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llvm / llvm-project / 9e3e1aad3161f4ce5301c3a59c7313ad83240a6d / . / mlir / tools / mlir-tblgen / AttrOrTypeFormatGen.cpp
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//===- AttrOrTypeFormatGen.cpp - MLIR attribute and type format generator -===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "AttrOrTypeFormatGen.h"
#include "FormatGen.h"
#include "mlir/Support/LLVM.h"
#include "mlir/Support/LogicalResult.h"
#include "mlir/TableGen/AttrOrTypeDef.h"
#include "mlir/TableGen/Format.h"
#include "mlir/TableGen/GenInfo.h"
#include "llvm/ADT/BitVector.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/SourceMgr.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/TableGenBackend.h"
using namespace mlir;
using namespace mlir::tblgen;
using llvm::formatv;
//===----------------------------------------------------------------------===//
// Element
//===----------------------------------------------------------------------===//
namespace {
/// This class represents a single format element.
class Element {
public:
/// LLVM-style RTTI.
enum class Kind {
/// This element is a directive.
ParamsDirective,
StructDirective,
/// This element is a literal.
Literal,
/// This element is a variable.
Variable,
};
Element(Kind kind) : kind(kind) {}
virtual ~Element() = default;
/// Return the kind of this element.
Kind getKind() const { return kind; }
private:
/// The kind of this element.
Kind kind;
};
/// This class represents an instance of a literal element.
class LiteralElement : public Element {
public:
LiteralElement(StringRef literal)
: Element(Kind::Literal), literal(literal) {}
static bool classof(const Element *el) {
return el->getKind() == Kind::Literal;
}
/// Get the literal spelling.
StringRef getSpelling() const { return literal; }
private:
/// The spelling of the literal for this element.
StringRef literal;
};
/// This class represents an instance of a variable element. A variable refers
/// to an attribute or type parameter.
class VariableElement : public Element {
public:
VariableElement(AttrOrTypeParameter param)
: Element(Kind::Variable), param(param) {}
static bool classof(const Element *el) {
return el->getKind() == Kind::Variable;
}
/// Get the parameter in the element.
const AttrOrTypeParameter &getParam() const { return param; }
private:
AttrOrTypeParameter param;
};
/// Base class for a directive that contains references to multiple variables.
template <Element::Kind ElementKind>
class ParamsDirectiveBase : public Element {
public:
using Base = ParamsDirectiveBase<ElementKind>;
ParamsDirectiveBase(SmallVector<std::unique_ptr<Element>> &&params)
: Element(ElementKind), params(std::move(params)) {}
static bool classof(const Element *el) {
return el->getKind() == ElementKind;
}
/// Get the parameters contained in this directive.
auto getParams() const {
return llvm::map_range(params, [](auto &el) {
return cast<VariableElement>(el.get())->getParam();
});
}
/// Get the number of parameters.
unsigned getNumParams() const { return params.size(); }
/// Take all of the parameters from this directive.
SmallVector<std::unique_ptr<Element>> takeParams() {
return std::move(params);
}
private:
/// The parameters captured by this directive.
SmallVector<std::unique_ptr<Element>> params;
};
/// This class represents a `params` directive that refers to all parameters
/// of an attribute or type. When used as a top-level directive, it generates
/// a format of the form:
///
/// (param-value (`,` param-value)*)?
///
/// When used as an argument to another directive that accepts variables,
/// `params` can be used in place of manually listing all parameters of an
/// attribute or type.
class ParamsDirective
: public ParamsDirectiveBase<Element::Kind::ParamsDirective> {
public:
using Base::Base;
};
/// This class represents a `struct` directive that generates a struct format
/// of the form:
///
/// `{` param-name `=` param-value (`,` param-name `=` param-value)* `}`
///
class StructDirective
: public ParamsDirectiveBase<Element::Kind::StructDirective> {
public:
using Base::Base;
};
} // end anonymous namespace
//===----------------------------------------------------------------------===//
// Format Strings
//===----------------------------------------------------------------------===//
/// Format for defining an attribute parser.
///
/// $0: The attribute C++ class name.
static const char *const attrParserDefn = R"(
::mlir::Attribute $0::parse(::mlir::AsmParser &$_parser,
::mlir::Type $_type) {
)";
/// Format for defining a type parser.
