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5e118f933b6590cecd7f1afb30845a1594bc4a5d
clang-p2996/mlir/lib/TableGen/Operator.cpp
Mehdi Amini 5e118f933b Introduce MLIR Op Properties 
This new features enabled to dedicate custom storage inline within operations.
This storage can be used as an alternative to attributes to store data that is
specific to an operation. Attribute can also be stored inside the properties
storage if desired, but any kind of data can be present as well. This offers
a way to store and mutate data without uniquing in the Context like Attribute.
See the OpPropertiesTest.cpp for an example where a struct with a
std::vector<> is attached to an operation and mutated in-place:

struct TestProperties {
  int a = -1;
  float b = -1.;
  std::vector<int64_t> array = {-33};
};

More complex scheme (including reference-counting) are also possible.

The only constraint to enable storing a C++ object as "properties" on an
operation is to implement three functions:

- convert from the candidate object to an Attribute
- convert from the Attribute to the candidate object
- hash the object

Optional the parsing and printing can also be customized with 2 extra
functions.

A new options is introduced to ODS to allow dialects to specify:

  let usePropertiesForAttributes = 1;

When set to true, the inherent attributes for all the ops in this dialect
will be using properties instead of being stored alongside discardable
attributes.
The TestDialect showcases this feature.

Another change is that we introduce new APIs on the Operation class
to access separately the inherent attributes from the discardable ones.
We envision deprecating and removing the `getAttr()`, `getAttrsDictionary()`,
and other similar method which don't make the distinction explicit, leading
to an entirely separate namespace for discardable attributes.

Recommit d572cd1b06 after fixing python bindings build.

Differential Revision: https://reviews.llvm.org/D141742
2023-05-01 23:16:34 -07:00

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//===- Operator.cpp - Operator 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
//
//===----------------------------------------------------------------------===//
//
// Operator wrapper to simplify using TableGen Record defining a MLIR Op.
//
//===----------------------------------------------------------------------===//
#include "mlir/TableGen/Operator.h"
#include "mlir/TableGen/Argument.h"
#include "mlir/TableGen/Predicate.h"
#include "mlir/TableGen/Trait.h"
#include "mlir/TableGen/Type.h"
#include "llvm/ADT/EquivalenceClasses.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/Sequence.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/TypeSwitch.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/Record.h"
#include <list>
#define DEBUG_TYPE "mlir-tblgen-operator"
using namespace mlir;
using namespace mlir::tblgen;
using llvm::DagInit;
using llvm::DefInit;
using llvm::Record;
Operator::Operator(const llvm::Record &def)
: dialect(def.getValueAsDef("opDialect")), def(def) {
// The first `_` in the op's TableGen def name is treated as separating the
// dialect prefix and the op class name. The dialect prefix will be ignored if
// not empty. Otherwise, if def name starts with a `_`, the `_` is considered
// as part of the class name.
StringRef prefix;
std::tie(prefix, cppClassName) = def.getName().split('_');
if (prefix.empty()) {
// Class name with a leading underscore and without dialect prefix
cppClassName = def.getName();
} else if (cppClassName.empty()) {
// Class name without dialect prefix
cppClassName = prefix;
}
cppNamespace = def.getValueAsString("cppNamespace");
populateOpStructure();
assertInvariants();
}
std::string Operator::getOperationName() const {
auto prefix = dialect.getName();
auto opName = def.getValueAsString("opName");
if (prefix.empty())
return std::string(opName);
return std::string(llvm::formatv("{0}.{1}", prefix, opName));
}
std::string Operator::getAdaptorName() const {
return std::string(llvm::formatv("{0}Adaptor", getCppClassName()));
}
std::string Operator::getGenericAdaptorName() const {
return std::string(llvm::formatv("{0}GenericAdaptor", getCppClassName()));
}
/// Assert the invariants of accessors generated for the given name.
static void assertAccessorInvariants(const Operator &op, StringRef name) {
std::string accessorName =
convertToCamelFromSnakeCase(name, /*capitalizeFirst=*/true);
// Functor used to detect when an accessor will cause an overlap with an
// operation API.
