source |* License. See LICENSE.TXT for details. |* \*===----------------------------------------------------------------------===*/ #include "InstrProfiling.h" #include "InstrProfilingInternal.h" #include "InstrProfilingUtil.h" /* For PS4 getenv shim. */ #include <limits.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #define INSTR_PROF_VALUE_PROF_DATA #define INSTR_PROF_COMMON_API_IMPL #include "InstrProfData.inc" static int hasStaticCounters = 1; static int OutOfNodesWarnings = 0; static int hasNonDefaultValsPerSite = 0; #define INSTR_PROF_MAX_VP_WARNS 10 #define INSTR_PROF_DEFAULT_NUM_VAL_PER_SITE 8 #define INSTR_PROF_VNODE_POOL_SIZE 1024 #ifndef _MSC_VER /* A shared static pool in addition to the vnodes statically * allocated by the compiler. */ COMPILER_RT_VISIBILITY ValueProfNode lprofValueProfNodes[INSTR_PROF_VNODE_POOL_SIZE] COMPILER_RT_SECTION( COMPILER_RT_SEG INSTR_PROF_VNODES_SECT_NAME_STR); #endif COMPILER_RT_VISIBILITY uint32_t VPMaxNumValsPerSite = INSTR_PROF_DEFAULT_NUM_VAL_PER_SITE; COMPILER_RT_VISIBILITY void lprofSetupValueProfiler() { const char *Str = 0; Str = getenv("LLVM_VP_MAX_NUM_VALS_PER_SITE"); if (Str && Str[0]) { VPMaxNumValsPerSite = atoi(Str); hasNonDefaultValsPerSite = 1; } if (VPMaxNumValsPerSite > INSTR_PROF_MAX_NUM_VAL_PER_SITE) VPMaxNumValsPerSite = INSTR_PROF_MAX_NUM_VAL_PER_SITE; } COMPILER_RT_VISIBILITY void lprofSetMaxValsPerSite(uint32_t MaxVals) { VPMaxNumValsPerSite = MaxVals; hasNonDefaultValsPerSite = 1; } /* This method is only used in value profiler mock testing. */ COMPILER_RT_VISIBILITY void __llvm_profile_set_num_value_sites(__llvm_profile_data *Data, uint32_t ValueKind, uint16_t NumValueSites) { *((uint16_t *)&Data->NumValueSites[ValueKind]) = NumValueSites; } /* This method is only used in value profiler mock testing. */ COMPILER_RT_VISIBILITY const __llvm_profile_data * __llvm_profile_iterate_data(const __llvm_profile_data *Data) { return Data + 1; } /* This method is only used in value profiler mock testing. */ COMPILER_RT_VISIBILITY void * __llvm_get_function_addr(const __llvm_profile_data *Data) { return Data->FunctionPointer; } /* Allocate an array that holds the pointers to the linked lists of * value profile counter nodes. The number of element of the array * is the total number of value profile sites instrumented. Returns * 0 if allocation fails. */ static int allocateValueProfileCounters(__llvm_profile_data *Data) { uint64_t NumVSites = 0; uint32_t VKI; /* This function will never be called when value site array is allocated statically at compile time. */ hasStaticCounters = 0; /* When dynamic allocation is enabled, allow tracking the max number of * values allowd. */ if (!hasNonDefaultValsPerSite) VPMaxNumValsPerSite = INSTR_PROF_MAX_NUM_VAL_PER_SITE; for (VKI = IPVK_First; VKI <= IPVK_Last; ++VKI) NumVSites += Data->NumValueSites[VKI]; ValueProfNode **Mem = (ValueProfNode **)calloc(NumVSites, sizeof(ValueProfNode *)); if (!Mem) return 0; if (!COMPILER_RT_BOOL_CMPXCHG(&Data->Values, 0, Mem)) { free(Mem); return 0; } return 1; } static ValueProfNode *allocateOneNode(__llvm_profile_data *Data, uint32_t Index, uint64_t Value) { ValueProfNode *Node; if (!hasStaticCounters) return (ValueProfNode *)calloc(1, sizeof(ValueProfNode)); /* Early check to avoid value wrapping around. */ if (CurrentVNode + 1 > EndVNode) { if (OutOfNodesWarnings++ < INSTR_PROF_MAX_VP_WARNS) { PROF_WARN("Unable to track new values: %s. " " Consider using option -mllvm -vp-counters-per-site=<n> to " "allocate more" " value profile counters at compile time. \n", "Running out of static counters"); } return 0; } Node = COMPILER_RT_PTR_FETCH_ADD(ValueProfNode, CurrentVNode, 1); /* Due to section padding, EndVNode point to a byte which is one pass * an incomplete VNode, so we need to skip the last incomplete node. */ if (Node + 1 > EndVNode) return 0; return Node; } COMPILER_RT_VISIBILITY void __llvm_profile_instrument_target(uint64_t TargetValue, void *Data, uint32_t CounterIndex) { __llvm_profile_data *PData = (__llvm_profile_data *)Data; if (!PData) return; if (!PData->Values) { if (!allocateValueProfileCounters(PData)) return; } ValueProfNode **ValueCounters = (ValueProfNode **)PData->Values; ValueProfNode *PrevVNode = NULL; ValueProfNode *MinCountVNode = NULL; ValueProfNode *CurVNode = ValueCounters[CounterIndex]; uint64_t MinCount = UINT64_MAX; uint8_t VDataCount = 0; while (CurVNode) { if (TargetValue == CurVNode->Value) { CurVNode->Count++; return; } if (CurVNode->Count < MinCount) { MinCount = CurVNode->Count; MinCountVNode = CurVNode; } PrevVNode = CurVNode; CurVNode = CurVNode->Next; ++VDataCount; } if (VDataCount >= VPMaxNumValsPerSite) { /* Bump down the min count node's count. If it reaches 0, * evict it. This eviction/replacement policy makes hot * targets more sticky while cold targets less so. In other * words, it makes it less likely for the hot targets to be * prematurally evicted during warmup/establishment period, * when their counts are still low. In a special case when * the number of values tracked is reduced to only one, this * policy will guarantee that the dominating target with >50% * total count will survive in the end. Note that this scheme * allows the runtime to track the min count node in an adaptive * manner. It can correct previous mistakes and eventually * lock on a cold target that is alread in stable state. * * In very rare cases, this replacement scheme may still lead * to target loss. For instance, out of \c N value slots, \c N-1 * slots are occupied by luke warm targets during the warmup * period and the remaining one slot is competed by two or more * very hot targets. If those hot targets occur in an interleaved * way, none of them will survive (gain enough weight to throw out * other established entries) due to the ping-pong effect. * To handle this situation, user can choose to increase the max * number of tracked values per value site. Alternatively, a more * expensive eviction mechanism can be implemented. It requires * the runtime to track the total number of evictions per-site. * When the total number of evictions reaches certain threshold, * the runtime can wipe out more than one lowest count entries * to give space for hot targets. */ if (!