llvm-project/mlir/lib/TableGen/Pattern.cpp

857 lines
29 KiB
C++

//===- Pattern.cpp - Pattern wrapper class --------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// Pattern wrapper class to simplify using TableGen Record defining a MLIR
// Pattern.
//
//===----------------------------------------------------------------------===//
#include <utility>
#include "mlir/TableGen/Pattern.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/Twine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/Record.h"
#define DEBUG_TYPE "mlir-tblgen-pattern"
using namespace mlir;
using namespace tblgen;
using llvm::formatv;
//===----------------------------------------------------------------------===//
// DagLeaf
//===----------------------------------------------------------------------===//
bool DagLeaf::isUnspecified() const {
return dyn_cast_or_null<llvm::UnsetInit>(def);
}
bool DagLeaf::isOperandMatcher() const {
// Operand matchers specify a type constraint.
return isSubClassOf("TypeConstraint");
}
bool DagLeaf::isAttrMatcher() const {
// Attribute matchers specify an attribute constraint.
return isSubClassOf("AttrConstraint");
}
bool DagLeaf::isNativeCodeCall() const {
return isSubClassOf("NativeCodeCall");
}
bool DagLeaf::isConstantAttr() const { return isSubClassOf("ConstantAttr"); }
bool DagLeaf::isEnumAttrCase() const {
return isSubClassOf("EnumAttrCaseInfo");
}
bool DagLeaf::isStringAttr() const { return isa<llvm::StringInit>(def); }
Constraint DagLeaf::getAsConstraint() const {
assert((isOperandMatcher() || isAttrMatcher()) &&
"the DAG leaf must be operand or attribute");
return Constraint(cast<llvm::DefInit>(def)->getDef());
}
ConstantAttr DagLeaf::getAsConstantAttr() const {
assert(isConstantAttr() && "the DAG leaf must be constant attribute");
return ConstantAttr(cast<llvm::DefInit>(def));
}
EnumAttrCase DagLeaf::getAsEnumAttrCase() const {
assert(isEnumAttrCase() && "the DAG leaf must be an enum attribute case");
return EnumAttrCase(cast<llvm::DefInit>(def));
}
std::string DagLeaf::getConditionTemplate() const {
return getAsConstraint().getConditionTemplate();
}
llvm::StringRef DagLeaf::getNativeCodeTemplate() const {
assert(isNativeCodeCall() && "the DAG leaf must be NativeCodeCall");
return cast<llvm::DefInit>(def)->getDef()->getValueAsString("expression");
}
int DagLeaf::getNumReturnsOfNativeCode() const {
assert(isNativeCodeCall() && "the DAG leaf must be NativeCodeCall");
return cast<llvm::DefInit>(def)->getDef()->getValueAsInt("numReturns");
}
std::string DagLeaf::getStringAttr() const {
assert(isStringAttr() && "the DAG leaf must be string attribute");
return def->getAsUnquotedString();
}
bool DagLeaf::isSubClassOf(StringRef superclass) const {
if (auto *defInit = dyn_cast_or_null<llvm::DefInit>(def))
return defInit->getDef()->isSubClassOf(superclass);
return false;
}
void DagLeaf::print(raw_ostream &os) const {
if (def)
def->print(os);
}
//===----------------------------------------------------------------------===//
// DagNode
//===----------------------------------------------------------------------===//
bool DagNode::isNativeCodeCall() const {
if (auto *defInit = dyn_cast_or_null<llvm::DefInit>(node->getOperator()))
return defInit->getDef()->isSubClassOf("NativeCodeCall");
return false;
}
bool DagNode::isOperation() const {
return !isNativeCodeCall() && !isReplaceWithValue() &&
!isLocationDirective() && !isReturnTypeDirective() && !isEither();
}
llvm::StringRef DagNode::getNativeCodeTemplate() const {
assert(isNativeCodeCall() && "the DAG leaf must be NativeCodeCall");
return cast<llvm::DefInit>(node->getOperator())
->getDef()
->getValueAsString("expression");
}
int DagNode::getNumReturnsOfNativeCode() const {
assert(isNativeCodeCall() && "the DAG leaf must be NativeCodeCall");
return cast<llvm::DefInit>(node->getOperator())
->getDef()
->getValueAsInt("numReturns");
}
llvm::StringRef DagNode::getSymbol() const { return node->getNameStr(); }
Operator &DagNode::getDialectOp(RecordOperatorMap *mapper) const {
llvm::Record *opDef = cast<llvm::DefInit>(node->getOperator())->getDef();
auto it = mapper->find(opDef);
if (it != mapper->end())
return *it->second;
return *mapper->try_emplace(opDef, std::make_unique<Operator>(opDef))
.first->second;
}
int DagNode::getNumOps() const {
// We want to get number of operations recursively involved in the DAG tree.