//
// There are a little bit more invasive checks possible for cases where not
// all ops have the trait that would cause overlap. For many cases here,
// renaming would be better (e.g., we can only guard in limited manner
// against methods from traits and interfaces here, so avoiding these in op
// definition is safer).
auto nameOverlapsWithOpAPI = [&](StringRef newName) {
if (newName == "AttributeNames" || newName == "Attributes" ||
newName == "Operation")
return true;
if (newName == "Operands")
return op.getNumOperands() != 1 || op.getNumVariableLengthOperands() != 1;
if (newName == "Regions")
return op.getNumRegions() != 1 || op.getNumVariadicRegions() != 1;
if (newName == "Type")
return op.getNumResults() != 1;
return false;
};
if (nameOverlapsWithOpAPI(accessorName)) {
// This error could be avoided in situations where the final function is
// identical, but preferably the op definition should avoid using generic
// names.
PrintFatalError(op.getLoc(), "generated accessor for `" + name +
"` overlaps with a default one; please "
"rename to avoid overlap");
}
}
void Operator::assertInvariants() const {
// Check that the name of arguments/results/regions/successors don't overlap.
DenseMap<StringRef, StringRef> existingNames;
auto checkName = [&](StringRef name, StringRef entity) {
if (name.empty())
return;
auto insertion = existingNames.insert({name, entity});
if (insertion.second) {
// Assert invariants for accessors generated for this name.
assertAccessorInvariants(*this, name);
return;
}
if (entity == insertion.first->second)
PrintFatalError(getLoc(), "op has a conflict with two " + entity +
" having the same name '" + name + "'");
PrintFatalError(getLoc(), "op has a conflict with " +
insertion.first->second + " and " + entity +
" both having an entry with the name '" +
name + "'");
};
// Check operands amongst themselves.
for (int i : llvm::seq<int>(0, getNumOperands()))
checkName(getOperand(i).name, "operands");
// Check results amongst themselves and against operands.
for (int i : llvm::seq<int>(0, getNumResults()))
checkName(getResult(i).name, "results");
// Check regions amongst themselves and against operands and results.
for (int i : llvm::seq<int>(0, getNumRegions()))
checkName(getRegion(i).name, "regions");
// Check successors amongst themselves and against operands, results, and
// regions.
for (int i : llvm::seq<int>(0, getNumSuccessors()))
checkName(getSuccessor(i).name, "successors");
}
StringRef Operator::getDialectName() const { return dialect.getName(); }
StringRef Operator::getCppClassName() const { return cppClassName; }
std::string Operator::getQualCppClassName() const {
if (cppNamespace.empty())
return std::string(cppClassName);
return std::string(llvm::formatv("{0}::{1}", cppNamespace, cppClassName));
}
StringRef Operator::getCppNamespace() const { return cppNamespace; }
int Operator::getNumResults() const {
DagInit *results = def.getValueAsDag("results");
return results->getNumArgs();
}
StringRef Operator::getExtraClassDeclaration() const {
constexpr auto attr = "extraClassDeclaration";
if (def.isValueUnset(attr))
return {};
return def.getValueAsString(attr);
}
StringRef Operator::getExtraClassDefinition() const {
constexpr auto attr = "extraClassDefinition";
if (def.isValueUnset(attr))
return {};
return def.getValueAsString(attr);
}
const llvm::Record &Operator::getDef() const { return def; }
bool Operator::skipDefaultBuilders() const {
return def.getValueAsBit("skipDefaultBuilders");
}
auto Operator::result_begin() const -> const_value_iterator {
return results.begin();
}
auto Operator::result_end() const -> const_value_iterator {
return results.end();
}
auto Operator::getResults() const -> const_value_range {
return {result_begin(), result_end()};
}
TypeConstraint Operator::getResultTypeConstraint(int index) const {
DagInit *results = def.getValueAsDag("results");
