llvm-6502/lib/Support/YAMLParser.cpp
Sean Silva 525398e137 Allow using MemoryBuffers with yaml::Stream directly.
The rationale is to get YAML filenames in diagnostics from
yaml::Stream::printError -- currently the filename is hard-coded as
"YAML" because there's no buffer information available.

Patch by Kim Gräsman!

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@168341 91177308-0d34-0410-b5e6-96231b3b80d8
2012-11-19 23:21:47 +00:00

2149 lines
59 KiB
C++

//===--- YAMLParser.cpp - Simple YAML parser ------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements a YAML parser.
//
//===----------------------------------------------------------------------===//
#include "llvm/Support/YAMLParser.h"
#include "llvm/ADT/ilist.h"
#include "llvm/ADT/ilist_node.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/Twine.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/Support/SourceMgr.h"
using namespace llvm;
using namespace yaml;
enum UnicodeEncodingForm {
UEF_UTF32_LE, ///< UTF-32 Little Endian
UEF_UTF32_BE, ///< UTF-32 Big Endian
UEF_UTF16_LE, ///< UTF-16 Little Endian
UEF_UTF16_BE, ///< UTF-16 Big Endian
UEF_UTF8, ///< UTF-8 or ascii.
UEF_Unknown ///< Not a valid Unicode encoding.
};
/// EncodingInfo - Holds the encoding type and length of the byte order mark if
/// it exists. Length is in {0, 2, 3, 4}.
typedef std::pair<UnicodeEncodingForm, unsigned> EncodingInfo;
/// getUnicodeEncoding - Reads up to the first 4 bytes to determine the Unicode
/// encoding form of \a Input.
///
/// @param Input A string of length 0 or more.
/// @returns An EncodingInfo indicating the Unicode encoding form of the input
/// and how long the byte order mark is if one exists.
static EncodingInfo getUnicodeEncoding(StringRef Input) {
if (Input.size() == 0)
return std::make_pair(UEF_Unknown, 0);
switch (uint8_t(Input[0])) {
case 0x00:
if (Input.size() >= 4) {
if ( Input[1] == 0
&& uint8_t(Input[2]) == 0xFE
&& uint8_t(Input[3]) == 0xFF)
return std::make_pair(UEF_UTF32_BE, 4);
if (Input[1] == 0 && Input[2] == 0 && Input[3] != 0)
return std::make_pair(UEF_UTF32_BE, 0);
}
if (Input.size() >= 2 && Input[1] != 0)
return std::make_pair(UEF_UTF16_BE, 0);
return std::make_pair(UEF_Unknown, 0);
case 0xFF:
if ( Input.size() >= 4
&& uint8_t(Input[1]) == 0xFE
&& Input[2] == 0
&& Input[3] == 0)
return std::make_pair(UEF_UTF32_LE, 4);
if (Input.size() >= 2 && uint8_t(Input[1]) == 0xFE)
return std::make_pair(UEF_UTF16_LE, 2);
return std::make_pair(UEF_Unknown, 0);
case 0xFE:
if (Input.size() >= 2 && uint8_t(Input[1]) == 0xFF)
return std::make_pair(UEF_UTF16_BE, 2);
return std::make_pair(UEF_Unknown, 0);
case 0xEF:
if ( Input.size() >= 3
&& uint8_t(Input[1]) == 0xBB
&& uint8_t(Input[2]) == 0xBF)
return std::make_pair(UEF_UTF8, 3);
return std::make_pair(UEF_Unknown, 0);
}
// It could still be utf-32 or utf-16.
if (Input.size() >= 4 && Input[1] == 0 && Input[2] == 0 && Input[3] == 0)
return std::make_pair(UEF_UTF32_LE, 0);
if (Input.size() >= 2 && Input[1] == 0)
return std::make_pair(UEF_UTF16_LE, 0);
return std::make_pair(UEF_UTF8, 0);
}
namespace llvm {
namespace yaml {
/// Token - A single YAML token.
struct Token : ilist_node<Token> {
enum TokenKind {
TK_Error, // Uninitialized token.
TK_StreamStart,
TK_StreamEnd,
TK_VersionDirective,
TK_TagDirective,
TK_DocumentStart,
TK_DocumentEnd,
TK_BlockEntry,
TK_BlockEnd,
TK_BlockSequenceStart,
TK_BlockMappingStart,
TK_FlowEntry,
TK_FlowSequenceStart,
TK_FlowSequenceEnd,
TK_FlowMappingStart,
TK_FlowMappingEnd,
TK_Key,
TK_Value,
TK_Scalar,
TK_Alias,
TK_Anchor,
TK_Tag
} Kind;
/// A string of length 0 or more whose begin() points to the logical location
/// of the token in the input.
StringRef Range;
Token() : Kind(TK_Error) {}
};
}
}
namespace llvm {
template<>
struct ilist_sentinel_traits<Token> {
Token *createSentinel() const {
return &Sentinel;
}
static void destroySentinel(Token*) {}
Token *provideInitialHead() const { return createSentinel(); }
Token *ensureHead(Token*) const { return createSentinel(); }
static void noteHead(Token*, Token*) {}
private:
mutable Token Sentinel;
};
template<>
struct ilist_node_traits<Token> {
Token *createNode(const Token &V) {
return new (Alloc.Allocate<Token>()) Token(V);
}
static void deleteNode(Token *V) {}
void addNodeToList(Token *) {}
void removeNodeFromList(Token *) {}
void transferNodesFromList(ilist_node_traits & /*SrcTraits*/,
ilist_iterator<Token> /*first*/,
ilist_iterator<Token> /*last*/) {}
BumpPtrAllocator Alloc;
};
}
typedef ilist<Token> TokenQueueT;
namespace {
/// @brief This struct is used to track simple keys.
///
/// Simple keys are handled by creating an entry in SimpleKeys for each Token
/// which could legally be the start of a simple key. When peekNext is called,
/// if the Token To be returned is referenced by a SimpleKey, we continue
/// tokenizing until that potential simple key has either been found to not be
/// a simple key (we moved on to the next line or went further than 1024 chars).
/// Or when we run into a Value, and then insert a Key token (and possibly
/// others) before the SimpleKey's Tok.
struct SimpleKey {
TokenQueueT::iterator Tok;
unsigned Column;
unsigned Line;
unsigned FlowLevel;
bool IsRequired;
bool operator ==(const SimpleKey &Other) {
return Tok == Other.Tok;
}
};
}
/// @brief The Unicode scalar value of a UTF-8 minimal well-formed code unit
/// subsequence and the subsequence's length in code units (uint8_t).
/// A length of 0 represents an error.
typedef std::pair<uint32_t, unsigned> UTF8Decoded;
static UTF8Decoded decodeUTF8(StringRef Range) {
StringRef::iterator Position= Range.begin();
StringRef::iterator End = Range.end();
// 1 byte: [0x00, 0x7f]
// Bit pattern: 0xxxxxxx
if ((*Position & 0x80) == 0) {
return std::make_pair(*Position, 1);
}
// 2 bytes: [0x80, 0x7ff]
// Bit pattern: 110xxxxx 10xxxxxx
if (Position + 1 != End &&
((*Position & 0xE0) == 0xC0) &&
((*(Position + 1) & 0xC0) == 0x80)) {
uint32_t codepoint = ((*Position & 0x1F) << 6) |
(*(Position + 1) & 0x3F);
if (codepoint >= 0x80)
return std::make_pair(codepoint, 2);
}
// 3 bytes: [0x8000, 0xffff]
// Bit pattern: 1110xxxx 10xxxxxx 10xxxxxx
if (Position + 2 != End &&
((*Position & 0xF0) == 0xE0) &&
((*(Position + 1) & 0xC0) == 0x80) &&
((*(Position + 2) & 0xC0) == 0x80)) {
uint32_t codepoint = ((*Position & 0x0F) << 12) |
((*(Position + 1) & 0x3F) << 6) |
(*(Position + 2) & 0x3F);
// Codepoints between 0xD800 and 0xDFFF are invalid, as
// they are high / low surrogate halves used by UTF-16.