///
/// $0: The type C++ class name.
static const char *const typeParserDefn = R"(
::mlir::Type $0::parse(::mlir::AsmParser &$_parser) {
)";
/// Default parser for attribute or type parameters.
static const char *const defaultParameterParser =
"::mlir::FieldParser<$0>::parse($_parser)";
/// Default printer for attribute or type parameters.
static const char *const defaultParameterPrinter = "$_printer << $_self";
/// Print an error when failing to parse an element.
///
/// $0: The parameter C++ class name.
static const char *const parseErrorStr =
"$_parser.emitError($_parser.getCurrentLocation(), ";
/// Format for defining an attribute or type printer.
///
/// $0: The attribute or type C++ class name.
static const char *const attrOrTypePrinterDefn = R"(
void $0::print(::mlir::AsmPrinter &$_printer) const {
)";
/// Loop declaration for struct parser.
///
/// $0: Number of expected parameters.
static const char *const structParseLoopStart = R"(
for (unsigned _index = 0; _index < $0; ++_index) {
StringRef _paramKey;
if ($_parser.parseKeyword(&_paramKey)) {
$_parser.emitError($_parser.getCurrentLocation(),
"expected a parameter name in struct");
return {};
}
)";
/// Terminator code segment for the struct parser loop. Check for duplicate or
/// unknown parameters. Parse a comma except on the last element.
///
/// {0}: Code template for printing an error.
/// {1}: Number of elements in the struct.
static const char *const structParseLoopEnd = R"({{
{0}"duplicate or unknown struct parameter name: ") << _paramKey;
return {{};
}
if ((_index != {1} - 1) && parser.parseComma())
return {{};
}
)";
/// Code format to parse a variable. Separate by lines because variable parsers
/// may be generated inside other directives, which requires indentation.
///
/// {0}: The parameter name.
/// {1}: The parse code for the parameter.
/// {2}: Code template for printing an error.
/// {3}: Name of the attribute or type.
/// {4}: C++ class of the parameter.
static const char *const variableParser[] = {
" // Parse variable '{0}'",
" _result_{0} = {1};",
" if (failed(_result_{0})) {{",
" {2}\"failed to parse {3} parameter '{0}' which is to be a `{4}`\");",
" return {{};",
" }",
};
//===----------------------------------------------------------------------===//
// Utility Functions
//===----------------------------------------------------------------------===//
/// Get a list of an attribute's or type's parameters. These can be wrapper
/// objects around `AttrOrTypeParameter` or string inits.
static auto getParameters(const AttrOrTypeDef &def) {
SmallVector<AttrOrTypeParameter> params;
def.getParameters(params);
return params;
}
//===----------------------------------------------------------------------===//
// AttrOrTypeFormat
//===----------------------------------------------------------------------===//
namespace {
class AttrOrTypeFormat {
public:
AttrOrTypeFormat(const AttrOrTypeDef &def,
std::vector<std::unique_ptr<Element>> &&elements)
: def(def), elements(std::move(elements)) {}
/// Generate the attribute or type parser.
void genParser(raw_ostream &os);
/// Generate the attribute or type printer.
void genPrinter(raw_ostream &os);
private:
/// Generate the parser code for a specific format element.
void genElementParser(Element *el, FmtContext &ctx, raw_ostream &os);
/// Generate the parser code for a literal.
void genLiteralParser(StringRef value, FmtContext &ctx, raw_ostream &os,
unsigned indent = 0);
/// Generate the parser code for a variable.
void genVariableParser(const AttrOrTypeParameter &param, FmtContext &ctx,
raw_ostream &os, unsigned indent = 0);
/// Generate the parser code for a `params` directive.
void genParamsParser(ParamsDirective *el, FmtContext &ctx, raw_ostream &os);
/// Generate the parser code for a `struct` directive.
void genStructParser(StructDirective *el, FmtContext &ctx, raw_ostream &os);
/// Generate the printer code for a specific format element.
void genElementPrinter(Element *el, FmtContext &ctx, raw_ostream &os);
/// Generate the printer code for a literal.
void genLiteralPrinter(StringRef value, FmtContext &ctx, raw_ostream &os);
/// Generate the printer code for a variable.
void genVariablePrinter(const AttrOrTypeParameter &param, FmtContext &ctx,
raw_ostream &os);
/// Generate the printer code for a `params` directive.
void genParamsPrinter(ParamsDirective *el, FmtContext &ctx, raw_ostream &os);
/// Generate the printer code for a `struct` directive.
