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|
//===-- Parser.cpp --------------------------------------------------------===//
//
// The KLEE Symbolic Virtual Machine
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "expr/Parser.h"
#include "expr/Lexer.h"
#include "klee/Constraints.h"
#include "klee/Solver.h"
#include "klee/util/ExprPPrinter.h"
#include "llvm/ADT/APInt.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/Streams.h"
#include <cassert>
#include <iostream>
#include <map>
#include <cstring>
using namespace llvm;
using namespace klee;
using namespace klee::expr;
namespace {
/// ParseResult - Represent a possibly invalid parse result.
template<typename T>
struct ParseResult {
bool IsValid;
T Value;
public:
ParseResult() : IsValid(false), Value() {}
ParseResult(T _Value) : IsValid(true), Value(_Value) {}
ParseResult(bool _IsValid, T _Value) : IsValid(_IsValid), Value(_Value) {}
bool isValid() {
return IsValid;
}
T get() {
assert(IsValid && "get() on invalid ParseResult!");
return Value;
}
};
class ExprResult {
bool IsValid;
ExprHandle Value;
public:
ExprResult() : IsValid(false) {}
ExprResult(ExprHandle _Value) : IsValid(true), Value(_Value) {}
ExprResult(ref<ConstantExpr> _Value) : IsValid(true), Value(_Value.get()) {}
ExprResult(bool _IsValid, ExprHandle _Value) : IsValid(_IsValid), Value(_Value) {}
bool isValid() {
return IsValid;
}
ExprHandle get() {
assert(IsValid && "get() on invalid ParseResult!");
return Value;
}
};
typedef ParseResult<Decl*> DeclResult;
typedef ParseResult<Expr::Width> TypeResult;
typedef ParseResult<VersionHandle> VersionResult;
typedef ParseResult<uint64_t> IntegerResult;
/// NumberOrExprResult - Represent a number or expression. This is used to
/// wrap an expression production which may be a number, but for
/// which the type width is unknown.
class NumberOrExprResult {
Token AsNumber;
ExprResult AsExpr;
bool IsNumber;
public:
NumberOrExprResult() : IsNumber(false) {}
explicit NumberOrExprResult(Token _AsNumber) : AsNumber(_AsNumber),
IsNumber(true) {}
explicit NumberOrExprResult(ExprResult _AsExpr) : AsExpr(_AsExpr),
IsNumber(false) {}
bool isNumber() const { return IsNumber; }
const Token &getNumber() const {
assert(IsNumber && "Invalid accessor call.");
return AsNumber;
}
const ExprResult &getExpr() const {
assert(!IsNumber && "Invalid accessor call.");
return AsExpr;
}
};
/// ParserImpl - Parser implementation.
class ParserImpl : public Parser {
typedef std::map<const std::string, const Identifier*> IdentifierTabTy;
typedef std::map<const Identifier*, ExprHandle> ExprSymTabTy;
typedef std::map<const Identifier*, VersionHandle> VersionSymTabTy;
const std::string Filename;
const MemoryBuffer *TheMemoryBuffer;
Lexer TheLexer;
unsigned MaxErrors;
unsigned NumErrors;
// FIXME: Use LLVM symbol tables?
IdentifierTabTy IdentifierTab;
std::map<const Identifier*, const ArrayDecl*> ArraySymTab;
ExprSymTabTy ExprSymTab;
VersionSymTabTy VersionSymTab;
/// Tok - The currently lexed token.
Token Tok;
/// ParenLevel - The current depth of matched '(' tokens.
unsigned ParenLevel;
/// SquareLevel - The current depth of matched '[' tokens.
unsigned SquareLevel;
/* Core parsing functionality */
const Identifier *GetOrCreateIdentifier(const Token &Tok);
void GetNextNonCommentToken() {
do {
TheLexer.Lex(Tok);
} while (Tok.kind == Token::Comment);
}
/// ConsumeToken - Consume the current 'peek token' and lex the next one.
void ConsumeToken() {
assert(Tok.kind != Token::LParen && Tok.kind != Token::RParen &&
Tok.kind != Token::LSquare && Tok.kind != Token::RSquare);
GetNextNonCommentToken();
}
/// ConsumeExpectedToken - Check that the current token is of the
/// expected kind and consume it.
void ConsumeExpectedToken(Token::Kind k) {
assert(Tok.kind != Token::LParen && Tok.kind != Token::RParen &&
Tok.kind != Token::LSquare && Tok.kind != Token::RSquare);
_ConsumeExpectedToken(k);
}
void _ConsumeExpectedToken(Token::Kind k) {
assert(Tok.kind == k && "Unexpected token!");
GetNextNonCommentToken();
}
void ConsumeLParen() {
++ParenLevel;
_ConsumeExpectedToken(Token::LParen);
}
void ConsumeRParen() {
if (ParenLevel) // Cannot go below zero.
--ParenLevel;
_ConsumeExpectedToken(Token::RParen);
}
void ConsumeLSquare() {
++SquareLevel;
_ConsumeExpectedToken(Token::LSquare);
}
void ConsumeRSquare() {
if (SquareLevel) // Cannot go below zero.
--SquareLevel;
_ConsumeExpectedToken(Token::RSquare);
}
void ConsumeAnyToken() {
switch (Tok.kind) {
case Token::LParen: return ConsumeLParen();
case Token::RParen: return ConsumeRParen();
case Token::LSquare: return ConsumeLSquare();
case Token::RSquare: return ConsumeRSquare();
default:
return ConsumeToken();
}
}
/* Utility functions */
/// SkipUntilRParen - Scan forward to the next token following an
/// rparen at the given level, or EOF, whichever is first.
void SkipUntilRParen(unsigned Level) {
// FIXME: I keep wavering on whether it is an error to call this
// with the current token an rparen. In most cases this should
// have been handled differently (error reported,
// whatever). Audit & resolve.
assert(Level <= ParenLevel &&
"Refusing to skip until rparen at higher level.");
while (Tok.kind != Token::EndOfFile) {
if (Tok.kind == Token::RParen && ParenLevel == Level) {
ConsumeRParen();
break;
}
ConsumeAnyToken();
}
}
/// SkipUntilRParen - Scan forward until reaching an rparen token
/// at the current level (or EOF).
void SkipUntilRParen() {
SkipUntilRParen(ParenLevel);
}
/// ExpectRParen - Utility method to close an sexp. This expects to
/// eat an rparen, and emits a diagnostic and skips to the next one
/// (or EOF) if it cannot.