if (codepoint >= 0x800 &&
(codepoint < 0xD800 || codepoint > 0xDFFF))
return std::make_pair(codepoint, 3);
}
// 4 bytes: [0x10000, 0x10FFFF]
// Bit pattern: 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
if (Position + 3 != End &&
((*Position & 0xF8) == 0xF0) &&
((*(Position + 1) & 0xC0) == 0x80) &&
((*(Position + 2) & 0xC0) == 0x80) &&
((*(Position + 3) & 0xC0) == 0x80)) {
uint32_t codepoint = ((*Position & 0x07) << 18) |
((*(Position + 1) & 0x3F) << 12) |
((*(Position + 2) & 0x3F) << 6) |
(*(Position + 3) & 0x3F);
if (codepoint >= 0x10000 && codepoint <= 0x10FFFF)
return std::make_pair(codepoint, 4);
}
return std::make_pair(0, 0);
}
namespace llvm {
namespace yaml {
/// @brief Scans YAML tokens from a MemoryBuffer.
class Scanner {
public:
Scanner(const StringRef Input, SourceMgr &SM);
Scanner(MemoryBuffer *Buffer, SourceMgr &SM_);
/// @brief Parse the next token and return it without popping it.
Token &peekNext();
/// @brief Parse the next token and pop it from the queue.
Token getNext();
void printError(SMLoc Loc, SourceMgr::DiagKind Kind, const Twine &Message,
ArrayRef<SMRange> Ranges = ArrayRef<SMRange>()) {
SM.PrintMessage(Loc, Kind, Message, Ranges);
}
void setError(const Twine &Message, StringRef::iterator Position) {
if (Current >= End)
Current = End - 1;
// Don't print out more errors after the first one we encounter. The rest
// are just the result of the first, and have no meaning.
if (!Failed)
printError(SMLoc::getFromPointer(Current), SourceMgr::DK_Error, Message);
Failed = true;
}
void setError(const Twine &Message) {
setError(Message, Current);
}
/// @brief Returns true if an error occurred while parsing.
bool failed() {
return Failed;
}
private:
StringRef currentInput() {
return StringRef(Current, End - Current);
}
/// @brief Decode a UTF-8 minimal well-formed code unit subsequence starting
/// at \a Position.
///
/// If the UTF-8 code units starting at Position do not form a well-formed
/// code unit subsequence, then the Unicode scalar value is 0, and the length
/// is 0.
UTF8Decoded decodeUTF8(StringRef::iterator Position) {
return ::decodeUTF8(StringRef(Position, End - Position));
}
// The following functions are based on the gramar rules in the YAML spec. The
// style of the function names it meant to closely match how they are written
// in the spec. The number within the [] is the number of the grammar rule in
// the spec.
//
// See 4.2 [Production Naming Conventions] for the meaning of the prefixes.
//
// c-
// A production starting and ending with a special character.
// b-
// A production matching a single line break.
// nb-
// A production starting and ending with a non-break character.
// s-
// A production starting and ending with a white space character.
// ns-
// A production starting and ending with a non-space character.
// l-
// A production matching complete line(s).
/// @brief Skip a single nb-char[27] starting at Position.
///
/// A nb-char is 0x9 | [0x20-0x7E] | 0x85 | [0xA0-0xD7FF] | [0xE000-0xFEFE]
/// | [0xFF00-0xFFFD] | [0x10000-0x10FFFF]
///
/// @returns The code unit after the nb-char, or Position if it's not an
/// nb-char.
StringRef::iterator skip_nb_char(StringRef::iterator Position);
/// @brief Skip a single b-break[28] starting at Position.
///
/// A b-break is 0xD 0xA | 0xD | 0xA
///
/// @returns The code unit after the b-break, or Position if it's not a
/// b-break.
StringRef::iterator skip_b_break(StringRef::iterator Position);
/// @brief Skip a single s-white[33] starting at Position.
///
/// A s-white is 0x20 | 0x9
///
/// @returns The code unit after the s-white, or Position if it's not a
/// s-white.
StringRef::iterator skip_s_white(StringRef::iterator Position);
/// @brief Skip a single ns-char[34] starting at Position.
///
/// A ns-char is nb-char - s-white
///
/// @returns The code unit after the ns-char, or Position if it's not a
/// ns-char.
StringRef::iterator skip_ns_char(StringRef::iterator Position);
typedef StringRef::iterator (Scanner::*SkipWhileFunc)(StringRef::iterator);
/// @brief Skip minimal well-formed code unit subsequences until Func
/// returns its input.
///
/// @returns The code unit after the last minimal well-formed code unit
/// subsequence that Func accepted.
StringRef::iterator skip_while( SkipWhileFunc Func
, StringRef::iterator Position);
/// @brief Scan ns-uri-char[39]s starting at Cur.
///
/// This updates Cur and Column while scanning.
///
/// @returns A StringRef starting at Cur which covers the longest contiguous
/// sequence of ns-uri-char.
StringRef scan_ns_uri_char();
/// @brief Scan ns-plain-one-line[133] starting at \a Cur.
StringRef scan_ns_plain_one_line();
/// @brief Consume a minimal well-formed code unit subsequence starting at
/// \a Cur. Return false if it is not the same Unicode scalar value as
/// \a Expected. This updates \a Column.
bool consume(uint32_t Expected);
/// @brief Skip \a Distance UTF-8 code units. Updates \a Cur and \a Column.
void skip(uint32_t Distance);
/// @brief Return true if the minimal well-formed code unit subsequence at
/// Pos is whitespace or a new line
bool isBlankOrBreak(StringRef::iterator Position);
/// @brief If IsSimpleKeyAllowed, create and push_back a new SimpleKey.
void saveSimpleKeyCandidate( TokenQueueT::iterator Tok
, unsigned AtColumn
, bool IsRequired);
/// @brief Remove simple keys that can no longer be valid simple keys.
///
/// Invalid simple keys are not on the current line or are further than 1024
/// columns back.
void removeStaleSimpleKeyCandidates();
/// @brief Remove all simple keys on FlowLevel \a Level.
void removeSimpleKeyCandidatesOnFlowLevel(unsigned Level);
/// @brief Unroll indentation in \a Indents back to \a Col. Creates BlockEnd
/// tokens if needed.
bool unrollIndent(int ToColumn);
/// @brief Increase indent to \a Col. Creates \a Kind token at \a InsertPoint
/// if needed.
bool rollIndent( int ToColumn
, Token::TokenKind Kind
, TokenQueueT::iterator InsertPoint);
/// @brief Skip whitespace and comments until the start of the next token.
void scanToNextToken();
/// @brief Must be the first token generated.
bool scanStreamStart();
/// @brief Generate tokens needed to close out the stream.
bool scanStreamEnd();
/// @brief Scan a %BLAH directive.
bool scanDirective();
/// @brief Scan a ... or ---.
bool scanDocumentIndicator(bool IsStart);
/// @brief Scan a [ or { and generate the proper flow collection start token.
bool scanFlowCollectionStart(bool IsSequence);
/// @brief Scan a ] or } and generate the proper flow collection end token.
bool scanFlowCollectionEnd(bool IsSequence);
/// @brief Scan the , that separates entries in a flow collection.
bool scanFlowEntry();
/// @brief Scan the - that starts block sequence entries.
bool scanBlockEntry();
/// @brief Scan an explicit ? indicating a key.
bool scanKey();
/// @brief Scan an explicit : indicating a value.
bool scanValue();
/// @brief Scan a quoted scalar.
bool scanFlowScalar(bool IsDoubleQuoted);
/// @brief Scan an unquoted scalar.
bool scanPlainScalar();
/// @brief Scan an Alias or Anchor starting with * or &.
bool scanAliasOrAnchor(bool IsAlias);
/// @brief Scan a block scalar starting with | or >.
bool scanBlockScalar(bool IsLiteral);
/// @brief Scan a tag of the form !stuff.
bool scanTag();
/// @brief Dispatch to the next scanning function based on \a *Cur.
bool fetchMoreTokens();
/// @brief The SourceMgr used for diagnostics and buffer management.