return TypeConstraint(cast<DefInit>(results->getArg(index)));
}
StringRef Operator::getResultName(int index) const {
DagInit *results = def.getValueAsDag("results");
return results->getArgNameStr(index);
}
auto Operator::getResultDecorators(int index) const -> var_decorator_range {
Record *result =
cast<DefInit>(def.getValueAsDag("results")->getArg(index))->getDef();
if (!result->isSubClassOf("OpVariable"))
return var_decorator_range(nullptr, nullptr);
return *result->getValueAsListInit("decorators");
}
unsigned Operator::getNumVariableLengthResults() const {
return llvm::count_if(results, [](const NamedTypeConstraint &c) {
return c.constraint.isVariableLength();
});
}
unsigned Operator::getNumVariableLengthOperands() const {
return llvm::count_if(operands, [](const NamedTypeConstraint &c) {
return c.constraint.isVariableLength();
});
}
bool Operator::hasSingleVariadicArg() const {
return getNumArgs() == 1 && getArg(0).is<NamedTypeConstraint *>() &&
getOperand(0).isVariadic();
}
Operator::arg_iterator Operator::arg_begin() const { return arguments.begin(); }
Operator::arg_iterator Operator::arg_end() const { return arguments.end(); }
Operator::arg_range Operator::getArgs() const {
return {arg_begin(), arg_end()};
}
StringRef Operator::getArgName(int index) const {
DagInit *argumentValues = def.getValueAsDag("arguments");
return argumentValues->getArgNameStr(index);
}
auto Operator::getArgDecorators(int index) const -> var_decorator_range {
Record *arg =
cast<DefInit>(def.getValueAsDag("arguments")->getArg(index))->getDef();
if (!arg->isSubClassOf("OpVariable"))
return var_decorator_range(nullptr, nullptr);
return *arg->getValueAsListInit("decorators");
}
const Trait *Operator::getTrait(StringRef trait) const {
for (const auto &t : traits) {
if (const auto *traitDef = dyn_cast<NativeTrait>(&t)) {
if (traitDef->getFullyQualifiedTraitName() == trait)
return traitDef;
} else if (const auto *traitDef = dyn_cast<InternalTrait>(&t)) {
if (traitDef->getFullyQualifiedTraitName() == trait)
return traitDef;
} else if (const auto *traitDef = dyn_cast<InterfaceTrait>(&t)) {
if (traitDef->getFullyQualifiedTraitName() == trait)
return traitDef;
}
}
return nullptr;
}
auto Operator::region_begin() const -> const_region_iterator {
return regions.begin();
}
auto Operator::region_end() const -> const_region_iterator {
return regions.end();
}
auto Operator::getRegions() const
-> llvm::iterator_range<const_region_iterator> {
return {region_begin(), region_end()};
}
unsigned Operator::getNumRegions() const { return regions.size(); }
const NamedRegion &Operator::getRegion(unsigned index) const {
return regions[index];
}
unsigned Operator::getNumVariadicRegions() const {
return llvm::count_if(regions,
[](const NamedRegion &c) { return c.isVariadic(); });
}
auto Operator::successor_begin() const -> const_successor_iterator {
return successors.begin();
}
auto Operator::successor_end() const -> const_successor_iterator {
return successors.end();
}
auto Operator::getSuccessors() const
-> llvm::iterator_range<const_successor_iterator> {
return {successor_begin(), successor_end()};
}
unsigned Operator::getNumSuccessors() const { return successors.size(); }
const NamedSuccessor &Operator::getSuccessor(unsigned index) const {
return successors[index];
}
unsigned Operator::getNumVariadicSuccessors() const {
return llvm::count_if(successors,
[](const NamedSuccessor &c) { return c.isVariadic(); });
}
auto Operator::trait_begin() const -> const_trait_iterator {
return traits.begin();
}
auto Operator::trait_end() const -> const_trait_iterator {
return traits.end();
}
auto Operator::getTraits() const -> llvm::iterator_range<const_trait_iterator> {
return {trait_begin(), trait_end()};
}
auto Operator::attribute_begin() const -> const_attribute_iterator {
return attributes.begin();
}
auto Operator::attribute_end() const -> const_attribute_iterator {