void ExpectRParen(const char *Msg) {
if (Tok.kind == Token::EndOfFile) {
// FIXME: Combine with Msg
Error("expected ')' but found end-of-file.", Tok);
} else if (Tok.kind != Token::RParen) {
Error(Msg, Tok);
SkipUntilRParen();
} else {
ConsumeRParen();
}
}
/// SkipUntilRSquare - Scan forward to the next token following an
/// rsquare at the given level, or EOF, whichever is first.
void SkipUntilRSquare(unsigned Level) {
// FIXME: I keep wavering on whether it is an error to call this
// with the current token an rparen. In most cases this should
// have been handled differently (error reported,
// whatever). Audit & resolve.
assert(Level <= ParenLevel &&
"Refusing to skip until rparen at higher level.");
while (Tok.kind != Token::EndOfFile) {
if (Tok.kind == Token::RSquare && ParenLevel == Level) {
ConsumeRSquare();
break;
}
ConsumeAnyToken();
}
}
/// SkipUntilRSquare - Scan forward until reaching an rsquare token
/// at the current level (or EOF).
void SkipUntilRSquare() {
SkipUntilRSquare(ParenLevel);
}
/// ExpectRSquare - Utility method to close an array. This expects
/// to eat an rparen, and emits a diagnostic and skips to the next
/// one (or EOF) if it cannot.
void ExpectRSquare(const char *Msg) {
if (Tok.kind == Token::EndOfFile) {
// FIXME: Combine with Msg
Error("expected ']' but found end-of-file.", Tok);
} else if (Tok.kind != Token::RSquare) {
Error(Msg, Tok);
SkipUntilRSquare();
} else {
ConsumeRSquare();
}
}
/*** Grammar productions ****/
/* Top level decls */
DeclResult ParseArrayDecl();
DeclResult ParseExprVarDecl();
DeclResult ParseVersionVarDecl();
DeclResult ParseCommandDecl();
/* Commands */
DeclResult ParseQueryCommand();
/* Etc. */
NumberOrExprResult ParseNumberOrExpr();
IntegerResult ParseIntegerConstant(Expr::Width Type);
ExprResult ParseExpr(TypeResult ExpectedType);
ExprResult ParseParenExpr(TypeResult ExpectedType);
ExprResult ParseUnaryParenExpr(const Token &Name,
unsigned Kind, bool IsFixed,
Expr::Width ResTy);
ExprResult ParseBinaryParenExpr(const Token &Name,
unsigned Kind, bool IsFixed,
Expr::Width ResTy);
ExprResult ParseSelectParenExpr(const Token &Name, Expr::Width ResTy);
ExprResult ParseConcatParenExpr(const Token &Name, Expr::Width ResTy);
ExprResult ParseExtractParenExpr(const Token &Name, Expr::Width ResTy);
ExprResult ParseAnyReadParenExpr(const Token &Name,
unsigned Kind,
Expr::Width ResTy);
void ParseMatchedBinaryArgs(const Token &Name,
TypeResult ExpectType,
ExprResult &LHS, ExprResult &RHS);
ExprResult ParseNumber(Expr::Width Width);
ExprResult ParseNumberToken(Expr::Width Width, const Token &Tok);
VersionResult ParseVersionSpecifier();
VersionResult ParseVersion();
TypeResult ParseTypeSpecifier();
/*** Diagnostics ***/
void Error(const char *Message, const Token &At);
void Error(const char *Message) { Error(Message, Tok); }
public:
ParserImpl(const std::string _Filename,
const MemoryBuffer *MB) : Filename(_Filename),
TheMemoryBuffer(MB),
TheLexer(MB),
MaxErrors(~0u),
NumErrors(0) {}
/// Initialize - Initialize the parsing state. This must be called
/// prior to the start of parsing.
void Initialize() {
ParenLevel = SquareLevel = 0;
ConsumeAnyToken();
}
/* Parser interface implementation */
virtual Decl *ParseTopLevelDecl();
virtual void SetMaxErrors(unsigned N) {
MaxErrors = N;
}
virtual unsigned GetNumErrors() const {
return NumErrors;
}
};
}
const Identifier *ParserImpl::GetOrCreateIdentifier(const Token &Tok) {
// FIXME: Make not horribly inefficient please.
assert(Tok.kind == Token::Identifier && "Expected only identifier tokens.");
std::string Name(Tok.start, Tok.length);
IdentifierTabTy::iterator it = IdentifierTab.find(Name);
if (it != IdentifierTab.end())
return it->second;
Identifier *I = new Identifier(Name);
IdentifierTab.insert(std::make_pair(Name, I));
return I;
}
Decl *ParserImpl::ParseTopLevelDecl() {
// Repeat until success or EOF.
while (Tok.kind != Token::EndOfFile) {
switch (Tok.kind) {
case Token::KWArray: {
DeclResult Res = ParseArrayDecl();
if (Res.isValid())
return Res.get();
break;
}
case Token::LParen: {
DeclResult Res = ParseCommandDecl();
if (Res.isValid())
return Res.get();
break;
}
default:
Error("expected 'array' or '(' token.");
ConsumeAnyToken();
}
}
return 0;
}
/// ParseArrayDecl - Parse an array declaration. The lexer should be positioned
/// at the opening 'array'.
///
/// array-declaration = "array" name "[" [ size ] "]" ":" domain "->" range
/// "=" array-initializer
/// array-initializer = "symbolic" | "{" { numeric-literal } "}"
DeclResult ParserImpl::ParseArrayDecl() {
// FIXME: Recovery here is horrible, we need to scan to next decl start or
// something.