SourceMgr &SM;
/// @brief The original input.
MemoryBuffer *InputBuffer;
/// @brief The current position of the scanner.
StringRef::iterator Current;
/// @brief The end of the input (one past the last character).
StringRef::iterator End;
/// @brief Current YAML indentation level in spaces.
int Indent;
/// @brief Current column number in Unicode code points.
unsigned Column;
/// @brief Current line number.
unsigned Line;
/// @brief How deep we are in flow style containers. 0 Means at block level.
unsigned FlowLevel;
/// @brief Are we at the start of the stream?
bool IsStartOfStream;
/// @brief Can the next token be the start of a simple key?
bool IsSimpleKeyAllowed;
/// @brief True if an error has occurred.
bool Failed;
/// @brief Queue of tokens. This is required to queue up tokens while looking
/// for the end of a simple key. And for cases where a single character
/// can produce multiple tokens (e.g. BlockEnd).
TokenQueueT TokenQueue;
/// @brief Indentation levels.
SmallVector<int, 4> Indents;
/// @brief Potential simple keys.
SmallVector<SimpleKey, 4> SimpleKeys;
};
} // end namespace yaml
} // end namespace llvm
/// encodeUTF8 - Encode \a UnicodeScalarValue in UTF-8 and append it to result.
static void encodeUTF8( uint32_t UnicodeScalarValue
, SmallVectorImpl<char> &Result) {
if (UnicodeScalarValue <= 0x7F) {
Result.push_back(UnicodeScalarValue & 0x7F);
} else if (UnicodeScalarValue <= 0x7FF) {
uint8_t FirstByte = 0xC0 | ((UnicodeScalarValue & 0x7C0) >> 6);
uint8_t SecondByte = 0x80 | (UnicodeScalarValue & 0x3F);
Result.push_back(FirstByte);
Result.push_back(SecondByte);
} else if (UnicodeScalarValue <= 0xFFFF) {
uint8_t FirstByte = 0xE0 | ((UnicodeScalarValue & 0xF000) >> 12);
uint8_t SecondByte = 0x80 | ((UnicodeScalarValue & 0xFC0) >> 6);
uint8_t ThirdByte = 0x80 | (UnicodeScalarValue & 0x3F);
Result.push_back(FirstByte);
Result.push_back(SecondByte);
Result.push_back(ThirdByte);
} else if (UnicodeScalarValue <= 0x10FFFF) {
uint8_t FirstByte = 0xF0 | ((UnicodeScalarValue & 0x1F0000) >> 18);
uint8_t SecondByte = 0x80 | ((UnicodeScalarValue & 0x3F000) >> 12);
uint8_t ThirdByte = 0x80 | ((UnicodeScalarValue & 0xFC0) >> 6);
uint8_t FourthByte = 0x80 | (UnicodeScalarValue & 0x3F);
Result.push_back(FirstByte);
Result.push_back(SecondByte);
Result.push_back(ThirdByte);
Result.push_back(FourthByte);
}
}
bool yaml::dumpTokens(StringRef Input, raw_ostream &OS) {
SourceMgr SM;
Scanner scanner(Input, SM);
while (true) {
Token T = scanner.getNext();
switch (T.Kind) {
case Token::TK_StreamStart:
OS << "Stream-Start: ";
break;
case Token::TK_StreamEnd:
OS << "Stream-End: ";
break;
case Token::TK_VersionDirective:
OS << "Version-Directive: ";
break;
case Token::TK_TagDirective:
OS << "Tag-Directive: ";
break;
case Token::TK_DocumentStart:
OS << "Document-Start: ";
break;
case Token::TK_DocumentEnd:
OS << "Document-End: ";
break;
case Token::TK_BlockEntry:
OS << "Block-Entry: ";
break;
case Token::TK_BlockEnd:
OS << "Block-End: ";
break;
case Token::TK_BlockSequenceStart:
OS << "Block-Sequence-Start: ";
break;
case Token::TK_BlockMappingStart:
OS << "Block-Mapping-Start: ";
break;
case Token::TK_FlowEntry:
OS << "Flow-Entry: ";
break;
case Token::TK_FlowSequenceStart:
OS << "Flow-Sequence-Start: ";
break;
case Token::TK_FlowSequenceEnd:
OS << "Flow-Sequence-End: ";
break;
case Token::TK_FlowMappingStart:
OS << "Flow-Mapping-Start: ";
break;
case Token::TK_FlowMappingEnd:
OS << "Flow-Mapping-End: ";
break;
case Token::TK_Key:
OS << "Key: ";
break;
case Token::TK_Value:
OS << "Value: ";
break;
case Token::TK_Scalar:
OS << "Scalar: ";
break;
case Token::TK_Alias:
OS << "Alias: ";
break;
case Token::TK_Anchor:
OS << "Anchor: ";
break;
case Token::TK_Tag:
OS << "Tag: ";
break;
case Token::TK_Error:
break;
}
OS << T.Range << "\n";
if (T.Kind == Token::TK_StreamEnd)
break;
else if (T.Kind == Token::TK_Error)
return false;
}
return true;
}
bool yaml::scanTokens(StringRef Input) {
llvm::SourceMgr SM;
llvm::yaml::Scanner scanner(Input, SM);
for (;;) {
llvm::yaml::Token T = scanner.getNext();
if (T.Kind == Token::TK_StreamEnd)
break;
else if (T.Kind == Token::TK_Error)
return false;
}
return true;
}
std::string yaml::escape(StringRef Input) {
std::string EscapedInput;
for (StringRef::iterator i = Input.begin(), e = Input.end(); i != e; ++i) {
if (*i == '\\')
EscapedInput += "\\\\";
else if (*i == '"')
EscapedInput += "\\\"";
else if (*i == 0)
EscapedInput += "\\0";
else if (*i == 0x07)
EscapedInput += "\\a";
else if (*i == 0x08)
EscapedInput += "\\b";
else if (*i == 0x09)
EscapedInput += "\\t";
else if (*i == 0x0A)
EscapedInput += "\\n";
else if (*i == 0x0B)
EscapedInput += "\\v";
else if (*i == 0x0C)
EscapedInput += "\\f";
else if (*i == 0x0D)
EscapedInput += "\\r";
else if (*i == 0x1B)
EscapedInput += "\\e";
else if ((unsigned char)*i < 0x20) { // Control characters not handled above.
std::string HexStr = utohexstr(*i);
EscapedInput += "\\x" + std::string(2 - HexStr.size(), '0') + HexStr;
} else if (*i & 0x80) { // UTF-8 multiple code unit subsequence.
UTF8Decoded UnicodeScalarValue
= decodeUTF8(StringRef(i, Input.end() - i));
if (UnicodeScalarValue.second == 0) {
// Found invalid char.