void genStructPrinter(StructDirective *el, FmtContext &ctx, raw_ostream &os);
/// The ODS definition of the attribute or type whose format is being used to
/// generate a parser and printer.
const AttrOrTypeDef &def;
/// The list of top-level format elements returned by the assembly format
/// parser.
std::vector<std::unique_ptr<Element>> elements;
/// Flags for printing spaces.
bool shouldEmitSpace;
bool lastWasPunctuation;
};
} // end anonymous namespace
//===----------------------------------------------------------------------===//
// ParserGen
//===----------------------------------------------------------------------===//
void AttrOrTypeFormat::genParser(raw_ostream &os) {
FmtContext ctx;
ctx.addSubst("_parser", "parser");
/// Generate the definition.
if (isa<AttrDef>(def)) {
ctx.addSubst("_type", "attrType");
os << tgfmt(attrParserDefn, &ctx, def.getCppClassName());
} else {
os << tgfmt(typeParserDefn, &ctx, def.getCppClassName());
}
/// Declare variables to store all of the parameters. Allocated parameters
/// such as `ArrayRef` and `StringRef` must provide a `storageType`. Store
/// FailureOr<T> to defer type construction for parameters that are parsed in
/// a loop (parsers return FailureOr anyways).
SmallVector<AttrOrTypeParameter> params = getParameters(def);
for (const AttrOrTypeParameter &param : params) {
os << formatv(" ::mlir::FailureOr<{0}> _result_{1};\n",
param.getCppStorageType(), param.getName());
}
/// Store the initial location of the parser.
ctx.addSubst("_loc", "loc");
os << tgfmt(" ::llvm::SMLoc $_loc = $_parser.getCurrentLocation();\n"
" (void) $_loc;\n",
&ctx);
/// Generate call to each parameter parser.
for (auto &el : elements)
genElementParser(el.get(), ctx, os);
/// Generate call to the attribute or type builder. Use the checked getter
/// if one was generated.
if (def.genVerifyDecl()) {
os << tgfmt(" return $_parser.getChecked<$0>($_loc, $_parser.getContext()",
&ctx, def.getCppClassName());
} else {
os << tgfmt(" return $0::get($_parser.getContext()", &ctx,
def.getCppClassName());
}
for (const AttrOrTypeParameter &param : params)
os << formatv(",\n _result_{0}.getValue()", param.getName());
os << ");\n}\n\n";
}
void AttrOrTypeFormat::genElementParser(Element *el, FmtContext &ctx,
raw_ostream &os) {
if (auto *literal = dyn_cast<LiteralElement>(el))
return genLiteralParser(literal->getSpelling(), ctx, os);
if (auto *var = dyn_cast<VariableElement>(el))
return genVariableParser(var->getParam(), ctx, os);
if (auto *params = dyn_cast<ParamsDirective>(el))
return genParamsParser(params, ctx, os);
if (auto *strct = dyn_cast<StructDirective>(el))
return genStructParser(strct, ctx, os);
llvm_unreachable("unknown format element");
}
void AttrOrTypeFormat::genLiteralParser(StringRef value, FmtContext &ctx,
raw_ostream &os, unsigned indent) {
os.indent(indent) << " // Parse literal '" << value << "'\n";
os.indent(indent) << tgfmt(" if ($_parser.parse", &ctx);
if (value.front() == '_' || isalpha(value.front())) {
os << "Keyword(\"" << value << "\")";
} else {
os << StringSwitch<StringRef>(value)
.Case("->", "Arrow")
.Case(":", "Colon")
.Case(",", "Comma")
.Case("=", "Equal")
.Case("<", "Less")
.Case(">", "Greater")
.Case("{", "LBrace")
.Case("}", "RBrace")
.Case("(", "LParen")
.Case(")", "RParen")
.Case("[", "LSquare")
.Case("]", "RSquare")
.Case("?", "Question")
.Case("+", "Plus")
.Case("*", "Star")
<< "()";
}
os << ")\n";
// Parser will emit an error
os.indent(indent) << " return {};\n";
}
void AttrOrTypeFormat::genVariableParser(const AttrOrTypeParameter &param,
FmtContext &ctx, raw_ostream &os,
unsigned indent) {
/// Check for a custom parser. Use the default attribute parser otherwise.