ConsumeExpectedToken(Token::KWArray);
if (Tok.kind != Token::Identifier) {
Error("expected identifier token.");
return DeclResult();
}
Token Name = Tok;
IntegerResult Size;
TypeResult DomainType;
TypeResult RangeType;
std::vector<ExprHandle> Values;
ConsumeToken();
if (Tok.kind != Token::LSquare) {
Error("expected '['.");
goto exit;
}
ConsumeLSquare();
if (Tok.kind != Token::RSquare) {
Size = ParseIntegerConstant(64);
}
if (Tok.kind != Token::RSquare) {
Error("expected ']'.");
goto exit;
}
ConsumeRSquare();
if (Tok.kind != Token::Colon) {
Error("expected ':'.");
goto exit;
}
ConsumeExpectedToken(Token::Colon);
DomainType = ParseTypeSpecifier();
if (Tok.kind != Token::Arrow) {
Error("expected '->'.");
goto exit;
}
ConsumeExpectedToken(Token::Arrow);
RangeType = ParseTypeSpecifier();
if (Tok.kind != Token::Equals) {
Error("expected '='.");
goto exit;
}
ConsumeExpectedToken(Token::Equals);
if (Tok.kind == Token::KWSymbolic) {
ConsumeExpectedToken(Token::KWSymbolic);
} else if (Tok.kind == Token::LSquare) {
ConsumeLSquare();
while (Tok.kind != Token::RSquare) {
if (Tok.kind == Token::EndOfFile) {
Error("unexpected end of file.");
goto exit;
}
ExprResult Res = ParseNumber(RangeType.get());
if (Res.isValid())
Values.push_back(Res.get());
}
ConsumeRSquare();
} else {
Error("expected 'symbolic' or '['.");
goto exit;
}
// Type check size.
if (!Size.isValid()) {
if (Values.empty()) {
Error("unsized arrays are not yet supported.");
Size = 1;
} else {
Size = Values.size();
}
}
if (!Values.empty()) {
if (Size.get() != Values.size()) {
// FIXME: Lame message.
Error("constant arrays must be completely specified.");
Values.clear();
}
for (unsigned i = 0; i != Size.get(); ++i) {
// FIXME: Must be constant expression.
}
}
// FIXME: Validate that size makes sense for domain type.
if (DomainType.get() != Expr::Int32) {
Error("array domain must currently be w32.");
DomainType = Expr::Int32;
Values.clear();
}
if (RangeType.get() != Expr::Int8) {
Error("array domain must currently be w8.");
RangeType = Expr::Int8;
Values.clear();
}
if (!Values.empty()) {
Error("constant arrays are not yet supported.");
Values.clear();
}
// FIXME: Validate that this array is undeclared.
exit:
if (!Size.isValid())
Size = 1;
if (!DomainType.isValid())
DomainType = 32;
if (!RangeType.isValid())
RangeType = 8;
// FIXME: Array should take domain and range.
const Identifier *Label = GetOrCreateIdentifier(Name);
Array *Root = new Array(Label->Name, Size.get());
ArrayDecl *AD = new ArrayDecl(Label, Size.get(),
DomainType.get(), RangeType.get(), Root);
ArraySymTab.insert(std::make_pair(Label, AD));
// Create the initial version reference.
VersionSymTab.insert(std::make_pair(Label,
UpdateList(Root, NULL)));
return AD;
}
/// ParseCommandDecl - Parse a command declaration. The lexer should
/// be positioned at the opening '('.
///
/// command = '(' name ... ')'
DeclResult ParserImpl::ParseCommandDecl() {
ConsumeLParen();
if (!Tok.isKeyword()) {
Error("malformed command.");
SkipUntilRParen();
return DeclResult();
}
switch (Tok.kind) {
case Token::KWQuery:
return ParseQueryCommand();
default:
Error("malformed command (unexpected keyword).");
SkipUntilRParen();
return DeclResult();
}
}
/// ParseQueryCommand - Parse query command. The lexer should be
/// positioned at the 'query' keyword.
///
/// 'query' expressions-list expression [expressions-list [array-list]]
DeclResult ParserImpl::ParseQueryCommand() {
std::vector<ExprHandle> Constraints;
std::vector<ExprHandle> Values;
std::vector<const Array*> Objects;
ExprResult Res;
// FIXME: We need a command for this. Or something.
ExprSymTab.clear();
VersionSymTab.clear();
// Reinsert initial array versions.
// FIXME: Remove this!
for (std::map<const Identifier*, const ArrayDecl*>::iterator
it = ArraySymTab.begin(), ie = ArraySymTab.end(); it != ie; ++it) {
VersionSymTab.insert(std::make_pair(it->second->Name,
UpdateList(it->second->Root, NULL)));
}
ConsumeExpectedToken(Token::KWQuery);
if (Tok.kind != Token::LSquare) {
Error("malformed query, expected constraint list.");
SkipUntilRParen();
return DeclResult();
}
ConsumeLSquare();
// FIXME: Should avoid reading past unbalanced parens here.
while (Tok.kind != Token::RSquare) {
if (Tok.kind == Token::EndOfFile) {
Error("unexpected end of file.");
Res = ExprResult(ConstantExpr::alloc(0, Expr::Bool));
goto exit;
}
ExprResult Constraint = ParseExpr(TypeResult(Expr::Bool));
if (Constraint.isValid())
Constraints.push_back(Constraint.get());
}
ConsumeRSquare();
Res = ParseExpr(TypeResult(Expr::Bool));
if (!Res.isValid()) // Error emitted by ParseExpr.
Res = ExprResult(ConstantExpr::alloc(0, Expr::Bool));
// Return if there are no optional lists of things to evaluate.
if (Tok.kind == Token::RParen)
goto exit;
if (Tok.kind != Token::LSquare) {
Error("malformed query, expected expression list.");
SkipUntilRParen();
return DeclResult();
}
ConsumeLSquare();
// FIXME: Should avoid reading past unbalanced parens here.
while (Tok.kind != Token::RSquare) {
if (Tok.kind == Token::EndOfFile) {
Error("unexpected end of file.");
goto exit;
}
ExprResult Res = ParseExpr(TypeResult());
if (Res.isValid())
Values.push_back(Res.get());
}
ConsumeRSquare();
// Return if there are no optional lists of things to evaluate.
if (Tok.kind == Token::RParen)
goto exit;
if (Tok.kind != Token::LSquare) {
Error("malformed query, expected array list.");
SkipUntilRParen();
return DeclResult();
}
ConsumeLSquare();
// FIXME: Should avoid reading past unbalanced parens here.
while (Tok.kind != Token::RSquare) {
if (Tok.kind == Token::EndOfFile) {
Error("unexpected end of file.");
goto exit;
}
// FIXME: Factor out.
if (Tok.kind != Token::Identifier) {
Error("unexpected token.");
ConsumeToken();
continue;
}
Token LTok = Tok;
const Identifier *Label = GetOrCreateIdentifier(Tok);
ConsumeToken();
// Lookup array.
std::map<const Identifier*, const ArrayDecl*>::iterator
it = ArraySymTab.find(Label);
if (it == ArraySymTab.end()) {
Error("unknown array", LTok);
} else {
Objects.push_back(it->second->Root);
}
}
ConsumeRSquare();
exit:
if (Tok.kind != Token::EndOfFile)
ExpectRParen("unexpected argument to 'query'.");
return new QueryCommand(Constraints, Res.get(), Values, Objects);
}
/// ParseNumberOrExpr - Parse an expression whose type cannot be
/// predicted.