return attributes.end();
}
auto Operator::getAttributes() const
-> llvm::iterator_range<const_attribute_iterator> {
return {attribute_begin(), attribute_end()};
}
auto Operator::attribute_begin() -> attribute_iterator {
return attributes.begin();
}
auto Operator::attribute_end() -> attribute_iterator {
return attributes.end();
}
auto Operator::getAttributes() -> llvm::iterator_range<attribute_iterator> {
return {attribute_begin(), attribute_end()};
}
auto Operator::operand_begin() const -> const_value_iterator {
return operands.begin();
}
auto Operator::operand_end() const -> const_value_iterator {
return operands.end();
}
auto Operator::getOperands() const -> const_value_range {
return {operand_begin(), operand_end()};
}
auto Operator::getArg(int index) const -> Argument { return arguments[index]; }
bool Operator::isVariadic() const {
return any_of(llvm::concat<const NamedTypeConstraint>(operands, results),
[](const NamedTypeConstraint &op) { return op.isVariadic(); });
}
void Operator::populateTypeInferenceInfo(
const llvm::StringMap<int> &argumentsAndResultsIndex) {
// If the type inference op interface is not registered, then do not attempt
// to determine if the result types an be inferred.
auto &recordKeeper = def.getRecords();
auto *inferTrait = recordKeeper.getDef(inferTypeOpInterface);
allResultsHaveKnownTypes = false;
if (!inferTrait)
return;
// If there are no results, the skip this else the build method generated
// overlaps with another autogenerated builder.
if (getNumResults() == 0)
return;
// Skip ops with variadic or optional results.
if (getNumVariableLengthResults() > 0)
return;
// Skip cases currently being custom generated.
// TODO: Remove special cases.
if (getTrait("::mlir::OpTrait::SameOperandsAndResultType")) {
// Check for a non-variable length operand to use as the type anchor.
auto *operandI = llvm::find_if(arguments, [](const Argument &arg) {
NamedTypeConstraint *operand = arg.dyn_cast<NamedTypeConstraint *>();
return operand && !operand->isVariableLength();
});
if (operandI == arguments.end())
return;
// All result types are inferred from the operand type.
int operandIdx = operandI - arguments.begin();
for (int i = 0; i < getNumResults(); ++i)
resultTypeMapping.emplace_back(operandIdx, "$_self");
allResultsHaveKnownTypes = true;
traits.push_back(Trait::create(inferTrait->getDefInit()));
return;
}
/// This struct represents a node in this operation's result type inferenece
/// graph. Each node has a list of incoming type inference edges `sources`.
/// Each edge represents a "source" from which the result type can be
/// inferred, either an operand (leaf) or another result (node). When a node
/// is known to have a fully-inferred type, `inferred` is set to true.
struct ResultTypeInference {
/// The list of incoming type inference edges.
SmallVector<InferredResultType> sources;
/// This flag is set to true when the result type is known to be inferrable.
bool inferred = false;
};
// This vector represents the type inference graph, with one node for each
// operation result. The nth element is the node for the nth result.
SmallVector<ResultTypeInference> inference(getNumResults(), {});
// For all results whose types are buildable, initialize their type inference
// nodes with an edge to themselves. Mark those nodes are fully-inferred.
for (auto [idx, infer] : llvm::enumerate(inference)) {
if (getResult(idx).constraint.getBuilderCall()) {
infer.sources.emplace_back(InferredResultType::mapResultIndex(idx),
"$_self");
infer.inferred = true;
}
}
// Use `AllTypesMatch` and `TypesMatchWith` operation traits to build the
// result type inference graph.
for (const Trait &trait : traits) {
const llvm::Record &def = trait.getDef();
// If the infer type op interface was manually added, then treat it as
// intention that the op needs special handling.
