Files
clang-p2996/llvm/lib/Analysis/MemoryProfileInfo.cpp
Teresa Johnson a4bdb27538 [MemProf] Use profiled lifetime access density directly
Now that the runtime tracks the lifetime access density directly, we can
use that directly in the threshold checks instead of less accurately
computing from other statistics.

Differential Revision: https://reviews.llvm.org/D149684
2023-05-02 15:19:34 -07:00

257 lines
9.8 KiB
C++

//===-- MemoryProfileInfo.cpp - memory profile info ------------------------==//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// This file contains utilities to analyze memory profile information.
//
//===----------------------------------------------------------------------===//
#include "llvm/Analysis/MemoryProfileInfo.h"
#include "llvm/Support/CommandLine.h"
using namespace llvm;
using namespace llvm::memprof;
#define DEBUG_TYPE "memory-profile-info"
// Upper bound on lifetime access density (accesses per byte per lifetime sec)
// for marking an allocation cold.
cl::opt<float> MemProfLifetimeAccessDensityColdThreshold(
"memprof-lifetime-access-density-cold-threshold", cl::init(0.05),
cl::Hidden,
cl::desc("The threshold the lifetime access density (accesses per byte per "
"lifetime sec) must be under to consider an allocation cold"));
// Lower bound on lifetime to mark an allocation cold (in addition to accesses
// per byte per sec above). This is to avoid pessimizing short lived objects.
cl::opt<unsigned> MemProfAveLifetimeColdThreshold(
"memprof-ave-lifetime-cold-threshold", cl::init(200), cl::Hidden,
cl::desc("The average lifetime (s) for an allocation to be considered "
"cold"));
AllocationType llvm::memprof::getAllocType(uint64_t TotalLifetimeAccessDensity,
uint64_t AllocCount,
uint64_t TotalLifetime) {
// The access densities are multiplied by 100 to hold 2 decimal places of
// precision, so need to divide by 100.
if (((float)TotalLifetimeAccessDensity) / AllocCount / 100 <
MemProfLifetimeAccessDensityColdThreshold
// Lifetime is expected to be in ms, so convert the threshold to ms.
&& ((float)TotalLifetime) / AllocCount >=
MemProfAveLifetimeColdThreshold * 1000)
return AllocationType::Cold;
return AllocationType::NotCold;
}
MDNode *llvm::memprof::buildCallstackMetadata(ArrayRef<uint64_t> CallStack,
LLVMContext &Ctx) {
std::vector<Metadata *> StackVals;
for (auto Id : CallStack) {
auto *StackValMD =
ValueAsMetadata::get(ConstantInt::get(Type::getInt64Ty(Ctx), Id));
StackVals.push_back(StackValMD);
}
return MDNode::get(Ctx, StackVals);
}
MDNode *llvm::memprof::getMIBStackNode(const MDNode *MIB) {
assert(MIB->getNumOperands() == 2);
// The stack metadata is the first operand of each memprof MIB metadata.
return cast<MDNode>(MIB->getOperand(0));
}
AllocationType llvm::memprof::getMIBAllocType(const MDNode *MIB) {
assert(MIB->getNumOperands() == 2);
// The allocation type is currently the second operand of each memprof
// MIB metadata. This will need to change as we add additional allocation
// types that can be applied based on the allocation profile data.
auto *MDS = dyn_cast<MDString>(MIB->getOperand(1));
assert(MDS);
if (MDS->getString().equals("cold"))
return AllocationType::Cold;
return AllocationType::NotCold;
}
static std::string getAllocTypeAttributeString(AllocationType Type) {
switch (Type) {
case AllocationType::NotCold:
return "notcold";
break;
case AllocationType::Cold:
return "cold";
break;
default:
assert(false && "Unexpected alloc type");
}
llvm_unreachable("invalid alloc type");
}
static void addAllocTypeAttribute(LLVMContext &Ctx, CallBase *CI,
AllocationType AllocType) {
auto AllocTypeString = getAllocTypeAttributeString(AllocType);
auto A = llvm::Attribute::get(Ctx, "memprof", AllocTypeString);
CI->addFnAttr(A);
}
bool llvm::memprof::hasSingleAllocType(uint8_t AllocTypes) {
const unsigned NumAllocTypes = llvm::popcount(AllocTypes);
assert(NumAllocTypes != 0);
return NumAllocTypes == 1;
}
void CallStackTrie::addCallStack(AllocationType AllocType,
ArrayRef<uint64_t> StackIds) {
bool First = true;
CallStackTrieNode *Curr = nullptr;
for (auto StackId : StackIds) {
// If this is the first stack frame, add or update alloc node.
if (First) {
First = false;
if (Alloc) {
assert(AllocStackId == StackId);
Alloc->AllocTypes |= static_cast<uint8_t>(AllocType);
} else {
AllocStackId = StackId;
Alloc = new CallStackTrieNode(AllocType);
}
Curr = Alloc;
continue;
}
// Update existing caller node if it exists.
auto Next = Curr->Callers.find(StackId);
if (Next != Curr->Callers.end()) {
Curr = Next->second;
Curr->AllocTypes |= static_cast<uint8_t>(AllocType);
continue;
}
// Otherwise add a new caller node.
