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https://github.com/KhronosGroup/SPIRV-Tools
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65ecfd1093
Found via `codespell -q 3 -L fo,lod,parm
540 lines
20 KiB
C++
540 lines
20 KiB
C++
// Copyright (c) 2018 Google LLC.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "source/opt/scalar_analysis.h"
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#include <functional>
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#include <map>
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#include <memory>
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#include <set>
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#include <unordered_set>
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#include <utility>
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#include <vector>
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// Simplifies scalar analysis DAGs.
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//
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// 1. Given a node passed to SimplifyExpression we first simplify the graph by
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// calling SimplifyPolynomial. This groups like nodes following basic arithmetic
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// rules, so multiple adds of the same load instruction could be grouped into a
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// single multiply of that instruction. SimplifyPolynomial will traverse the DAG
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// and build up an accumulator buffer for each class of instruction it finds.
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// For example take the loop:
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// for (i=0, i<N; i++) { i+B+23+4+B+C; }
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// In this example the expression "i+B+23+4+B+C" has four classes of
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// instruction, induction variable i, the two value unknowns B and C, and the
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// constants. The accumulator buffer is then used to rebuild the graph using
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// the accumulation of each type. This example would then be folded into
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// i+2*B+C+27.
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//
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// This new graph contains a single add node (or if only one type found then
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// just that node) with each of the like terms (or multiplication node) as a
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// child.
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//
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// 2. FoldRecurrentAddExpressions is then called on this new DAG. This will take
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// RecurrentAddExpressions which are with respect to the same loop and fold them
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// into a single new RecurrentAddExpression with respect to that same loop. An
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// expression can have multiple RecurrentAddExpression's with respect to
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// different loops in the case of nested loops. These expressions cannot be
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// folded further. For example:
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//
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// for (i=0; i<N;i++) for(j=0,k=1; j<N;++j,++k)
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//
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// The 'j' and 'k' are RecurrentAddExpression with respect to the second loop
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// and 'i' to the first. If 'j' and 'k' are used in an expression together then
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// they will be folded into a new RecurrentAddExpression with respect to the
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// second loop in that expression.
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//
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//
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// 3. If the DAG now only contains a single RecurrentAddExpression we can now
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// perform a final optimization SimplifyRecurrentAddExpression. This will
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// transform the entire DAG into a RecurrentAddExpression. Additions to the
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// RecurrentAddExpression are added to the offset field and multiplications to
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// the coefficient.
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//
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namespace spvtools {
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namespace opt {
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// Implementation of the functions which are used to simplify the graph. Graphs
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// of unknowns, multiplies, additions, and constants can be turned into a linear
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// add node with each term as a child. For instance a large graph built from, X
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// + X*2 + Y - Y*3 + 4 - 1, would become a single add expression with the
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// children X*3, -Y*2, and the constant 3. Graphs containing a recurrent
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// expression will be simplified to represent the entire graph around a single
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// recurrent expression. So for an induction variable (i=0, i++) if you add 1 to
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// i in an expression we can rewrite the graph of that expression to be a single
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// recurrent expression of (i=1,i++).
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class SENodeSimplifyImpl {
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public:
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SENodeSimplifyImpl(ScalarEvolutionAnalysis* analysis,
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SENode* node_to_simplify)
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: analysis_(*analysis),
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node_(node_to_simplify),
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constant_accumulator_(0) {}
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// Return the result of the simplification.
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SENode* Simplify();
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private:
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// Recursively descend through the graph to build up the accumulator objects
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// which are used to flatten the graph. |child| is the node currently being
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// traversed and the |negation| flag is used to signify that this operation
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// was preceded by a unary negative operation and as such the result should be
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// negated.
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void GatherAccumulatorsFromChildNodes(SENode* new_node, SENode* child,
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bool negation);
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// Given a |multiply| node add to the accumulators for the term type within
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// the |multiply| expression. Will return true if the accumulators could be
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// calculated successfully. If the |multiply| is in any form other than
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// unknown*constant then we return false. |negation| signifies that the
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// operation was preceded by a unary negative.