// TODO: Reconsider whether to always generate, this is more conservative
// and keeps existing behavior so starting that way for now.
if (def.isSubClassOf(
llvm::formatv("{0}::Trait", inferTypeOpInterface).str()))
return;
if (const auto *traitDef = dyn_cast<InterfaceTrait>(&trait))
if (&traitDef->getDef() == inferTrait)
return;
// The `TypesMatchWith` trait represents a 1 -> 1 type inference edge with a
// type transformer.
if (def.isSubClassOf("TypesMatchWith")) {
int target = argumentsAndResultsIndex.lookup(def.getValueAsString("rhs"));
// Ignore operand type inference.
if (InferredResultType::isArgIndex(target))
continue;
int resultIndex = InferredResultType::unmapResultIndex(target);
ResultTypeInference &infer = inference[resultIndex];
// If the type of the result has already been inferred, do nothing.
if (infer.inferred)
continue;
int sourceIndex =
argumentsAndResultsIndex.lookup(def.getValueAsString("lhs"));
infer.sources.emplace_back(sourceIndex,
def.getValueAsString("transformer").str());
// Locally propagate inferredness.
infer.inferred =
InferredResultType::isArgIndex(sourceIndex) ||
inference[InferredResultType::unmapResultIndex(sourceIndex)].inferred;
continue;
}
if (!def.isSubClassOf("AllTypesMatch"))
continue;
auto values = def.getValueAsListOfStrings("values");
// The `AllTypesMatch` trait represents an N <-> N fanin and fanout. That
// is, every result type has an edge from every other type. However, if any
// one of the values refers to an operand or a result with a fully-inferred
// type, we can infer all other types from that value. Try to find a
// fully-inferred type in the list.
std::optional<int> fullyInferredIndex;
SmallVector<int> resultIndices;
for (StringRef name : values) {
int index = argumentsAndResultsIndex.lookup(name);
if (InferredResultType::isResultIndex(index))
resultIndices.push_back(InferredResultType::unmapResultIndex(index));
if (InferredResultType::isArgIndex(index) ||
inference[InferredResultType::unmapResultIndex(index)].inferred)
fullyInferredIndex = index;
}
if (fullyInferredIndex) {
// Make the fully-inferred type the only source for all results that
// aren't already inferred -- a 1 -> N fanout.
for (int resultIndex : resultIndices) {
ResultTypeInference &infer = inference[resultIndex];
if (!infer.inferred) {
infer.sources.assign(1, {*fullyInferredIndex, "$_self"});
infer.inferred = true;
}
}
} else {
// Add an edge between every result and every other type; N <-> N.
for (int resultIndex : resultIndices) {
for (int otherResultIndex : resultIndices) {
if (resultIndex == otherResultIndex)
continue;
inference[resultIndex].sources.emplace_back(otherResultIndex,
"$_self");
}
}
}
}
// Propagate inferredness until a fixed point.
std::vector<ResultTypeInference *> worklist;
for (ResultTypeInference &infer : inference)
if (!infer.inferred)
worklist.push_back(&infer);
bool changed;
do {
changed = false;
for (auto cur = worklist.begin(); cur != worklist.end();) {
ResultTypeInference &infer = **cur;
InferredResultType *iter =
llvm::find_if(infer.sources, [&](const InferredResultType &source) {
assert(InferredResultType::isResultIndex(source.getIndex()));
return inference[InferredResultType::unmapResultIndex(
source.getIndex())]
.inferred;
});
if (iter == infer.sources.end()) {
++cur;
continue;
}
changed = true;
infer.inferred = true;
// Make this the only source for the result. This breaks any cycles.
infer.sources.assign(1, *iter);
cur = worklist.erase(cur);
}
} while (changed);
allResultsHaveKnownTypes = worklist.empty();
// If the types could be computed, then add type inference trait.
