SPIRV-Tools/source/opt/ccp_pass.cpp
Alan Baker 6587d3f8a3 Adding early exit versions of several ForEach* methods
* Looked through code for instances where code would benefit from early
exit
 * Added a corresponding WhileEach* method and updated the code
2018-01-12 17:05:09 -05:00

291 lines
10 KiB
C++

// Copyright (c) 2017 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.
// This file implements conditional constant propagation as described in
//
// Constant propagation with conditional branches,
// Wegman and Zadeck, ACM TOPLAS 13(2):181-210.
#include "ccp_pass.h"
#include "fold.h"
#include "function.h"
#include "module.h"
#include "propagator.h"
#include <algorithm>
namespace spvtools {
namespace opt {
namespace {
// This SSA id is never defined nor referenced in the IR. It is a special ID
// which represents varying values. When an ID is found to have a varying
// value, its entry in the |values_| table maps to kVaryingSSAId.
const uint32_t kVaryingSSAId = std::numeric_limits<uint32_t>::max();
} // namespace
bool CCPPass::IsVaryingValue(uint32_t id) const { return id == kVaryingSSAId; }
SSAPropagator::PropStatus CCPPass::MarkInstructionVarying(
ir::Instruction* instr) {
assert(instr->result_id() != 0 &&
"Instructions with no result cannot be marked varying.");
values_[instr->result_id()] = kVaryingSSAId;
return SSAPropagator::kVarying;
}
SSAPropagator::PropStatus CCPPass::VisitPhi(ir::Instruction* phi) {
uint32_t meet_val_id = 0;
// Implement the lattice meet operation. The result of this Phi instruction is
// interesting only if the meet operation over arguments coming through
// executable edges yields the same constant value.
for (uint32_t i = 2; i < phi->NumOperands(); i += 2) {
if (!propagator_->IsPhiArgExecutable(phi, i)) {
// Ignore arguments coming through non-executable edges.
continue;
}
uint32_t phi_arg_id = phi->GetSingleWordOperand(i);
auto it = values_.find(phi_arg_id);
if (it != values_.end()) {
// We found an argument with a constant value. Apply the meet operation
// with the previous arguments.
if (meet_val_id == 0) {
// This is the first argument we find. Initialize the result to its
// constant value id.
meet_val_id = it->second;
} else if (it->second == meet_val_id) {
// The argument is the same constant value already computed. Continue
// looking.
continue;
} else {
// We either found a varying value, or another constant value different
// from the previous computed meet value. This Phi will never be
// constant.
return MarkInstructionVarying(phi);
}
} else {
// If any argument is not a constant, the Phi produces nothing
// interesting for now. The propagator will callback again, if needed.
return SSAPropagator::kNotInteresting;
}
}
// If there are no incoming executable edges, the meet ID will still be 0. In
// that case, return not interesting to evaluate the Phi node again.
if (meet_val_id == 0) {
return SSAPropagator::kNotInteresting;
}
// All the operands have the same constant value represented by |meet_val_id|.
// Set the Phi's result to that value and declare it interesting.
values_[phi->result_id()] = meet_val_id;
return SSAPropagator::kInteresting;
}
SSAPropagator::PropStatus CCPPass::VisitAssignment(ir::Instruction* instr) {
assert(instr->result_id() != 0 &&
"Expecting an instruction that produces a result");
// If this is a copy operation, and the RHS is a known constant, assign its
// value to the LHS.
if (instr->opcode() == SpvOpCopyObject) {
uint32_t rhs_id = instr->GetSingleWordInOperand(0);
auto it = values_.find(rhs_id);
if (it != values_.end()) {
if (IsVaryingValue(it->second)) {
return MarkInstructionVarying(instr);
} else {
values_[instr->result_id()] = it->second;
return SSAPropagator::kInteresting;
}
}
return SSAPropagator::kNotInteresting;
}
// Instructions with a RHS that cannot produce a constant are always varying.
if (!instr->IsFoldable()) {
return MarkInstructionVarying(instr);
}
// See if the RHS of the assignment folds into a constant value.
auto map_func = [this](uint32_t id) {
auto it = values_.find(id);
if (it == values_.end() || IsVaryingValue(it->second)) {
return id;
}
return it->second;
};
ir::Instruction* folded_inst =
opt::FoldInstructionToConstant(instr, map_func);
if (folded_inst != nullptr) {
// We do not want to change the body of the function by adding new
// instructions. When folding we can only generate new constants.
assert(folded_inst->IsConstant() && "CCP is only interested in constant.");
values_[instr->result_id()] = folded_inst->result_id();
return SSAPropagator::kInteresting;
}
// If not, see if there is a least one unknown operand to the instruction. If
// so, we might be able to fold it later.
if (!instr->WhileEachInId([this](uint32_t* op_id) {
auto it = values_.find(*op_id);
if (it == values_.end()) return false;
return true;
})) {
return SSAPropagator::kNotInteresting;
}
// Otherwise, we will never be able to fold this instruction, so mark it
// varying.