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bool AccumulatorsFromMultiply(SENode* multiply, bool negation);
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SERecurrentNode* UpdateCoefficient(SERecurrentNode* recurrent,
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int64_t coefficient_update) const;
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// If the graph contains a recurrent expression, ie, an expression with the
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// loop iterations as a term in the expression, then the whole expression
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// can be rewritten to be a recurrent expression.
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SENode* SimplifyRecurrentAddExpression(SERecurrentNode* node);
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// Simplify the whole graph by linking like terms together in a single flat
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// add node. So X*2 + Y -Y + 3 +6 would become X*2 + 9. Where X and Y are a
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// ValueUnknown node (i.e, a load) or a recurrent expression.
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SENode* SimplifyPolynomial();
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// Each recurrent expression is an expression with respect to a specific loop.
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// If we have two different recurrent terms with respect to the same loop in a
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// single expression then we can fold those terms into a single new term.
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// For instance:
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//
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// induction i = 0, i++
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// temp = i*10
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// array[i+temp]
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//
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// We can fold the i + temp into a single expression. Rec(0,1) + Rec(0,10) can
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// become Rec(0,11).
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SENode* FoldRecurrentAddExpressions(SENode*);
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// We can eliminate recurrent expressions which have a coefficient of zero by
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// replacing them with their offset value. We are able to do this because a
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// recurrent expression represents the equation coefficient*iterations +
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// offset.
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SENode* EliminateZeroCoefficientRecurrents(SENode* node);
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// A reference the analysis which requested the simplification.
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ScalarEvolutionAnalysis& analysis_;
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// The node being simplified.
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SENode* node_;
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// An accumulator of the net result of all the constant operations performed
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// in a graph.
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int64_t constant_accumulator_;
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// An accumulator for each of the non constant terms in the graph.
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std::map<SENode*, int64_t> accumulators_;
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};
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// From a |multiply| build up the accumulator objects.
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bool SENodeSimplifyImpl::AccumulatorsFromMultiply(SENode* multiply,
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bool negation) {
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if (multiply->GetChildren().size() != 2 ||
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multiply->GetType() != SENode::Multiply)
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return false;
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SENode* operand_1 = multiply->GetChild(0);
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SENode* operand_2 = multiply->GetChild(1);
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SENode* value_unknown = nullptr;
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SENode* constant = nullptr;
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// Work out which operand is the unknown value.
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if (operand_1->GetType() == SENode::ValueUnknown ||
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operand_1->GetType() == SENode::RecurrentAddExpr)
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value_unknown = operand_1;
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else if (operand_2->GetType() == SENode::ValueUnknown ||
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operand_2->GetType() == SENode::RecurrentAddExpr)
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value_unknown = operand_2;
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// Work out which operand is the constant coefficient.
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if (operand_1->GetType() == SENode::Constant)
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constant = operand_1;
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else if (operand_2->GetType() == SENode::Constant)
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constant = operand_2;
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// If the expression is not a variable multiplied by a constant coefficient,
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// exit out.
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if (!(value_unknown && constant)) {
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return false;
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}
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int64_t sign = negation ? -1 : 1;
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auto iterator = accumulators_.find(value_unknown);
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int64_t new_value = constant->AsSEConstantNode()->FoldToSingleValue() * sign;
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// Add the result of the multiplication to the accumulators.
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if (iterator != accumulators_.end()) {
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(*iterator).second += new_value;
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} else {
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accumulators_.insert({value_unknown, new_value});
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}
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return true;
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}
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SENode* SENodeSimplifyImpl::Simplify() {
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// We only handle graphs with an addition, multiplication, or negation, at the
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// root.
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if (node_->GetType() != SENode::Add && node_->GetType() != SENode::Multiply &&
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node_->GetType() != SENode::Negative)
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return node_;
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SENode* simplified_polynomial = SimplifyPolynomial();
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SERecurrentNode* recurrent_expr = nullptr;
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node_ = simplified_polynomial;
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// Fold recurrent expressions which are with respect to the same loop into a
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// single recurrent expression.
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simplified_polynomial = FoldRecurrentAddExpressions(simplified_polynomial);
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simplified_polynomial =
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EliminateZeroCoefficientRecurrents(simplified_polynomial);
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// Traverse the immediate children of the new node to find the recurrent
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// expression. If there is more than one there is nothing further we can do.