(--MinCountVNode->Count)) { CurVNode = MinCountVNode; CurVNode->Value = TargetValue; CurVNode->Count++; } return; } CurVNode = allocateOneNode(PData, CounterIndex, TargetValue); if (!CurVNode) return; CurVNode->Value = TargetValue; CurVNode->Count++; uint32_t Success = 0; if (!ValueCounters[CounterIndex]) Success = COMPILER_RT_BOOL_CMPXCHG(&ValueCounters[CounterIndex], 0, CurVNode); else if (PrevVNode && !PrevVNode->Next) Success = COMPILER_RT_BOOL_CMPXCHG(&(PrevVNode->Next), 0, CurVNode); if (!Success && !hasStaticCounters) { free(CurVNode); return; } } /* * A wrapper struct that represents value profile runtime data. * Like InstrProfRecord class which is used by profiling host tools, * ValueProfRuntimeRecord also implements the abstract intefaces defined in * ValueProfRecordClosure so that the runtime data can be serialized using * shared C implementation. */ typedef struct ValueProfRuntimeRecord { const __llvm_profile_data *Data; ValueProfNode **NodesKind[IPVK_Last + 1]; uint8_t **SiteCountArray; } ValueProfRuntimeRecord; /* ValueProfRecordClosure Interface implementation. */ static uint32_t getNumValueSitesRT(const void *R, uint32_t VK) { return ((const ValueProfRuntimeRecord *)R)->Data->NumValueSites[VK]; } static uint32_t getNumValueDataRT(const void *R, uint32_t VK) { uint32_t S = 0, I; const ValueProfRuntimeRecord *Record = (const ValueProfRuntimeRecord *)R; if (Record->SiteCountArray[VK] == INSTR_PROF_NULLPTR) return 0; for (I = 0; I < Record->Data->NumValueSites[VK]; I++) S += Record->SiteCountArray[VK][I]; return S; } static uint32_t getNumValueDataForSiteRT(const void *R, uint32_t VK, uint32_t S) { const ValueProfRuntimeRecord *Record = (const ValueProfRuntimeRecord *)R; return Record->SiteCountArray[VK][S]; } static ValueProfRuntimeRecord RTRecord; static ValueProfRecordClosure RTRecordClosure = { &RTRecord, INSTR_PROF_NULLPTR, /* GetNumValueKinds */ getNumValueSitesRT, getNumValueDataRT, getNumValueDataForSiteRT, INSTR_PROF_NULLPTR, /* RemapValueData */ INSTR_PROF_NULLPTR, /* GetValueForSite, */ INSTR_PROF_NULLPTR /* AllocValueProfData */ }; static uint32_t initializeValueProfRuntimeRecord(const __llvm_profile_data *Data, uint8_t *SiteCountArray[]) { unsigned I, J, S = 0, NumValueKinds = 0; ValueProfNode **Nodes = (ValueProfNode **)Data->Values; RTRecord.Data = Data; RTRecord.SiteCountArray = SiteCountArray; for (I = 0; I <= IPVK_Last; I++) { uint16_t N = Data->NumValueSites[I]; if (!N) continue; NumValueKinds++; RTRecord.NodesKind[I] = Nodes ? &Nodes[S] : INSTR_PROF_NULLPTR; for (J = 0; J < N; J++) { /* Compute value count for each site. */ uint32_t C = 0; ValueProfNode *Site = Nodes ? RTRecord.NodesKind[I][J] : INSTR_PROF_NULLPTR; while (Site) { C++; Site = Site->Next; } if (C > UCHAR_MAX) C = UCHAR_MAX; RTRecord.SiteCountArray[I][J] = C; } S += N; } return NumValueKinds; } static ValueProfNode *getNextNValueData(uint32_t VK, uint32_t Site, InstrProfValueData *Dst, ValueProfNode *StartNode, uint32_t N) { unsigned I; ValueProfNode *VNode = StartNode ? StartNode : RTRecord.NodesKind[VK][Site]; for (I = 0; I < N; I++) { Dst[I].Value = VNode->Value; Dst[I].Count = VNode->Count; VNode = VNode->Next; } return VNode; } static uint32_t getValueProfDataSizeWrapper(void) { return getValueProfDataSize(&RTRecordClosure); } static uint32_t getNumValueDataForSiteWrapper(uint32_t VK, uint32_t S) { return getNumValueDataForSiteRT(&RTRecord, VK, S); } static VPDataReaderType TheVPDataReader = { initializeValueProfRuntimeRecord, getValueProfRecordHeaderSize, getFirstValueProfRecord, getNumValueDataForSiteWrapper, getValueProfDataSizeWrapper, getNextNValueData}; COMPILER_RT_VISIBILITY VPDataReaderType *lprofGetVPDataReader() { return &TheVPDataReader; }