llvm/utils/TableGen/DAGISelMatcherEmitter.cpp
Daniel Sanders d5d860727b [tablegen] Use categories on options that only matter to one emitter.
Summary:
The categories are emitted in a strange order in this patch due to a bug in the
CommandLine library.

Reviewers: ab

Reviewed By: ab

Subscribers: ab, llvm-commits

Differential Revision: https://reviews.llvm.org/D30995

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@298843 91177308-0d34-0410-b5e6-96231b3b80d8
2017-03-27 13:15:13 +00:00

983 lines
33 KiB
C++

//===- DAGISelMatcherEmitter.cpp - Matcher Emitter ------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains code to generate C++ code for a matcher.
//
//===----------------------------------------------------------------------===//
#include "CodeGenDAGPatterns.h"
#include "DAGISelMatcher.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/MapVector.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/TinyPtrVector.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/FormattedStream.h"
#include "llvm/Support/SourceMgr.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/Record.h"
using namespace llvm;
enum {
CommentIndent = 30
};
cl::OptionCategory DAGISelCat("Options for -gen-dag-isel");
// To reduce generated source code size.
static cl::opt<bool> OmitComments("omit-comments",
cl::desc("Do not generate comments"),
cl::init(false), cl::cat(DAGISelCat));
static cl::opt<bool> InstrumentCoverage(
"instrument-coverage",
cl::desc("Generates tables to help identify patterns matched"),
cl::init(false), cl::cat(DAGISelCat));
namespace {
class MatcherTableEmitter {
const CodeGenDAGPatterns &CGP;
DenseMap<TreePattern *, unsigned> NodePredicateMap;
std::vector<TreePredicateFn> NodePredicates;
// We de-duplicate the predicates by code string, and use this map to track
// all the patterns with "identical" predicates.
StringMap<TinyPtrVector<TreePattern *>> NodePredicatesByCodeToRun;
StringMap<unsigned> PatternPredicateMap;
std::vector<std::string> PatternPredicates;
DenseMap<const ComplexPattern*, unsigned> ComplexPatternMap;
std::vector<const ComplexPattern*> ComplexPatterns;
DenseMap<Record*, unsigned> NodeXFormMap;
std::vector<Record*> NodeXForms;
std::vector<std::string> VecIncludeStrings;
MapVector<std::string, unsigned, StringMap<unsigned> > VecPatterns;
unsigned getPatternIdxFromTable(std::string &&P, std::string &&include_loc) {
const auto It = VecPatterns.find(P);
if (It == VecPatterns.end()) {
VecPatterns.insert(make_pair(std::move(P), VecPatterns.size()));
VecIncludeStrings.push_back(std::move(include_loc));
return VecIncludeStrings.size() - 1;
}
return It->second;
}
public:
MatcherTableEmitter(const CodeGenDAGPatterns &cgp)
: CGP(cgp) {}
unsigned EmitMatcherList(const Matcher *N, unsigned Indent,
unsigned StartIdx, formatted_raw_ostream &OS);
void EmitPredicateFunctions(formatted_raw_ostream &OS);
void EmitHistogram(const Matcher *N, formatted_raw_ostream &OS);
void EmitPatternMatchTable(raw_ostream &OS);
private:
unsigned EmitMatcher(const Matcher *N, unsigned Indent, unsigned CurrentIdx,
formatted_raw_ostream &OS);
unsigned getNodePredicate(TreePredicateFn Pred) {
TreePattern *TP = Pred.getOrigPatFragRecord();
unsigned &Entry = NodePredicateMap[TP];
if (Entry == 0) {
TinyPtrVector<TreePattern *> &SameCodePreds =
NodePredicatesByCodeToRun[Pred.getCodeToRunOnSDNode()];
if (SameCodePreds.empty()) {
// We've never seen a predicate with the same code: allocate an entry.
NodePredicates.push_back(Pred);
Entry = NodePredicates.size();
} else {
// We did see an identical predicate: re-use it.
Entry = NodePredicateMap[SameCodePreds.front()];
assert(Entry != 0);
}
// In both cases, we've never seen this particular predicate before, so
// mark it in the list of predicates sharing the same code.
SameCodePreds.push_back(TP);
}
return Entry-1;
}
unsigned getPatternPredicate(StringRef PredName) {
unsigned &Entry = PatternPredicateMap[PredName];
if (Entry == 0) {
PatternPredicates.push_back(PredName.str());
Entry = PatternPredicates.size();
}
return Entry-1;
}
unsigned getComplexPat(const ComplexPattern &P) {
unsigned &Entry = ComplexPatternMap[&P];
if (Entry == 0) {
ComplexPatterns.push_back(&P);
Entry = ComplexPatterns.size();
}
return Entry-1;
}
unsigned getNodeXFormID(Record *Rec) {
unsigned &Entry = NodeXFormMap[Rec];
if (Entry == 0) {
NodeXForms.push_back(Rec);
Entry = NodeXForms.size();
}
return Entry-1;
}
};
} // end anonymous namespace.
