SPIRV-Tools/include/spirv-tools/optimizer.hpp
Steven Perron 79a00649b4 Allow pointers to pointers in logical addressing mode.
A few optimizations are updates to handle code that is suppose to be
using the logical addressing mode, but still has variables that contain
pointers as long as the pointer are to opaque objects.  This is called
"relaxed logical addressing".

|Instruction::GetBaseAddress| will check that pointers that are use meet
the relaxed logical addressing rules.  Optimization that now handle
relaxed logical addressing instead of logical addressing are:

 - aggressive dead-code elimination
 - local access chain convert
 - local store elimination passes.
2017-12-19 14:29:14 -05:00

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C++

// Copyright (c) 2016 Google Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#ifndef SPIRV_TOOLS_OPTIMIZER_HPP_
#define SPIRV_TOOLS_OPTIMIZER_HPP_
#include <memory>
#include <string>
#include <unordered_map>
#include <vector>
#include "libspirv.hpp"
namespace spvtools {
// C++ interface for SPIR-V optimization functionalities. It wraps the context
// (including target environment and the corresponding SPIR-V grammar) and
// provides methods for registering optimization passes and optimizing.
//
// Instances of this class provides basic thread-safety guarantee.
class Optimizer {
public:
// The token for an optimization pass. It is returned via one of the
// Create*Pass() standalone functions at the end of this header file and
// consumed by the RegisterPass() method. Tokens are one-time objects that
// only support move; copying is not allowed.
struct PassToken {
struct Impl; // Opaque struct for holding inernal data.
PassToken(std::unique_ptr<Impl>);
// Tokens can only be moved. Copying is disabled.
PassToken(const PassToken&) = delete;
PassToken(PassToken&&);
PassToken& operator=(const PassToken&) = delete;
PassToken& operator=(PassToken&&);
~PassToken();
std::unique_ptr<Impl> impl_; // Unique pointer to internal data.
};
// Constructs an instance with the given target |env|, which is used to decode
// the binaries to be optimized later.
//
// The constructed instance will have an empty message consumer, which just
// ignores all messages from the library. Use SetMessageConsumer() to supply
// one if messages are of concern.
explicit Optimizer(spv_target_env env);
// Disables copy/move constructor/assignment operations.
Optimizer(const Optimizer&) = delete;
Optimizer(Optimizer&&) = delete;
Optimizer& operator=(const Optimizer&) = delete;
Optimizer& operator=(Optimizer&&) = delete;
// Destructs this instance.
~Optimizer();
// Sets the message consumer to the given |consumer|. The |consumer| will be
// invoked once for each message communicated from the library.
void SetMessageConsumer(MessageConsumer consumer);
// Registers the given |pass| to this optimizer. Passes will be run in the
// exact order of registration. The token passed in will be consumed by this
// method.
Optimizer& RegisterPass(PassToken&& pass);
// Registers passes that attempt to improve performance of generated code.
// This sequence of passes is subject to constant review and will change
// from time to time.
Optimizer& RegisterPerformancePasses();
// Registers passes that attempt to improve the size of generated code.
// This sequence of passes is subject to constant review and will change
// from time to time.
Optimizer& RegisterSizePasses();
// Registers passes that attempt to legalize the generated code.
//
// Note: this recipe is specially for legalizing SPIR-V. It should be used
// by compilers after translating HLSL source code literally. It should
// *not* be used by general workloads for performance or size improvement.
//
// This sequence of passes is subject to constant review and will change
// from time to time.
Optimizer& RegisterLegalizationPasses();
// Optimizes the given SPIR-V module |original_binary| and writes the
// optimized binary into |optimized_binary|.
// Returns true on successful optimization, whether or not the module is
// modified. Returns false if errors occur when processing |original_binary|
// using any of the registered passes. In that case, no further passes are
// executed and the contents in |optimized_binary| may be invalid.