// All other directives should be excluded.
int count = isOperation() ? 1 : 0;
for (int i = 0, e = getNumArgs(); i != e; ++i) {
if (auto child = getArgAsNestedDag(i))
count += child.getNumOps();
}
return count;
}
int DagNode::getNumArgs() const { return node->getNumArgs(); }
bool DagNode::isNestedDagArg(unsigned index) const {
return isa<llvm::DagInit>(node->getArg(index));
}
DagNode DagNode::getArgAsNestedDag(unsigned index) const {
return DagNode(dyn_cast_or_null<llvm::DagInit>(node->getArg(index)));
}
DagLeaf DagNode::getArgAsLeaf(unsigned index) const {
assert(!isNestedDagArg(index));
return DagLeaf(node->getArg(index));
}
StringRef DagNode::getArgName(unsigned index) const {
return node->getArgNameStr(index);
}
bool DagNode::isReplaceWithValue() const {
auto *dagOpDef = cast<llvm::DefInit>(node->getOperator())->getDef();
return dagOpDef->getName() == "replaceWithValue";
}
bool DagNode::isLocationDirective() const {
auto *dagOpDef = cast<llvm::DefInit>(node->getOperator())->getDef();
return dagOpDef->getName() == "location";
}
bool DagNode::isReturnTypeDirective() const {
auto *dagOpDef = cast<llvm::DefInit>(node->getOperator())->getDef();
return dagOpDef->getName() == "returnType";
}
bool DagNode::isEither() const {
auto *dagOpDef = cast<llvm::DefInit>(node->getOperator())->getDef();
return dagOpDef->getName() == "either";
}
void DagNode::print(raw_ostream &os) const {
if (node)
node->print(os);
}
//===----------------------------------------------------------------------===//
// SymbolInfoMap
//===----------------------------------------------------------------------===//
StringRef SymbolInfoMap::getValuePackName(StringRef symbol, int *index) {
StringRef name, indexStr;
int idx = -1;
std::tie(name, indexStr) = symbol.rsplit("__");
if (indexStr.consumeInteger(10, idx)) {
// The second part is not an index; we return the whole symbol as-is.
return symbol;
}
if (index) {
*index = idx;
}
return name;
}
SymbolInfoMap::SymbolInfo::SymbolInfo(const Operator *op, SymbolInfo::Kind kind,
Optional<DagAndConstant> dagAndConstant)
: op(op), kind(kind), dagAndConstant(std::move(dagAndConstant)) {}
int SymbolInfoMap::SymbolInfo::getStaticValueCount() const {
switch (kind) {
case Kind::Attr:
case Kind::Operand:
case Kind::Value:
return 1;
case Kind::Result:
return op->getNumResults();
case Kind::MultipleValues:
return getSize();
}
llvm_unreachable("unknown kind");
}
std::string SymbolInfoMap::SymbolInfo::getVarName(StringRef name) const {
return alternativeName.hasValue() ? alternativeName.getValue() : name.str();
}
std::string SymbolInfoMap::SymbolInfo::getVarTypeStr(StringRef name) const {
LLVM_DEBUG(llvm::dbgs() << "getVarTypeStr for '" << name << "': ");
switch (kind) {
case Kind::Attr: {
if (op)
return op->getArg(getArgIndex())
.get<NamedAttribute *>()
->attr.getStorageType()
.str();
// TODO(suderman): Use a more exact type when available.
return "::mlir::Attribute";
}
case Kind::Operand: {
// Use operand range for captured operands (to support potential variadic
// operands).
return "::mlir::Operation::operand_range";
}
case Kind::Value: {
return "::mlir::Value";
}
case Kind::MultipleValues: {
return "::mlir::ValueRange";
}
case Kind::Result: {
// Use the op itself for captured results.
