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f5d3346387
For IR generated by a compiler, this is really simple: you just take the datalayout from the beginning of the file, and apply it to all the IR later in the file. For optimization testcases that don't care about the datalayout, this is also really simple: we just use the default datalayout. The complexity here comes from the fact that some LLVM tools allow overriding the datalayout: some tools have an explicit flag for this, some tools will infer a datalayout based on the code generation target. Supporting this properly required plumbing through a bunch of new machinery: we want to allow overriding the datalayout after the datalayout is parsed from the file, but before we use any information from it. Therefore, IR/bitcode parsing now has a callback to allow tools to compute the datalayout at the appropriate time. Not sure if I covered all the LLVM tools that want to use the callback. (clang? lli? Misc IR manipulation tools like llvm-link?). But this is at least enough for all the LLVM regression tests, and IR without a datalayout is not something frontends should generate. This change had some sort of weird effects for certain CodeGen regression tests: if the datalayout is overridden with a datalayout with a different program or stack address space, we now parse IR based on the overridden datalayout, instead of the one written in the file (or the default one, if none is specified). This broke a few AVR tests, and one AMDGPU test. Outside the CodeGen tests I mentioned, the test changes are all just fixing CHECK lines and moving around datalayout lines in weird places. Differential Revision: https://reviews.llvm.org/D78403
283 lines
11 KiB
C++
283 lines
11 KiB
C++
//===- llvm/Bitcode/BitcodeReader.h - Bitcode reader ------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This header defines interfaces to read LLVM bitcode files/streams.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_BITCODE_BITCODEREADER_H
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#define LLVM_BITCODE_BITCODEREADER_H
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#include "llvm/ADT/ArrayRef.h"
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#include "llvm/ADT/StringRef.h"
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#include "llvm/Bitstream/BitCodes.h"
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#include "llvm/IR/ModuleSummaryIndex.h"
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#include "llvm/Support/Endian.h"
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#include "llvm/Support/Error.h"
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#include "llvm/Support/ErrorOr.h"
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#include "llvm/Support/MemoryBuffer.h"
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#include <cstdint>
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#include <memory>
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#include <string>
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#include <system_error>
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#include <vector>
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namespace llvm {
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class LLVMContext;
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class Module;
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typedef llvm::function_ref<Optional<std::string>(StringRef)>
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DataLayoutCallbackTy;
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// These functions are for converting Expected/Error values to
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// ErrorOr/std::error_code for compatibility with legacy clients. FIXME:
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// Remove these functions once no longer needed by the C and libLTO APIs.
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std::error_code errorToErrorCodeAndEmitErrors(LLVMContext &Ctx, Error Err);
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template <typename T>
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ErrorOr<T> expectedToErrorOrAndEmitErrors(LLVMContext &Ctx, Expected<T> Val) {
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if (!Val)
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return errorToErrorCodeAndEmitErrors(Ctx, Val.takeError());
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return std::move(*Val);
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}
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struct BitcodeFileContents;
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/// Basic information extracted from a bitcode module to be used for LTO.
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struct BitcodeLTOInfo {
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bool IsThinLTO;
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bool HasSummary;
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bool EnableSplitLTOUnit;
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};
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/// Represents a module in a bitcode file.
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class BitcodeModule {
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// This covers the identification (if present) and module blocks.
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ArrayRef<uint8_t> Buffer;
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StringRef ModuleIdentifier;
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// The string table used to interpret this module.
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StringRef Strtab;
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// The bitstream location of the IDENTIFICATION_BLOCK.
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uint64_t IdentificationBit;
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// The bitstream location of this module's MODULE_BLOCK.
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uint64_t ModuleBit;
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BitcodeModule(ArrayRef<uint8_t> Buffer, StringRef ModuleIdentifier,
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uint64_t IdentificationBit, uint64_t ModuleBit)
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: Buffer(Buffer), ModuleIdentifier(ModuleIdentifier),
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IdentificationBit(IdentificationBit), ModuleBit(ModuleBit) {}
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// Calls the ctor.
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friend Expected<BitcodeFileContents>
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getBitcodeFileContents(MemoryBufferRef Buffer);
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Expected<std::unique_ptr<Module>>
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getModuleImpl(LLVMContext &Context, bool MaterializeAll,
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bool ShouldLazyLoadMetadata, bool IsImporting,
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DataLayoutCallbackTy DataLayoutCallback);
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public:
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StringRef getBuffer() const {
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return StringRef((const char *)Buffer.begin(), Buffer.size());
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}
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StringRef getStrtab() const { return Strtab; }
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StringRef getModuleIdentifier() const { return ModuleIdentifier; }
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/// Read the bitcode module and prepare for lazy deserialization of function
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/// bodies. If ShouldLazyLoadMetadata is true, lazily load metadata as well.