//
// It's allowed to alias |original_binary| to the start of |optimized_binary|.
bool Run(const uint32_t* original_binary, size_t original_binary_size,
std::vector<uint32_t>* optimized_binary) const;
// Returns a vector of strings with all the pass names added to this
// optimizer's pass manager. These strings are valid until the associated
// pass manager is destroyed.
std::vector<const char*> GetPassNames() const;
private:
struct Impl; // Opaque struct for holding internal data.
std::unique_ptr<Impl> impl_; // Unique pointer to internal data.
};
// Creates a null pass.
// A null pass does nothing to the SPIR-V module to be optimized.
Optimizer::PassToken CreateNullPass();
// Creates a strip-debug-info pass.
// A strip-debug-info pass removes all debug instructions (as documented in
// Section 3.32.2 of the SPIR-V spec) of the SPIR-V module to be optimized.
Optimizer::PassToken CreateStripDebugInfoPass();
// Creates an eliminate-dead-functions pass.
// An eliminate-dead-functions pass will remove all functions that are not in
// the call trees rooted at entry points and exported functions. These
// functions are not needed because they will never be called.
Optimizer::PassToken CreateEliminateDeadFunctionsPass();
// Creates a set-spec-constant-default-value pass from a mapping from spec-ids
// to the default values in the form of string.
// A set-spec-constant-default-value pass sets the default values for the
// spec constants that have SpecId decorations (i.e., those defined by
// OpSpecConstant{|True|False} instructions).
Optimizer::PassToken CreateSetSpecConstantDefaultValuePass(
const std::unordered_map<uint32_t, std::string>& id_value_map);
// Creates a set-spec-constant-default-value pass from a mapping from spec-ids
// to the default values in the form of bit pattern.
// A set-spec-constant-default-value pass sets the default values for the
// spec constants that have SpecId decorations (i.e., those defined by
// OpSpecConstant{|True|False} instructions).
Optimizer::PassToken CreateSetSpecConstantDefaultValuePass(
const std::unordered_map<uint32_t, std::vector<uint32_t>>& id_value_map);
// Creates a flatten-decoration pass.
// A flatten-decoration pass replaces grouped decorations with equivalent
// ungrouped decorations. That is, it replaces each OpDecorationGroup
// instruction and associated OpGroupDecorate and OpGroupMemberDecorate
// instructions with equivalent OpDecorate and OpMemberDecorate instructions.
// The pass does not attempt to preserve debug information for instructions
// it removes.
Optimizer::PassToken CreateFlattenDecorationPass();
// Creates a freeze-spec-constant-value pass.
// A freeze-spec-constant pass specializes the value of spec constants to
// their default values. This pass only processes the spec constants that have
// SpecId decorations (defined by OpSpecConstant, OpSpecConstantTrue, or
// OpSpecConstantFalse instructions) and replaces them with their normal
// counterparts (OpConstant, OpConstantTrue, or OpConstantFalse). The
// corresponding SpecId annotation instructions will also be removed. This
// pass does not fold the newly added normal constants and does not process
// other spec constants defined by OpSpecConstantComposite or
// OpSpecConstantOp.
Optimizer::PassToken CreateFreezeSpecConstantValuePass();
// Creates a fold-spec-constant-op-and-composite pass.
// A fold-spec-constant-op-and-composite pass folds spec constants defined by
// OpSpecConstantOp or OpSpecConstantComposite instruction, to normal Constants
// defined by OpConstantTrue, OpConstantFalse, OpConstant, OpConstantNull, or
// OpConstantComposite instructions. Note that spec constants defined with
// OpSpecConstant, OpSpecConstantTrue, or OpSpecConstantFalse instructions are
// not handled, as these instructions indicate their value are not determined
// and can be changed in future. A spec constant is foldable if all of its
// value(s) can be determined from the module. E.g., an integer spec constant
// defined with OpSpecConstantOp instruction can be folded if its value won't
// change later. This pass will replace the original OpSpecContantOp instruction
// with an OpConstant instruction. When folding composite spec constants,
// new instructions may be inserted to define the components of the composite
// constant first, then the original spec constants will be replaced by
// OpConstantComposite instructions.