return op->getQualCppClassName();
}
}
llvm_unreachable("unknown kind");
}
std::string SymbolInfoMap::SymbolInfo::getVarDecl(StringRef name) const {
LLVM_DEBUG(llvm::dbgs() << "getVarDecl for '" << name << "': ");
std::string varInit = kind == Kind::Operand ? "(op0->getOperands())" : "";
return std::string(
formatv("{0} {1}{2};\n", getVarTypeStr(name), getVarName(name), varInit));
}
std::string SymbolInfoMap::SymbolInfo::getArgDecl(StringRef name) const {
LLVM_DEBUG(llvm::dbgs() << "getArgDecl for '" << name << "': ");
return std::string(
formatv("{0} &{1}", getVarTypeStr(name), getVarName(name)));
}
std::string SymbolInfoMap::SymbolInfo::getValueAndRangeUse(
StringRef name, int index, const char *fmt, const char *separator) const {
LLVM_DEBUG(llvm::dbgs() << "getValueAndRangeUse for '" << name << "': ");
switch (kind) {
case Kind::Attr: {
assert(index < 0);
auto repl = formatv(fmt, name);
LLVM_DEBUG(llvm::dbgs() << repl << " (Attr)\n");
return std::string(repl);
}
case Kind::Operand: {
assert(index < 0);
auto *operand = op->getArg(getArgIndex()).get<NamedTypeConstraint *>();
// If this operand is variadic, then return a range. Otherwise, return the
// value itself.
if (operand->isVariableLength()) {
auto repl = formatv(fmt, name);
LLVM_DEBUG(llvm::dbgs() << repl << " (VariadicOperand)\n");
return std::string(repl);
}
auto repl = formatv(fmt, formatv("(*{0}.begin())", name));
LLVM_DEBUG(llvm::dbgs() << repl << " (SingleOperand)\n");
return std::string(repl);
}
case Kind::Result: {
// If `index` is greater than zero, then we are referencing a specific
// result of a multi-result op. The result can still be variadic.
if (index >= 0) {
std::string v =
std::string(formatv("{0}.getODSResults({1})", name, index));
if (!op->getResult(index).isVariadic())
v = std::string(formatv("(*{0}.begin())", v));
auto repl = formatv(fmt, v);
LLVM_DEBUG(llvm::dbgs() << repl << " (SingleResult)\n");
return std::string(repl);
}
// If this op has no result at all but still we bind a symbol to it, it
// means we want to capture the op itself.
if (op->getNumResults() == 0) {
LLVM_DEBUG(llvm::dbgs() << name << " (Op)\n");
return formatv(fmt, name);
}
// We are referencing all results of the multi-result op. A specific result
// can either be a value or a range. Then join them with `separator`.
SmallVector<std::string, 4> values;
values.reserve(op->getNumResults());
for (int i = 0, e = op->getNumResults(); i < e; ++i) {
std::string v = std::string(formatv("{0}.getODSResults({1})", name, i));
if (!op->getResult(i).isVariadic()) {
v = std::string(formatv("(*{0}.begin())", v));
}
values.push_back(std::string(formatv(fmt, v)));
}
auto repl = llvm::join(values, separator);
LLVM_DEBUG(llvm::dbgs() << repl << " (VariadicResult)\n");
return repl;
}
case Kind::Value: {
assert(index < 0);
assert(op == nullptr);
auto repl = formatv(fmt, name);
LLVM_DEBUG(llvm::dbgs() << repl << " (Value)\n");
return std::string(repl);
}
case Kind::MultipleValues: {
assert(op == nullptr);
assert(index < getSize());
if (index >= 0) {
std::string repl =
formatv(fmt, std::string(formatv("{0}[{1}]", name, index)));
LLVM_DEBUG(llvm::dbgs() << repl << " (MultipleValues)\n");
return repl;
}
// If it doesn't specify certain element, unpack them all.
auto repl =
formatv(fmt, std::string(formatv("{0}.begin(), {0}.end()", name)));
LLVM_DEBUG(llvm::dbgs() << repl << " (MultipleValues)\n");
return std::string(repl);
}
}
llvm_unreachable("unknown kind");
}
std::string SymbolInfoMap::SymbolInfo::getAllRangeUse(
StringRef name, int index, const char *fmt, const char *separator) const {
LLVM_DEBUG(llvm::dbgs() << "getAllRangeUse for '" << name << "': ");
switch (kind) {
case Kind::Attr:
case Kind::Operand: {
assert(index < 0 && "only allowed for symbol bound to result");
auto repl = formatv(fmt, name);
LLVM_DEBUG(llvm::dbgs() << repl << " (Operand/Attr)\n");
return std::string(repl);
}
case Kind::Result: {
if (index >= 0) {
auto repl = formatv(fmt, formatv("{0}.getODSResults({1})", name, index));
LLVM_DEBUG(llvm::dbgs() << repl << " (SingleResult)\n");
return std::string(repl);
}
// We are referencing all results of the multi-result op. Each result should
// have a value range, and then join them with `separator`.