if (allResultsHaveKnownTypes) {
traits.push_back(Trait::create(inferTrait->getDefInit()));
for (const ResultTypeInference &infer : inference)
resultTypeMapping.push_back(infer.sources.front());
}
}
void Operator::populateOpStructure() {
auto &recordKeeper = def.getRecords();
auto *typeConstraintClass = recordKeeper.getClass("TypeConstraint");
auto *attrClass = recordKeeper.getClass("Attr");
auto *propertyClass = recordKeeper.getClass("Property");
auto *derivedAttrClass = recordKeeper.getClass("DerivedAttr");
auto *opVarClass = recordKeeper.getClass("OpVariable");
numNativeAttributes = 0;
DagInit *argumentValues = def.getValueAsDag("arguments");
unsigned numArgs = argumentValues->getNumArgs();
// Mapping from name of to argument or result index. Arguments are indexed
// to match getArg index, while the results are negatively indexed.
llvm::StringMap<int> argumentsAndResultsIndex;
// Handle operands and native attributes.
for (unsigned i = 0; i != numArgs; ++i) {
auto *arg = argumentValues->getArg(i);
auto givenName = argumentValues->getArgNameStr(i);
auto *argDefInit = dyn_cast<DefInit>(arg);
if (!argDefInit)
PrintFatalError(def.getLoc(),
Twine("undefined type for argument #") + Twine(i));
Record *argDef = argDefInit->getDef();
if (argDef->isSubClassOf(opVarClass))
argDef = argDef->getValueAsDef("constraint");
if (argDef->isSubClassOf(typeConstraintClass)) {
operands.push_back(
NamedTypeConstraint{givenName, TypeConstraint(argDef)});
} else if (argDef->isSubClassOf(attrClass)) {
if (givenName.empty())
PrintFatalError(argDef->getLoc(), "attributes must be named");
if (argDef->isSubClassOf(derivedAttrClass))
PrintFatalError(argDef->getLoc(),
"derived attributes not allowed in argument list");
attributes.push_back({givenName, Attribute(argDef)});
++numNativeAttributes;
} else if (argDef->isSubClassOf(propertyClass)) {
if (givenName.empty())
PrintFatalError(argDef->getLoc(), "properties must be named");
properties.push_back({givenName, Property(argDef)});
} else {
PrintFatalError(def.getLoc(),
"unexpected def type; only defs deriving "
"from TypeConstraint or Attr or Property are allowed");
}
if (!givenName.empty())
argumentsAndResultsIndex[givenName] = i;
}
// Handle derived attributes.
for (const auto &val : def.getValues()) {
if (auto *record = dyn_cast<llvm::RecordRecTy>(val.getType())) {
if (!record->isSubClassOf(attrClass))
continue;
if (!record->isSubClassOf(derivedAttrClass))
PrintFatalError(def.getLoc(),
"unexpected Attr where only DerivedAttr is allowed");
if (record->getClasses().size() != 1) {
PrintFatalError(
def.getLoc(),
"unsupported attribute modelling, only single class expected");
}
attributes.push_back(
{cast<llvm::StringInit>(val.getNameInit())->getValue(),
Attribute(cast<DefInit>(val.getValue()))});
}
}
// Populate `arguments`. This must happen after we've finalized `operands` and
// `attributes` because we will put their elements' pointers in `arguments`.
// SmallVector may perform re-allocation under the hood when adding new
// elements.
int operandIndex = 0, attrIndex = 0, propIndex = 0;
for (unsigned i = 0; i != numArgs; ++i) {
Record *argDef = dyn_cast<DefInit>(argumentValues->getArg(i))->getDef();
if (argDef->isSubClassOf(opVarClass))
argDef = argDef->getValueAsDef("constraint");
if (argDef->isSubClassOf(typeConstraintClass)) {
attrOrOperandMapping.push_back(
{OperandOrAttribute::Kind::Operand, operandIndex});
arguments.emplace_back(&operands[operandIndex++]);
} else if (argDef->isSubClassOf(attrClass)) {
attrOrOperandMapping.push_back(
{OperandOrAttribute::Kind::Attribute, attrIndex});
arguments.emplace_back(&attributes[attrIndex++]);
} else {
assert(argDef->isSubClassOf(propertyClass));
arguments.emplace_back(&properties[propIndex++]);
}
}
auto *resultsDag = def.getValueAsDag("results");
auto *outsOp = dyn_cast<DefInit>(resultsDag->getOperator());
if (!outsOp || outsOp->getDef()->getName() != "outs") {
PrintFatalError(def.getLoc(), "'results' must have 'outs' directive");
}
// Handle results.