static std::string GetPatFromTreePatternNode(const TreePatternNode *N) {
std::string str;
raw_string_ostream Stream(str);
Stream << *N;
Stream.str();
return str;
}
static unsigned GetVBRSize(unsigned Val) {
if (Val <= 127) return 1;
unsigned NumBytes = 0;
while (Val >= 128) {
Val >>= 7;
++NumBytes;
}
return NumBytes+1;
}
/// EmitVBRValue - Emit the specified value as a VBR, returning the number of
/// bytes emitted.
static uint64_t EmitVBRValue(uint64_t Val, raw_ostream &OS) {
if (Val <= 127) {
OS << Val << ", ";
return 1;
}
uint64_t InVal = Val;
unsigned NumBytes = 0;
while (Val >= 128) {
OS << (Val&127) << "|128,";
Val >>= 7;
++NumBytes;
}
OS << Val;
if (!OmitComments)
OS << "/*" << InVal << "*/";
OS << ", ";
return NumBytes+1;
}
// This is expensive and slow.
static std::string getIncludePath(const Record *R) {
std::string str;
raw_string_ostream Stream(str);
auto Locs = R->getLoc();
SMLoc L;
if (Locs.size() > 1) {
// Get where the pattern prototype was instantiated
L = Locs[1];
} else if (Locs.size() == 1) {
L = Locs[0];
}
unsigned CurBuf = SrcMgr.FindBufferContainingLoc(L);
assert(CurBuf && "Invalid or unspecified location!");
Stream << SrcMgr.getBufferInfo(CurBuf).Buffer->getBufferIdentifier() << ":"
<< SrcMgr.FindLineNumber(L, CurBuf);
Stream.str();
return str;
}
void MatcherTableEmitter::EmitPatternMatchTable(raw_ostream &OS) {
assert(isUInt<16>(VecPatterns.size()) &&
"Using only 16 bits to encode offset into Pattern Table");
assert(VecPatterns.size() == VecIncludeStrings.size() &&
"The sizes of Pattern and include vectors should be the same");
OS << "StringRef getPatternForIndex(unsigned Index) override {\n";
OS << "static const char * PATTERN_MATCH_TABLE[] = {\n";
for (const auto &It : VecPatterns) {
OS << "\"" << It.first << "\",\n";
}
OS << "\n};";
OS << "\nreturn StringRef(PATTERN_MATCH_TABLE[Index]);";
OS << "\n}";
OS << "\nStringRef getIncludePathForIndex(unsigned Index) override {\n";
OS << "static const char * INCLUDE_PATH_TABLE[] = {\n";
for (const auto &It : VecIncludeStrings) {
OS << "\"" << It << "\",\n";
}
OS << "\n};";
OS << "\nreturn StringRef(INCLUDE_PATH_TABLE[Index]);";
OS << "\n}";
}
/// EmitMatcher - Emit bytes for the specified matcher and return
/// the number of bytes emitted.
unsigned MatcherTableEmitter::
EmitMatcher(const Matcher *N, unsigned Indent, unsigned CurrentIdx,
formatted_raw_ostream &OS) {
OS.PadToColumn(Indent*2);
switch (N->getKind()) {
case Matcher::Scope: {
const ScopeMatcher *SM = cast<ScopeMatcher>(N);
assert(SM->getNext() == nullptr && "Shouldn't have next after scope");
unsigned StartIdx = CurrentIdx;
// Emit all of the children.
for (unsigned i = 0, e = SM->getNumChildren(); i != e; ++i) {
if (i == 0) {
OS << "OPC_Scope, ";
++CurrentIdx;
} else {
if (!OmitComments) {
OS << "/*" << CurrentIdx << "*/";
OS.PadToColumn(Indent*2) << "/*Scope*/ ";
} else
OS.PadToColumn(Indent*2);
}
// We need to encode the child and the offset of the failure code before
// emitting either of them. Handle this by buffering the output into a
// string while we get the size. Unfortunately, the offset of the
// children depends on the VBR size of the child, so for large children we
// have to iterate a bit.