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for (SENode* child : simplified_polynomial->GetChildren()) {
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if (child->GetType() == SENode::RecurrentAddExpr) {
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recurrent_expr = child->AsSERecurrentNode();
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}
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}
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// We need to count the number of unique recurrent expressions in the DAG to
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// ensure there is only one.
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for (auto child_iterator = simplified_polynomial->graph_begin();
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child_iterator != simplified_polynomial->graph_end(); ++child_iterator) {
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if (child_iterator->GetType() == SENode::RecurrentAddExpr &&
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recurrent_expr != child_iterator->AsSERecurrentNode()) {
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return simplified_polynomial;
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}
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}
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if (recurrent_expr) {
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return SimplifyRecurrentAddExpression(recurrent_expr);
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}
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return simplified_polynomial;
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}
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// Traverse the graph to build up the accumulator objects.
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void SENodeSimplifyImpl::GatherAccumulatorsFromChildNodes(SENode* new_node,
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SENode* child,
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bool negation) {
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int32_t sign = negation ? -1 : 1;
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if (child->GetType() == SENode::Constant) {
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// Collect all the constants and add them together.
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constant_accumulator_ +=
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child->AsSEConstantNode()->FoldToSingleValue() * sign;
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} else if (child->GetType() == SENode::ValueUnknown ||
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child->GetType() == SENode::RecurrentAddExpr) {
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// To rebuild the graph of X+X+X*2 into 4*X we count the occurrences of X
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// and create a new node of count*X after. X can either be a ValueUnknown or
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// a RecurrentAddExpr. The count for each X is stored in the accumulators_
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// map.
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auto iterator = accumulators_.find(child);
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// If we've encountered this term before add to the accumulator for it.
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if (iterator == accumulators_.end())
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accumulators_.insert({child, sign});
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else
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iterator->second += sign;
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} else if (child->GetType() == SENode::Multiply) {
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if (!AccumulatorsFromMultiply(child, negation)) {
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new_node->AddChild(child);
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}
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} else if (child->GetType() == SENode::Add) {
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for (SENode* next_child : *child) {
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GatherAccumulatorsFromChildNodes(new_node, next_child, negation);
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}
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} else if (child->GetType() == SENode::Negative) {
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SENode* negated_node = child->GetChild(0);
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GatherAccumulatorsFromChildNodes(new_node, negated_node, !negation);
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} else {
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// If we can't work out how to fold the expression just add it back into
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// the graph.
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new_node->AddChild(child);
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}
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}
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SERecurrentNode* SENodeSimplifyImpl::UpdateCoefficient(
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SERecurrentNode* recurrent, int64_t coefficient_update) const {
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std::unique_ptr<SERecurrentNode> new_recurrent_node{new SERecurrentNode(
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recurrent->GetParentAnalysis(), recurrent->GetLoop())};
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SENode* new_coefficient = analysis_.CreateMultiplyNode(
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recurrent->GetCoefficient(),
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analysis_.CreateConstant(coefficient_update));
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// See if the node can be simplified.
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SENode* simplified = analysis_.SimplifyExpression(new_coefficient);
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if (simplified->GetType() != SENode::CanNotCompute)
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new_coefficient = simplified;
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if (coefficient_update < 0) {
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new_recurrent_node->AddOffset(
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analysis_.CreateNegation(recurrent->GetOffset()));
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} else {
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new_recurrent_node->AddOffset(recurrent->GetOffset());
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}
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new_recurrent_node->AddCoefficient(new_coefficient);
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return analysis_.GetCachedOrAdd(std::move(new_recurrent_node))
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->AsSERecurrentNode();
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}
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// Simplify all the terms in the polynomial function.
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SENode* SENodeSimplifyImpl::SimplifyPolynomial() {
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std::unique_ptr<SENode> new_add{new SEAddNode(node_->GetParentAnalysis())};
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// Traverse the graph and gather the accumulators from it.
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GatherAccumulatorsFromChildNodes(new_add.get(), node_, false);
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// Fold all the constants into a single constant node.