auto customParser = param.getParser();
auto parser =
customParser ? *customParser : StringRef(defaultParameterParser);
for (const char *line : variableParser) {
os.indent(indent) << formatv(line, param.getName(),
tgfmt(parser, &ctx, param.getCppStorageType()),
tgfmt(parseErrorStr, &ctx), def.getName(),
param.getCppType())
<< "\n";
}
}
void AttrOrTypeFormat::genParamsParser(ParamsDirective *el, FmtContext &ctx,
raw_ostream &os) {
os << " // Parse parameter list\n";
llvm::interleave(
el->getParams(),
[&](auto param) { this->genVariableParser(param, ctx, os); },
[&]() { this->genLiteralParser(",", ctx, os); });
}
void AttrOrTypeFormat::genStructParser(StructDirective *el, FmtContext &ctx,
raw_ostream &os) {
os << " // Parse parameter struct\n";
/// Declare a "seen" variable for each key.
for (const AttrOrTypeParameter &param : el->getParams())
os << formatv(" bool _seen_{0} = false;\n", param.getName());
/// Generate the parsing loop.
os << tgfmt(structParseLoopStart, &ctx, el->getNumParams());
genLiteralParser("=", ctx, os, 2);
os << " ";
for (const AttrOrTypeParameter &param : el->getParams()) {
os << formatv("if (!_seen_{0} && _paramKey == \"{0}\") {\n"
" _seen_{0} = true;\n",
param.getName());
genVariableParser(param, ctx, os, 4);
os << " } else ";
}
/// Duplicate or unknown parameter.
os << formatv(structParseLoopEnd, tgfmt(parseErrorStr, &ctx),
el->getNumParams());
/// Because the loop loops N times and each non-failing iteration sets 1 of
/// N flags, successfully exiting the loop means that all parameters have been
/// seen. `parseOptionalComma` would cause issues with any formats that use
/// "struct(...) `,`" beacuse structs aren't sounded by braces.
}
//===----------------------------------------------------------------------===//
// PrinterGen
//===----------------------------------------------------------------------===//
void AttrOrTypeFormat::genPrinter(raw_ostream &os) {
FmtContext ctx;
ctx.addSubst("_printer", "printer");
/// Generate the definition.
os << tgfmt(attrOrTypePrinterDefn, &ctx, def.getCppClassName());
/// Generate printers.
shouldEmitSpace = true;
lastWasPunctuation = false;
for (auto &el : elements)
genElementPrinter(el.get(), ctx, os);
os << "}\n\n";
}
void AttrOrTypeFormat::genElementPrinter(Element *el, FmtContext &ctx,
raw_ostream &os) {
if (auto *literal = dyn_cast<LiteralElement>(el))
return genLiteralPrinter(literal->getSpelling(), ctx, os);
if (auto *params = dyn_cast<ParamsDirective>(el))
return genParamsPrinter(params, ctx, os);
if (auto *strct = dyn_cast<StructDirective>(el))
return genStructPrinter(strct, ctx, os);
if (auto *var = dyn_cast<VariableElement>(el))
return genVariablePrinter(var->getParam(), ctx, os);
llvm_unreachable("unknown format element");
}
void AttrOrTypeFormat::genLiteralPrinter(StringRef value, FmtContext &ctx,
raw_ostream &os) {
/// Don't insert a space before certain punctuation.
bool needSpace =
shouldEmitSpace && shouldEmitSpaceBefore(value, lastWasPunctuation);
os << tgfmt(" $_printer$0 << \"$1\";\n", &ctx, needSpace ? " << ' '" : "",
value);
/// Update the flags.
shouldEmitSpace =
value.size() != 1 || !StringRef("<({[").contains(value.front());
lastWasPunctuation = !(value.front() == '_' || isalpha(value.front()));
}
void AttrOrTypeFormat::genVariablePrinter(const AttrOrTypeParameter &param,
FmtContext &ctx, raw_ostream &os) {
/// Insert a space before the next parameter, if necessary.