NumberOrExprResult ParserImpl::ParseNumberOrExpr() {
if (Tok.kind == Token::Number){
Token Num = Tok;
ConsumeToken();
return NumberOrExprResult(Num);
} else {
return NumberOrExprResult(ParseExpr(TypeResult()));
}
}
/// ParseExpr - Parse an expression with the given \arg
/// ExpectedType. \arg ExpectedType can be invalid if the type cannot
/// be inferred from the context.
///
/// expr = false | true
/// expr = <constant>
/// expr = <identifier>
/// expr = [<identifier>:] paren-expr
ExprResult ParserImpl::ParseExpr(TypeResult ExpectedType) {
// FIXME: Is it right to need to do this here?
if (Tok.kind == Token::EndOfFile) {
Error("unexpected end of file.");
return ExprResult();
}
if (Tok.kind == Token::KWFalse || Tok.kind == Token::KWTrue) {
bool Value = Tok.kind == Token::KWTrue;
ConsumeToken();
return ExprResult(ConstantExpr::alloc(Value, Expr::Bool));
}
if (Tok.kind == Token::Number) {
if (!ExpectedType.isValid()) {
Error("cannot infer type of number.");
ConsumeToken();
return ExprResult();
}
return ParseNumber(ExpectedType.get());
}
const Identifier *Label = 0;
if (Tok.kind == Token::Identifier) {
Token LTok = Tok;
Label = GetOrCreateIdentifier(Tok);
ConsumeToken();
if (Tok.kind != Token::Colon) {
ExprSymTabTy::iterator it = ExprSymTab.find(Label);
if (it == ExprSymTab.end()) {
Error("invalid expression label reference.", LTok);
return ExprResult();
}
return it->second;
}
ConsumeToken();
if (ExprSymTab.count(Label)) {
Error("duplicate expression label definition.", LTok);
Label = 0;
}
}
Token Start = Tok;
ExprResult Res = ParseParenExpr(ExpectedType);
if (!Res.isValid()) {
// If we know the type, define the identifier just so we don't get
// use-of-undef errors.
// FIXME: Maybe we should let the symbol table map to invalid
// entries?
if (Label && ExpectedType.isValid()) {
ref<Expr> Value = ConstantExpr::alloc(0, ExpectedType.get());
ExprSymTab.insert(std::make_pair(Label, Value));
}
return Res;
} else if (ExpectedType.isValid()) {
// Type check result.
if (Res.get()->getWidth() != ExpectedType.get()) {
// FIXME: Need more info, and range
Error("expression has incorrect type.", Start);
return ExprResult();
}
}
if (Label)
ExprSymTab.insert(std::make_pair(Label, Res.get()));
return Res;
}
// Additional kinds for macro forms.
enum MacroKind {
eMacroKind_Not = Expr::LastKind + 1, // false == x
eMacroKind_Neg, // 0 - x
eMacroKind_ReadLSB, // Multibyte read
eMacroKind_ReadMSB, // Multibyte write
eMacroKind_Concat, // Magic concatenation syntax
eMacroKind_LastMacroKind = eMacroKind_ReadMSB
};
/// LookupExprInfo - Return information on the named token, if it is
/// recognized.
///
/// \param Kind [out] - The Expr::Kind or MacroKind of the identifier.
/// \param IsFixed [out] - True if the given kinds result and
/// (expression) arguments are all of the same width.
/// \param NumArgs [out] - The number of expression arguments for this
/// kind. -1 indicates the kind is variadic or has non-expression
/// arguments.
/// \return True if the token is a valid kind or macro name.
static bool LookupExprInfo(const Token &Tok, unsigned &Kind,
bool &IsFixed, int &NumArgs) {
#define SetOK(kind, isfixed, numargs) (Kind=kind, IsFixed=isfixed,\
NumArgs=numargs, true)
assert(Tok.kind == Token::Identifier && "Unexpected token.");
switch (Tok.length) {
case 2:
if (memcmp(Tok.start, "Eq", 2) == 0)
return SetOK(Expr::Eq, false, 2);
if (memcmp(Tok.start, "Ne", 2) == 0)
return SetOK(Expr::Ne, false, 2);
if (memcmp(Tok.start, "Or", 2) == 0)
return SetOK(Expr::Or, true, 2);
break;
case 3:
if (memcmp(Tok.start, "Add", 3) == 0)
return SetOK(Expr::Add, true, 2);
if (memcmp(Tok.start, "Sub", 3) == 0)
return SetOK(Expr::Sub, true, 2);
if (memcmp(Tok.start, "Mul", 3) == 0)
return SetOK(Expr::Mul, true, 2);
if (memcmp(Tok.start, "And", 3) == 0)
return SetOK(Expr::And, true, 2);
if (memcmp(Tok.start, "Shl", 3) == 0)
return SetOK(Expr::Shl, true, 2);
if (memcmp(Tok.start, "Xor", 3) == 0)
return SetOK(Expr::Xor, true, 2);
if (memcmp(Tok.start, "Not", 3) == 0)
return SetOK(eMacroKind_Not, true, 1);
if (memcmp(Tok.start, "Neg", 3) == 0)
return SetOK(eMacroKind_Neg, true, 1);
if (memcmp(Tok.start, "Ult", 3) == 0)
return SetOK(Expr::Ult, false, 2);
if (memcmp(Tok.start, "Ule", 3) == 0)
return SetOK(Expr::Ule, false, 2);
if (memcmp(Tok.start, "Ugt", 3) == 0)
return SetOK(Expr::Ugt, false, 2);
if (memcmp(Tok.start, "Uge", 3) == 0)
return SetOK(Expr::Uge, false, 2);
if (memcmp(Tok.start, "Slt", 3) == 0)
return SetOK(Expr::Slt, false, 2);
if (memcmp(Tok.start, "Sle", 3) == 0)
return SetOK(Expr::Sle, false, 2);
if (memcmp(Tok.start, "Sgt", 3) == 0)
return SetOK(Expr::Sgt, false, 2);
if (memcmp(Tok.start, "Sge", 3) == 0)
return SetOK(Expr::Sge, false, 2);
break;
case 4:
if (memcmp(Tok.start, "Read", 4) == 0)
return SetOK(Expr::Read, true, -1);
if (memcmp(Tok.start, "AShr", 4) == 0)
return SetOK(Expr::AShr, true, 2);
if (memcmp(Tok.start, "LShr", 4) == 0)
return SetOK(Expr::LShr, true, 2);
if (memcmp(Tok.start, "UDiv", 4) == 0)
return SetOK(Expr::UDiv, true, 2);
if (memcmp(Tok.start, "SDiv", 4) == 0)
return SetOK(Expr::SDiv, true, 2);
if (memcmp(Tok.start, "URem", 4) == 0)
return SetOK(Expr::URem, true, 2);
if (memcmp(Tok.start, "SRem", 4) == 0)
return SetOK(Expr::SRem, true, 2);
if (memcmp(Tok.start, "SExt", 4) == 0)
return SetOK(Expr::SExt, false, 1);
if (memcmp(Tok.start, "ZExt", 4) == 0)
return SetOK(Expr::ZExt, false, 1);
break;
case 6:
if (memcmp(Tok.start, "Concat", 6) == 0)
return SetOK(eMacroKind_Concat, false, -1);
if (memcmp(Tok.start, "Select", 6) == 0)
return SetOK(Expr::Select, false, 3);
break;
case 7:
if (memcmp(Tok.start, "Extract", 7) == 0)
return SetOK(Expr::Extract, false, -1);
if (memcmp(Tok.start, "ReadLSB", 7) == 0)
return SetOK(eMacroKind_ReadLSB, true, -1);
if (memcmp(Tok.start, "ReadMSB", 7) == 0)
return SetOK(eMacroKind_ReadMSB, true, -1);
break;
}
return false;
#undef SetOK
}
/// ParseParenExpr - Parse a parenthesized expression with the given
/// \arg ExpectedType. \arg ExpectedType can be invalid if the type
/// cannot be inferred from the context.