//
// There are some operations not supported yet:
// OpSConvert, OpFConvert, OpQuantizeToF16 and
// all the operations under Kernel capability.
// TODO(qining): Add support for the operations listed above.
Optimizer::PassToken CreateFoldSpecConstantOpAndCompositePass();
// Creates a unify-constant pass.
// A unify-constant pass de-duplicates the constants. Constants with the exact
// same value and identical form will be unified and only one constant will
// be kept for each unique pair of type and value.
// There are several cases not handled by this pass:
// 1) Constants defined by OpConstantNull instructions (null constants) and
// constants defined by OpConstantFalse, OpConstant or OpConstantComposite
// with value 0 (zero-valued normal constants) are not considered equivalent.
// So null constants won't be used to replace zero-valued normal constants,
// vice versa.
// 2) Whenever there are decorations to the constant's result id id, the
// constant won't be handled, which means, it won't be used to replace any
// other constants, neither can other constants replace it.
// 3) NaN in float point format with different bit patterns are not unified.
Optimizer::PassToken CreateUnifyConstantPass();
// Creates a eliminate-dead-constant pass.
// A eliminate-dead-constant pass removes dead constants, including normal
// contants defined by OpConstant, OpConstantComposite, OpConstantTrue, or
// OpConstantFalse and spec constants defined by OpSpecConstant,
// OpSpecConstantComposite, OpSpecConstantTrue, OpSpecConstantFalse or
// OpSpecConstantOp.
Optimizer::PassToken CreateEliminateDeadConstantPass();
// Creates a strength-reduction pass.
// A strength-reduction pass will look for opportunities to replace an
// instruction with an equivalent and less expensive one. For example,
// multiplying by a power of 2 can be replaced by a bit shift.
Optimizer::PassToken CreateStrengthReductionPass();
// Creates a block merge pass.
// This pass searches for blocks with a single Branch to a block with no
// other predecessors and merges the blocks into a single block. Continue
// blocks and Merge blocks are not candidates for the second block.
//
// The pass is most useful after Dead Branch Elimination, which can leave
// such sequences of blocks. Merging them makes subsequent passes more
// effective, such as single block local store-load elimination.
//
// While this pass reduces the number of occurrences of this sequence, at
// this time it does not guarantee all such sequences are eliminated.
//
// Presence of phi instructions can inhibit this optimization. Handling
// these is left for future improvements.
Optimizer::PassToken CreateBlockMergePass();
// Creates an exhaustive inline pass.
// An exhaustive inline pass attempts to exhaustively inline all function
// calls in all functions in an entry point call tree. The intent is to enable,
// albeit through brute force, analysis and optimization across function
// calls by subsequent optimization passes. As the inlining is exhaustive,
// there is no attempt to optimize for size or runtime performance. Functions
// that are not in the call tree of an entry point are not changed.
Optimizer::PassToken CreateInlineExhaustivePass();
// Creates an opaque inline pass.
// An opaque inline pass inlines all function calls in all functions in all
// entry point call trees where the called function contains an opaque type
// in either its parameter types or return type. An opaque type is currently
// defined as Image, Sampler or SampledImage. The intent is to enable, albeit
// through brute force, analysis and optimization across these function calls
// by subsequent passes in order to remove the storing of opaque types which is
// not legal in Vulkan. Functions that are not in the call tree of an entry
// point are not changed.
Optimizer::PassToken CreateInlineOpaquePass();
// Creates a single-block local variable load/store elimination pass.
// For every entry point function, do single block memory optimization of
// function variables referenced only with non-access-chain loads and stores.