SmallString<128> TmpBuf;
unsigned ChildSize = 0;
unsigned VBRSize = 0;
do {
VBRSize = GetVBRSize(ChildSize);
TmpBuf.clear();
raw_svector_ostream OS(TmpBuf);
formatted_raw_ostream FOS(OS);
ChildSize = EmitMatcherList(SM->getChild(i), Indent+1,
CurrentIdx+VBRSize, FOS);
} while (GetVBRSize(ChildSize) != VBRSize);
assert(ChildSize != 0 && "Should not have a zero-sized child!");
CurrentIdx += EmitVBRValue(ChildSize, OS);
if (!OmitComments) {
OS << "/*->" << CurrentIdx+ChildSize << "*/";
if (i == 0)
OS.PadToColumn(CommentIndent) << "// " << SM->getNumChildren()
<< " children in Scope";
}
OS << '\n' << TmpBuf;
CurrentIdx += ChildSize;
}
// Emit a zero as a sentinel indicating end of 'Scope'.
if (!OmitComments)
OS << "/*" << CurrentIdx << "*/";
OS.PadToColumn(Indent*2) << "0, ";
if (!OmitComments)
OS << "/*End of Scope*/";
OS << '\n';
return CurrentIdx - StartIdx + 1;
}
case Matcher::RecordNode:
OS << "OPC_RecordNode,";
if (!OmitComments)
OS.PadToColumn(CommentIndent) << "// #"
<< cast<RecordMatcher>(N)->getResultNo() << " = "
<< cast<RecordMatcher>(N)->getWhatFor();
OS << '\n';
return 1;
case Matcher::RecordChild:
OS << "OPC_RecordChild" << cast<RecordChildMatcher>(N)->getChildNo()
<< ',';
if (!OmitComments)
OS.PadToColumn(CommentIndent) << "// #"
<< cast<RecordChildMatcher>(N)->getResultNo() << " = "
<< cast<RecordChildMatcher>(N)->getWhatFor();
OS << '\n';
return 1;
case Matcher::RecordMemRef:
OS << "OPC_RecordMemRef,\n";
return 1;
case Matcher::CaptureGlueInput:
OS << "OPC_CaptureGlueInput,\n";
return 1;
case Matcher::MoveChild: {
const auto *MCM = cast<MoveChildMatcher>(N);
OS << "OPC_MoveChild";
// Handle the specialized forms.
if (MCM->getChildNo() >= 8)
OS << ", ";
OS << MCM->getChildNo() << ",\n";
return (MCM->getChildNo() >= 8) ? 2 : 1;
}
case Matcher::MoveParent:
OS << "OPC_MoveParent,\n";
return 1;
case Matcher::CheckSame:
OS << "OPC_CheckSame, "
<< cast<CheckSameMatcher>(N)->getMatchNumber() << ",\n";
return 2;
case Matcher::CheckChildSame:
OS << "OPC_CheckChild"
<< cast<CheckChildSameMatcher>(N)->getChildNo() << "Same, "
<< cast<CheckChildSameMatcher>(N)->getMatchNumber() << ",\n";
return 2;
case Matcher::CheckPatternPredicate: {
StringRef Pred =cast<CheckPatternPredicateMatcher>(N)->getPredicate();
OS << "OPC_CheckPatternPredicate, " << getPatternPredicate(Pred) << ',';
if (!OmitComments)
OS.PadToColumn(CommentIndent) << "// " << Pred;
OS << '\n';
return 2;
}
case Matcher::CheckPredicate: {
TreePredicateFn Pred = cast<CheckPredicateMatcher>(N)->getPredicate();
OS << "OPC_CheckPredicate, " << getNodePredicate(Pred) << ',';
if (!OmitComments)
OS.PadToColumn(CommentIndent) << "// " << Pred.getFnName();
OS << '\n';
return 2;
}
case Matcher::CheckOpcode:
OS << "OPC_CheckOpcode, TARGET_VAL("
<< cast<CheckOpcodeMatcher>(N)->getOpcode().getEnumName() << "),\n";
return 3;
case Matcher::SwitchOpcode:
case Matcher::SwitchType: {
unsigned StartIdx = CurrentIdx;
unsigned NumCases;
if (const SwitchOpcodeMatcher *SOM = dyn_cast<SwitchOpcodeMatcher>(N)) {
OS << "OPC_SwitchOpcode ";
NumCases = SOM->getNumCases();
} else {
OS << "OPC_SwitchType ";
NumCases = cast<SwitchTypeMatcher>(N)->getNumCases();
}
if (!OmitComments)
OS << "/*" << NumCases << " cases */";
OS << ", ";
++CurrentIdx;
// For each case we emit the size, then the opcode, then the matcher.
for (unsigned i = 0, e = NumCases; i != e; ++i) {
const Matcher *Child;
unsigned IdxSize;
if (const SwitchOpcodeMatcher *SOM = dyn_cast<SwitchOpcodeMatcher>(N)) {
Child = SOM->getCaseMatcher(i);
IdxSize = 2; // size of opcode in table is 2 bytes.
} else {
Child = cast<SwitchTypeMatcher>(N)->getCaseMatcher(i);
IdxSize = 1; // size of type in table is 1 byte.
}
// We need to encode the opcode and the offset of the case code before
// emitting the case code. Handle this by buffering the output into a
// string while we get the size. Unfortunately, the offset of the
// children depends on the VBR size of the child, so for large children we
// have to iterate a bit.