///
/// paren-expr = '(' type number ')'
/// paren-expr = '(' identifier [type] expr+ ')
/// paren-expr = '(' ('Read' | 'ReadMSB' | 'ReadLSB') type expr update-list ')'
ExprResult ParserImpl::ParseParenExpr(TypeResult FIXME_UNUSED) {
if (Tok.kind != Token::LParen) {
Error("unexpected token.");
ConsumeAnyToken();
return ExprResult();
}
ConsumeLParen();
// Check for coercion case (w32 11).
if (Tok.kind == Token::KWWidth) {
TypeResult ExpectedType = ParseTypeSpecifier();
if (Tok.kind != Token::Number) {
Error("coercion can only apply to a number.");
SkipUntilRParen();
return ExprResult();
}
// Make sure this was a type specifier we support.
ExprResult Res;
if (ExpectedType.isValid())
Res = ParseNumber(ExpectedType.get());
else
ConsumeToken();
ExpectRParen("unexpected argument in coercion.");
return Res;
}
if (Tok.kind != Token::Identifier) {
Error("unexpected token, expected expression.");
SkipUntilRParen();
return ExprResult();
}
Token Name = Tok;
ConsumeToken();
// FIXME: Use invalid type (i.e. width==0)?
Token TypeTok = Tok;
bool HasType = TypeTok.kind == Token::KWWidth;
TypeResult Type = HasType ? ParseTypeSpecifier() : Expr::Bool;
// FIXME: For now just skip to rparen on error. It might be nice
// to try and actually parse the child nodes though for error
// messages & better recovery?
if (!Type.isValid()) {
SkipUntilRParen();
return ExprResult();
}
Expr::Width ResTy = Type.get();
unsigned ExprKind;
bool IsFixed;
int NumArgs;
if (!LookupExprInfo(Name, ExprKind, IsFixed, NumArgs)) {
// FIXME: For now just skip to rparen on error. It might be nice
// to try and actually parse the child nodes though for error
// messages & better recovery?
Error("unknown expression kind.", Name);
SkipUntilRParen();
return ExprResult();
}
// See if we have to parse this form specially.
if (NumArgs == -1) {
switch (ExprKind) {
case eMacroKind_Concat:
return ParseConcatParenExpr(Name, ResTy);
case Expr::Extract:
return ParseExtractParenExpr(Name, ResTy);
case eMacroKind_ReadLSB:
case eMacroKind_ReadMSB:
case Expr::Read:
return ParseAnyReadParenExpr(Name, ExprKind, ResTy);
default:
Error("internal error, unimplemented special form.", Name);
SkipUntilRParen();
return ExprResult(ConstantExpr::alloc(0, ResTy));
}
}
switch (NumArgs) {
case 1:
return ParseUnaryParenExpr(Name, ExprKind, IsFixed, ResTy);
case 2:
return ParseBinaryParenExpr(Name, ExprKind, IsFixed, ResTy);
case 3:
if (ExprKind == Expr::Select)
return ParseSelectParenExpr(Name, ResTy);
default:
assert(0 && "Invalid argument kind (number of args).");
return ExprResult();
}
}
ExprResult ParserImpl::ParseUnaryParenExpr(const Token &Name,
unsigned Kind, bool IsFixed,
Expr::Width ResTy) {
if (Tok.kind == Token::RParen) {
Error("unexpected end of arguments.", Name);
ConsumeRParen();
return ConstantExpr::alloc(0, ResTy);
}
ExprResult Arg = ParseExpr(IsFixed ? ResTy : TypeResult());
if (!Arg.isValid())
Arg = ConstantExpr::alloc(0, ResTy);
ExpectRParen("unexpected argument in unary expression.");
ExprHandle E = Arg.get();
switch (Kind) {
case eMacroKind_Not:
return EqExpr::alloc(ConstantExpr::alloc(0, E->getWidth()), E);
case eMacroKind_Neg:
return SubExpr::alloc(ConstantExpr::alloc(0, E->getWidth()), E);
case Expr::SExt:
// FIXME: Type check arguments.
return SExtExpr::alloc(E, ResTy);
case Expr::ZExt:
// FIXME: Type check arguments.
return ZExtExpr::alloc(E, ResTy);
default:
Error("internal error, unhandled kind.", Name);
return ConstantExpr::alloc(0, ResTy);
}
}
/// ParseMatchedBinaryArgs - Parse a pair of arguments who are
/// expected to be of the same type. Upon return, if both LHS and RHS
/// are valid then they are guaranteed to have the same type.
///
/// Name - The name token of the expression, for diagnostics.