if (shouldEmitSpace || !lastWasPunctuation)
os << tgfmt(" $_printer << ' ';\n", &ctx);
shouldEmitSpace = true;
lastWasPunctuation = false;
ctx.withSelf(getParameterAccessorName(param.getName()) + "()");
os << " ";
if (auto printer = param.getPrinter())
os << tgfmt(*printer, &ctx) << ";\n";
else
os << tgfmt(defaultParameterPrinter, &ctx) << ";\n";
}
void AttrOrTypeFormat::genParamsPrinter(ParamsDirective *el, FmtContext &ctx,
raw_ostream &os) {
llvm::interleave(
el->getParams(),
[&](auto param) { this->genVariablePrinter(param, ctx, os); },
[&]() { this->genLiteralPrinter(",", ctx, os); });
}
void AttrOrTypeFormat::genStructPrinter(StructDirective *el, FmtContext &ctx,
raw_ostream &os) {
llvm::interleave(
el->getParams(),
[&](auto param) {
this->genLiteralPrinter(param.getName(), ctx, os);
this->genLiteralPrinter("=", ctx, os);
os << tgfmt(" $_printer << ' ';\n", &ctx);
this->genVariablePrinter(param, ctx, os);
},
[&]() { this->genLiteralPrinter(",", ctx, os); });
}
//===----------------------------------------------------------------------===//
// FormatParser
//===----------------------------------------------------------------------===//
namespace {
class FormatParser {
public:
FormatParser(llvm::SourceMgr &mgr, const AttrOrTypeDef &def)
: lexer(mgr, def.getLoc()[0]), curToken(lexer.lexToken()), def(def),
seenParams(def.getNumParameters()) {}
/// Parse the attribute or type format and create the format elements.
FailureOr<AttrOrTypeFormat> parse();
private:
/// The current context of the parser when parsing an element.
enum ParserContext {
/// The element is being parsed in the default context - at the top of the
/// format
TopLevelContext,
/// The element is being parsed as a child to a `struct` directive.
StructDirective,
};
/// Emit an error.
LogicalResult emitError(const Twine &msg) {
lexer.emitError(curToken.getLoc(), msg);
return failure();
}
/// Parse an expected token.
LogicalResult parseToken(FormatToken::Kind kind, const Twine &msg) {
if (curToken.getKind() != kind)
return emitError(msg);
consumeToken();
return success();
}
/// Advance the lexer to the next token.
void consumeToken() {
assert(curToken.getKind() != FormatToken::eof &&
curToken.getKind() != FormatToken::error &&
"shouldn't advance past EOF or errors");
curToken = lexer.lexToken();
}
/// Parse any element.
FailureOr<std::unique_ptr<Element>> parseElement(ParserContext ctx);
/// Parse a literal element.
FailureOr<std::unique_ptr<Element>> parseLiteral(ParserContext ctx);
/// Parse a variable element.
FailureOr<std::unique_ptr<Element>> parseVariable(ParserContext ctx);
/// Parse a directive.
FailureOr<std::unique_ptr<Element>> parseDirective(ParserContext ctx);
/// Parse a `params` directive.
FailureOr<std::unique_ptr<Element>> parseParamsDirective();
/// Parse a `struct` directive.
FailureOr<std::unique_ptr<Element>> parseStructDirective();
/// The current format lexer.
FormatLexer lexer;
/// The current token in the stream.
FormatToken curToken;
/// Attribute or type tablegen def.
const AttrOrTypeDef &def;
/// Seen attribute or type parameters.
llvm::BitVector seenParams;
};
} // end anonymous namespace
FailureOr<AttrOrTypeFormat> FormatParser::parse() {
std::vector<std::unique_ptr<Element>> elements;
elements.reserve(16);
/// Parse the format elements.
while (curToken.getKind() != FormatToken::eof) {
auto element = parseElement(TopLevelContext);
if (failed(element))
return failure();
/// Add the format element and continue.
elements.push_back(std::move(*element));
}
/// Check that all parameters have been seen.
SmallVector<AttrOrTypeParameter> params = getParameters(def);
for (auto it : llvm::enumerate(params)) {
if (!seenParams.test(it.index())) {
return emitError("format is missing reference to parameter: " +
it.value().getName());
}
}
return AttrOrTypeFormat(def, std::move(elements));
}
FailureOr<std::unique_ptr<Element>>
FormatParser::parseElement(ParserContext ctx) {
if (curToken.getKind() == FormatToken::literal)
return parseLiteral(ctx);
if (curToken.getKind() == FormatToken::variable)
return parseVariable(ctx);
if (curToken.isKeyword())
return parseDirective(ctx);
return emitError("expected literal, directive, or variable");
}
FailureOr<std::unique_ptr<Element>>
FormatParser::parseLiteral(ParserContext ctx) {
if (ctx != TopLevelContext) {
return emitError(
"literals may only be used in the top-level section of the format");
}
/// Get the literal spelling without the surrounding "`".
auto value = curToken.getSpelling().drop_front().drop_back();
if (!isValidLiteral(value))
return emitError("literal '" + value + "' is not valid");
consumeToken();
return {std::make_unique<LiteralElement>(value)};
}
FailureOr<std::unique_ptr<Element>>
FormatParser::parseVariable(ParserContext ctx) {
/// Get the parameter name without the preceding "$".
auto name = curToken.getSpelling().drop_front();
/// Lookup the parameter.
