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[llvm-core.git] / include / llvm / Support / BinaryStreamArray.h
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1 //===- BinaryStreamArray.h - Array backed by an arbitrary stream *- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
9 #ifndef LLVM_SUPPORT_BINARYSTREAMARRAY_H
10 #define LLVM_SUPPORT_BINARYSTREAMARRAY_H
12 #include "llvm/ADT/ArrayRef.h"
13 #include "llvm/ADT/iterator.h"
14 #include "llvm/Support/BinaryStreamRef.h"
15 #include "llvm/Support/Error.h"
16 #include <cassert>
17 #include <cstdint>
19 /// Lightweight arrays that are backed by an arbitrary BinaryStream. This file
20 /// provides two different array implementations.
21 ///
22 /// VarStreamArray - Arrays of variable length records. The user specifies
23 /// an Extractor type that can extract a record from a given offset and
24 /// return the number of bytes consumed by the record.
25 ///
26 /// FixedStreamArray - Arrays of fixed length records. This is similar in
27 /// spirit to ArrayRef<T>, but since it is backed by a BinaryStream, the
28 /// elements of the array need not be laid out in contiguous memory.
29 namespace llvm {
31 /// VarStreamArrayExtractor is intended to be specialized to provide customized
32 /// extraction logic. On input it receives a BinaryStreamRef pointing to the
33 /// beginning of the next record, but where the length of the record is not yet
34 /// known. Upon completion, it should return an appropriate Error instance if
35 /// a record could not be extracted, or if one could be extracted it should
36 /// return success and set Len to the number of bytes this record occupied in
37 /// the underlying stream, and it should fill out the fields of the value type
38 /// Item appropriately to represent the current record.
39 ///
40 /// You can specialize this template for your own custom value types to avoid
41 /// having to specify a second template argument to VarStreamArray (documented
42 /// below).
43 template <typename T> struct VarStreamArrayExtractor {
44 // Method intentionally deleted. You must provide an explicit specialization
45 // with the following method implemented.
46 Error operator()(BinaryStreamRef Stream, uint32_t &Len,
47 T &Item) const = delete;
50 /// VarStreamArray represents an array of variable length records backed by a
51 /// stream. This could be a contiguous sequence of bytes in memory, it could
52 /// be a file on disk, or it could be a PDB stream where bytes are stored as
53 /// discontiguous blocks in a file. Usually it is desirable to treat arrays
54 /// as contiguous blocks of memory, but doing so with large PDB files, for
55 /// example, could mean allocating huge amounts of memory just to allow
56 /// re-ordering of stream data to be contiguous before iterating over it. By
57 /// abstracting this out, we need not duplicate this memory, and we can
58 /// iterate over arrays in arbitrarily formatted streams. Elements are parsed
59 /// lazily on iteration, so there is no upfront cost associated with building
60 /// or copying a VarStreamArray, no matter how large it may be.
61 ///
62 /// You create a VarStreamArray by specifying a ValueType and an Extractor type.
63 /// If you do not specify an Extractor type, you are expected to specialize
64 /// VarStreamArrayExtractor<T> for your ValueType.
65 ///
66 /// By default an Extractor is default constructed in the class, but in some
67 /// cases you might find it useful for an Extractor to maintain state across
68 /// extractions. In this case you can provide your own Extractor through a
69 /// secondary constructor. The following examples show various ways of
70 /// creating a VarStreamArray.
71 ///
72 /// // Will use VarStreamArrayExtractor<MyType> as the extractor.
73 /// VarStreamArray<MyType> MyTypeArray;
74 ///
75 /// // Will use a default-constructed MyExtractor as the extractor.
76 /// VarStreamArray<MyType, MyExtractor> MyTypeArray2;
77 ///
78 /// // Will use the specific instance of MyExtractor provided.
79 /// // MyExtractor need not be default-constructible in this case.