SmallString<4> Val;
encodeUTF8(0xFFFD, Val);
EscapedInput.insert(EscapedInput.end(), Val.begin(), Val.end());
// FIXME: Error reporting.
return EscapedInput;
}
if (UnicodeScalarValue.first == 0x85)
EscapedInput += "\\N";
else if (UnicodeScalarValue.first == 0xA0)
EscapedInput += "\\_";
else if (UnicodeScalarValue.first == 0x2028)
EscapedInput += "\\L";
else if (UnicodeScalarValue.first == 0x2029)
EscapedInput += "\\P";
else {
std::string HexStr = utohexstr(UnicodeScalarValue.first);
if (HexStr.size() <= 2)
EscapedInput += "\\x" + std::string(2 - HexStr.size(), '0') + HexStr;
else if (HexStr.size() <= 4)
EscapedInput += "\\u" + std::string(4 - HexStr.size(), '0') + HexStr;
else if (HexStr.size() <= 8)
EscapedInput += "\\U" + std::string(8 - HexStr.size(), '0') + HexStr;
}
i += UnicodeScalarValue.second - 1;
} else
EscapedInput.push_back(*i);
}
return EscapedInput;
}
Scanner::Scanner(StringRef Input, SourceMgr &sm)
: SM(sm)
, Indent(-1)
, Column(0)
, Line(0)
, FlowLevel(0)
, IsStartOfStream(true)
, IsSimpleKeyAllowed(true)
, Failed(false) {
InputBuffer = MemoryBuffer::getMemBuffer(Input, "YAML");
SM.AddNewSourceBuffer(InputBuffer, SMLoc());
Current = InputBuffer->getBufferStart();
End = InputBuffer->getBufferEnd();
}
Scanner::Scanner(MemoryBuffer *Buffer, SourceMgr &SM_)
: SM(SM_)
, InputBuffer(Buffer)
, Current(InputBuffer->getBufferStart())
, End(InputBuffer->getBufferEnd())
, Indent(-1)
, Column(0)
, Line(0)
, FlowLevel(0)
, IsStartOfStream(true)
, IsSimpleKeyAllowed(true)
, Failed(false) {
SM.AddNewSourceBuffer(InputBuffer, SMLoc());
}
Token &Scanner::peekNext() {
// If the current token is a possible simple key, keep parsing until we
// can confirm.
bool NeedMore = false;
while (true) {
if (TokenQueue.empty() || NeedMore) {
if (!fetchMoreTokens()) {
TokenQueue.clear();
TokenQueue.push_back(Token());
return TokenQueue.front();
}
}
assert(!TokenQueue.empty() &&
"fetchMoreTokens lied about getting tokens!");
removeStaleSimpleKeyCandidates();
SimpleKey SK;
SK.Tok = TokenQueue.front();
if (std::find(SimpleKeys.begin(), SimpleKeys.end(), SK)
== SimpleKeys.end())
break;
else
NeedMore = true;
}
return TokenQueue.front();
}
Token Scanner::getNext() {
Token Ret = peekNext();
// TokenQueue can be empty if there was an error getting the next token.
if (!TokenQueue.empty())
TokenQueue.pop_front();
// There cannot be any referenced Token's if the TokenQueue is empty. So do a
// quick deallocation of them all.
if (TokenQueue.empty()) {
TokenQueue.Alloc.Reset();
}
return Ret;
}
StringRef::iterator Scanner::skip_nb_char(StringRef::iterator Position) {
if (Position == End)
return Position;
// Check 7 bit c-printable - b-char.
if ( *Position == 0x09
|| (*Position >= 0x20 && *Position <= 0x7E))
return Position + 1;
// Check for valid UTF-8.
if (uint8_t(*Position) & 0x80) {
UTF8Decoded u8d = decodeUTF8(Position);
if ( u8d.second != 0
&& u8d.first != 0xFEFF
&& ( u8d.first == 0x85
|| ( u8d.first >= 0xA0
&& u8d.first <= 0xD7FF)
|| ( u8d.first >= 0xE000
&& u8d.first <= 0xFFFD)
|| ( u8d.first >= 0x10000
&& u8d.first <= 0x10FFFF)))
return Position + u8d.second;
}
return Position;
}
StringRef::iterator Scanner::skip_b_break(StringRef::iterator Position) {
if (Position == End)
return Position;
if (*Position == 0x0D) {
if (Position + 1 != End && *(Position + 1) == 0x0A)
return Position + 2;
return Position + 1;
}
if (*Position == 0x0A)
return Position + 1;
return Position;
}
StringRef::iterator Scanner::skip_s_white(StringRef::iterator Position) {
if (Position == End)
return Position;
if (*Position == ' ' || *Position == '\t')
return Position + 1;
return Position;
}
StringRef::iterator Scanner::skip_ns_char(StringRef::iterator Position) {
if (Position == End)
return Position;
if (*Position == ' ' || *Position == '\t')
return Position;
return skip_nb_char(Position);
}
StringRef::iterator Scanner::skip_while( SkipWhileFunc Func
, StringRef::iterator Position) {
while (true) {
StringRef::iterator i = (this->*Func)(Position);
if (i == Position)
break;
Position = i;
}
return Position;
}
static bool is_ns_hex_digit(const char C) {
return (C >= '0' && C <= '9')
|| (C >= 'a' && C <= 'z')
|| (C >= 'A' && C <= 'Z');
}
static bool is_ns_word_char(const char C) {
return C == '-'
|| (C >= 'a' && C <= 'z')
|| (C >= 'A' && C <= 'Z');
}
StringRef Scanner::scan_ns_uri_char() {
StringRef::iterator Start = Current;
while (true) {
if (Current == End)
break;
if (( *Current == '%'
&& Current + 2 < End
&& is_ns_hex_digit(*(Current + 1))
&& is_ns_hex_digit(*(Current + 2)))
|| is_ns_word_char(*Current)
|| StringRef(Current, 1).find_first_of("#;/?:@&=+$,_.!~*'()[]")
!= StringRef::npos) {
++Current;
++Column;
} else
break;
}
return StringRef(Start, Current - Start);
}
StringRef Scanner::scan_ns_plain_one_line() {
StringRef::iterator start = Current;
// The first character must already be verified.
++Current;
while (true) {
if (Current == End) {
break;
} else if (*Current == ':') {
// Check if the next character is a ns-char.
if (Current + 1 == End)
break;
StringRef::iterator i = skip_ns_char(Current + 1);
if (Current + 1 != i) {
Current = i;
Column += 2; // Consume both the ':' and ns-char.
} else
break;
} else if (*Current == '#') {
// Check if the previous character was a ns-char.
// The & 0x80 check is to check for the trailing byte of a utf-8
if (*(Current - 1) & 0x80 || skip_ns_char(Current - 1) == Current) {
++Current;
++Column;
} else
break;
} else {
StringRef::iterator i = skip_nb_char(Current);
if (i == Current)
break;
Current = i;
++Column;
}
}
return StringRef(start, Current - start);
}
bool Scanner::consume(uint32_t Expected) {
if (Expected >= 0x80)
report_fatal_error("Not dealing with this yet");
if (Current == End)
return false;
if (uint8_t(*Current) >= 0x80)
report_fatal_error("Not dealing with this yet");
if (uint8_t(*Current) == Expected) {
++Current;
++Column;
return true;
}
return false;
}
void Scanner::skip(uint32_t Distance) {
Current += Distance;
Column += Distance;
assert(Current <= End && "Skipped past the end");
}
bool Scanner::isBlankOrBreak(StringRef::iterator Position) {
if (Position == End)
return false;
if ( *Position == ' ' || *Position == '\t'
|| *Position == '\r' || *Position == '\n')
return true;
return false;
}
void Scanner::saveSimpleKeyCandidate( TokenQueueT::iterator Tok
, unsigned AtColumn
, bool IsRequired) {
if (IsSimpleKeyAllowed) {
SimpleKey SK;
SK.Tok = Tok;
SK.Line = Line;
SK.Column = AtColumn;
SK.IsRequired = IsRequired;
SK.FlowLevel = FlowLevel;
SimpleKeys.push_back(SK);
}
}
void Scanner::removeStaleSimpleKeyCandidates() {
for (SmallVectorImpl<SimpleKey>::iterator i = SimpleKeys.begin();
i != SimpleKeys.end();) {
if (i->Line != Line || i->Column + 1024 < Column) {
if (i->IsRequired)
setError( "Could not find expected : for simple key"
, i->Tok->Range.begin());
i = SimpleKeys.erase(i);
} else
++i;
}
}
void Scanner::removeSimpleKeyCandidatesOnFlowLevel(unsigned Level) {
if (!SimpleKeys.empty() && (SimpleKeys.end() - 1)->FlowLevel == Level)
SimpleKeys.pop_back();
}
bool Scanner::unrollIndent(int ToColumn) {
Token T;
// Indentation is ignored in flow.