SmallVector<AttrOrTypeParameter> params = getParameters(def);
auto *it = llvm::find_if(
params, [&](auto &param) { return param.getName() == name; });
/// Check that the parameter reference is valid.
if (it == params.end())
return emitError(def.getName() + " has no parameter named '" + name + "'");
auto idx = std::distance(params.begin(), it);
if (seenParams.test(idx))
return emitError("duplicate parameter '" + name + "'");
seenParams.set(idx);
consumeToken();
return {std::make_unique<VariableElement>(*it)};
}
FailureOr<std::unique_ptr<Element>>
FormatParser::parseDirective(ParserContext ctx) {
switch (curToken.getKind()) {
case FormatToken::kw_params:
return parseParamsDirective();
case FormatToken::kw_struct:
if (ctx != TopLevelContext) {
return emitError(
"`struct` may only be used in the top-level section of the format");
}
return parseStructDirective();
default:
return emitError("unknown directive in format: " + curToken.getSpelling());
}
}
FailureOr<std::unique_ptr<Element>> FormatParser::parseParamsDirective() {
consumeToken();
/// Collect all of the attribute's or type's parameters.
SmallVector<AttrOrTypeParameter> params = getParameters(def);
SmallVector<std::unique_ptr<Element>> vars;
/// Ensure that none of the parameters have already been captured.
for (auto it : llvm::enumerate(params)) {
if (seenParams.test(it.index())) {
return emitError("`params` captures duplicate parameter: " +
it.value().getName());
}
seenParams.set(it.index());
vars.push_back(std::make_unique<VariableElement>(it.value()));
}
return {std::make_unique<ParamsDirective>(std::move(vars))};
}
FailureOr<std::unique_ptr<Element>> FormatParser::parseStructDirective() {
consumeToken();
if (failed(parseToken(FormatToken::l_paren,
"expected '(' before `struct` argument list")))
return failure();
/// Parse variables captured by `struct`.
SmallVector<std::unique_ptr<Element>> vars;
/// Parse first captured parameter or a `params` directive.
FailureOr<std::unique_ptr<Element>> var = parseElement(StructDirective);
if (failed(var) || !isa<VariableElement, ParamsDirective>(*var))
return emitError("`struct` argument list expected a variable or directive");
if (isa<VariableElement>(*var)) {
/// Parse any other parameters.
vars.push_back(std::move(*var));
while (curToken.getKind() == FormatToken::comma) {
consumeToken();
var = parseElement(StructDirective);
if (failed(var) || !isa<VariableElement>(*var))
return emitError("expected a variable in `struct` argument list");
vars.push_back(std::move(*var));
}
} else {
/// `struct(params)` captures all parameters in the attribute or type.
vars = cast<ParamsDirective>(var->get())->takeParams();
}
if (curToken.getKind() != FormatToken::r_paren)
return emitError("expected ')' at the end of an argument list");
consumeToken();
return {std::make_unique<::StructDirective>(std::move(vars))};
}
//===----------------------------------------------------------------------===//
// Interface
//===----------------------------------------------------------------------===//
void mlir::tblgen::generateAttrOrTypeFormat(const AttrOrTypeDef &def,
raw_ostream &os) {
llvm::SourceMgr mgr;
mgr.AddNewSourceBuffer(
llvm::MemoryBuffer::getMemBuffer(*def.getAssemblyFormat()),
llvm::SMLoc());
/// Parse the custom assembly format>
FormatParser parser(mgr, def);
FailureOr<AttrOrTypeFormat> format = parser.parse();
if (failed(format)) {
if (formatErrorIsFatal)
PrintFatalError(def.getLoc(), "failed to parse assembly format");
return;
}
/// Generate the parser and printer.
format->genParser(os);
format->genPrinter(os);
}