SmallVector<std::string, 4> values;
values.reserve(op->getNumResults());
for (int i = 0, e = op->getNumResults(); i < e; ++i) {
values.push_back(std::string(
formatv(fmt, formatv("{0}.getODSResults({1})", name, i))));
}
auto repl = llvm::join(values, separator);
LLVM_DEBUG(llvm::dbgs() << repl << " (VariadicResult)\n");
return repl;
}
case Kind::Value: {
assert(index < 0 && "only allowed for symbol bound to result");
assert(op == nullptr);
auto repl = formatv(fmt, formatv("{{{0}}", name));
LLVM_DEBUG(llvm::dbgs() << repl << " (Value)\n");
return std::string(repl);
}
case Kind::MultipleValues: {
assert(op == nullptr);
assert(index < getSize());
if (index >= 0) {
std::string repl =
formatv(fmt, std::string(formatv("{0}[{1}]", name, index)));
LLVM_DEBUG(llvm::dbgs() << repl << " (MultipleValues)\n");
return repl;
}
auto repl =
formatv(fmt, std::string(formatv("{0}.begin(), {0}.end()", name)));
LLVM_DEBUG(llvm::dbgs() << repl << " (MultipleValues)\n");
return std::string(repl);
}
}
llvm_unreachable("unknown kind");
}
bool SymbolInfoMap::bindOpArgument(DagNode node, StringRef symbol,
const Operator &op, int argIndex) {
StringRef name = getValuePackName(symbol);
if (name != symbol) {
auto error = formatv(
"symbol '{0}' with trailing index cannot bind to op argument", symbol);
PrintFatalError(loc, error);
}
auto symInfo = op.getArg(argIndex).is<NamedAttribute *>()
? SymbolInfo::getAttr(&op, argIndex)
: SymbolInfo::getOperand(node, &op, argIndex);
std::string key = symbol.str();
if (symbolInfoMap.count(key)) {
// Only non unique name for the operand is supported.
if (symInfo.kind != SymbolInfo::Kind::Operand) {
return false;
}
// Cannot add new operand if there is already non operand with the same
// name.
if (symbolInfoMap.find(key)->second.kind != SymbolInfo::Kind::Operand) {
return false;
}
}
symbolInfoMap.emplace(key, symInfo);
return true;
}
bool SymbolInfoMap::bindOpResult(StringRef symbol, const Operator &op) {
std::string name = getValuePackName(symbol).str();
auto inserted = symbolInfoMap.emplace(name, SymbolInfo::getResult(&op));
return symbolInfoMap.count(inserted->first) == 1;
}
bool SymbolInfoMap::bindValues(StringRef symbol, int numValues) {
std::string name = getValuePackName(symbol).str();
if (numValues > 1)
return bindMultipleValues(name, numValues);
return bindValue(name);
}
bool SymbolInfoMap::bindValue(StringRef symbol) {
auto inserted = symbolInfoMap.emplace(symbol.str(), SymbolInfo::getValue());
return symbolInfoMap.count(inserted->first) == 1;
}
bool SymbolInfoMap::bindMultipleValues(StringRef symbol, int numValues) {
std::string name = getValuePackName(symbol).str();
auto inserted =
symbolInfoMap.emplace(name, SymbolInfo::getMultipleValues(numValues));
return symbolInfoMap.count(inserted->first) == 1;
}
bool SymbolInfoMap::bindAttr(StringRef symbol) {
auto inserted = symbolInfoMap.emplace(symbol.str(), SymbolInfo::getAttr());
