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llvm-mirror/include/llvm/Support/YAMLParser.h
Hamza Sood 34a3716b46 Replace uses of std::iterator with explicit using
This patch removes all uses of `std::iterator`, which was deprecated in C++17.
While this isn't currently an issue while compiling LLVM, it's useful for those using LLVM as a library.

For some reason there're a few places that were seemingly able to use `std` functions unqualified, which no longer works after this patch. I've updated those places, but I'm not really sure why it worked in the first place.

Reviewed By: MaskRay

Differential Revision: https://reviews.llvm.org/D67586
2021-04-12 10:47:14 -07:00

629 lines
17 KiB
C++

//===- YAMLParser.h - Simple YAML parser ------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This is a YAML 1.2 parser.
//
// See http://www.yaml.org/spec/1.2/spec.html for the full standard.
//
// This currently does not implement the following:
// * Multi-line literal folding.
// * Tag resolution.
// * UTF-16.
// * BOMs anywhere other than the first Unicode scalar value in the file.
//
// The most important class here is Stream. This represents a YAML stream with
// 0, 1, or many documents.
//
// SourceMgr sm;
// StringRef input = getInput();
// yaml::Stream stream(input, sm);
//
// for (yaml::document_iterator di = stream.begin(), de = stream.end();
// di != de; ++di) {
// yaml::Node *n = di->getRoot();
// if (n) {
// // Do something with n...
// } else
// break;
// }
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_SUPPORT_YAMLPARSER_H
#define LLVM_SUPPORT_YAMLPARSER_H
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/SMLoc.h"
#include "llvm/Support/SourceMgr.h"
#include <cassert>
#include <cstddef>
#include <iterator>
#include <map>
#include <memory>
#include <string>
#include <system_error>
namespace llvm {
class MemoryBufferRef;
class raw_ostream;
class Twine;
namespace yaml {
class Document;
class document_iterator;
class Node;
class Scanner;
struct Token;
/// Dump all the tokens in this stream to OS.
/// \returns true if there was an error, false otherwise.
bool dumpTokens(StringRef Input, raw_ostream &);
/// Scans all tokens in input without outputting anything. This is used
/// for benchmarking the tokenizer.
/// \returns true if there was an error, false otherwise.
bool scanTokens(StringRef Input);
/// Escape \a Input for a double quoted scalar; if \p EscapePrintable
/// is true, all UTF8 sequences will be escaped, if \p EscapePrintable is
/// false, those UTF8 sequences encoding printable unicode scalars will not be
/// escaped, but emitted verbatim.
std::string escape(StringRef Input, bool EscapePrintable = true);
/// Parse \p S as a bool according to https://yaml.org/type/bool.html.
llvm::Optional<bool> parseBool(StringRef S);
/// This class represents a YAML stream potentially containing multiple
/// documents.
class Stream {
public:
/// This keeps a reference to the string referenced by \p Input.
Stream(StringRef Input, SourceMgr &, bool ShowColors = true,
std::error_code *EC = nullptr);
Stream(MemoryBufferRef InputBuffer, SourceMgr &, bool ShowColors = true,
std::error_code *EC = nullptr);
~Stream();
document_iterator begin();
document_iterator end();
void skip();
bool failed();
bool validate() {
skip();
return !failed();
}
void printError(Node *N, const Twine &Msg,
SourceMgr::DiagKind Kind = SourceMgr::DK_Error);
void printError(const SMRange &Range, const Twine &Msg,
SourceMgr::DiagKind Kind = SourceMgr::DK_Error);
private:
friend class Document;
std::unique_ptr<Scanner> scanner;
std::unique_ptr<Document> CurrentDoc;
};
/// Abstract base class for all Nodes.
class Node {
virtual void anchor();
public:
enum NodeKind {
NK_Null,
NK_Scalar,
NK_BlockScalar,
NK_KeyValue,
NK_Mapping,
NK_Sequence,
NK_Alias
};
Node(unsigned int Type, std::unique_ptr<Document> &, StringRef Anchor,
StringRef Tag);
// It's not safe to copy YAML nodes; the document is streamed and the position
// is part of the state.
