glslang/SPIRV/SPVRemapper.h
LoopDawg 8004d36528 Remapper: make remapper robust against non-exiting error handlers
Remapper errors are generally fatal: there has been some unexpected situation while
parsing the SPV binary, and there is no reasonable way to carry on.  The
errorHandler() function is called in this case, which by default exits, but
it is possible to submit a handler which does not.  In that case the remapper would
carry on in a bad state.

This change ensures a graceful termination of the remap() function.

While a try {} catch {} construct would be the ideal and safe way to do this,
that's off limits for certain environments, so this tries to do the same thing
with explicit code, to catch all the bailout paths.
2017-09-20 15:19:43 -06:00

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//
// Copyright (C) 2015 LunarG, Inc.
//
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//
// Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
//
// Neither the name of 3Dlabs Inc. Ltd. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
// COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
// LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
// LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
// ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
#ifndef SPIRVREMAPPER_H
#define SPIRVREMAPPER_H
#include <string>
#include <vector>
#include <cstdlib>
#include <exception>
namespace spv {
// MSVC defines __cplusplus as an older value, even when it supports almost all of 11.
// We handle that here by making our own symbol.
#if __cplusplus >= 201103L || _MSC_VER >= 1700
# define use_cpp11 1
#endif
class spirvbin_base_t
{
public:
enum Options {
NONE = 0,
STRIP = (1<<0),
MAP_TYPES = (1<<1),
MAP_NAMES = (1<<2),
MAP_FUNCS = (1<<3),
DCE_FUNCS = (1<<4),
DCE_VARS = (1<<5),
DCE_TYPES = (1<<6),
OPT_LOADSTORE = (1<<7),
OPT_FWD_LS = (1<<8), // EXPERIMENTAL: PRODUCES INVALID SCHEMA-0 SPIRV
MAP_ALL = (MAP_TYPES | MAP_NAMES | MAP_FUNCS),
DCE_ALL = (DCE_FUNCS | DCE_VARS | DCE_TYPES),
OPT_ALL = (OPT_LOADSTORE),
ALL_BUT_STRIP = (MAP_ALL | DCE_ALL | OPT_ALL),
DO_EVERYTHING = (STRIP | ALL_BUT_STRIP)
};
};
} // namespace SPV
#if !defined (use_cpp11)
#include <cstdio>
#include <cstdint>
namespace spv {
class spirvbin_t : public spirvbin_base_t
{
public:
spirvbin_t(int /*verbose = 0*/) { }
void remap(std::vector<std::uint32_t>& /*spv*/, unsigned int /*opts = 0*/)
{
printf("Tool not compiled for C++11, which is required for SPIR-V remapping.\n");
exit(5);
}
};
} // namespace SPV
#else // defined (use_cpp11)
#include <functional>
#include <cstdint>
#include <unordered_map>
#include <unordered_set>
#include <map>
#include <set>
#include <cassert>
#include "spirv.hpp"
#include "spvIR.h"
namespace spv {
// class to hold SPIR-V binary data for remapping, DCE, and debug stripping
class spirvbin_t : public spirvbin_base_t
{
public:
spirvbin_t(int verbose = 0) : entryPoint(spv::NoResult), largestNewId(0), verbose(verbose), errorLatch(false)
{ }
virtual ~spirvbin_t() { }
// remap on an existing binary in memory
void remap(std::vector<std::uint32_t>& spv, std::uint32_t opts = DO_EVERYTHING);
// Type for error/log handler functions
typedef std::function<void(const std::string&)> errorfn_t;
typedef std::function<void(const std::string&)> logfn_t;
// Register error/log handling functions (can be lambda fn / functor / etc)
static void registerErrorHandler(errorfn_t handler) { errorHandler = handler; }
static void registerLogHandler(logfn_t handler) { logHandler = handler; }
protected:
// This can be overridden to provide other message behavior if needed
virtual void msg(int minVerbosity, int indent, const std::string& txt) const;
private:
// Local to global, or global to local ID map
typedef std::unordered_map<spv::Id, spv::Id> idmap_t;
typedef std::unordered_set<spv::Id> idset_t;
typedef std::unordered_map<spv::Id, int> blockmap_t;
void remap(std::uint32_t opts = DO_EVERYTHING);
// Map of names to IDs
typedef std::unordered_map<std::string, spv::Id> namemap_t;
typedef std::uint32_t spirword_t;
typedef std::pair<unsigned, unsigned> range_t;
typedef std::function<void(spv::Id&)> idfn_t;
typedef std::function<bool(spv::Op, unsigned start)> instfn_t;
// Special Values for ID map:
static const spv::Id unmapped; // unchanged from default value
static const spv::Id unused; // unused ID
static const int header_size; // SPIR header = 5 words
class id_iterator_t;
// For mapping type entries between different shaders
typedef std::vector<spirword_t> typeentry_t;
typedef std::map<spv::Id, typeentry_t> globaltypes_t;
// A set that preserves position order, and a reverse map
typedef std::set<int> posmap_t;
typedef std::unordered_map<spv::Id, int> posmap_rev_t;
// Maps and ID to the size of its base type, if known.
typedef std::unordered_map<spv::Id, unsigned> typesize_map_t;
// handle error
void error(const std::string& txt) const { errorLatch = true; errorHandler(txt); }
bool isConstOp(spv::Op opCode) const;
bool isTypeOp(spv::Op opCode) const;
bool isStripOp(spv::Op opCode) const;
bool isFlowCtrl(spv::Op opCode) const;
range_t literalRange(spv::Op opCode) const;
range_t typeRange(spv::Op opCode) const;
range_t constRange(spv::Op opCode) const;