SmallString<128> TmpBuf;
unsigned ChildSize = 0;
unsigned VBRSize = 0;
do {
VBRSize = GetVBRSize(ChildSize);
TmpBuf.clear();
raw_svector_ostream OS(TmpBuf);
formatted_raw_ostream FOS(OS);
ChildSize = EmitMatcherList(Child, Indent+1, CurrentIdx+VBRSize+IdxSize,
FOS);
} while (GetVBRSize(ChildSize) != VBRSize);
assert(ChildSize != 0 && "Should not have a zero-sized child!");
if (i != 0) {
if (!OmitComments)
OS << "/*" << CurrentIdx << "*/";
OS.PadToColumn(Indent*2);
if (!OmitComments)
OS << (isa<SwitchOpcodeMatcher>(N) ?
"/*SwitchOpcode*/ " : "/*SwitchType*/ ");
}
// Emit the VBR.
CurrentIdx += EmitVBRValue(ChildSize, OS);
if (const SwitchOpcodeMatcher *SOM = dyn_cast<SwitchOpcodeMatcher>(N))
OS << "TARGET_VAL(" << SOM->getCaseOpcode(i).getEnumName() << "),";
else
OS << getEnumName(cast<SwitchTypeMatcher>(N)->getCaseType(i)) << ',';
CurrentIdx += IdxSize;
if (!OmitComments)
OS << "// ->" << CurrentIdx+ChildSize;
OS << '\n';
OS << TmpBuf;
CurrentIdx += ChildSize;
}
// Emit the final zero to terminate the switch.
if (!OmitComments)
OS << "/*" << CurrentIdx << "*/";
OS.PadToColumn(Indent*2) << "0, ";
if (!OmitComments)
OS << (isa<SwitchOpcodeMatcher>(N) ?
"// EndSwitchOpcode" : "// EndSwitchType");
OS << '\n';
++CurrentIdx;
return CurrentIdx-StartIdx;
}
case Matcher::CheckType:
assert(cast<CheckTypeMatcher>(N)->getResNo() == 0 &&
"FIXME: Add support for CheckType of resno != 0");
OS << "OPC_CheckType, "
<< getEnumName(cast<CheckTypeMatcher>(N)->getType()) << ",\n";
return 2;
case Matcher::CheckChildType:
OS << "OPC_CheckChild"
<< cast<CheckChildTypeMatcher>(N)->getChildNo() << "Type, "
<< getEnumName(cast<CheckChildTypeMatcher>(N)->getType()) << ",\n";
return 2;
case Matcher::CheckInteger: {
OS << "OPC_CheckInteger, ";
unsigned Bytes=1+EmitVBRValue(cast<CheckIntegerMatcher>(N)->getValue(), OS);
OS << '\n';
return Bytes;
}
case Matcher::CheckChildInteger: {
OS << "OPC_CheckChild" << cast<CheckChildIntegerMatcher>(N)->getChildNo()
<< "Integer, ";
unsigned Bytes=1+EmitVBRValue(cast<CheckChildIntegerMatcher>(N)->getValue(),
OS);
OS << '\n';
return Bytes;
}
case Matcher::CheckCondCode:
OS << "OPC_CheckCondCode, ISD::"
<< cast<CheckCondCodeMatcher>(N)->getCondCodeName() << ",\n";
return 2;
case Matcher::CheckValueType:
OS << "OPC_CheckValueType, MVT::"
<< cast<CheckValueTypeMatcher>(N)->getTypeName() << ",\n";
return 2;
case Matcher::CheckComplexPat: {
const CheckComplexPatMatcher *CCPM = cast<CheckComplexPatMatcher>(N);
const ComplexPattern &Pattern = CCPM->getPattern();
OS << "OPC_CheckComplexPat, /*CP*/" << getComplexPat(Pattern) << ", /*#*/"
<< CCPM->getMatchNumber() << ',';
if (!OmitComments) {
OS.PadToColumn(CommentIndent) << "// " << Pattern.getSelectFunc();
OS << ":$" << CCPM->getName();
for (unsigned i = 0, e = Pattern.getNumOperands(); i != e; ++i)
OS << " #" << CCPM->getFirstResult()+i;
if (Pattern.hasProperty(SDNPHasChain))
OS << " + chain result";
}
OS << '\n';
return 3;
}
case Matcher::CheckAndImm: {
OS << "OPC_CheckAndImm, ";
unsigned Bytes=1+EmitVBRValue(cast<CheckAndImmMatcher>(N)->getValue(), OS);
OS << '\n';
return Bytes;
}
case Matcher::CheckOrImm: {
OS << "OPC_CheckOrImm, ";
unsigned Bytes = 1+EmitVBRValue(cast<CheckOrImmMatcher>(N)->getValue(), OS);
OS << '\n';
return Bytes;
}
case Matcher::CheckFoldableChainNode:
OS << "OPC_CheckFoldableChainNode,\n";
return 1;
case Matcher::EmitInteger: {
int64_t Val = cast<EmitIntegerMatcher>(N)->getValue();
OS << "OPC_EmitInteger, "
<< getEnumName(cast<EmitIntegerMatcher>(N)->getVT()) << ", ";
unsigned Bytes = 2+EmitVBRValue(Val, OS);
OS << '\n';
return Bytes;
}
case Matcher::EmitStringInteger: {
const std::string &Val = cast<EmitStringIntegerMatcher>(N)->getValue();
// These should always fit into one byte.