for (unsigned i = 0, e = resultsDag->getNumArgs(); i < e; ++i) {
auto name = resultsDag->getArgNameStr(i);
auto *resultInit = dyn_cast<DefInit>(resultsDag->getArg(i));
if (!resultInit) {
PrintFatalError(def.getLoc(),
Twine("undefined type for result #") + Twine(i));
}
auto *resultDef = resultInit->getDef();
if (resultDef->isSubClassOf(opVarClass))
resultDef = resultDef->getValueAsDef("constraint");
results.push_back({name, TypeConstraint(resultDef)});
if (!name.empty())
argumentsAndResultsIndex[name] = InferredResultType::mapResultIndex(i);
// We currently only support VariadicOfVariadic operands.
if (results.back().constraint.isVariadicOfVariadic()) {
PrintFatalError(
def.getLoc(),
"'VariadicOfVariadic' results are currently not supported");
}
}
// Handle successors
auto *successorsDag = def.getValueAsDag("successors");
auto *successorsOp = dyn_cast<DefInit>(successorsDag->getOperator());
if (!successorsOp || successorsOp->getDef()->getName() != "successor") {
PrintFatalError(def.getLoc(),
"'successors' must have 'successor' directive");
}
for (unsigned i = 0, e = successorsDag->getNumArgs(); i < e; ++i) {
auto name = successorsDag->getArgNameStr(i);
auto *successorInit = dyn_cast<DefInit>(successorsDag->getArg(i));
if (!successorInit) {
PrintFatalError(def.getLoc(),
Twine("undefined kind for successor #") + Twine(i));
}
Successor successor(successorInit->getDef());
// Only support variadic successors if it is the last one for now.
if (i != e - 1 && successor.isVariadic())
PrintFatalError(def.getLoc(), "only the last successor can be variadic");
successors.push_back({name, successor});
}
// Create list of traits, skipping over duplicates: appending to lists in
// tablegen is easy, making them unique less so, so dedupe here.
if (auto *traitList = def.getValueAsListInit("traits")) {
// This is uniquing based on pointers of the trait.
SmallPtrSet<const llvm::Init *, 32> traitSet;
traits.reserve(traitSet.size());
// The declaration order of traits imply the verification order of traits.
// Some traits may require other traits to be verified first then they can
// do further verification based on those verified facts. If you see this
// error, fix the traits declaration order by checking the `dependentTraits`
// field.
auto verifyTraitValidity = [&](Record *trait) {
auto *dependentTraits = trait->getValueAsListInit("dependentTraits");
for (auto *traitInit : *dependentTraits)
if (!traitSet.contains(traitInit))
PrintFatalError(
def.getLoc(),
trait->getValueAsString("trait") + " requires " +
cast<DefInit>(traitInit)->getDef()->getValueAsString(
"trait") +
" to precede it in traits list");
};
std::function<void(llvm::ListInit *)> insert;
insert = [&](llvm::ListInit *traitList) {
for (auto *traitInit : *traitList) {
auto *def = cast<DefInit>(traitInit)->getDef();
if (def->isSubClassOf("TraitList")) {
insert(def->getValueAsListInit("traits"));
continue;
}
// Ignore duplicates.
if (!traitSet.insert(traitInit).second)
continue;
// If this is an interface with base classes, add the bases to the
// trait list.
if (def->isSubClassOf("Interface"))
insert(def->getValueAsListInit("baseInterfaces"));
// Verify if the trait has all the dependent traits declared before
// itself.