/// ExpectType - The expected type of the arguments, if known.
void ParserImpl::ParseMatchedBinaryArgs(const Token &Name,
TypeResult ExpectType,
ExprResult &LHS, ExprResult &RHS) {
if (Tok.kind == Token::RParen) {
Error("unexpected end of arguments.", Name);
ConsumeRParen();
return;
}
// Avoid NumberOrExprResult overhead and give more precise
// diagnostics when we know the type.
if (ExpectType.isValid()) {
LHS = ParseExpr(ExpectType);
if (Tok.kind == Token::RParen) {
Error("unexpected end of arguments.", Name);
ConsumeRParen();
return;
}
RHS = ParseExpr(ExpectType);
} else {
NumberOrExprResult LHS_NOE = ParseNumberOrExpr();
if (Tok.kind == Token::RParen) {
Error("unexpected end of arguments.", Name);
ConsumeRParen();
return;
}
if (LHS_NOE.isNumber()) {
NumberOrExprResult RHS_NOE = ParseNumberOrExpr();
if (RHS_NOE.isNumber()) {
Error("ambiguous arguments to expression.", Name);
} else {
RHS = RHS_NOE.getExpr();
if (RHS.isValid())
LHS = ParseNumberToken(RHS.get()->getWidth(), LHS_NOE.getNumber());
}
} else {
LHS = LHS_NOE.getExpr();
if (!LHS.isValid()) {
// FIXME: Should suppress ambiguity warnings here.
RHS = ParseExpr(TypeResult());
} else {
RHS = ParseExpr(LHS.get()->getWidth());
}
}
}
ExpectRParen("unexpected argument to expression.");
}
ExprResult ParserImpl::ParseBinaryParenExpr(const Token &Name,
unsigned Kind, bool IsFixed,
Expr::Width ResTy) {
ExprResult LHS, RHS;
ParseMatchedBinaryArgs(Name, IsFixed ? TypeResult(ResTy) : TypeResult(),
LHS, RHS);
if (!LHS.isValid() || !RHS.isValid())
return ConstantExpr::alloc(0, ResTy);
ref<Expr> LHS_E = LHS.get(), RHS_E = RHS.get();
if (LHS_E->getWidth() != RHS_E->getWidth()) {
Error("type widths do not match in binary expression", Name);
return ConstantExpr::alloc(0, ResTy);
}
switch (Kind) {
case Expr::Add: return AddExpr::alloc(LHS_E, RHS_E);
case Expr::Sub: return SubExpr::alloc(LHS_E, RHS_E);
case Expr::Mul: return MulExpr::alloc(LHS_E, RHS_E);
case Expr::UDiv: return UDivExpr::alloc(LHS_E, RHS_E);
case Expr::SDiv: return SDivExpr::alloc(LHS_E, RHS_E);
case Expr::URem: return URemExpr::alloc(LHS_E, RHS_E);
case Expr::SRem: return SRemExpr::alloc(LHS_E, RHS_E);
case Expr::AShr: return AShrExpr::alloc(LHS_E, RHS_E);
case Expr::LShr: return LShrExpr::alloc(LHS_E, RHS_E);
case Expr::Shl: return AndExpr::alloc(LHS_E, RHS_E);
case Expr::And: return AndExpr::alloc(LHS_E, RHS_E);
case Expr::Or: return OrExpr::alloc(LHS_E, RHS_E);
case Expr::Xor: return XorExpr::alloc(LHS_E, RHS_E);
case Expr::Eq: return EqExpr::alloc(LHS_E, RHS_E);
case Expr::Ne: return NeExpr::alloc(LHS_E, RHS_E);
case Expr::Ult: return UltExpr::alloc(LHS_E, RHS_E);
case Expr::Ule: return UleExpr::alloc(LHS_E, RHS_E);
case Expr::Ugt: return UgtExpr::alloc(LHS_E, RHS_E);
case Expr::Uge: return UgeExpr::alloc(LHS_E, RHS_E);
case Expr::Slt: return SltExpr::alloc(LHS_E, RHS_E);
case Expr::Sle: return SleExpr::alloc(LHS_E, RHS_E);
case Expr::Sgt: return SgtExpr::alloc(LHS_E, RHS_E);
case Expr::Sge: return SgeExpr::alloc(LHS_E, RHS_E);
default:
Error("FIXME: unhandled kind.", Name);
return ConstantExpr::alloc(0, ResTy);
}
}
ExprResult ParserImpl::ParseSelectParenExpr(const Token &Name,
Expr::Width ResTy) {
// FIXME: Why does this need to be here?
if (Tok.kind == Token::RParen) {
Error("unexpected end of arguments.", Name);
ConsumeRParen();
return ConstantExpr::alloc(0, ResTy);
}
ExprResult Cond = ParseExpr(Expr::Bool);
ExprResult LHS, RHS;
ParseMatchedBinaryArgs(Name, ResTy, LHS, RHS);
if (!Cond.isValid() || !LHS.isValid() || !RHS.isValid())
return ConstantExpr::alloc(0, ResTy);
return SelectExpr::alloc(Cond.get(), LHS.get(), RHS.get());
}
// FIXME: Rewrite to only accept binary form. Make type optional.
ExprResult ParserImpl::ParseConcatParenExpr(const Token &Name,
Expr::Width ResTy) {
std::vector<ExprHandle> Kids;
unsigned Width = 0;
while (Tok.kind != Token::RParen) {
ExprResult E = ParseExpr(TypeResult());
// Skip to end of expr on error.
if (!E.isValid()) {
SkipUntilRParen();
return ConstantExpr::alloc(0, ResTy);
}
Kids.push_back(E.get());
Width += E.get()->getWidth();
}
ConsumeRParen();
if (Width != ResTy) {
Error("concat does not match expected result size.");
return ConstantExpr::alloc(0, ResTy);
}
return ConcatExpr::createN(Kids.size(), &Kids[0]);
}
IntegerResult ParserImpl::ParseIntegerConstant(Expr::Width Type) {
ExprResult Res = ParseNumber(Type);
if (!Res.isValid())
return IntegerResult();
return cast<ConstantExpr>(Res.get())->getConstantValue();
}
ExprResult ParserImpl::ParseExtractParenExpr(const Token &Name,
Expr::Width ResTy) {
IntegerResult OffsetExpr = ParseIntegerConstant(Expr::Int32);
ExprResult Child = ParseExpr(TypeResult());
ExpectRParen("unexpected argument to expression.");
if (!OffsetExpr.isValid() || !Child.isValid())
return ConstantExpr::alloc(0, ResTy);
unsigned Offset = (unsigned) OffsetExpr.get();
if (Offset + ResTy > Child.get()->getWidth()) {
Error("extract out-of-range of child expression.", Name);
return ConstantExpr::alloc(0, ResTy);
}
return ExtractExpr::alloc(Child.get(), Offset, ResTy);
}
ExprResult ParserImpl::ParseAnyReadParenExpr(const Token &Name,
unsigned Kind,
Expr::Width ResTy) {
NumberOrExprResult Index = ParseNumberOrExpr();
VersionResult Array = ParseVersionSpecifier();
ExpectRParen("unexpected argument in read expression.");
if (!Array.isValid())
return ConstantExpr::alloc(0, ResTy);
// FIXME: Need generic way to get array width. Needs to work with
// anonymous arrays.