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/// If IsImporting is true, this module is being parsed for ThinLTO
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/// importing into another module.
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Expected<std::unique_ptr<Module>> getLazyModule(LLVMContext &Context,
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bool ShouldLazyLoadMetadata,
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bool IsImporting);
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/// Read the entire bitcode module and return it.
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Expected<std::unique_ptr<Module>> parseModule(
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LLVMContext &Context, DataLayoutCallbackTy DataLayoutCallback =
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[](StringRef) { return None; });
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/// Returns information about the module to be used for LTO: whether to
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/// compile with ThinLTO, and whether it has a summary.
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Expected<BitcodeLTOInfo> getLTOInfo();
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/// Parse the specified bitcode buffer, returning the module summary index.
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Expected<std::unique_ptr<ModuleSummaryIndex>> getSummary();
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/// Parse the specified bitcode buffer and merge its module summary index
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/// into CombinedIndex.
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Error readSummary(ModuleSummaryIndex &CombinedIndex, StringRef ModulePath,
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uint64_t ModuleId);
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};
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struct BitcodeFileContents {
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std::vector<BitcodeModule> Mods;
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StringRef Symtab, StrtabForSymtab;
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};
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/// Returns the contents of a bitcode file. This includes the raw contents of
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/// the symbol table embedded in the bitcode file. Clients which require a
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/// symbol table should prefer to use irsymtab::read instead of this function
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/// because it creates a reader for the irsymtab and handles upgrading bitcode
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/// files without a symbol table or with an old symbol table.
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Expected<BitcodeFileContents> getBitcodeFileContents(MemoryBufferRef Buffer);
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/// Returns a list of modules in the specified bitcode buffer.
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Expected<std::vector<BitcodeModule>>
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getBitcodeModuleList(MemoryBufferRef Buffer);
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/// Read the header of the specified bitcode buffer and prepare for lazy
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/// deserialization of function bodies. If ShouldLazyLoadMetadata is true,
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/// lazily load metadata as well. If IsImporting is true, this module is
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/// being parsed for ThinLTO importing into another module.
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Expected<std::unique_ptr<Module>>
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getLazyBitcodeModule(MemoryBufferRef Buffer, LLVMContext &Context,
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bool ShouldLazyLoadMetadata = false,
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bool IsImporting = false);
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/// Like getLazyBitcodeModule, except that the module takes ownership of
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/// the memory buffer if successful. If successful, this moves Buffer. On
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/// error, this *does not* move Buffer. If IsImporting is true, this module is
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/// being parsed for ThinLTO importing into another module.
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Expected<std::unique_ptr<Module>> getOwningLazyBitcodeModule(
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std::unique_ptr<MemoryBuffer> &&Buffer, LLVMContext &Context,
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bool ShouldLazyLoadMetadata = false, bool IsImporting = false);
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/// Read the header of the specified bitcode buffer and extract just the
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/// triple information. If successful, this returns a string. On error, this
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/// returns "".
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Expected<std::string> getBitcodeTargetTriple(MemoryBufferRef Buffer);
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/// Return true if \p Buffer contains a bitcode file with ObjC code (category
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/// or class) in it.
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Expected<bool> isBitcodeContainingObjCCategory(MemoryBufferRef Buffer);
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/// Read the header of the specified bitcode buffer and extract just the
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/// producer string information. If successful, this returns a string. On
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/// error, this returns "".
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Expected<std::string> getBitcodeProducerString(MemoryBufferRef Buffer);
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/// Read the specified bitcode file, returning the module.
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Expected<std::unique_ptr<Module>> parseBitcodeFile(
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MemoryBufferRef Buffer, LLVMContext &Context,
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DataLayoutCallbackTy DataLayoutCallback = [](StringRef) {
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return None;
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});
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/// Returns LTO information for the specified bitcode file.
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Expected<BitcodeLTOInfo> getBitcodeLTOInfo(MemoryBufferRef Buffer);
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/// Parse the specified bitcode buffer, returning the module summary index.