OS << "OPC_EmitInteger, "
<< getEnumName(cast<EmitStringIntegerMatcher>(N)->getVT()) << ", "
<< Val << ",\n";
return 3;
}
case Matcher::EmitRegister: {
const EmitRegisterMatcher *Matcher = cast<EmitRegisterMatcher>(N);
const CodeGenRegister *Reg = Matcher->getReg();
// If the enum value of the register is larger than one byte can handle,
// use EmitRegister2.
if (Reg && Reg->EnumValue > 255) {
OS << "OPC_EmitRegister2, " << getEnumName(Matcher->getVT()) << ", ";
OS << "TARGET_VAL(" << getQualifiedName(Reg->TheDef) << "),\n";
return 4;
} else {
OS << "OPC_EmitRegister, " << getEnumName(Matcher->getVT()) << ", ";
if (Reg) {
OS << getQualifiedName(Reg->TheDef) << ",\n";
} else {
OS << "0 ";
if (!OmitComments)
OS << "/*zero_reg*/";
OS << ",\n";
}
return 3;
}
}
case Matcher::EmitConvertToTarget:
OS << "OPC_EmitConvertToTarget, "
<< cast<EmitConvertToTargetMatcher>(N)->getSlot() << ",\n";
return 2;
case Matcher::EmitMergeInputChains: {
const EmitMergeInputChainsMatcher *MN =
cast<EmitMergeInputChainsMatcher>(N);
// Handle the specialized forms OPC_EmitMergeInputChains1_0, 1_1, and 1_2.
if (MN->getNumNodes() == 1 && MN->getNode(0) < 3) {
OS << "OPC_EmitMergeInputChains1_" << MN->getNode(0) << ",\n";
return 1;
}
OS << "OPC_EmitMergeInputChains, " << MN->getNumNodes() << ", ";
for (unsigned i = 0, e = MN->getNumNodes(); i != e; ++i)
OS << MN->getNode(i) << ", ";
OS << '\n';
return 2+MN->getNumNodes();
}
case Matcher::EmitCopyToReg:
OS << "OPC_EmitCopyToReg, "
<< cast<EmitCopyToRegMatcher>(N)->getSrcSlot() << ", "
<< getQualifiedName(cast<EmitCopyToRegMatcher>(N)->getDestPhysReg())
<< ",\n";
return 3;
case Matcher::EmitNodeXForm: {
const EmitNodeXFormMatcher *XF = cast<EmitNodeXFormMatcher>(N);
OS << "OPC_EmitNodeXForm, " << getNodeXFormID(XF->getNodeXForm()) << ", "
<< XF->getSlot() << ',';
if (!OmitComments)
OS.PadToColumn(CommentIndent) << "// "<<XF->getNodeXForm()->getName();
OS <<'\n';
return 3;
}
case Matcher::EmitNode:
case Matcher::MorphNodeTo: {
auto NumCoveredBytes = 0;
if (InstrumentCoverage) {
if (const MorphNodeToMatcher *SNT = dyn_cast<MorphNodeToMatcher>(N)) {
NumCoveredBytes = 3;
OS << "OPC_Coverage, ";
std::string src =
GetPatFromTreePatternNode(SNT->getPattern().getSrcPattern());
std::string dst =
GetPatFromTreePatternNode(SNT->getPattern().getDstPattern());
Record *PatRecord = SNT->getPattern().getSrcRecord();
std::string include_src = getIncludePath(PatRecord);
unsigned Offset =
getPatternIdxFromTable(src + " -> " + dst, std::move(include_src));
OS << "TARGET_VAL(" << Offset << "),\n";
OS.PadToColumn(Indent * 2);
}
}
const EmitNodeMatcherCommon *EN = cast<EmitNodeMatcherCommon>(N);
OS << (isa<EmitNodeMatcher>(EN) ? "OPC_EmitNode" : "OPC_MorphNodeTo");
bool CompressVTs = EN->getNumVTs() < 3;
if (CompressVTs)
OS << EN->getNumVTs();
OS << ", TARGET_VAL(" << EN->getOpcodeName() << "), 0";
if (EN->hasChain()) OS << "|OPFL_Chain";
if (EN->hasInFlag()) OS << "|OPFL_GlueInput";
if (EN->hasOutFlag()) OS << "|OPFL_GlueOutput";
if (EN->hasMemRefs()) OS << "|OPFL_MemRefs";
if (EN->getNumFixedArityOperands() != -1)
OS << "|OPFL_Variadic" << EN->getNumFixedArityOperands();
OS << ",\n";
OS.PadToColumn(Indent*2+4);
if (!CompressVTs) {
OS << EN->getNumVTs();
if (!OmitComments)
OS << "/*#VTs*/";
OS << ", ";
}
for (unsigned i = 0, e = EN->getNumVTs(); i != e; ++i)
OS << getEnumName(EN->getVT(i)) << ", ";
OS << EN->getNumOperands();
if (!OmitComments)
OS << "/*#Ops*/";
OS << ", ";
unsigned NumOperandBytes = 0;
for (unsigned i = 0, e = EN->getNumOperands(); i != e; ++i)
NumOperandBytes += EmitVBRValue(EN->getOperand(i), OS);
if (!OmitComments) {
// Print the result #'s for EmitNode.