return symbolInfoMap.count(inserted->first) == 1;
}
bool SymbolInfoMap::contains(StringRef symbol) const {
return find(symbol) != symbolInfoMap.end();
}
SymbolInfoMap::const_iterator SymbolInfoMap::find(StringRef key) const {
std::string name = getValuePackName(key).str();
return symbolInfoMap.find(name);
}
SymbolInfoMap::const_iterator
SymbolInfoMap::findBoundSymbol(StringRef key, DagNode node, const Operator &op,
int argIndex) const {
return findBoundSymbol(key, SymbolInfo::getOperand(node, &op, argIndex));
}
SymbolInfoMap::const_iterator
SymbolInfoMap::findBoundSymbol(StringRef key,
const SymbolInfo &symbolInfo) const {
std::string name = getValuePackName(key).str();
auto range = symbolInfoMap.equal_range(name);
for (auto it = range.first; it != range.second; ++it)
if (it->second.dagAndConstant == symbolInfo.dagAndConstant)
return it;
return symbolInfoMap.end();
}
std::pair<SymbolInfoMap::iterator, SymbolInfoMap::iterator>
SymbolInfoMap::getRangeOfEqualElements(StringRef key) {
std::string name = getValuePackName(key).str();
return symbolInfoMap.equal_range(name);
}
int SymbolInfoMap::count(StringRef key) const {
std::string name = getValuePackName(key).str();
return symbolInfoMap.count(name);
}
int SymbolInfoMap::getStaticValueCount(StringRef symbol) const {
StringRef name = getValuePackName(symbol);
if (name != symbol) {
// If there is a trailing index inside symbol, it references just one
// static value.
return 1;
}
// Otherwise, find how many it represents by querying the symbol's info.
return find(name)->second.getStaticValueCount();
}
std::string SymbolInfoMap::getValueAndRangeUse(StringRef symbol,
const char *fmt,
const char *separator) const {
int index = -1;
StringRef name = getValuePackName(symbol, &index);
auto it = symbolInfoMap.find(name.str());
if (it == symbolInfoMap.end()) {
auto error = formatv("referencing unbound symbol '{0}'", symbol);
PrintFatalError(loc, error);
}
return it->second.getValueAndRangeUse(name, index, fmt, separator);
}
std::string SymbolInfoMap::getAllRangeUse(StringRef symbol, const char *fmt,
const char *separator) const {
int index = -1;
StringRef name = getValuePackName(symbol, &index);
auto it = symbolInfoMap.find(name.str());
if (it == symbolInfoMap.end()) {
auto error = formatv("referencing unbound symbol '{0}'", symbol);
PrintFatalError(loc, error);
}
return it->second.getAllRangeUse(name, index, fmt, separator);
}
void SymbolInfoMap::assignUniqueAlternativeNames() {
llvm::StringSet<> usedNames;
for (auto symbolInfoIt = symbolInfoMap.begin();
symbolInfoIt != symbolInfoMap.end();) {
auto range = symbolInfoMap.equal_range(symbolInfoIt->first);
auto startRange = range.first;
auto endRange = range.second;
auto operandName = symbolInfoIt->first;
int startSearchIndex = 0;
for (++startRange; startRange != endRange; ++startRange) {
// Current operand name is not unique, find a unique one
// and set the alternative name.