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Expected<std::unique_ptr<ModuleSummaryIndex>>
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getModuleSummaryIndex(MemoryBufferRef Buffer);
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/// Parse the specified bitcode buffer and merge the index into CombinedIndex.
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Error readModuleSummaryIndex(MemoryBufferRef Buffer,
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ModuleSummaryIndex &CombinedIndex,
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uint64_t ModuleId);
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/// Parse the module summary index out of an IR file and return the module
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/// summary index object if found, or an empty summary if not. If Path refers
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/// to an empty file and IgnoreEmptyThinLTOIndexFile is true, then
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/// this function will return nullptr.
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Expected<std::unique_ptr<ModuleSummaryIndex>>
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getModuleSummaryIndexForFile(StringRef Path,
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bool IgnoreEmptyThinLTOIndexFile = false);
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/// isBitcodeWrapper - Return true if the given bytes are the magic bytes
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/// for an LLVM IR bitcode wrapper.
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inline bool isBitcodeWrapper(const unsigned char *BufPtr,
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const unsigned char *BufEnd) {
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// See if you can find the hidden message in the magic bytes :-).
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// (Hint: it's a little-endian encoding.)
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return BufPtr != BufEnd &&
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BufPtr[0] == 0xDE &&
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BufPtr[1] == 0xC0 &&
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BufPtr[2] == 0x17 &&
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BufPtr[3] == 0x0B;
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}
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/// isRawBitcode - Return true if the given bytes are the magic bytes for
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/// raw LLVM IR bitcode (without a wrapper).
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inline bool isRawBitcode(const unsigned char *BufPtr,
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const unsigned char *BufEnd) {
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// These bytes sort of have a hidden message, but it's not in
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// little-endian this time, and it's a little redundant.
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return BufPtr != BufEnd &&
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BufPtr[0] == 'B' &&
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BufPtr[1] == 'C' &&
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BufPtr[2] == 0xc0 &&
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BufPtr[3] == 0xde;
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}
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/// isBitcode - Return true if the given bytes are the magic bytes for
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/// LLVM IR bitcode, either with or without a wrapper.
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inline bool isBitcode(const unsigned char *BufPtr,
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const unsigned char *BufEnd) {
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return isBitcodeWrapper(BufPtr, BufEnd) ||
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isRawBitcode(BufPtr, BufEnd);
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}
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/// SkipBitcodeWrapperHeader - Some systems wrap bc files with a special
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/// header for padding or other reasons. The format of this header is:
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///
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/// struct bc_header {
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/// uint32_t Magic; // 0x0B17C0DE
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/// uint32_t Version; // Version, currently always 0.
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/// uint32_t BitcodeOffset; // Offset to traditional bitcode file.
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/// uint32_t BitcodeSize; // Size of traditional bitcode file.
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/// ... potentially other gunk ...
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/// };
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///
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/// This function is called when we find a file with a matching magic number.
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/// In this case, skip down to the subsection of the file that is actually a
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/// BC file.
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/// If 'VerifyBufferSize' is true, check that the buffer is large enough to
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/// contain the whole bitcode file.
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inline bool SkipBitcodeWrapperHeader(const unsigned char *&BufPtr,
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const unsigned char *&BufEnd,
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bool VerifyBufferSize) {
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// Must contain the offset and size field!
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if (unsigned(BufEnd - BufPtr) < BWH_SizeField + 4)
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return true;
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unsigned Offset = support::endian::read32le(&BufPtr[BWH_OffsetField]);
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unsigned Size = support::endian::read32le(&BufPtr[BWH_SizeField]);
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uint64_t BitcodeOffsetEnd = (uint64_t)Offset + (uint64_t)Size;
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// Verify that Offset+Size fits in the file.
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if (VerifyBufferSize && BitcodeOffsetEnd > uint64_t(BufEnd-BufPtr))
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return true;
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BufPtr += Offset;
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BufEnd = BufPtr+Size;
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return false;
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}
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APInt readWideAPInt(ArrayRef<uint64_t> Vals, unsigned TypeBits);
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const std::error_category &BitcodeErrorCategory();
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enum class BitcodeError { CorruptedBitcode = 1 };
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inline std::error_code make_error_code(BitcodeError E) {
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return std::error_code(static_cast<int>(E), BitcodeErrorCategory());
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}
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} // end namespace llvm
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namespace std {
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template <> struct is_error_code_enum<llvm::BitcodeError> : std::true_type {};
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} // end namespace std
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#endif // LLVM_BITCODE_BITCODEREADER_H
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