if (FlowLevel != 0)
return true;
while (Indent > ToColumn) {
T.Kind = Token::TK_BlockEnd;
T.Range = StringRef(Current, 1);
TokenQueue.push_back(T);
Indent = Indents.pop_back_val();
}
return true;
}
bool Scanner::rollIndent( int ToColumn
, Token::TokenKind Kind
, TokenQueueT::iterator InsertPoint) {
if (FlowLevel)
return true;
if (Indent < ToColumn) {
Indents.push_back(Indent);
Indent = ToColumn;
Token T;
T.Kind = Kind;
T.Range = StringRef(Current, 0);
TokenQueue.insert(InsertPoint, T);
}
return true;
}
void Scanner::scanToNextToken() {
while (true) {
while (*Current == ' ' || *Current == '\t') {
skip(1);
}
// Skip comment.
if (*Current == '#') {
while (true) {
// This may skip more than one byte, thus Column is only incremented
// for code points.
StringRef::iterator i = skip_nb_char(Current);
if (i == Current)
break;
Current = i;
++Column;
}
}
// Skip EOL.
StringRef::iterator i = skip_b_break(Current);
if (i == Current)
break;
Current = i;
++Line;
Column = 0;
// New lines may start a simple key.
if (!FlowLevel)
IsSimpleKeyAllowed = true;
}
}
bool Scanner::scanStreamStart() {
IsStartOfStream = false;
EncodingInfo EI = getUnicodeEncoding(currentInput());
Token T;
T.Kind = Token::TK_StreamStart;
T.Range = StringRef(Current, EI.second);
TokenQueue.push_back(T);
Current += EI.second;
return true;
}
bool Scanner::scanStreamEnd() {
// Force an ending new line if one isn't present.
if (Column != 0) {
Column = 0;
++Line;
}
unrollIndent(-1);
SimpleKeys.clear();
IsSimpleKeyAllowed = false;
Token T;
T.Kind = Token::TK_StreamEnd;
T.Range = StringRef(Current, 0);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanDirective() {
// Reset the indentation level.
unrollIndent(-1);
SimpleKeys.clear();
IsSimpleKeyAllowed = false;
StringRef::iterator Start = Current;
consume('%');
StringRef::iterator NameStart = Current;
Current = skip_while(&Scanner::skip_ns_char, Current);
StringRef Name(NameStart, Current - NameStart);
Current = skip_while(&Scanner::skip_s_white, Current);
if (Name == "YAML") {
Current = skip_while(&Scanner::skip_ns_char, Current);
Token T;
T.Kind = Token::TK_VersionDirective;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
return true;
}
return false;
}
bool Scanner::scanDocumentIndicator(bool IsStart) {
unrollIndent(-1);
SimpleKeys.clear();
IsSimpleKeyAllowed = false;
Token T;
T.Kind = IsStart ? Token::TK_DocumentStart : Token::TK_DocumentEnd;
T.Range = StringRef(Current, 3);
skip(3);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanFlowCollectionStart(bool IsSequence) {
Token T;
T.Kind = IsSequence ? Token::TK_FlowSequenceStart
: Token::TK_FlowMappingStart;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
// [ and { may begin a simple key.
saveSimpleKeyCandidate(TokenQueue.back(), Column - 1, false);
// And may also be followed by a simple key.
IsSimpleKeyAllowed = true;
++FlowLevel;
return true;
}
bool Scanner::scanFlowCollectionEnd(bool IsSequence) {
removeSimpleKeyCandidatesOnFlowLevel(FlowLevel);
IsSimpleKeyAllowed = false;
Token T;
T.Kind = IsSequence ? Token::TK_FlowSequenceEnd
: Token::TK_FlowMappingEnd;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
if (FlowLevel)
--FlowLevel;
return true;
}
bool Scanner::scanFlowEntry() {
removeSimpleKeyCandidatesOnFlowLevel(FlowLevel);
IsSimpleKeyAllowed = true;
Token T;
T.Kind = Token::TK_FlowEntry;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanBlockEntry() {
rollIndent(Column, Token::TK_BlockSequenceStart, TokenQueue.end());
removeSimpleKeyCandidatesOnFlowLevel(FlowLevel);
IsSimpleKeyAllowed = true;
Token T;
T.Kind = Token::TK_BlockEntry;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanKey() {
if (!FlowLevel)
rollIndent(Column, Token::TK_BlockMappingStart, TokenQueue.end());
removeSimpleKeyCandidatesOnFlowLevel(FlowLevel);
IsSimpleKeyAllowed = !FlowLevel;
Token T;
T.Kind = Token::TK_Key;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanValue() {
// If the previous token could have been a simple key, insert the key token
// into the token queue.
if (!SimpleKeys.empty()) {
SimpleKey SK = SimpleKeys.pop_back_val();
Token T;
T.Kind = Token::TK_Key;
T.Range = SK.Tok->Range;
TokenQueueT::iterator i, e;
for (i = TokenQueue.begin(), e = TokenQueue.end(); i != e; ++i) {
if (i == SK.Tok)
break;
}
assert(i != e && "SimpleKey not in token queue!");
i = TokenQueue.insert(i, T);
// We may also need to add a Block-Mapping-Start token.
rollIndent(SK.Column, Token::TK_BlockMappingStart, i);
IsSimpleKeyAllowed = false;
} else {
if (!FlowLevel)
rollIndent(Column, Token::TK_BlockMappingStart, TokenQueue.end());
IsSimpleKeyAllowed = !FlowLevel;
}
Token T;
T.Kind = Token::TK_Value;
T.Range = StringRef(Current, 1);
skip(1);
TokenQueue.push_back(T);
return true;
}
// Forbidding inlining improves performance by roughly 20%.
// FIXME: Remove once llvm optimizes this to the faster version without hints.
LLVM_ATTRIBUTE_NOINLINE static bool
wasEscaped(StringRef::iterator First, StringRef::iterator Position);
// Returns whether a character at 'Position' was escaped with a leading '\'.
// 'First' specifies the position of the first character in the string.
static bool wasEscaped(StringRef::iterator First,
StringRef::iterator Position) {
assert(Position - 1 >= First);
StringRef::iterator I = Position - 1;
// We calculate the number of consecutive '\'s before the current position
// by iterating backwards through our string.
while (I >= First && *I == '\\') --I;
// (Position - 1 - I) now contains the number of '\'s before the current
// position. If it is odd, the character at 'Position' was escaped.
return (Position - 1 - I) % 2 == 1;
}
bool Scanner::scanFlowScalar(bool IsDoubleQuoted) {
StringRef::iterator Start = Current;
unsigned ColStart = Column;
if (IsDoubleQuoted) {
do {
++Current;
while (Current != End && *Current != '"')
++Current;
// Repeat until the previous character was not a '\' or was an escaped
// backslash.
} while ( Current != End
&& *(Current - 1) == '\\'
&& wasEscaped(Start + 1, Current));
} else {
skip(1);
while (true) {
// Skip a ' followed by another '.
if (Current + 1 < End && *Current == '\'' && *(Current + 1) == '\'') {
skip(2);
continue;
} else if (*Current == '\'')
break;
StringRef::iterator i = skip_nb_char(Current);
if (i == Current) {
i = skip_b_break(Current);
if (i == Current)
break;
Current = i;
Column = 0;
++Line;
} else {
if (i == End)
break;
Current = i;
++Column;
}
}
}
if (Current == End) {
setError("Expected quote at end of scalar", Current);
return false;
}
skip(1); // Skip ending quote.