auto *New = new CallStackTrieNode(AllocType);
Curr->Callers[StackId] = New;
Curr = New;
}
assert(Curr);
}
void CallStackTrie::addCallStack(MDNode *MIB) {
MDNode *StackMD = getMIBStackNode(MIB);
assert(StackMD);
std::vector<uint64_t> CallStack;
CallStack.reserve(StackMD->getNumOperands());
for (const auto &MIBStackIter : StackMD->operands()) {
auto *StackId = mdconst::dyn_extract<ConstantInt>(MIBStackIter);
assert(StackId);
CallStack.push_back(StackId->getZExtValue());
}
addCallStack(getMIBAllocType(MIB), CallStack);
}
static MDNode *createMIBNode(LLVMContext &Ctx,
std::vector<uint64_t> &MIBCallStack,
AllocationType AllocType) {
std::vector<Metadata *> MIBPayload(
{buildCallstackMetadata(MIBCallStack, Ctx)});
MIBPayload.push_back(
MDString::get(Ctx, getAllocTypeAttributeString(AllocType)));
return MDNode::get(Ctx, MIBPayload);
}
// Recursive helper to trim contexts and create metadata nodes.
// Caller should have pushed Node's loc to MIBCallStack. Doing this in the
// caller makes it simpler to handle the many early returns in this method.
bool CallStackTrie::buildMIBNodes(CallStackTrieNode *Node, LLVMContext &Ctx,
std::vector<uint64_t> &MIBCallStack,
std::vector<Metadata *> &MIBNodes,
bool CalleeHasAmbiguousCallerContext) {
// Trim context below the first node in a prefix with a single alloc type.
// Add an MIB record for the current call stack prefix.
if (hasSingleAllocType(Node->AllocTypes)) {
MIBNodes.push_back(
createMIBNode(Ctx, MIBCallStack, (AllocationType)Node->AllocTypes));
return true;
}
// We don't have a single allocation for all the contexts sharing this prefix,
// so recursively descend into callers in trie.
if (!Node->Callers.empty()) {
bool NodeHasAmbiguousCallerContext = Node->Callers.size() > 1;
bool AddedMIBNodesForAllCallerContexts = true;
for (auto &Caller : Node->Callers) {
MIBCallStack.push_back(Caller.first);
AddedMIBNodesForAllCallerContexts &=
buildMIBNodes(Caller.second, Ctx, MIBCallStack, MIBNodes,
NodeHasAmbiguousCallerContext);
// Remove Caller.
MIBCallStack.pop_back();
}
if (AddedMIBNodesForAllCallerContexts)
return true;
// We expect that the callers should be forced to add MIBs to disambiguate
// the context in this case (see below).
assert(!NodeHasAmbiguousCallerContext);
}
// If we reached here, then this node does not have a single allocation type,
// and we didn't add metadata for a longer call stack prefix including any of
// Node's callers. That means we never hit a single allocation type along all
// call stacks with this prefix. This can happen due to recursion collapsing
// or the stack being deeper than tracked by the profiler runtime, leading to
// contexts with different allocation types being merged. In that case, we
// trim the context just below the deepest context split, which is this
// node if the callee has an ambiguous caller context (multiple callers),
// since the recursive calls above returned false. Conservatively give it
// non-cold allocation type.
if (!CalleeHasAmbiguousCallerContext)
return false;
MIBNodes.push_back(createMIBNode(Ctx, MIBCallStack, AllocationType::NotCold));
return true;
}
// Build and attach the minimal necessary MIB metadata. If the alloc has a
// single allocation type, add a function attribute instead. Returns true if
// memprof metadata attached, false if not (attribute added).
bool CallStackTrie::buildAndAttachMIBMetadata(CallBase *CI) {
auto &Ctx = CI->getContext();
if (hasSingleAllocType(Alloc->AllocTypes)) {
addAllocTypeAttribute(Ctx, CI, (AllocationType)Alloc->AllocTypes);
return false;
}
std::vector<uint64_t> MIBCallStack;
MIBCallStack.push_back(AllocStackId);
std::vector<Metadata *> MIBNodes;
assert(!Alloc->Callers.empty() && "addCallStack has not been called yet");
buildMIBNodes(Alloc, Ctx, MIBCallStack, MIBNodes,
/*CalleeHasAmbiguousCallerContext=*/true);
assert(MIBCallStack.size() == 1 &&
"Should only be left with Alloc's location in stack");
CI->setMetadata(LLVMContext::MD_memprof, MDNode::get(Ctx, MIBNodes));
return true;
}
template <>
CallStack<MDNode, MDNode::op_iterator>::CallStackIterator::CallStackIterator(
const MDNode *N, bool End)
: N(N) {
if (!N)
return;
Iter = End ? N->op_end() : N->op_begin();
}
template <>
uint64_t
CallStack<MDNode, MDNode::op_iterator>::CallStackIterator::operator*() {
assert(Iter != N->op_end());
ConstantInt *StackIdCInt = mdconst::dyn_extract<ConstantInt>(*Iter);
assert(StackIdCInt);
return StackIdCInt->getZExtValue();
}
template <> uint64_t CallStack<MDNode, MDNode::op_iterator>::back() const {
assert(N);
return mdconst::dyn_extract<ConstantInt>(N->operands().back())
->getZExtValue();
}