// For each targeted variable load, if previous store to that variable in the
// block, replace the load's result id with the value id of the store.
// If previous load within the block, replace the current load's result id
// with the previous load's result id. In either case, delete the current
// load. Finally, check if any remaining stores are useless, and delete store
// and variable if possible.
//
// The presence of access chain references and function calls can inhibit
// the above optimization.
//
// Only modules with relaxed logical addressing (see opt/instruction.h) are
// currently processed.
//
// This pass is most effective if preceeded by Inlining and
// LocalAccessChainConvert. This pass will reduce the work needed to be done
// by LocalSingleStoreElim and LocalMultiStoreElim.
//
// Only functions in the call tree of an entry point are processed.
Optimizer::PassToken CreateLocalSingleBlockLoadStoreElimPass();
// Create dead branch elimination pass.
// For each entry point function, this pass will look for SelectionMerge
// BranchConditionals with constant condition and convert to a Branch to
// the indicated label. It will delete resulting dead blocks.
//
// For all phi functions in merge block, replace all uses with the id
// corresponding to the living predecessor.
//
// This pass only works on shaders (guaranteed to have structured control
// flow). Note that some such branches and blocks may be left to avoid
// creating invalid control flow. Improving this is left to future work.
//
// This pass is most effective when preceeded by passes which eliminate
// local loads and stores, effectively propagating constant values where
// possible.
Optimizer::PassToken CreateDeadBranchElimPass();
// Creates an SSA local variable load/store elimination pass.
// For every entry point function, eliminate all loads and stores of function
// scope variables only referenced with non-access-chain loads and stores.
// Eliminate the variables as well.
//
// The presence of access chain references and function calls can inhibit
// the above optimization.
//
// Only shader modules with relaxed logical addressing (see opt/instruction.h)
// are currently processed. Currently modules with any extensions enabled are
// not processed. This is left for future work.
//
// This pass is most effective if preceeded by Inlining and
// LocalAccessChainConvert. LocalSingleStoreElim and LocalSingleBlockElim
// will reduce the work that this pass has to do.
Optimizer::PassToken CreateLocalMultiStoreElimPass();
// Creates a local access chain conversion pass.
// A local access chain conversion pass identifies all function scope
// variables which are accessed only with loads, stores and access chains
// with constant indices. It then converts all loads and stores of such
// variables into equivalent sequences of loads, stores, extracts and inserts.
//
// This pass only processes entry point functions. It currently only converts
// non-nested, non-ptr access chains. It does not process modules with
// non-32-bit integer types present. Optional memory access options on loads
// and stores are ignored as we are only processing function scope variables.
//
// This pass unifies access to these variables to a single mode and simplifies
// subsequent analysis and elimination of these variables along with their
// loads and stores allowing values to propagate to their points of use where
// possible.
Optimizer::PassToken CreateLocalAccessChainConvertPass();
// Creates a local single store elimination pass.
// For each entry point function, this pass eliminates loads and stores for
// function scope variable that are stored to only once, where possible. Only
// whole variable loads and stores are eliminated; access-chain references are
// not optimized. Replace all loads of such variables with the value that is
// stored and eliminate any resulting dead code.
//
// Currently, the presence of access chains and function calls can inhibit this
// pass, however the Inlining and LocalAccessChainConvert passes can make it
// more effective. In additional, many non-load/store memory operations are
// not supported and will prohibit optimization of a function. Support of
// these operations are future work.
//
// Only shader modules with relaxed logical addressing (see opt/instruction.h)
// are currently processed.
//
// This pass will reduce the work needed to be done by LocalSingleBlockElim
// and LocalMultiStoreElim and can improve the effectiveness of other passes
// such as DeadBranchElimination which depend on values for their analysis.
Optimizer::PassToken CreateLocalSingleStoreElimPass();
// Creates an insert/extract elimination pass.