return MarkInstructionVarying(instr);
}
SSAPropagator::PropStatus CCPPass::VisitBranch(ir::Instruction* instr,
ir::BasicBlock** dest_bb) const {
assert(instr->IsBranch() && "Expected a branch instruction.");
*dest_bb = nullptr;
uint32_t dest_label = 0;
if (instr->opcode() == SpvOpBranch) {
// An unconditional jump always goes to its unique destination.
dest_label = instr->GetSingleWordInOperand(0);
} else if (instr->opcode() == SpvOpBranchConditional) {
// For a conditional branch, determine whether the predicate selector has a
// known value in |values_|. If it does, set the destination block
// according to the selector's boolean value.
uint32_t pred_id = instr->GetSingleWordOperand(0);
auto it = values_.find(pred_id);
if (it == values_.end() || IsVaryingValue(it->second)) {
// The predicate has an unknown value, either branch could be taken.
return SSAPropagator::kVarying;
}
// Get the constant value for the predicate selector from the value table.
// Use it to decide which branch will be taken.
uint32_t pred_val_id = it->second;
const analysis::Constant* c = const_mgr_->FindDeclaredConstant(pred_val_id);
assert(c && "Expected to find a constant declaration for a known value.");
const analysis::BoolConstant* val = c->AsBoolConstant();
dest_label = val->value() ? instr->GetSingleWordOperand(1)
: instr->GetSingleWordOperand(2);
} else {
// For an OpSwitch, extract the value taken by the switch selector and check
// which of the target literals it matches. The branch associated with that
// literal is the taken branch.
assert(instr->opcode() == SpvOpSwitch);
if (instr->GetOperand(0).words.size() != 1) {
// If the selector is wider than 32-bits, return varying. TODO(dnovillo):
// Add support for wider constants.
return SSAPropagator::kVarying;
}
uint32_t select_id = instr->GetSingleWordOperand(0);
auto it = values_.find(select_id);
if (it == values_.end() || IsVaryingValue(it->second)) {
// The selector has an unknown value, any of the branches could be taken.
return SSAPropagator::kVarying;
}
// Get the constant value for the selector from the value table. Use it to
// decide which branch will be taken.
uint32_t select_val_id = it->second;
const analysis::Constant* c =
const_mgr_->FindDeclaredConstant(select_val_id);
assert(c && "Expected to find a constant declaration for a known value.");
const analysis::IntConstant* val = c->AsIntConstant();
// Start assuming that the selector will take the default value;
dest_label = instr->GetSingleWordOperand(1);
for (uint32_t i = 2; i < instr->NumOperands(); i += 2) {
if (val->words()[0] == instr->GetSingleWordOperand(i)) {
dest_label = instr->GetSingleWordOperand(i + 1);
break;
}
}
}
assert(dest_label && "Destination label should be set at this point.");
*dest_bb = context()->cfg()->block(dest_label);
return SSAPropagator::kInteresting;
}
SSAPropagator::PropStatus CCPPass::VisitInstruction(ir::Instruction* instr,
ir::BasicBlock** dest_bb) {
*dest_bb = nullptr;
if (instr->opcode() == SpvOpPhi) {
return VisitPhi(instr);
} else if (instr->IsBranch()) {
return VisitBranch(instr, dest_bb);
} else if (instr->result_id()) {
return VisitAssignment(instr);
}
return SSAPropagator::kVarying;
}
bool CCPPass::ReplaceValues() {
bool retval = false;
for (const auto& it : values_) {
uint32_t id = it.first;
uint32_t cst_id = it.second;
if (!IsVaryingValue(cst_id) && id != cst_id) {
retval |= context()->ReplaceAllUsesWith(id, cst_id);
}
}
return retval;
}
bool CCPPass::PropagateConstants(ir::Function* fp) {
const auto visit_fn = [this](ir::Instruction* instr,
ir::BasicBlock** dest_bb) {
return VisitInstruction(instr, dest_bb);
};
propagator_ =
std::unique_ptr<SSAPropagator>(new SSAPropagator(context(), visit_fn));
if (propagator_->Run(fp)) {
return ReplaceValues();
}
return false;
}
void CCPPass::Initialize(ir::IRContext* c) {
InitializeProcessing(c);
const_mgr_ = context()->get_constant_mgr();
// Populate the constant table with values from constant declarations in the
// module. The values of each OpConstant declaration is the identity
// assignment (i.e., each constant is its own value).
for (const auto& inst : context()->module()->GetConstants()) {
values_[inst->result_id()] = inst->result_id();
}
}
Pass::Status CCPPass::Process(ir::IRContext* c) {
Initialize(c);
// Process all entry point functions.
ProcessFunction pfn = [this](ir::Function* fp) {
return PropagateConstants(fp);
};
bool modified = ProcessReachableCallTree(pfn, context());
return modified ? Pass::Status::SuccessWithChange
: Pass::Status::SuccessWithoutChange;
}
} // namespace opt
} // namespace spvtools