unsigned typeSizeInWords(spv::Id id) const;
unsigned idTypeSizeInWords(spv::Id id) const;
spv::Id& asId(unsigned word) { return spv[word]; }
const spv::Id& asId(unsigned word) const { return spv[word]; }
spv::Op asOpCode(unsigned word) const { return opOpCode(spv[word]); }
std::uint32_t asOpCodeHash(unsigned word);
spv::Decoration asDecoration(unsigned word) const { return spv::Decoration(spv[word]); }
unsigned asWordCount(unsigned word) const { return opWordCount(spv[word]); }
spv::Id asTypeConstId(unsigned word) const { return asId(word + (isTypeOp(asOpCode(word)) ? 1 : 2)); }
unsigned idPos(spv::Id id) const;
static unsigned opWordCount(spirword_t data) { return data >> spv::WordCountShift; }
static spv::Op opOpCode(spirword_t data) { return spv::Op(data & spv::OpCodeMask); }
// Header access & set methods
spirword_t magic() const { return spv[0]; } // return magic number
spirword_t bound() const { return spv[3]; } // return Id bound from header
spirword_t bound(spirword_t b) { return spv[3] = b; };
spirword_t genmagic() const { return spv[2]; } // generator magic
spirword_t genmagic(spirword_t m) { return spv[2] = m; }
spirword_t schemaNum() const { return spv[4]; } // schema number from header
// Mapping fns: get
spv::Id localId(spv::Id id) const { return idMapL[id]; }
// Mapping fns: set
inline spv::Id localId(spv::Id id, spv::Id newId);
void countIds(spv::Id id);
// Return next unused new local ID.
// NOTE: boost::dynamic_bitset would be more efficient due to find_next(),
// which std::vector<bool> doens't have.
inline spv::Id nextUnusedId(spv::Id id);
void buildLocalMaps();
std::string literalString(unsigned word) const; // Return literal as a std::string
int literalStringWords(const std::string& str) const { return (int(str.size())+4)/4; }
bool isNewIdMapped(spv::Id newId) const { return isMapped(newId); }
bool isOldIdUnmapped(spv::Id oldId) const { return localId(oldId) == unmapped; }
bool isOldIdUnused(spv::Id oldId) const { return localId(oldId) == unused; }
bool isOldIdMapped(spv::Id oldId) const { return !isOldIdUnused(oldId) && !isOldIdUnmapped(oldId); }
bool isFunction(spv::Id oldId) const { return fnPos.find(oldId) != fnPos.end(); }
// bool matchType(const globaltypes_t& globalTypes, spv::Id lt, spv::Id gt) const;
// spv::Id findType(const globaltypes_t& globalTypes, spv::Id lt) const;
std::uint32_t hashType(unsigned typeStart) const;
spirvbin_t& process(instfn_t, idfn_t, unsigned begin = 0, unsigned end = 0);
int processInstruction(unsigned word, instfn_t, idfn_t);
void validate() const;
void mapTypeConst();
void mapFnBodies();
void optLoadStore();
void dceFuncs();
void dceVars();
void dceTypes();
void mapNames();
void foldIds(); // fold IDs to smallest space
void forwardLoadStores(); // load store forwarding (EXPERIMENTAL)
void offsetIds(); // create relative offset IDs
void applyMap(); // remap per local name map
void mapRemainder(); // map any IDs we haven't touched yet
void stripDebug(); // strip all debug info
void stripDeadRefs(); // strips debug info for now-dead references after DCE
void strip(); // remove debug symbols
std::vector<spirword_t> spv; // SPIR words
namemap_t nameMap; // ID names from OpName
// Since we want to also do binary ops, we can't use std::vector<bool>. we could use
// boost::dynamic_bitset, but we're trying to avoid a boost dependency.
typedef std::uint64_t bits_t;
std::vector<bits_t> mapped; // which new IDs have been mapped
static const int mBits = sizeof(bits_t) * 4;
bool isMapped(spv::Id id) const { return id < maxMappedId() && ((mapped[id/mBits] & (1LL<<(id%mBits))) != 0); }
void setMapped(spv::Id id) { resizeMapped(id); mapped[id/mBits] |= (1LL<<(id%mBits)); }
void resizeMapped(spv::Id id) { if (id >= maxMappedId()) mapped.resize(id/mBits+1, 0); }
size_t maxMappedId() const { return mapped.size() * mBits; }
// Add a strip range for a given instruction starting at 'start'
// Note: avoiding brace initializers to please older versions os MSVC.
void stripInst(unsigned start) { stripRange.push_back(range_t(start, start + asWordCount(start))); }
// Function start and end. use unordered_map because we'll have
// many fewer functions than IDs.
std::unordered_map<spv::Id, range_t> fnPos;
// Which functions are called, anywhere in the module, with a call count
std::unordered_map<spv::Id, int> fnCalls;
posmap_t typeConstPos; // word positions that define types & consts (ordered)
posmap_rev_t idPosR; // reverse map from IDs to positions
typesize_map_t idTypeSizeMap; // maps each ID to its type size, if known.
std::vector<spv::Id> idMapL; // ID {M}ap from {L}ocal to {G}lobal IDs
spv::Id entryPoint; // module entry point
spv::Id largestNewId; // biggest new ID we have mapped anything to
// Sections of the binary to strip, given as [begin,end)
std::vector<range_t> stripRange;
// processing options:
std::uint32_t options;
int verbose; // verbosity level
// Error latch: this is set if the error handler is ever executed. It would be better to
// use a try/catch block and throw, but that's not desired for certain environments, so
// this is the alternative.
mutable bool errorLatch;
static errorfn_t errorHandler;
static logfn_t logHandler;
};
} // namespace SPV
#endif // defined (use_cpp11)
#endif // SPIRVREMAPPER_H