80 /// MyExtractor E(SomeContext);
81 /// VarStreamArray<MyType, MyExtractor> MyTypeArray3(E);
82 ///
84 template <typename ValueType, typename Extractor> class VarStreamArrayIterator;
86 template <typename ValueType,
87 typename Extractor = VarStreamArrayExtractor<ValueType>>
88 class VarStreamArray {
89 friend class VarStreamArrayIterator<ValueType, Extractor>;
91 public:
92 typedef VarStreamArrayIterator<ValueType, Extractor> Iterator;
94 VarStreamArray() = default;
96 explicit VarStreamArray(const Extractor &E) : E(E) {}
98 explicit VarStreamArray(BinaryStreamRef Stream, uint32_t Skew = 0)
99 : Stream(Stream), Skew(Skew) {}
101 VarStreamArray(BinaryStreamRef Stream, const Extractor &E, uint32_t Skew = 0)
102 : Stream(Stream), E(E), Skew(Skew) {}
104 Iterator begin(bool *HadError = nullptr) const {
105 return Iterator(*this, E, Skew, nullptr);
108 bool valid() const { return Stream.valid(); }
110 uint32_t skew() const { return Skew; }
111 Iterator end() const { return Iterator(E); }
113 bool empty() const { return Stream.getLength() == 0; }
115 VarStreamArray<ValueType, Extractor> substream(uint32_t Begin,
116 uint32_t End) const {
117 assert(Begin >= Skew);
118 // We should never cut off the beginning of the stream since it might be
119 // skewed, meaning the initial bytes are important.
120 BinaryStreamRef NewStream = Stream.slice(0, End);
121 return {NewStream, E, Begin};
124 /// given an offset into the array's underlying stream, return an
125 /// iterator to the record at that offset. This is considered unsafe
126 /// since the behavior is undefined if \p Offset does not refer to the
127 /// beginning of a valid record.
128 Iterator at(uint32_t Offset) const {
129 return Iterator(*this, E, Offset, nullptr);
132 const Extractor &getExtractor() const { return E; }
133 Extractor &getExtractor() { return E; }
135 BinaryStreamRef getUnderlyingStream() const { return Stream; }
136 void setUnderlyingStream(BinaryStreamRef S, uint32_t Skew = 0) {
137 Stream = S;
138 this->Skew = Skew;
141 void drop_front() { Skew += begin()->length(); }
143 private:
144 BinaryStreamRef Stream;
145 Extractor E;
146 uint32_t Skew;
149 template <typename ValueType, typename Extractor>
150 class VarStreamArrayIterator
151 : public iterator_facade_base<VarStreamArrayIterator<ValueType, Extractor>,
152 std::forward_iterator_tag, ValueType> {
153 typedef VarStreamArrayIterator<ValueType, Extractor> IterType;
154 typedef VarStreamArray<ValueType, Extractor> ArrayType;
156 public:
157 VarStreamArrayIterator(const ArrayType &Array, const Extractor &E,
158 uint32_t Offset, bool *HadError)
159 : IterRef(Array.Stream.drop_front(Offset)), Extract(E),
160 Array(&Array), AbsOffset(Offset), HadError(HadError) {
161 if (IterRef.getLength() == 0)
162 moveToEnd();
163 else {
164 auto EC = Extract(IterRef, ThisLen, ThisValue);
165 if (EC) {
166 consumeError(std::move(EC));
167 markError();
172 VarStreamArrayIterator() = default;
173 explicit VarStreamArrayIterator(const Extractor &E) : Extract(E) {}
174 ~VarStreamArrayIterator() = default;
176 bool operator==(const IterType &R) const {
177 if (Array && R.Array) {
178 // Both have a valid array, make sure they're same.
179 assert(Array == R.Array);
180 return IterRef == R.IterRef;
183 // Both iterators are at the end.
184 if (!Array && !R.Array)
185 return true;
187 // One is not at the end and one is.
188 return false;
191 const ValueType &operator*() const {
192 assert(Array && !HasError);
193 return ThisValue;
196 ValueType &operator*() {
197 assert(Array && !HasError);
198 return ThisValue;
201 IterType &operator+=(unsigned N) {
202 for (unsigned I = 0; I < N; ++I) {
203 // We are done with the current record, discard it so that we are
204 // positioned at the next record.
205 AbsOffset += ThisLen;
206 IterRef = IterRef.drop_front(ThisLen);
207 if (IterRef.getLength() == 0) {
208 // There is nothing after the current record, we must make this an end
209 // iterator.
210 moveToEnd();
211 } else {
212 // There is some data after the current record.
213 auto EC = Extract(IterRef, ThisLen, ThisValue);
214 if (EC) {
215 consumeError(std::move(EC));
216 markError();
217 } else if (ThisLen == 0) {
218 // An empty record? Make this an end iterator.