if (const EmitNodeMatcher *E = dyn_cast<EmitNodeMatcher>(EN)) {
if (unsigned NumResults = EN->getNumVTs()) {
OS.PadToColumn(CommentIndent) << "// Results =";
unsigned First = E->getFirstResultSlot();
for (unsigned i = 0; i != NumResults; ++i)
OS << " #" << First+i;
}
}
OS << '\n';
if (const MorphNodeToMatcher *SNT = dyn_cast<MorphNodeToMatcher>(N)) {
OS.PadToColumn(Indent*2) << "// Src: "
<< *SNT->getPattern().getSrcPattern() << " - Complexity = "
<< SNT->getPattern().getPatternComplexity(CGP) << '\n';
OS.PadToColumn(Indent*2) << "// Dst: "
<< *SNT->getPattern().getDstPattern() << '\n';
}
} else
OS << '\n';
return 5 + !CompressVTs + EN->getNumVTs() + NumOperandBytes +
NumCoveredBytes;
}
case Matcher::CompleteMatch: {
const CompleteMatchMatcher *CM = cast<CompleteMatchMatcher>(N);
auto NumCoveredBytes = 0;
if (InstrumentCoverage) {
NumCoveredBytes = 3;
OS << "OPC_Coverage, ";
std::string src =
GetPatFromTreePatternNode(CM->getPattern().getSrcPattern());
std::string dst =
GetPatFromTreePatternNode(CM->getPattern().getDstPattern());
Record *PatRecord = CM->getPattern().getSrcRecord();
std::string include_src = getIncludePath(PatRecord);
unsigned Offset =
getPatternIdxFromTable(src + " -> " + dst, std::move(include_src));
OS << "TARGET_VAL(" << Offset << "),\n";
OS.PadToColumn(Indent * 2);
}
OS << "OPC_CompleteMatch, " << CM->getNumResults() << ", ";
unsigned NumResultBytes = 0;
for (unsigned i = 0, e = CM->getNumResults(); i != e; ++i)
NumResultBytes += EmitVBRValue(CM->getResult(i), OS);
OS << '\n';
if (!OmitComments) {
OS.PadToColumn(Indent*2) << "// Src: "
<< *CM->getPattern().getSrcPattern() << " - Complexity = "
<< CM->getPattern().getPatternComplexity(CGP) << '\n';
OS.PadToColumn(Indent*2) << "// Dst: "
<< *CM->getPattern().getDstPattern();
}
OS << '\n';
return 2 + NumResultBytes + NumCoveredBytes;
}
}
llvm_unreachable("Unreachable");
}
/// EmitMatcherList - Emit the bytes for the specified matcher subtree.
unsigned MatcherTableEmitter::
EmitMatcherList(const Matcher *N, unsigned Indent, unsigned CurrentIdx,
formatted_raw_ostream &OS) {
unsigned Size = 0;
while (N) {
if (!OmitComments)
OS << "/*" << CurrentIdx << "*/";
unsigned MatcherSize = EmitMatcher(N, Indent, CurrentIdx, OS);
Size += MatcherSize;
CurrentIdx += MatcherSize;
// If there are other nodes in this list, iterate to them, otherwise we're
// done.
N = N->getNext();
}
return Size;
}
void MatcherTableEmitter::EmitPredicateFunctions(formatted_raw_ostream &OS) {
// Emit pattern predicates.
if (!PatternPredicates.empty()) {
OS << "bool CheckPatternPredicate(unsigned PredNo) const override {\n";
OS << " switch (PredNo) {\n";
OS << " default: llvm_unreachable(\"Invalid predicate in table?\");\n";
for (unsigned i = 0, e = PatternPredicates.size(); i != e; ++i)
OS << " case " << i << ": return " << PatternPredicates[i] << ";\n";
OS << " }\n";
OS << "}\n\n";
}
// Emit Node predicates.
if (!NodePredicates.empty()) {
OS << "bool CheckNodePredicate(SDNode *Node,\n";
OS << " unsigned PredNo) const override {\n";
OS << " switch (PredNo) {\n";
OS << " default: llvm_unreachable(\"Invalid predicate in table?\");\n";
for (unsigned i = 0, e = NodePredicates.size(); i != e; ++i) {
// Emit the predicate code corresponding to this pattern.