// This pass processes each entry point function in the module, searching for
// extracts on a sequence of inserts. It further searches the sequence for an
// insert with indices identical to the extract. If such an insert can be
// found before hitting a conflicting insert, the extract's result id is
// replaced with the id of the values from the insert.
//
// Besides removing extracts this pass enables subsequent dead code elimination
// passes to delete the inserts. This pass performs best after access chains are
// converted to inserts and extracts and local loads and stores are eliminated.
Optimizer::PassToken CreateInsertExtractElimPass();
// Creates a pass to consolidate uniform references.
// For each entry point function in the module, first change all constant index
// access chain loads into equivalent composite extracts. Then consolidate
// identical uniform loads into one uniform load. Finally, consolidate
// identical uniform extracts into one uniform extract. This may require
// moving a load or extract to a point which dominates all uses.
//
// This pass requires a module to have structured control flow ie shader
// capability. It also requires logical addressing ie Addresses capability
// is not enabled. It also currently does not support any extensions.
//
// This pass currently only optimizes loads with a single index.
Optimizer::PassToken CreateCommonUniformElimPass();
// Create aggressive dead code elimination pass
// This pass eliminates unused code from functions. In addition,
// it detects and eliminates code which may have spurious uses but which do
// not contribute to the output of the function. The most common cause of
// such code sequences is summations in loops whose result is no longer used
// due to dead code elimination. This optimization has additional compile
// time cost over standard dead code elimination.
//
// This pass only processes entry point functions. It also only processes
// shaders with relaxed logical addressing (see opt/instruction.h). It currently
// will not process functions with function calls.
//
// This pass will be made more effective by first running passes that remove
// dead control flow and inlines function calls.
//
// This pass can be especially useful after running Local Access Chain
// Conversion, which tends to cause cycles of dead code to be left after
// Store/Load elimination passes are completed. These cycles cannot be
// eliminated with standard dead code elimination.
Optimizer::PassToken CreateAggressiveDCEPass();
// Creates a compact ids pass.
// The pass remaps result ids to a compact and gapless range starting from %1.
Optimizer::PassToken CreateCompactIdsPass();
// Creates a remove duplicate capabilities pass.
Optimizer::PassToken CreateRemoveDuplicatesPass();
// Creates a CFG cleanup pass.
// This pass removes cruft from the control flow graph of functions that are
// reachable from entry points and exported functions. It currently includes the
// following functionality:
//
// - Removal of unreachable basic blocks.
Optimizer::PassToken CreateCFGCleanupPass();
// Create dead variable elimination pass.
// This pass will delete module scope variables, along with their decorations,
// that are not referenced.
Optimizer::PassToken CreateDeadVariableEliminationPass();
// Create merge return pass.
// This pass replaces all returns with unconditional branches to a new block
// containing a return. If necessary, this new block will contain a PHI node to
// select the correct return value.
//
// This pass does not consider unreachable code, nor does it perform any other
// optimizations.
//
// This pass does not currently support structured control flow. It bails out if
// the shader capability is detected.
Optimizer::PassToken CreateMergeReturnPass();
// Create value numbering pass.
// This pass will look for instructions in the same basic block that compute the
// same value, and remove the redundant ones.
Optimizer::PassToken CreateLocalRedundancyEliminationPass();
// Create global value numbering pass.
// This pass will look for instructions where the same value is computed on all
// paths leading to the instruction. Those instructions are deleted.
Optimizer::PassToken CreateRedundancyEliminationPass();
// Create scalar replacement pass.
// This pass replaces composite function scope variables with variables for each
// element if those elements are accessed individually.
Optimizer::PassToken CreateScalarReplacementPass();
// Create a private to local pass.
// This pass looks for variables delcared in the private storage class that are
// used in only one function. Those variables are moved to the function storage
// class in the function that they are used.
Optimizer::PassToken CreatePrivateToLocalPass();
} // namespace spvtools
#endif // SPIRV_TOOLS_OPTIMIZER_HPP_