219 moveToEnd();
223 return *this;
226 uint32_t offset() const { return AbsOffset; }
227 uint32_t getRecordLength() const { return ThisLen; }
229 private:
230 void moveToEnd() {
231 Array = nullptr;
232 ThisLen = 0;
234 void markError() {
235 moveToEnd();
236 HasError = true;
237 if (HadError != nullptr)
238 *HadError = true;
241 ValueType ThisValue;
242 BinaryStreamRef IterRef;
243 Extractor Extract;
244 const ArrayType *Array{nullptr};
245 uint32_t ThisLen{0};
246 uint32_t AbsOffset{0};
247 bool HasError{false};
248 bool *HadError{nullptr};
251 template <typename T> class FixedStreamArrayIterator;
253 /// FixedStreamArray is similar to VarStreamArray, except with each record
254 /// having a fixed-length. As with VarStreamArray, there is no upfront
255 /// cost associated with building or copying a FixedStreamArray, as the
256 /// memory for each element is not read from the backing stream until that
257 /// element is iterated.
258 template <typename T> class FixedStreamArray {
259 friend class FixedStreamArrayIterator<T>;
261 public:
262 typedef FixedStreamArrayIterator<T> Iterator;
264 FixedStreamArray() = default;
265 explicit FixedStreamArray(BinaryStreamRef Stream) : Stream(Stream) {
266 assert(Stream.getLength() % sizeof(T) == 0);
269 bool operator==(const FixedStreamArray<T> &Other) const {
270 return Stream == Other.Stream;
273 bool operator!=(const FixedStreamArray<T> &Other) const {
274 return !(*this == Other);
277 FixedStreamArray &operator=(const FixedStreamArray &) = default;
279 const T &operator[](uint32_t Index) const {
280 assert(Index < size());
281 uint32_t Off = Index * sizeof(T);
282 ArrayRef<uint8_t> Data;
283 if (auto EC = Stream.readBytes(Off, sizeof(T), Data)) {
284 assert(false && "Unexpected failure reading from stream");
285 // This should never happen since we asserted that the stream length was
286 // an exact multiple of the element size.
287 consumeError(std::move(EC));
289 assert(llvm::alignmentAdjustment(Data.data(), alignof(T)) == 0);
290 return *reinterpret_cast<const T *>(Data.data());
293 uint32_t size() const { return Stream.getLength() / sizeof(T); }
295 bool empty() const { return size() == 0; }
297 FixedStreamArrayIterator<T> begin() const {
298 return FixedStreamArrayIterator<T>(*this, 0);
301 FixedStreamArrayIterator<T> end() const {
302 return FixedStreamArrayIterator<T>(*this, size());
305 const T &front() const { return *begin(); }
306 const T &back() const {
307 FixedStreamArrayIterator<T> I = end();
308 return *(--I);
311 BinaryStreamRef getUnderlyingStream() const { return Stream; }
313 private:
314 BinaryStreamRef Stream;
317 template <typename T>
318 class FixedStreamArrayIterator
319 : public iterator_facade_base<FixedStreamArrayIterator<T>,
320 std::random_access_iterator_tag, const T> {
322 public:
323 FixedStreamArrayIterator(const FixedStreamArray<T> &Array, uint32_t Index)
324 : Array(Array), Index(Index) {}
326 FixedStreamArrayIterator<T> &
327 operator=(const FixedStreamArrayIterator<T> &Other) {
328 Array = Other.Array;
329 Index = Other.Index;
330 return *this;
333 const T &operator*() const { return Array[Index]; }
334 const T &operator*() { return Array[Index]; }
336 bool operator==(const FixedStreamArrayIterator<T> &R) const {
337 assert(Array == R.Array);
338 return (Index == R.Index) && (Array == R.Array);
341 FixedStreamArrayIterator<T> &operator+=(std::ptrdiff_t N) {
342 Index += N;
343 return *this;
346 FixedStreamArrayIterator<T> &operator-=(std::ptrdiff_t N) {
347 assert(std::ptrdiff_t(Index) >= N);
348 Index -= N;
349 return *this;
352 std::ptrdiff_t operator-(const FixedStreamArrayIterator<T> &R) const {
353 assert(Array == R.Array);
354 assert(Index >= R.Index);
355 return Index - R.Index;
358 bool operator<(const FixedStreamArrayIterator<T> &RHS) const {
359 assert(Array == RHS.Array);
360 return Index < RHS.Index;
363 private:
364 FixedStreamArray<T> Array;
365 uint32_t Index;
368 } // namespace llvm
370 #endif // LLVM_SUPPORT_BINARYSTREAMARRAY_H