TreePredicateFn PredFn = NodePredicates[i];
assert(!PredFn.isAlwaysTrue() && "No code in this predicate");
OS << " case " << i << ": { \n";
for (auto *SimilarPred :
NodePredicatesByCodeToRun[PredFn.getCodeToRunOnSDNode()])
OS << " // " << TreePredicateFn(SimilarPred).getFnName() <<'\n';
OS << PredFn.getCodeToRunOnSDNode() << "\n }\n";
}
OS << " }\n";
OS << "}\n\n";
}
// Emit CompletePattern matchers.
// FIXME: This should be const.
if (!ComplexPatterns.empty()) {
OS << "bool CheckComplexPattern(SDNode *Root, SDNode *Parent,\n";
OS << " SDValue N, unsigned PatternNo,\n";
OS << " SmallVectorImpl<std::pair<SDValue, SDNode*> > &Result) override {\n";
OS << " unsigned NextRes = Result.size();\n";
OS << " switch (PatternNo) {\n";
OS << " default: llvm_unreachable(\"Invalid pattern # in table?\");\n";
for (unsigned i = 0, e = ComplexPatterns.size(); i != e; ++i) {
const ComplexPattern &P = *ComplexPatterns[i];
unsigned NumOps = P.getNumOperands();
if (P.hasProperty(SDNPHasChain))
++NumOps; // Get the chained node too.
OS << " case " << i << ":\n";
if (InstrumentCoverage)
OS << " {\n";
OS << " Result.resize(NextRes+" << NumOps << ");\n";
if (InstrumentCoverage)
OS << " bool Succeeded = " << P.getSelectFunc();
else
OS << " return " << P.getSelectFunc();
OS << "(";
// If the complex pattern wants the root of the match, pass it in as the
// first argument.
if (P.hasProperty(SDNPWantRoot))
OS << "Root, ";
// If the complex pattern wants the parent of the operand being matched,
// pass it in as the next argument.
if (P.hasProperty(SDNPWantParent))
OS << "Parent, ";
OS << "N";
for (unsigned i = 0; i != NumOps; ++i)
OS << ", Result[NextRes+" << i << "].first";
OS << ");\n";
if (InstrumentCoverage) {
OS << " if (Succeeded)\n";
OS << " dbgs() << \"\\nCOMPLEX_PATTERN: " << P.getSelectFunc()
<< "\\n\" ;\n";
OS << " return Succeeded;\n";
OS << " }\n";
}
}
OS << " }\n";
OS << "}\n\n";
}
// Emit SDNodeXForm handlers.
// FIXME: This should be const.
if (!NodeXForms.empty()) {
OS << "SDValue RunSDNodeXForm(SDValue V, unsigned XFormNo) override {\n";
OS << " switch (XFormNo) {\n";
OS << " default: llvm_unreachable(\"Invalid xform # in table?\");\n";
// FIXME: The node xform could take SDValue's instead of SDNode*'s.
for (unsigned i = 0, e = NodeXForms.size(); i != e; ++i) {
const CodeGenDAGPatterns::NodeXForm &Entry =
CGP.getSDNodeTransform(NodeXForms[i]);
Record *SDNode = Entry.first;
const std::string &Code = Entry.second;
OS << " case " << i << ": { ";
if (!OmitComments)
OS << "// " << NodeXForms[i]->getName();
OS << '\n';
std::string ClassName = CGP.getSDNodeInfo(SDNode).getSDClassName();
if (ClassName == "SDNode")
OS << " SDNode *N = V.getNode();\n";
else
OS << " " << ClassName << " *N = cast<" << ClassName
<< ">(V.getNode());\n";
OS << Code << "\n }\n";
}
OS << " }\n";
OS << "}\n\n";
}
}
static void BuildHistogram(const Matcher *M, std::vector<unsigned> &OpcodeFreq){
for (; M != nullptr; M = M->getNext()) {
// Count this node.
if (unsigned(M->getKind()) >= OpcodeFreq.size())
OpcodeFreq.resize(M->getKind()+1);
OpcodeFreq[M->getKind()]++;
// Handle recursive nodes.