Expr::Width ArrayDomainType = Expr::Int32;
Expr::Width ArrayRangeType = Expr::Int8;
// Coerce number to correct type.
ExprResult IndexExpr;
if (Index.isNumber())
IndexExpr = ParseNumberToken(ArrayDomainType, Index.getNumber());
else
IndexExpr = Index.getExpr();
if (!IndexExpr.isValid())
return ConstantExpr::alloc(0, ResTy);
else if (IndexExpr.get()->getWidth() != ArrayDomainType) {
Error("index width does not match array domain.");
return ConstantExpr::alloc(0, ResTy);
}
// FIXME: Check range width.
switch (Kind) {
default:
assert(0 && "Invalid kind.");
return ConstantExpr::alloc(0, ResTy);
case eMacroKind_ReadLSB:
case eMacroKind_ReadMSB: {
unsigned NumReads = ResTy / ArrayRangeType;
if (ResTy != NumReads*ArrayRangeType) {
Error("invalid ordered read (not multiple of range type).", Name);
return ConstantExpr::alloc(0, ResTy);
}
std::vector<ExprHandle> Kids;
Kids.reserve(NumReads);
ExprHandle Index = IndexExpr.get();
for (unsigned i=0; i<NumReads; ++i) {
// FIXME: using folding here
ExprHandle OffsetIndex = AddExpr::create(IndexExpr.get(),
ConstantExpr::alloc(i, ArrayDomainType));
Kids.push_back(ReadExpr::alloc(Array.get(), OffsetIndex));
}
if (Kind == eMacroKind_ReadLSB)
std::reverse(Kids.begin(), Kids.end());
return ConcatExpr::createN(NumReads, &Kids[0]);
}
case Expr::Read:
return ReadExpr::alloc(Array.get(), IndexExpr.get());
}
}
/// version-specifier = <identifier>
/// version-specifier = [<identifier>:] [ version ]
VersionResult ParserImpl::ParseVersionSpecifier() {
const Identifier *Label = 0;
if (Tok.kind == Token::Identifier) {
Token LTok = Tok;
Label = GetOrCreateIdentifier(Tok);
ConsumeToken();
if (Tok.kind != Token::Colon) {
VersionSymTabTy::iterator it = VersionSymTab.find(Label);
if (it == VersionSymTab.end()) {
Error("invalid version reference.", LTok);
return VersionResult(false, UpdateList(0, NULL));
}
return it->second;
}
ConsumeToken();
if (VersionSymTab.count(Label)) {
Error("duplicate update list label definition.", LTok);
Label = 0;
}
}
Token Start = Tok;
VersionResult Res = ParseVersion();
// Define update list to avoid use-of-undef errors.
if (!Res.isValid()) {
Res = VersionResult(true, UpdateList(new Array("", 0), NULL));
}
if (Label)
VersionSymTab.insert(std::make_pair(Label, Res.get()));
return Res;
}
namespace {
/// WriteInfo - Helper class used for storing information about a parsed
/// write, prior to type checking.
struct WriteInfo {
NumberOrExprResult LHS;
NumberOrExprResult RHS;
Token LHSTok;
Token RHSTok;
WriteInfo(NumberOrExprResult _LHS, NumberOrExprResult _RHS,
Token _LHSTok, Token _RHSTok) : LHS(_LHS), RHS(_RHS),
LHSTok(_LHSTok), RHSTok(_RHSTok) {
}
};
}
/// version - '[' update-list? ']' '@' version-specifier
/// update-list - empty
/// update-list - lhs '=' rhs [',' update-list]
VersionResult ParserImpl::ParseVersion() {
if (Tok.kind != Token::LSquare)
return VersionResult(false, UpdateList(0, NULL));
std::vector<WriteInfo> Writes;
ConsumeLSquare();
for (;;) {
Token LHSTok = Tok;
NumberOrExprResult LHS = ParseNumberOrExpr();
if (Tok.kind != Token::Equals) {
Error("expected '='.", Tok);
break;
}
ConsumeToken();
Token RHSTok = Tok;
NumberOrExprResult RHS = ParseNumberOrExpr();
Writes.push_back(WriteInfo(LHS, RHS, LHSTok, RHSTok));
if (Tok.kind == Token::Comma)
ConsumeToken();
else
break;
}
ExpectRSquare("expected close of update list");
VersionHandle Base(0, NULL);
if (Tok.kind != Token::At) {
Error("expected '@'.", Tok);
return VersionResult(false, UpdateList(0, NULL));
}
ConsumeExpectedToken(Token::At);
VersionResult BaseRes = ParseVersionSpecifier();
if (!BaseRes.isValid())
return BaseRes;
Base = BaseRes.get();
Expr::Width ArrayDomainType = Expr::Int32;
Expr::Width ArrayRangeType = Expr::Int8;
for (std::vector<WriteInfo>::reverse_iterator it = Writes.rbegin(),
ie = Writes.rend(); it != ie; ++it) {
const WriteInfo &WI = *it;
ExprResult LHS, RHS;
// FIXME: This can be factored into common helper for coercing a
// NumberOrExpr into an Expr.
if (WI.LHS.isNumber()) {
LHS = ParseNumberToken(ArrayDomainType, WI.LHS.getNumber());
} else {
LHS = WI.LHS.getExpr();
if (LHS.isValid() && LHS.get()->getWidth() != ArrayDomainType) {
Error("invalid write index (doesn't match array domain).", WI.LHSTok);
LHS = ExprResult();
}
}
if (WI.RHS.isNumber()) {
RHS = ParseNumberToken(ArrayRangeType, WI.RHS.getNumber());
} else {
RHS = WI.RHS.getExpr();
if (RHS.isValid() && RHS.get()->getWidth() != ArrayRangeType) {
Error("invalid write value (doesn't match array range).", WI.RHSTok);
RHS = ExprResult();
}
}
if (LHS.isValid() && RHS.isValid())
Base.extend(LHS.get(), RHS.get());
}
return Base;
}
/// ParseNumber - Parse a number of the given type.