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if (constant_accumulator_ != 0) {
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new_add->AddChild(analysis_.CreateConstant(constant_accumulator_));
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}
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for (auto& pair : accumulators_) {
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SENode* term = pair.first;
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int64_t count = pair.second;
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// We can eliminate the term completely.
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if (count == 0) continue;
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if (count == 1) {
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new_add->AddChild(term);
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} else if (count == -1 && term->GetType() != SENode::RecurrentAddExpr) {
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// If the count is -1 we can just add a negative version of that node,
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// unless it is a recurrent expression as we would rather the negative
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// goes on the recurrent expressions children. This makes it easier to
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// work with in other places.
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new_add->AddChild(analysis_.CreateNegation(term));
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} else {
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// Output value unknown terms as count*term and output recurrent
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// expression terms as rec(offset, coefficient + count) offset and
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// coefficient are the same as in the original expression.
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if (term->GetType() == SENode::ValueUnknown) {
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SENode* count_as_constant = analysis_.CreateConstant(count);
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new_add->AddChild(
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analysis_.CreateMultiplyNode(count_as_constant, term));
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} else {
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assert(term->GetType() == SENode::RecurrentAddExpr &&
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"We only handle value unknowns or recurrent expressions");
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// Create a new recurrent expression by adding the count to the
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// coefficient of the old one.
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new_add->AddChild(UpdateCoefficient(term->AsSERecurrentNode(), count));
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}
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}
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}
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// If there is only one term in the addition left just return that term.
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if (new_add->GetChildren().size() == 1) {
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return new_add->GetChild(0);
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}
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// If there are no terms left in the addition just return 0.
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if (new_add->GetChildren().size() == 0) {
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return analysis_.CreateConstant(0);
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}
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return analysis_.GetCachedOrAdd(std::move(new_add));
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}
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SENode* SENodeSimplifyImpl::FoldRecurrentAddExpressions(SENode* root) {
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std::unique_ptr<SEAddNode> new_node{new SEAddNode(&analysis_)};
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// A mapping of loops to the list of recurrent expressions which are with
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// respect to those loops.
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std::map<const Loop*, std::vector<std::pair<SERecurrentNode*, bool>>>
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loops_to_recurrent{};
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bool has_multiple_same_loop_recurrent_terms = false;
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for (SENode* child : *root) {
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bool negation = false;
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if (child->GetType() == SENode::Negative) {
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child = child->GetChild(0);
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negation = true;
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}
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if (child->GetType() == SENode::RecurrentAddExpr) {
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const Loop* loop = child->AsSERecurrentNode()->GetLoop();
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SERecurrentNode* rec = child->AsSERecurrentNode();
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if (loops_to_recurrent.find(loop) == loops_to_recurrent.end()) {
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loops_to_recurrent[loop] = {std::make_pair(rec, negation)};
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} else {
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loops_to_recurrent[loop].push_back(std::make_pair(rec, negation));
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has_multiple_same_loop_recurrent_terms = true;
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}
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} else {
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new_node->AddChild(child);
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}
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}
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if (!has_multiple_same_loop_recurrent_terms) return root;
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for (auto pair : loops_to_recurrent) {
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std::vector<std::pair<SERecurrentNode*, bool>>& recurrent_expressions =
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pair.second;
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const Loop* loop = pair.first;
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std::unique_ptr<SENode> new_coefficient{new SEAddNode(&analysis_)};
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std::unique_ptr<SENode> new_offset{new SEAddNode(&analysis_)};
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for (auto node_pair : recurrent_expressions) {
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SERecurrentNode* node = node_pair.first;
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bool negative = node_pair.second;
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if (!negative) {
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new_coefficient->AddChild(node->GetCoefficient());
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new_offset->AddChild(node->GetOffset());
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} else {
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new_coefficient->AddChild(
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analysis_.CreateNegation(node->GetCoefficient()));
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new_offset->AddChild(analysis_.CreateNegation(node->GetOffset()));
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}
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}
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std::unique_ptr<SERecurrentNode> new_recurrent{
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new SERecurrentNode(&analysis_, loop)};
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SENode* new_coefficient_simplified =
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analysis_.SimplifyExpression(new_coefficient.get());
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SENode* new_offset_simplified =
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analysis_.SimplifyExpression(new_offset.get());
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if (new_coefficient_simplified->GetType() == SENode::Constant &&
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new_coefficient_simplified->AsSEConstantNode()->FoldToSingleValue() ==
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0) {
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return new_offset_simplified;
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}
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new_recurrent->AddCoefficient(new_coefficient_simplified);
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new_recurrent->AddOffset(new_offset_simplified);
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new_node->AddChild(analysis_.GetCachedOrAdd(std::move(new_recurrent)));
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}
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// If we only have one child in the add just return that.