Node(const Node &) = delete;
void operator=(const Node &) = delete;
void *operator new(size_t Size, BumpPtrAllocator &Alloc,
size_t Alignment = 16) noexcept {
return Alloc.Allocate(Size, Alignment);
}
void operator delete(void *Ptr, BumpPtrAllocator &Alloc,
size_t Size) noexcept {
Alloc.Deallocate(Ptr, Size, 0);
}
void operator delete(void *) noexcept = delete;
/// Get the value of the anchor attached to this node. If it does not
/// have one, getAnchor().size() will be 0.
StringRef getAnchor() const { return Anchor; }
/// Get the tag as it was written in the document. This does not
/// perform tag resolution.
StringRef getRawTag() const { return Tag; }
/// Get the verbatium tag for a given Node. This performs tag resoluton
/// and substitution.
std::string getVerbatimTag() const;
SMRange getSourceRange() const { return SourceRange; }
void setSourceRange(SMRange SR) { SourceRange = SR; }
// These functions forward to Document and Scanner.
Token &peekNext();
Token getNext();
Node *parseBlockNode();
BumpPtrAllocator &getAllocator();
void setError(const Twine &Message, Token &Location) const;
bool failed() const;
virtual void skip() {}
unsigned int getType() const { return TypeID; }
protected:
std::unique_ptr<Document> &Doc;
SMRange SourceRange;
~Node() = default;
private:
unsigned int TypeID;
StringRef Anchor;
/// The tag as typed in the document.
StringRef Tag;
};
/// A null value.
///
/// Example:
/// !!null null
class NullNode final : public Node {
void anchor() override;
public:
NullNode(std::unique_ptr<Document> &D)
: Node(NK_Null, D, StringRef(), StringRef()) {}
static bool classof(const Node *N) { return N->getType() == NK_Null; }
};
/// A scalar node is an opaque datum that can be presented as a
/// series of zero or more Unicode scalar values.
///
/// Example:
/// Adena
class ScalarNode final : public Node {
void anchor() override;
public:
ScalarNode(std::unique_ptr<Document> &D, StringRef Anchor, StringRef Tag,
StringRef Val)
: Node(NK_Scalar, D, Anchor, Tag), Value(Val) {
SMLoc Start = SMLoc::getFromPointer(Val.begin());
SMLoc End = SMLoc::getFromPointer(Val.end());
SourceRange = SMRange(Start, End);
}
// Return Value without any escaping or folding or other fun YAML stuff. This
// is the exact bytes that are contained in the file (after conversion to
// utf8).
StringRef getRawValue() const { return Value; }
/// Gets the value of this node as a StringRef.
///
/// \param Storage is used to store the content of the returned StringRef if
/// it requires any modification from how it appeared in the source.
/// This happens with escaped characters and multi-line literals.
StringRef getValue(SmallVectorImpl<char> &Storage) const;
static bool classof(const Node *N) {
return N->getType() == NK_Scalar;
}
private:
StringRef Value;
StringRef unescapeDoubleQuoted(StringRef UnquotedValue,
StringRef::size_type Start,
SmallVectorImpl<char> &Storage) const;
};
/// A block scalar node is an opaque datum that can be presented as a
/// series of zero or more Unicode scalar values.
///
/// Example:
/// |
/// Hello
/// World
class BlockScalarNode final : public Node {
void anchor() override;
public:
BlockScalarNode(std::unique_ptr<Document> &D, StringRef Anchor, StringRef Tag,
StringRef Value, StringRef RawVal)
: Node(NK_BlockScalar, D, Anchor, Tag), Value(Value) {
SMLoc Start = SMLoc::getFromPointer(RawVal.begin());
SMLoc End = SMLoc::getFromPointer(RawVal.end());
SourceRange = SMRange(Start, End);
}
/// Gets the value of this node as a StringRef.
StringRef getValue() const { return Value; }
static bool classof(const Node *N) {
return N->getType() == NK_BlockScalar;
}
private:
StringRef Value;
};
/// A key and value pair. While not technically a Node under the YAML
/// representation graph, it is easier to treat them this way.
///
/// TODO: Consider making this not a child of Node.
///
/// Example:
/// Section: .text
class KeyValueNode final : public Node {
void anchor() override;
public:
KeyValueNode(std::unique_ptr<Document> &D)
: Node(NK_KeyValue, D, StringRef(), StringRef()) {}
/// Parse and return the key.
///
/// This may be called multiple times.