ExprResult ParserImpl::ParseNumber(Expr::Width Type) {
ExprResult Res = ParseNumberToken(Type, Tok);
ConsumeExpectedToken(Token::Number);
return Res;
}
/// ParseNumberToken - Parse a number of the given type from the given
/// token.
ExprResult ParserImpl::ParseNumberToken(Expr::Width Type, const Token &Tok) {
const char *S = Tok.start;
unsigned N = Tok.length;
unsigned Radix = 10, RadixBits = 4;
bool HasMinus = false;
// Detect +/- (a number token cannot have both).
if (S[0] == '+') {
++S;
--N;
} else if (S[0] == '-') {
HasMinus = true;
++S;
--N;
}
// Detect 0[box].
if ((Tok.length >= 2 && S[0] == '0') &&
(S[1] == 'b' || S[1] == 'o' || S[1] == 'x')) {
if (S[1] == 'b') {
Radix = 2;
RadixBits = 1;
} else if (S[1] == 'o') {
Radix = 8;
RadixBits = 3;
} else {
Radix = 16;
RadixBits = 4;
}
S += 2;
N -= 2;
// Diagnose 0[box] with no trailing digits.
if (!N) {
Error("invalid numeric token (no digits).", Tok);
return ConstantExpr::alloc(0, Type);
}
}
// This is a simple but slow way to handle overflow.
APInt Val(std::max(64U, RadixBits * N), 0);
APInt RadixVal(Val.getBitWidth(), Radix);
APInt DigitVal(Val.getBitWidth(), 0);
for (unsigned i=0; i<N; ++i) {
unsigned Digit, Char = S[i];
if (Char == '_')
continue;
if ('0' <= Char && Char <= '9')
Digit = Char - '0';
else if ('a' <= Char && Char <= 'z')
Digit = Char - 'a' + 10;
else if ('A' <= Char && Char <= 'Z')
Digit = Char - 'A' + 10;
else {
Error("invalid character in numeric token.", Tok);
return ConstantExpr::alloc(0, Type);
}
if (Digit >= Radix) {
Error("invalid character in numeric token (out of range).", Tok);
return ConstantExpr::alloc(0, Type);
}
DigitVal = Digit;
Val = Val * RadixVal + DigitVal;
}
// FIXME: Actually do the check for overflow.
if (HasMinus)
Val = -Val;
if (Type < Val.getBitWidth())
Val = Val.trunc(Type);
return ExprResult(ConstantExpr::alloc(Val.getZExtValue(), Type));
}
/// ParseTypeSpecifier - Parse a type specifier.
///
/// type = w[0-9]+
TypeResult ParserImpl::ParseTypeSpecifier() {
assert(Tok.kind == Token::KWWidth && "Unexpected token.");
// FIXME: Need APInt technically.
Token TypeTok = Tok;
int width = atoi(std::string(Tok.start+1,Tok.length-1).c_str());
ConsumeToken();
// FIXME: We should impose some sort of maximum just for sanity?
return TypeResult(width);
}
void ParserImpl::Error(const char *Message, const Token &At) {
++NumErrors;
if (MaxErrors && NumErrors >= MaxErrors)
return;
llvm::cerr << Filename
<< ":" << At.line << ":" << At.column
<< ": error: " << Message << "\n";
// Skip carat diagnostics on EOF token.
if (At.kind == Token::EndOfFile)
return;
// Simple caret style diagnostics.
const char *LineBegin = At.start, *LineEnd = At.start,
*BufferBegin = TheMemoryBuffer->getBufferStart(),
*BufferEnd = TheMemoryBuffer->getBufferEnd();
// Run line pointers forward and back.
while (LineBegin > BufferBegin &&
LineBegin[-1] != '\r' && LineBegin[-1] != '\n')
--LineBegin;
while (LineEnd < BufferEnd &&
LineEnd[0] != '\r' && LineEnd[0] != '\n')
++LineEnd;
// Show the line.
llvm::cerr << std::string(LineBegin, LineEnd) << "\n";
// Show the caret or squiggly, making sure to print back spaces the
// same.
for (const char *S=LineBegin; S != At.start; ++S)
llvm::cerr << (isspace(*S) ? *S : ' ');
if (At.length > 1) {
for (unsigned i=0; i<At.length; ++i)
llvm::cerr << '~';
} else
llvm::cerr << '^';
llvm::cerr << '\n';
}
// AST API
// FIXME: Move out of parser.
Decl::Decl(DeclKind _Kind) : Kind(_Kind) {}
void ArrayDecl::dump() {
// FIXME: For now, print using the Array* "name".
std::cout << "array " << Root->name
<< "[" << Size << "]"
<< " : " << 'w' << Domain << " -> " << 'w' << Range << " = ";
if (Contents.empty()) {
std::cout << "symbolic\n";
} else {
std::cout << '{';
for (std::vector<ExprHandle>::const_iterator it = Contents.begin(),
ie = Contents.end(); it != ie;) {
std::cout << *it;
if (++it != ie)
std::cout << " ";
}
std::cout << "}\n";
}
}
void QueryCommand::dump() {
const ExprHandle *ValuesBegin = 0, *ValuesEnd = 0;
const Array * const* ObjectsBegin = 0, * const* ObjectsEnd = 0;
if (!Values.empty()) {
ValuesBegin = &Values[0];
ValuesEnd = ValuesBegin + Values.size();
}
if (!Objects.empty()) {
ObjectsBegin = &Objects[0];
ObjectsEnd = ObjectsBegin + Objects.size();
}
ExprPPrinter::printQuery(std::cout, ConstraintManager(Constraints),
Query, ValuesBegin, ValuesEnd,
ObjectsBegin, ObjectsEnd,
false);
}
// Public parser API
Parser::Parser() {
}
Parser::~Parser() {
}
Parser *Parser::Create(const std::string Filename,
const MemoryBuffer *MB) {
ParserImpl *P = new ParserImpl(Filename, MB);
P->Initialize();
return P;
}
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