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if (new_node->GetChildren().size() == 1) {
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return new_node->GetChild(0);
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}
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return analysis_.GetCachedOrAdd(std::move(new_node));
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}
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SENode* SENodeSimplifyImpl::EliminateZeroCoefficientRecurrents(SENode* node) {
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if (node->GetType() != SENode::Add) return node;
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bool has_change = false;
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std::vector<SENode*> new_children{};
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for (SENode* child : *node) {
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if (child->GetType() == SENode::RecurrentAddExpr) {
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SENode* coefficient = child->AsSERecurrentNode()->GetCoefficient();
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// If coefficient is zero then we can eliminate the recurrent expression
|
|
// entirely and just return the offset as the recurrent expression is
|
|
// representing the equation coefficient*iterations + offset.
|
|
if (coefficient->GetType() == SENode::Constant &&
|
|
coefficient->AsSEConstantNode()->FoldToSingleValue() == 0) {
|
|
new_children.push_back(child->AsSERecurrentNode()->GetOffset());
|
|
has_change = true;
|
|
} else {
|
|
new_children.push_back(child);
|
|
}
|
|
} else {
|
|
new_children.push_back(child);
|
|
}
|
|
}
|
|
|
|
if (!has_change) return node;
|
|
|
|
std::unique_ptr<SENode> new_add{new SEAddNode(node_->GetParentAnalysis())};
|
|
|
|
for (SENode* child : new_children) {
|
|
new_add->AddChild(child);
|
|
}
|
|
|
|
return analysis_.GetCachedOrAdd(std::move(new_add));
|
|
}
|
|
|
|
SENode* SENodeSimplifyImpl::SimplifyRecurrentAddExpression(
|
|
SERecurrentNode* recurrent_expr) {
|
|
const std::vector<SENode*>& children = node_->GetChildren();
|
|
|
|
std::unique_ptr<SERecurrentNode> recurrent_node{new SERecurrentNode(
|
|
recurrent_expr->GetParentAnalysis(), recurrent_expr->GetLoop())};
|
|
|
|
// Create and simplify the new offset node.
|
|
std::unique_ptr<SENode> new_offset{
|
|
new SEAddNode(recurrent_expr->GetParentAnalysis())};
|
|
new_offset->AddChild(recurrent_expr->GetOffset());
|
|
|
|
for (SENode* child : children) {
|
|
if (child->GetType() != SENode::RecurrentAddExpr) {
|
|
new_offset->AddChild(child);
|
|
}
|
|
}
|
|
|
|
// Simplify the new offset.
|
|
SENode* simplified_child = analysis_.SimplifyExpression(new_offset.get());
|
|
|
|
// If the child can be simplified, add the simplified form otherwise, add it
|
|
// via the usual caching mechanism.
|
|
if (simplified_child->GetType() != SENode::CanNotCompute) {
|
|
recurrent_node->AddOffset(simplified_child);
|
|
} else {
|
|
recurrent_expr->AddOffset(analysis_.GetCachedOrAdd(std::move(new_offset)));
|
|
}
|
|
|
|
recurrent_node->AddCoefficient(recurrent_expr->GetCoefficient());
|
|
|
|
return analysis_.GetCachedOrAdd(std::move(recurrent_node));
|
|
}
|
|
|
|
/*
|
|
* Scalar Analysis simplification public methods.
|
|
*/
|
|
|
|
SENode* ScalarEvolutionAnalysis::SimplifyExpression(SENode* node) {
|
|
SENodeSimplifyImpl impl{this, node};
|
|
|
|
return impl.Simplify();
|
|
}
|
|
|
|
} // namespace opt
|
|
} // namespace spvtools
|