for (int i = startSearchIndex;; ++i) {
std::string alternativeName = operandName + std::to_string(i);
if (!usedNames.contains(alternativeName) &&
symbolInfoMap.count(alternativeName) == 0) {
usedNames.insert(alternativeName);
startRange->second.alternativeName = alternativeName;
startSearchIndex = i + 1;
break;
}
}
}
symbolInfoIt = endRange;
}
}
//===----------------------------------------------------------------------===//
// Pattern
//==----------------------------------------------------------------------===//
Pattern::Pattern(const llvm::Record *def, RecordOperatorMap *mapper)
: def(*def), recordOpMap(mapper) {}
DagNode Pattern::getSourcePattern() const {
return DagNode(def.getValueAsDag("sourcePattern"));
}
int Pattern::getNumResultPatterns() const {
auto *results = def.getValueAsListInit("resultPatterns");
return results->size();
}
DagNode Pattern::getResultPattern(unsigned index) const {
auto *results = def.getValueAsListInit("resultPatterns");
return DagNode(cast<llvm::DagInit>(results->getElement(index)));
}
void Pattern::collectSourcePatternBoundSymbols(SymbolInfoMap &infoMap) {
LLVM_DEBUG(llvm::dbgs() << "start collecting source pattern bound symbols\n");
collectBoundSymbols(getSourcePattern(), infoMap, /*isSrcPattern=*/true);
LLVM_DEBUG(llvm::dbgs() << "done collecting source pattern bound symbols\n");
LLVM_DEBUG(llvm::dbgs() << "start assigning alternative names for symbols\n");
infoMap.assignUniqueAlternativeNames();
LLVM_DEBUG(llvm::dbgs() << "done assigning alternative names for symbols\n");
}
void Pattern::collectResultPatternBoundSymbols(SymbolInfoMap &infoMap) {
LLVM_DEBUG(llvm::dbgs() << "start collecting result pattern bound symbols\n");
for (int i = 0, e = getNumResultPatterns(); i < e; ++i) {
auto pattern = getResultPattern(i);
collectBoundSymbols(pattern, infoMap, /*isSrcPattern=*/false);
}
LLVM_DEBUG(llvm::dbgs() << "done collecting result pattern bound symbols\n");
}
const Operator &Pattern::getSourceRootOp() {
return getSourcePattern().getDialectOp(recordOpMap);
}
Operator &Pattern::getDialectOp(DagNode node) {
return node.getDialectOp(recordOpMap);
}
std::vector<AppliedConstraint> Pattern::getConstraints() const {
auto *listInit = def.getValueAsListInit("constraints");
std::vector<AppliedConstraint> ret;
ret.reserve(listInit->size());
for (auto *it : *listInit) {
auto *dagInit = dyn_cast<llvm::DagInit>(it);
if (!dagInit)
PrintFatalError(&def, "all elements in Pattern multi-entity "
"constraints should be DAG nodes");
std::vector<std::string> entities;
entities.reserve(dagInit->arg_size());
for (auto *argName : dagInit->getArgNames()) {
if (!argName) {
PrintFatalError(
&def,
"operands to additional constraints can only be symbol references");
}
entities.emplace_back(argName->getValue());
}
ret.emplace_back(cast<llvm::DefInit>(dagInit->getOperator())->getDef(),
dagInit->getNameStr(), std::move(entities));
}
return ret;
}
int Pattern::getBenefit() const {
// The initial benefit value is a heuristic with number of ops in the source
// pattern.
int initBenefit = getSourcePattern().getNumOps();
llvm::DagInit *delta = def.getValueAsDag("benefitDelta");
if (delta->getNumArgs() != 1 || !isa<llvm::IntInit>(delta->getArg(0))) {
PrintFatalError(&def,
"The 'addBenefit' takes and only takes one integer value");
}
return initBenefit + dyn_cast<llvm::IntInit>(delta->getArg(0))->getValue();
}
std::vector<Pattern::IdentifierLine> Pattern::getLocation() const {
std::vector<std::pair<StringRef, unsigned>> result;
result.reserve(def.getLoc().size());
for (auto loc : def.getLoc()) {
unsigned buf = llvm::SrcMgr.FindBufferContainingLoc(loc);
assert(buf && "invalid source location");
result.emplace_back(
llvm::SrcMgr.getBufferInfo(buf).Buffer->getBufferIdentifier(),
llvm::SrcMgr.getLineAndColumn(loc, buf).first);
}
return result;
}
void Pattern::verifyBind(bool result, StringRef symbolName) {
if (!result) {
auto err = formatv("symbol '{0}' bound more than once", symbolName);
PrintFatalError(&def, err);
}
}
void Pattern::collectBoundSymbols(DagNode tree, SymbolInfoMap &infoMap,
bool isSrcPattern) {
auto treeName = tree.getSymbol();
auto numTreeArgs = tree.getNumArgs();
if (tree.isNativeCodeCall()) {
if (!treeName.empty()) {
if (!isSrcPattern) {
LLVM_DEBUG(llvm::dbgs() << "found symbol bound to NativeCodeCall: "
<< treeName << '\n');
verifyBind(
infoMap.bindValues(treeName, tree.getNumReturnsOfNativeCode()),
treeName);
} else {
PrintFatalError(&def,
formatv("binding symbol '{0}' to NativecodeCall in "
"MatchPattern is not supported",
treeName));
}
}
for (int i = 0; i != numTreeArgs; ++i) {
if (auto treeArg = tree.getArgAsNestedDag(i)) {
// This DAG node argument is a DAG node itself. Go inside recursively.