///
/// \returns The key, or nullptr if failed() == true.
Node *getKey();
/// Parse and return the value.
///
/// This may be called multiple times.
///
/// \returns The value, or nullptr if failed() == true.
Node *getValue();
void skip() override {
if (Node *Key = getKey()) {
Key->skip();
if (Node *Val = getValue())
Val->skip();
}
}
static bool classof(const Node *N) {
return N->getType() == NK_KeyValue;
}
private:
Node *Key = nullptr;
Node *Value = nullptr;
};
/// This is an iterator abstraction over YAML collections shared by both
/// sequences and maps.
///
/// BaseT must have a ValueT* member named CurrentEntry and a member function
/// increment() which must set CurrentEntry to 0 to create an end iterator.
template <class BaseT, class ValueT> class basic_collection_iterator {
public:
using iterator_category = std::input_iterator_tag;
using value_type = ValueT;
using difference_type = std::ptrdiff_t;
using pointer = value_type *;
using reference = value_type &;
basic_collection_iterator() = default;
basic_collection_iterator(BaseT *B) : Base(B) {}
ValueT *operator->() const {
assert(Base && Base->CurrentEntry && "Attempted to access end iterator!");
return Base->CurrentEntry;
}
ValueT &operator*() const {
assert(Base && Base->CurrentEntry &&
"Attempted to dereference end iterator!");
return *Base->CurrentEntry;
}
operator ValueT *() const {
assert(Base && Base->CurrentEntry && "Attempted to access end iterator!");
return Base->CurrentEntry;
}
/// Note on EqualityComparable:
///
/// The iterator is not re-entrant,
/// it is meant to be used for parsing YAML on-demand
/// Once iteration started - it can point only to one entry at a time
/// hence Base.CurrentEntry and Other.Base.CurrentEntry are equal
/// iff Base and Other.Base are equal.
bool operator==(const basic_collection_iterator &Other) const {
if (Base && (Base == Other.Base)) {
assert((Base->CurrentEntry == Other.Base->CurrentEntry)
&& "Equal Bases expected to point to equal Entries");
}
return Base == Other.Base;
}
bool operator!=(const basic_collection_iterator &Other) const {
return !(Base == Other.Base);
}
basic_collection_iterator &operator++() {
assert(Base && "Attempted to advance iterator past end!");
Base->increment();
// Create an end iterator.
if (!Base->CurrentEntry)
Base = nullptr;
return *this;
}
private:
BaseT *Base = nullptr;
};
// The following two templates are used for both MappingNode and Sequence Node.
template <class CollectionType>
typename CollectionType::iterator begin(CollectionType &C) {
assert(C.IsAtBeginning && "You may only iterate over a collection once!");
C.IsAtBeginning = false;
typename CollectionType::iterator ret(&C);
++ret;
return ret;
}
template <class CollectionType> void skip(CollectionType &C) {
// TODO: support skipping from the middle of a parsed collection ;/
assert((C.IsAtBeginning || C.IsAtEnd) && "Cannot skip mid parse!");
if (C.IsAtBeginning)
for (typename CollectionType::iterator i = begin(C), e = C.end(); i != e;
++i)
i->skip();
}
/// Represents a YAML map created from either a block map for a flow map.
///
/// This parses the YAML stream as increment() is called.
///
/// Example:
/// Name: _main
/// Scope: Global
class MappingNode final : public Node {
void anchor() override;
public:
enum MappingType {
MT_Block,
MT_Flow,
MT_Inline ///< An inline mapping node is used for "[key: value]".
};
MappingNode(std::unique_ptr<Document> &D, StringRef Anchor, StringRef Tag,
MappingType MT)
: Node(NK_Mapping, D, Anchor, Tag), Type(MT) {}
friend class basic_collection_iterator<MappingNode, KeyValueNode>;
using iterator = basic_collection_iterator<MappingNode, KeyValueNode>;
template <class T> friend typename T::iterator yaml::begin(T &);
template <class T> friend void yaml::skip(T &);
iterator begin() { return yaml::begin(*this); }
iterator end() { return iterator(); }
void skip() override { yaml::skip(*this); }
static bool classof(const Node *N) {
return N->getType() == NK_Mapping;
}
private:
MappingType Type;
bool IsAtBeginning = true;
bool IsAtEnd = false;
KeyValueNode *CurrentEntry = nullptr;
void increment();
};
/// Represents a YAML sequence created from either a block sequence for a
/// flow sequence.