verifyTraitValidity(def);
traits.push_back(Trait::create(traitInit));
}
};
insert(traitList);
}
populateTypeInferenceInfo(argumentsAndResultsIndex);
// Handle regions
auto *regionsDag = def.getValueAsDag("regions");
auto *regionsOp = dyn_cast<DefInit>(regionsDag->getOperator());
if (!regionsOp || regionsOp->getDef()->getName() != "region") {
PrintFatalError(def.getLoc(), "'regions' must have 'region' directive");
}
for (unsigned i = 0, e = regionsDag->getNumArgs(); i < e; ++i) {
auto name = regionsDag->getArgNameStr(i);
auto *regionInit = dyn_cast<DefInit>(regionsDag->getArg(i));
if (!regionInit) {
PrintFatalError(def.getLoc(),
Twine("undefined kind for region #") + Twine(i));
}
Region region(regionInit->getDef());
if (region.isVariadic()) {
// Only support variadic regions if it is the last one for now.
if (i != e - 1)
PrintFatalError(def.getLoc(), "only the last region can be variadic");
if (name.empty())
PrintFatalError(def.getLoc(), "variadic regions must be named");
}
regions.push_back({name, region});
}
// Populate the builders.
auto *builderList =
dyn_cast_or_null<llvm::ListInit>(def.getValueInit("builders"));
if (builderList && !builderList->empty()) {
for (llvm::Init *init : builderList->getValues())
builders.emplace_back(cast<llvm::DefInit>(init)->getDef(), def.getLoc());
} else if (skipDefaultBuilders()) {
PrintFatalError(
def.getLoc(),
"default builders are skipped and no custom builders provided");
}
LLVM_DEBUG(print(llvm::dbgs()));
}
const InferredResultType &Operator::getInferredResultType(int index) const {
assert(allResultTypesKnown());
return resultTypeMapping[index];
}
ArrayRef<SMLoc> Operator::getLoc() const { return def.getLoc(); }
bool Operator::hasDescription() const {
return def.getValue("description") != nullptr;
}
StringRef Operator::getDescription() const {
return def.getValueAsString("description");
}
bool Operator::hasSummary() const { return def.getValue("summary") != nullptr; }
StringRef Operator::getSummary() const {
return def.getValueAsString("summary");
}
bool Operator::hasAssemblyFormat() const {
auto *valueInit = def.getValueInit("assemblyFormat");
return isa<llvm::StringInit>(valueInit);
}
StringRef Operator::getAssemblyFormat() const {
return TypeSwitch<llvm::Init *, StringRef>(def.getValueInit("assemblyFormat"))
.Case<llvm::StringInit>([&](auto *init) { return init->getValue(); });
}
void Operator::print(llvm::raw_ostream &os) const {
os << "op '" << getOperationName() << "'\n";
for (Argument arg : arguments) {
if (auto *attr = arg.dyn_cast<NamedAttribute *>())
os << "[attribute] " << attr->name << '\n';
else
os << "[operand] " << arg.get<NamedTypeConstraint *>()->name << '\n';
}
}
auto Operator::VariableDecoratorIterator::unwrap(llvm::Init *init)
-> VariableDecorator {
return VariableDecorator(cast<llvm::DefInit>(init)->getDef());
}
auto Operator::getArgToOperandOrAttribute(int index) const
-> OperandOrAttribute {
return attrOrOperandMapping[index];
}
std::string Operator::getGetterName(StringRef name) const {
return "get" + convertToCamelFromSnakeCase(name, /*capitalizeFirst=*/true);
}
std::string Operator::getSetterName(StringRef name) const {
return "set" + convertToCamelFromSnakeCase(name, /*capitalizeFirst=*/true);
}
std::string Operator::getRemoverName(StringRef name) const {
return "remove" + convertToCamelFromSnakeCase(name, /*capitalizeFirst=*/true);
}
bool Operator::hasFolder() const { return def.getValueAsBit("hasFolder"); }
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