if (const ScopeMatcher *SM = dyn_cast<ScopeMatcher>(M)) {
for (unsigned i = 0, e = SM->getNumChildren(); i != e; ++i)
BuildHistogram(SM->getChild(i), OpcodeFreq);
} else if (const SwitchOpcodeMatcher *SOM =
dyn_cast<SwitchOpcodeMatcher>(M)) {
for (unsigned i = 0, e = SOM->getNumCases(); i != e; ++i)
BuildHistogram(SOM->getCaseMatcher(i), OpcodeFreq);
} else if (const SwitchTypeMatcher *STM = dyn_cast<SwitchTypeMatcher>(M)) {
for (unsigned i = 0, e = STM->getNumCases(); i != e; ++i)
BuildHistogram(STM->getCaseMatcher(i), OpcodeFreq);
}
}
}
void MatcherTableEmitter::EmitHistogram(const Matcher *M,
formatted_raw_ostream &OS) {
if (OmitComments)
return;
std::vector<unsigned> OpcodeFreq;
BuildHistogram(M, OpcodeFreq);
OS << " // Opcode Histogram:\n";
for (unsigned i = 0, e = OpcodeFreq.size(); i != e; ++i) {
OS << " // #";
switch ((Matcher::KindTy)i) {
case Matcher::Scope: OS << "OPC_Scope"; break;
case Matcher::RecordNode: OS << "OPC_RecordNode"; break;
case Matcher::RecordChild: OS << "OPC_RecordChild"; break;
case Matcher::RecordMemRef: OS << "OPC_RecordMemRef"; break;
case Matcher::CaptureGlueInput: OS << "OPC_CaptureGlueInput"; break;
case Matcher::MoveChild: OS << "OPC_MoveChild"; break;
case Matcher::MoveParent: OS << "OPC_MoveParent"; break;
case Matcher::CheckSame: OS << "OPC_CheckSame"; break;
case Matcher::CheckChildSame: OS << "OPC_CheckChildSame"; break;
case Matcher::CheckPatternPredicate:
OS << "OPC_CheckPatternPredicate"; break;
case Matcher::CheckPredicate: OS << "OPC_CheckPredicate"; break;
case Matcher::CheckOpcode: OS << "OPC_CheckOpcode"; break;
case Matcher::SwitchOpcode: OS << "OPC_SwitchOpcode"; break;
case Matcher::CheckType: OS << "OPC_CheckType"; break;
case Matcher::SwitchType: OS << "OPC_SwitchType"; break;
case Matcher::CheckChildType: OS << "OPC_CheckChildType"; break;
case Matcher::CheckInteger: OS << "OPC_CheckInteger"; break;
case Matcher::CheckChildInteger: OS << "OPC_CheckChildInteger"; break;
case Matcher::CheckCondCode: OS << "OPC_CheckCondCode"; break;
case Matcher::CheckValueType: OS << "OPC_CheckValueType"; break;
case Matcher::CheckComplexPat: OS << "OPC_CheckComplexPat"; break;
case Matcher::CheckAndImm: OS << "OPC_CheckAndImm"; break;
case Matcher::CheckOrImm: OS << "OPC_CheckOrImm"; break;
case Matcher::CheckFoldableChainNode:
OS << "OPC_CheckFoldableChainNode"; break;
case Matcher::EmitInteger: OS << "OPC_EmitInteger"; break;
case Matcher::EmitStringInteger: OS << "OPC_EmitStringInteger"; break;
case Matcher::EmitRegister: OS << "OPC_EmitRegister"; break;
case Matcher::EmitConvertToTarget: OS << "OPC_EmitConvertToTarget"; break;
case Matcher::EmitMergeInputChains: OS << "OPC_EmitMergeInputChains"; break;
case Matcher::EmitCopyToReg: OS << "OPC_EmitCopyToReg"; break;
case Matcher::EmitNode: OS << "OPC_EmitNode"; break;
case Matcher::MorphNodeTo: OS << "OPC_MorphNodeTo"; break;
case Matcher::EmitNodeXForm: OS << "OPC_EmitNodeXForm"; break;
case Matcher::CompleteMatch: OS << "OPC_CompleteMatch"; break;
}
OS.PadToColumn(40) << " = " << OpcodeFreq[i] << '\n';
}
OS << '\n';
}
void llvm::EmitMatcherTable(const Matcher *TheMatcher,
const CodeGenDAGPatterns &CGP,
raw_ostream &O) {
formatted_raw_ostream OS(O);
OS << "// The main instruction selector code.\n";
OS << "void SelectCode(SDNode *N) {\n";
MatcherTableEmitter MatcherEmitter(CGP);
OS << " // Some target values are emitted as 2 bytes, TARGET_VAL handles\n";
OS << " // this.\n";
OS << " #define TARGET_VAL(X) X & 255, unsigned(X) >> 8\n";
OS << " static const unsigned char MatcherTable[] = {\n";
unsigned TotalSize = MatcherEmitter.EmitMatcherList(TheMatcher, 6, 0, OS);
OS << " 0\n }; // Total Array size is " << (TotalSize+1) << " bytes\n\n";
MatcherEmitter.EmitHistogram(TheMatcher, OS);
OS << " #undef TARGET_VAL\n";
OS << " SelectCodeCommon(N, MatcherTable,sizeof(MatcherTable));\n";
OS << "}\n";
// Next up, emit the function for node and pattern predicates:
MatcherEmitter.EmitPredicateFunctions(OS);
if (InstrumentCoverage)
MatcherEmitter.EmitPatternMatchTable(OS);
}