Token T;
T.Kind = Token::TK_Scalar;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
saveSimpleKeyCandidate(TokenQueue.back(), ColStart, false);
IsSimpleKeyAllowed = false;
return true;
}
bool Scanner::scanPlainScalar() {
StringRef::iterator Start = Current;
unsigned ColStart = Column;
unsigned LeadingBlanks = 0;
assert(Indent >= -1 && "Indent must be >= -1 !");
unsigned indent = static_cast<unsigned>(Indent + 1);
while (true) {
if (*Current == '#')
break;
while (!isBlankOrBreak(Current)) {
if ( FlowLevel && *Current == ':'
&& !(isBlankOrBreak(Current + 1) || *(Current + 1) == ',')) {
setError("Found unexpected ':' while scanning a plain scalar", Current);
return false;
}
// Check for the end of the plain scalar.
if ( (*Current == ':' && isBlankOrBreak(Current + 1))
|| ( FlowLevel
&& (StringRef(Current, 1).find_first_of(",:?[]{}")
!= StringRef::npos)))
break;
StringRef::iterator i = skip_nb_char(Current);
if (i == Current)
break;
Current = i;
++Column;
}
// Are we at the end?
if (!isBlankOrBreak(Current))
break;
// Eat blanks.
StringRef::iterator Tmp = Current;
while (isBlankOrBreak(Tmp)) {
StringRef::iterator i = skip_s_white(Tmp);
if (i != Tmp) {
if (LeadingBlanks && (Column < indent) && *Tmp == '\t') {
setError("Found invalid tab character in indentation", Tmp);
return false;
}
Tmp = i;
++Column;
} else {
i = skip_b_break(Tmp);
if (!LeadingBlanks)
LeadingBlanks = 1;
Tmp = i;
Column = 0;
++Line;
}
}
if (!FlowLevel && Column < indent)
break;
Current = Tmp;
}
if (Start == Current) {
setError("Got empty plain scalar", Start);
return false;
}
Token T;
T.Kind = Token::TK_Scalar;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
// Plain scalars can be simple keys.
saveSimpleKeyCandidate(TokenQueue.back(), ColStart, false);
IsSimpleKeyAllowed = false;
return true;
}
bool Scanner::scanAliasOrAnchor(bool IsAlias) {
StringRef::iterator Start = Current;
unsigned ColStart = Column;
skip(1);
while(true) {
if ( *Current == '[' || *Current == ']'
|| *Current == '{' || *Current == '}'
|| *Current == ','
|| *Current == ':')
break;
StringRef::iterator i = skip_ns_char(Current);
if (i == Current)
break;
Current = i;
++Column;
}
if (Start == Current) {
setError("Got empty alias or anchor", Start);
return false;
}
Token T;
T.Kind = IsAlias ? Token::TK_Alias : Token::TK_Anchor;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
// Alias and anchors can be simple keys.
saveSimpleKeyCandidate(TokenQueue.back(), ColStart, false);
IsSimpleKeyAllowed = false;
return true;
}
bool Scanner::scanBlockScalar(bool IsLiteral) {
StringRef::iterator Start = Current;
skip(1); // Eat | or >
while(true) {
StringRef::iterator i = skip_nb_char(Current);
if (i == Current) {
if (Column == 0)
break;
i = skip_b_break(Current);
if (i != Current) {
// We got a line break.
Column = 0;
++Line;
Current = i;
continue;
} else {
// There was an error, which should already have been printed out.
return false;
}
}
Current = i;
++Column;
}
if (Start == Current) {
setError("Got empty block scalar", Start);
return false;
}
Token T;
T.Kind = Token::TK_Scalar;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
return true;
}
bool Scanner::scanTag() {
StringRef::iterator Start = Current;
unsigned ColStart = Column;
skip(1); // Eat !.
if (Current == End || isBlankOrBreak(Current)); // An empty tag.
else if (*Current == '<') {
skip(1);
scan_ns_uri_char();
if (!consume('>'))
return false;
} else {
// FIXME: Actually parse the c-ns-shorthand-tag rule.
Current = skip_while(&Scanner::skip_ns_char, Current);
}
Token T;
T.Kind = Token::TK_Tag;
T.Range = StringRef(Start, Current - Start);
TokenQueue.push_back(T);
// Tags can be simple keys.
saveSimpleKeyCandidate(TokenQueue.back(), ColStart, false);
IsSimpleKeyAllowed = false;
return true;
}
bool Scanner::fetchMoreTokens() {
if (IsStartOfStream)
return scanStreamStart();
scanToNextToken();
if (Current == End)
return scanStreamEnd();
removeStaleSimpleKeyCandidates();
unrollIndent(Column);
if (Column == 0 && *Current == '%')
return scanDirective();
if (Column == 0 && Current + 4 <= End
&& *Current == '-'
&& *(Current + 1) == '-'
&& *(Current + 2) == '-'
&& (Current + 3 == End || isBlankOrBreak(Current + 3)))
return scanDocumentIndicator(true);
if (Column == 0 && Current + 4 <= End
&& *Current == '.'
&& *(Current + 1) == '.'
&& *(Current + 2) == '.'
&& (Current + 3 == End || isBlankOrBreak(Current + 3)))
return scanDocumentIndicator(false);
if (*Current == '[')
return scanFlowCollectionStart(true);
if (*Current == '{')
return scanFlowCollectionStart(false);
if (*Current == ']')
return scanFlowCollectionEnd(true);
if (*Current == '}')
return scanFlowCollectionEnd(false);
if (*Current == ',')
return scanFlowEntry();
if (*Current == '-' && isBlankOrBreak(Current + 1))
return scanBlockEntry();
if (*Current == '?' && (FlowLevel || isBlankOrBreak(Current + 1)))
return scanKey();
if (*Current == ':' && (FlowLevel || isBlankOrBreak(Current + 1)))
return scanValue();
if (*Current == '*')
return scanAliasOrAnchor(true);
if (*Current == '&')
return scanAliasOrAnchor(false);
if (*Current == '!')
return scanTag();
if (*Current == '|' && !FlowLevel)
return scanBlockScalar(true);
if (*Current == '>' && !FlowLevel)
return scanBlockScalar(false);
if (*Current == '\'')
return scanFlowScalar(false);
if (*Current == '"')
return scanFlowScalar(true);
// Get a plain scalar.
StringRef FirstChar(Current, 1);
if (!(isBlankOrBreak(Current)
|| FirstChar.find_first_of("-?:,[]{}#&*!|>'\"%@`") != StringRef::npos)
|| (*Current == '-' && !isBlankOrBreak(Current + 1))
|| (!FlowLevel && (*Current == '?' || *Current == ':')
&& isBlankOrBreak(Current + 1))
|| (!FlowLevel && *Current == ':'
&& Current + 2 < End
&& *(Current + 1) == ':'
&& !isBlankOrBreak(Current + 2)))
return scanPlainScalar();
setError("Unrecognized character while tokenizing.");
return false;
}
Stream::Stream(StringRef Input, SourceMgr &SM)
: scanner(new Scanner(Input, SM))
, CurrentDoc(0) {}
Stream::Stream(MemoryBuffer *InputBuffer, SourceMgr &SM)
: scanner(new Scanner(InputBuffer, SM))
, CurrentDoc(0) {}
Stream::~Stream() {}
bool Stream::failed() { return scanner->failed(); }
void Stream::printError(Node *N, const Twine &Msg) {
SmallVector<SMRange, 1> Ranges;
Ranges.push_back(N->getSourceRange());
scanner->printError( N->getSourceRange().Start
, SourceMgr::DK_Error
, Msg
, Ranges);
}
void Stream::handleYAMLDirective(const Token &t) {
// TODO: Ensure version is 1.x.