///
/// This parses the YAML stream as increment() is called.
///
/// Example:
/// - Hello
/// - World
class SequenceNode final : public Node {
void anchor() override;
public:
enum SequenceType {
ST_Block,
ST_Flow,
// Use for:
//
// key:
// - val1
// - val2
//
// As a BlockMappingEntry and BlockEnd are not created in this case.
ST_Indentless
};
SequenceNode(std::unique_ptr<Document> &D, StringRef Anchor, StringRef Tag,
SequenceType ST)
: Node(NK_Sequence, D, Anchor, Tag), SeqType(ST) {}
friend class basic_collection_iterator<SequenceNode, Node>;
using iterator = basic_collection_iterator<SequenceNode, Node>;
template <class T> friend typename T::iterator yaml::begin(T &);
template <class T> friend void yaml::skip(T &);
void increment();
iterator begin() { return yaml::begin(*this); }
iterator end() { return iterator(); }
void skip() override { yaml::skip(*this); }
static bool classof(const Node *N) {
return N->getType() == NK_Sequence;
}
private:
SequenceType SeqType;
bool IsAtBeginning = true;
bool IsAtEnd = false;
bool WasPreviousTokenFlowEntry = true; // Start with an imaginary ','.
Node *CurrentEntry = nullptr;
};
/// Represents an alias to a Node with an anchor.
///
/// Example:
/// *AnchorName
class AliasNode final : public Node {
void anchor() override;
public:
AliasNode(std::unique_ptr<Document> &D, StringRef Val)
: Node(NK_Alias, D, StringRef(), StringRef()), Name(Val) {}
StringRef getName() const { return Name; }
static bool classof(const Node *N) { return N->getType() == NK_Alias; }
private:
StringRef Name;
};
/// A YAML Stream is a sequence of Documents. A document contains a root
/// node.
class Document {
public:
Document(Stream &ParentStream);
/// Root for parsing a node. Returns a single node.
Node *parseBlockNode();
/// Finish parsing the current document and return true if there are
/// more. Return false otherwise.
bool skip();
/// Parse and return the root level node.
Node *getRoot() {
if (Root)
return Root;
return Root = parseBlockNode();
}
const std::map<StringRef, StringRef> &getTagMap() const { return TagMap; }
private:
friend class Node;
friend class document_iterator;
/// Stream to read tokens from.
Stream &stream;
/// Used to allocate nodes to. All are destroyed without calling their
/// destructor when the document is destroyed.
BumpPtrAllocator NodeAllocator;
/// The root node. Used to support skipping a partially parsed
/// document.
Node *Root;
/// Maps tag prefixes to their expansion.
std::map<StringRef, StringRef> TagMap;
Token &peekNext();
Token getNext();
void setError(const Twine &Message, Token &Location) const;
bool failed() const;
/// Parse %BLAH directives and return true if any were encountered.
bool parseDirectives();
/// Parse %YAML
void parseYAMLDirective();
/// Parse %TAG
void parseTAGDirective();
/// Consume the next token and error if it is not \a TK.
bool expectToken(int TK);
};
/// Iterator abstraction for Documents over a Stream.
class document_iterator {
public:
document_iterator() = default;
document_iterator(std::unique_ptr<Document> &D) : Doc(&D) {}
bool operator==(const document_iterator &Other) const {
if (isAtEnd() || Other.isAtEnd())
return isAtEnd() && Other.isAtEnd();
return Doc == Other.Doc;
}
bool operator!=(const document_iterator &Other) const {
return !(*this == Other);
}
document_iterator operator++() {
assert(Doc && "incrementing iterator past the end.");
if (!(*Doc)->skip()) {
Doc->reset(nullptr);
} else {
Stream &S = (*Doc)->stream;
Doc->reset(new Document(S));
}
return *this;
}
Document &operator*() { return *Doc->get(); }
std::unique_ptr<Document> &operator->() { return *Doc; }
private:
bool isAtEnd() const { return !Doc || !*Doc; }
std::unique_ptr<Document> *Doc = nullptr;
};
} // end namespace yaml
} // end namespace llvm
#endif // LLVM_SUPPORT_YAMLPARSER_H