collectBoundSymbols(treeArg, infoMap, isSrcPattern);
continue;
}
if (!isSrcPattern)
continue;
// We can only bind symbols to arguments in source pattern. Those
// symbols are referenced in result patterns.
auto treeArgName = tree.getArgName(i);
// `$_` is a special symbol meaning ignore the current argument.
if (!treeArgName.empty() && treeArgName != "_") {
DagLeaf leaf = tree.getArgAsLeaf(i);
// In (NativeCodeCall<"Foo($_self, $0, $1, $2)"> I8Attr:$a, I8:$b, $c),
if (leaf.isUnspecified()) {
// This is case of $c, a Value without any constraints.
verifyBind(infoMap.bindValue(treeArgName), treeArgName);
} else {
auto constraint = leaf.getAsConstraint();
bool isAttr = leaf.isAttrMatcher() || leaf.isEnumAttrCase() ||
leaf.isConstantAttr() ||
constraint.getKind() == Constraint::Kind::CK_Attr;
if (isAttr) {
// This is case of $a, a binding to a certain attribute.
verifyBind(infoMap.bindAttr(treeArgName), treeArgName);
continue;
}
// This is case of $b, a binding to a certain type.
verifyBind(infoMap.bindValue(treeArgName), treeArgName);
}
}
}
return;
}
if (tree.isOperation()) {
auto &op = getDialectOp(tree);
auto numOpArgs = op.getNumArgs();
int numEither = 0;
// We need to exclude the trailing directives and `either` directive groups
// two operands of the operation.
int numDirectives = 0;
for (int i = numTreeArgs - 1; i >= 0; --i) {
if (auto dagArg = tree.getArgAsNestedDag(i)) {
if (dagArg.isLocationDirective() || dagArg.isReturnTypeDirective())
++numDirectives;
else if (dagArg.isEither())
++numEither;
}
}
if (numOpArgs != numTreeArgs - numDirectives + numEither) {
auto err =
formatv("op '{0}' argument number mismatch: "
"{1} in pattern vs. {2} in definition",
op.getOperationName(), numTreeArgs + numEither, numOpArgs);
PrintFatalError(&def, err);
}
// The name attached to the DAG node's operator is for representing the
// results generated from this op. It should be remembered as bound results.
if (!treeName.empty()) {
LLVM_DEBUG(llvm::dbgs()
<< "found symbol bound to op result: " << treeName << '\n');
verifyBind(infoMap.bindOpResult(treeName, op), treeName);
}
// The operand in `either` DAG should be bound to the operation in the
// parent DagNode.
auto collectSymbolInEither = [&](DagNode parent, DagNode tree,
int &opArgIdx) {
for (int i = 0; i < tree.getNumArgs(); ++i, ++opArgIdx) {
if (DagNode subTree = tree.getArgAsNestedDag(i)) {
collectBoundSymbols(subTree, infoMap, isSrcPattern);
} else {
auto argName = tree.getArgName(i);
if (!argName.empty() && argName != "_")
verifyBind(infoMap.bindOpArgument(parent, argName, op, opArgIdx),
argName);
}
}
};
for (int i = 0, opArgIdx = 0; i != numTreeArgs; ++i, ++opArgIdx) {
if (auto treeArg = tree.getArgAsNestedDag(i)) {
if (treeArg.isEither()) {
collectSymbolInEither(tree, treeArg, opArgIdx);
} else {
// This DAG node argument is a DAG node itself. Go inside recursively.
collectBoundSymbols(treeArg, infoMap, isSrcPattern);
}
continue;
}
if (isSrcPattern) {
// We can only bind symbols to op arguments in source pattern. Those
// symbols are referenced in result patterns.
auto treeArgName = tree.getArgName(i);
// `$_` is a special symbol meaning ignore the current argument.
if (!treeArgName.empty() && treeArgName != "_") {
LLVM_DEBUG(llvm::dbgs() << "found symbol bound to op argument: "
<< treeArgName << '\n');
verifyBind(infoMap.bindOpArgument(tree, treeArgName, op, opArgIdx),
treeArgName);
}
}
}
return;
}
if (!treeName.empty()) {
PrintFatalError(
&def, formatv("binding symbol '{0}' to non-operation/native code call "
"unsupported right now",
treeName));
}
}