}
document_iterator Stream::begin() {
if (CurrentDoc)
report_fatal_error("Can only iterate over the stream once");
// Skip Stream-Start.
scanner->getNext();
CurrentDoc.reset(new Document(*this));
return document_iterator(CurrentDoc);
}
document_iterator Stream::end() {
return document_iterator();
}
void Stream::skip() {
for (document_iterator i = begin(), e = end(); i != e; ++i)
i->skip();
}
Node::Node(unsigned int Type, OwningPtr<Document> &D, StringRef A)
: Doc(D)
, TypeID(Type)
, Anchor(A) {
SMLoc Start = SMLoc::getFromPointer(peekNext().Range.begin());
SourceRange = SMRange(Start, Start);
}
Token &Node::peekNext() {
return Doc->peekNext();
}
Token Node::getNext() {
return Doc->getNext();
}
Node *Node::parseBlockNode() {
return Doc->parseBlockNode();
}
BumpPtrAllocator &Node::getAllocator() {
return Doc->NodeAllocator;
}
void Node::setError(const Twine &Msg, Token &Tok) const {
Doc->setError(Msg, Tok);
}
bool Node::failed() const {
return Doc->failed();
}
StringRef ScalarNode::getValue(SmallVectorImpl<char> &Storage) const {
// TODO: Handle newlines properly. We need to remove leading whitespace.
if (Value[0] == '"') { // Double quoted.
// Pull off the leading and trailing "s.
StringRef UnquotedValue = Value.substr(1, Value.size() - 2);
// Search for characters that would require unescaping the value.
StringRef::size_type i = UnquotedValue.find_first_of("\\\r\n");
if (i != StringRef::npos)
return unescapeDoubleQuoted(UnquotedValue, i, Storage);
return UnquotedValue;
} else if (Value[0] == '\'') { // Single quoted.
// Pull off the leading and trailing 's.
StringRef UnquotedValue = Value.substr(1, Value.size() - 2);
StringRef::size_type i = UnquotedValue.find('\'');
if (i != StringRef::npos) {
// We're going to need Storage.
Storage.clear();
Storage.reserve(UnquotedValue.size());
for (; i != StringRef::npos; i = UnquotedValue.find('\'')) {
StringRef Valid(UnquotedValue.begin(), i);
Storage.insert(Storage.end(), Valid.begin(), Valid.end());
Storage.push_back('\'');
UnquotedValue = UnquotedValue.substr(i + 2);
}
Storage.insert(Storage.end(), UnquotedValue.begin(), UnquotedValue.end());
return StringRef(Storage.begin(), Storage.size());
}
return UnquotedValue;
}
// Plain or block.
return Value.rtrim(" ");
}
StringRef ScalarNode::unescapeDoubleQuoted( StringRef UnquotedValue
, StringRef::size_type i
, SmallVectorImpl<char> &Storage)
const {
// Use Storage to build proper value.
Storage.clear();
Storage.reserve(UnquotedValue.size());
for (; i != StringRef::npos; i = UnquotedValue.find_first_of("\\\r\n")) {
// Insert all previous chars into Storage.
StringRef Valid(UnquotedValue.begin(), i);
Storage.insert(Storage.end(), Valid.begin(), Valid.end());
// Chop off inserted chars.
UnquotedValue = UnquotedValue.substr(i);
assert(!UnquotedValue.empty() && "Can't be empty!");
// Parse escape or line break.
switch (UnquotedValue[0]) {
case '\r':
case '\n':
Storage.push_back('\n');
if ( UnquotedValue.size() > 1
&& (UnquotedValue[1] == '\r' || UnquotedValue[1] == '\n'))
UnquotedValue = UnquotedValue.substr(1);
UnquotedValue = UnquotedValue.substr(1);
break;
default:
if (UnquotedValue.size() == 1)
// TODO: Report error.
break;
UnquotedValue = UnquotedValue.substr(1);
switch (UnquotedValue[0]) {
default: {
Token T;
T.Range = StringRef(UnquotedValue.begin(), 1);
setError("Unrecognized escape code!", T);
return "";
}
case '\r':
case '\n':
// Remove the new line.
if ( UnquotedValue.size() > 1
&& (UnquotedValue[1] == '\r' || UnquotedValue[1] == '\n'))
UnquotedValue = UnquotedValue.substr(1);
// If this was just a single byte newline, it will get skipped
// below.
break;
case '0':
Storage.push_back(0x00);
break;
case 'a':
Storage.push_back(0x07);
break;
case 'b':
Storage.push_back(0x08);
break;
case 't':
case 0x09:
Storage.push_back(0x09);
break;
case 'n':
Storage.push_back(0x0A);
break;
case 'v':
Storage.push_back(0x0B);
break;
case 'f':
Storage.push_back(0x0C);
break;
case 'r':
Storage.push_back(0x0D);
break;
case 'e':
Storage.push_back(0x1B);
break;
case ' ':
Storage.push_back(0x20);
break;
case '"':
Storage.push_back(0x22);
break;
case '/':
Storage.push_back(0x2F);
break;
case '\\':
Storage.push_back(0x5C);
break;
case 'N':
encodeUTF8(0x85, Storage);
break;
case '_':
encodeUTF8(0xA0, Storage);
break;
case 'L':
encodeUTF8(0x2028, Storage);
break;
case 'P':
encodeUTF8(0x2029, Storage);
break;
case 'x': {
if (UnquotedValue.size() < 3)
// TODO: Report error.
break;
unsigned int UnicodeScalarValue;
if (UnquotedValue.substr(1, 2).getAsInteger(16, UnicodeScalarValue))
// TODO: Report error.
UnicodeScalarValue = 0xFFFD;
encodeUTF8(UnicodeScalarValue, Storage);
UnquotedValue = UnquotedValue.substr(2);
break;
}
case 'u': {
if (UnquotedValue.size() < 5)
// TODO: Report error.
break;
unsigned int UnicodeScalarValue;
if (UnquotedValue.substr(1, 4).getAsInteger(16, UnicodeScalarValue))
// TODO: Report error.
UnicodeScalarValue = 0xFFFD;
encodeUTF8(UnicodeScalarValue, Storage);
UnquotedValue = UnquotedValue.substr(4);
break;
}
case 'U': {
if (UnquotedValue.size() < 9)
// TODO: Report error.
break;
unsigned int UnicodeScalarValue;
if (UnquotedValue.substr(1, 8).getAsInteger(16, UnicodeScalarValue))
// TODO: Report error.
UnicodeScalarValue = 0xFFFD;
encodeUTF8(UnicodeScalarValue, Storage);
UnquotedValue = UnquotedValue.substr(8);
break;
}
}
UnquotedValue = UnquotedValue.substr(1);
}
}
Storage.insert(Storage.end(), UnquotedValue.begin(), UnquotedValue.end());
return StringRef(Storage.begin(), Storage.size());
}
Node *KeyValueNode::getKey() {
if (Key)
return Key;
// Handle implicit null keys.
{
Token &t = peekNext();
if ( t.Kind == Token::TK_BlockEnd
|| t.Kind == Token::TK_Value
|| t.Kind == Token::TK_Error) {
return Key = new (getAllocator()) NullNode(Doc);
}
if (t.Kind == Token::TK_Key)
getNext(); // skip TK_Key.
}
// Handle explicit null keys.
Token &t = peekNext();
if (t.Kind == Token::TK_BlockEnd || t.Kind == Token::TK_Value) {
return Key = new (getAllocator()) NullNode(Doc);
}
// We've got a normal key.
return Key = parseBlockNode();
}
Node *KeyValueNode::getValue() {
if (Value)
return Value;
getKey()->skip();
if (failed())
return Value = new (getAllocator()) NullNode(Doc);
// Handle implicit null values.
{
Token &t = peekNext();
if ( t.Kind == Token::TK_BlockEnd
|| t.Kind == Token::TK_FlowMappingEnd
|| t.Kind == Token::TK_Key
|| t.Kind == Token::TK_FlowEntry
|| t.Kind == Token::TK_Error) {
return Value = new (getAllocator()) NullNode(Doc);
}
if (t.Kind != Token::TK_Value) {
setError("Unexpected token in Key Value.", t);
return Value = new (getAllocator()) NullNode(Doc);
}
getNext(); // skip TK_Value.
}
// Handle explicit null values.
Token &t = peekNext();
if (t.Kind == Token::TK_BlockEnd || t.Kind == Token::TK_Key) {
return Value = new (getAllocator()) NullNode(Doc);
}
// We got a normal value.
return Value = parseBlockNode();
}
void MappingNode::increment() {
if (failed()) {
IsAtEnd = true;
CurrentEntry = 0;
return;
}
if (CurrentEntry) {
CurrentEntry->skip();
if (Type == MT_Inline) {
IsAtEnd = true;
CurrentEntry = 0;
return;
}
}
Token T = peekNext();
if (T.Kind == Token::TK_Key || T.Kind == Token::TK_Scalar) {
// KeyValueNode eats the TK_Key. That way it can detect null keys.
CurrentEntry = new (getAllocator()) KeyValueNode(Doc);
} else if (Type == MT_Block) {
switch (T.Kind) {
case Token::TK_BlockEnd:
getNext();
IsAtEnd = true;
CurrentEntry = 0;
break;
default:
setError("Unexpected token. Expected Key or Block End", T);
case Token::TK_Error:
IsAtEnd = true;
CurrentEntry = 0;
}
} else {
switch (T.Kind) {
case Token::TK_FlowEntry:
// Eat the flow entry and recurse.
getNext();
return increment();
case Token::TK_FlowMappingEnd:
getNext();
case Token::TK_Error:
// Set this to end iterator.
IsAtEnd = true;
CurrentEntry = 0;
break;
default:
setError( "Unexpected token. Expected Key, Flow Entry, or Flow "
"Mapping End."
, T);
IsAtEnd = true;
CurrentEntry = 0;
}
}
}
void SequenceNode::increment() {
if (failed()) {
IsAtEnd = true;
CurrentEntry = 0;
return;
}
if (CurrentEntry)
CurrentEntry->skip();
Token T = peekNext();
if (SeqType == ST_Block) {
switch (T.Kind) {
case Token::TK_BlockEntry:
getNext();
CurrentEntry = parseBlockNode();
if (CurrentEntry == 0) { // An error occurred.
IsAtEnd = true;
CurrentEntry = 0;
}
break;
case Token::TK_BlockEnd:
getNext();
IsAtEnd = true;
CurrentEntry = 0;
break;
default:
setError( "Unexpected token. Expected Block Entry or Block End."
, T);
case Token::TK_Error:
IsAtEnd = true;
CurrentEntry = 0;
}
} else if (SeqType == ST_Indentless) {
switch (T.Kind) {
case Token::TK_BlockEntry:
getNext();
CurrentEntry = parseBlockNode();
if (CurrentEntry == 0) { // An error occurred.
IsAtEnd = true;
CurrentEntry = 0;
}
break;
default:
case Token::TK_Error:
IsAtEnd = true;
CurrentEntry = 0;
}
} else if (SeqType == ST_Flow) {
switch (T.Kind) {
case Token::TK_FlowEntry:
// Eat the flow entry and recurse.
getNext();
WasPreviousTokenFlowEntry = true;
return increment();
case Token::TK_FlowSequenceEnd:
getNext();
case Token::TK_Error:
// Set this to end iterator.
IsAtEnd = true;
CurrentEntry = 0;
break;
case Token::TK_StreamEnd:
case Token::TK_DocumentEnd:
case Token::TK_DocumentStart:
setError("Could not find closing ]!", T);
// Set this to end iterator.
IsAtEnd = true;
CurrentEntry = 0;
break;
default:
if (!WasPreviousTokenFlowEntry) {
setError("Expected , between entries!", T);
IsAtEnd = true;
CurrentEntry = 0;
break;
}
// Otherwise it must be a flow entry.
CurrentEntry = parseBlockNode();
if (!CurrentEntry) {
IsAtEnd = true;
}
WasPreviousTokenFlowEntry = false;
break;
}
}
}
Document::Document(Stream &S) : stream(S), Root(0) {
if (parseDirectives())
expectToken(Token::TK_DocumentStart);
Token &T = peekNext();
if (T.Kind == Token::TK_DocumentStart)
getNext();
}
bool Document::skip() {
if (stream.scanner->failed())
return false;
if (!Root)
getRoot();
Root->skip();
Token &T = peekNext();
if (T.Kind == Token::TK_StreamEnd)
return false;
if (T.Kind == Token::TK_DocumentEnd) {
getNext();
return skip();
}
return true;
}
Token &Document::peekNext() {
return stream.scanner->peekNext();
}
Token Document::getNext() {
return stream.scanner->getNext();
}
void Document::setError(const Twine &Message, Token &Location) const {
stream.scanner->setError(Message, Location.Range.begin());
}
bool Document::failed() const {
return stream.scanner->failed();
}
Node *Document::parseBlockNode() {
Token T = peekNext();
// Handle properties.
Token AnchorInfo;
parse_property:
switch (T.Kind) {
case Token::TK_Alias:
getNext();
return new (NodeAllocator) AliasNode(stream.CurrentDoc, T.Range.substr(1));
case Token::TK_Anchor:
if (AnchorInfo.Kind == Token::TK_Anchor) {
setError("Already encountered an anchor for this node!", T);
return 0;
}
AnchorInfo = getNext(); // Consume TK_Anchor.
T = peekNext();
goto parse_property;
case Token::TK_Tag:
getNext(); // Skip TK_Tag.
T = peekNext();
goto parse_property;
default:
break;
}
switch (T.Kind) {
case Token::TK_BlockEntry:
// We got an unindented BlockEntry sequence. This is not terminated with
// a BlockEnd.
// Don't eat the TK_BlockEntry, SequenceNode needs it.
return new (NodeAllocator) SequenceNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, SequenceNode::ST_Indentless);
case Token::TK_BlockSequenceStart:
getNext();
return new (NodeAllocator)
SequenceNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, SequenceNode::ST_Block);
case Token::TK_BlockMappingStart:
getNext();
return new (NodeAllocator)
MappingNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, MappingNode::MT_Block);
case Token::TK_FlowSequenceStart:
getNext();
return new (NodeAllocator)
SequenceNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, SequenceNode::ST_Flow);
case Token::TK_FlowMappingStart:
getNext();
return new (NodeAllocator)
MappingNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, MappingNode::MT_Flow);
case Token::TK_Scalar:
getNext();
return new (NodeAllocator)
ScalarNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, T.Range);
case Token::TK_Key:
// Don't eat the TK_Key, KeyValueNode expects it.
return new (NodeAllocator)
MappingNode( stream.CurrentDoc
, AnchorInfo.Range.substr(1)
, MappingNode::MT_Inline);
case Token::TK_DocumentStart:
case Token::TK_DocumentEnd:
case Token::TK_StreamEnd:
default:
// TODO: Properly handle tags. "[!!str ]" should resolve to !!str "", not
// !!null null.
return new (NodeAllocator) NullNode(stream.CurrentDoc);
case Token::TK_Error:
return 0;
}
llvm_unreachable("Control flow shouldn't reach here.");
return 0;
}
bool Document::parseDirectives() {
bool isDirective = false;
while (true) {
Token T = peekNext();
if (T.Kind == Token::TK_TagDirective) {
handleTagDirective(getNext());
isDirective = true;
} else if (T.Kind == Token::TK_VersionDirective) {
stream.handleYAMLDirective(getNext());
isDirective = true;
} else
break;
}
return isDirective;
}
bool Document::expectToken(int TK) {
Token T = getNext();
if (T.Kind != TK) {
setError("Unexpected token", T);
return false;
}
return true;
}