src/tint/transform/expand_compound_assignment.cc - tint - Git at Google

 // Copyright 2022 The Tint Authors.
 //
 // 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.

 #include "src/tint/transform/expand_compound_assignment.h"

 #include <utility>

 #include "src/tint/ast/compound_assignment_statement.h"
 #include "src/tint/ast/increment_decrement_statement.h"
 #include "src/tint/program_builder.h"
 #include "src/tint/sem/block_statement.h"
 #include "src/tint/sem/expression.h"
 #include "src/tint/sem/for_loop_statement.h"
 #include "src/tint/sem/statement.h"
 #include "src/tint/transform/utils/hoist_to_decl_before.h"

 TINT_INSTANTIATE_TYPEINFO(tint::transform::ExpandCompoundAssignment);

 using namespace tint::number_suffixes;  // NOLINT

 namespace tint::transform {

 ExpandCompoundAssignment::ExpandCompoundAssignment() = default;

 ExpandCompoundAssignment::~ExpandCompoundAssignment() = default;

 bool ExpandCompoundAssignment::ShouldRun(const Program* program, const DataMap&) const {
     for (auto* node : program->ASTNodes().Objects()) {
         if (node->IsAnyOf<ast::CompoundAssignmentStatement, ast::IncrementDecrementStatement>()) {
             return true;
         }
     }
     return false;
 }

 namespace {

 /// Internal class used to collect statement expansions during the transform.
 class State {
   private:
     /// The clone context.
     CloneContext& ctx;

     /// The program builder.
     ProgramBuilder& b;

     /// The HoistToDeclBefore helper instance.
     HoistToDeclBefore hoist_to_decl_before;

   public:
     /// Constructor
     /// @param context the clone context
     explicit State(CloneContext& context) : ctx(context), b(*ctx.dst), hoist_to_decl_before(ctx) {}

     /// Replace `stmt` with a regular assignment statement of the form:
     ///     lhs = lhs op rhs
     /// The LHS expression will only be evaluated once, and any side effects will
     /// be hoisted to `let` declarations above the assignment statement.
     /// @param stmt the statement to replace
     /// @param lhs the lhs expression from the source statement
     /// @param rhs the rhs expression in the destination module
     /// @param op the binary operator
     void Expand(const ast::Statement* stmt,
                 const ast::Expression* lhs,
                 const ast::Expression* rhs,
                 ast::BinaryOp op) {
         // Helper function to create the new LHS expression. This will be called
         // twice when building the non-compound assignment statement, so must
         // not produce expressions that cause side effects.
         std::function<const ast::Expression*()> new_lhs;

         // Helper function to create a variable that is a pointer to `expr`.
         auto hoist_pointer_to = [&](const ast::Expression* expr) {
             auto name = b.Sym();
             auto* ptr = b.AddressOf(ctx.Clone(expr));
             auto* decl = b.Decl(b.Let(name, nullptr, ptr));
             hoist_to_decl_before.InsertBefore(ctx.src->Sem().Get(stmt), decl);
             return name;
         };

         // Helper function to hoist `expr` to a let declaration.
         auto hoist_expr_to_let = [&](const ast::Expression* expr) {
             auto name = b.Sym();
             auto* decl = b.Decl(b.Let(name, nullptr, ctx.Clone(expr)));
             hoist_to_decl_before.InsertBefore(ctx.src->Sem().Get(stmt), decl);
             return name;
         };

         // Helper function that returns `true` if the type of `expr` is a vector.
         auto is_vec = [&](const ast::Expression* expr) {
             return ctx.src->Sem().Get(expr)->Type()->UnwrapRef()->Is<sem::Vector>();
         };

         // Hoist the LHS expression subtree into local constants to produce a new
         // LHS that we can evaluate twice.
         // We need to special case compound assignments to vector components since
         // we cannot take the address of a vector component.
         auto* index_accessor = lhs->As<ast::IndexAccessorExpression>();
         auto* member_accessor = lhs->As<ast::MemberAccessorExpression>();
         if (lhs->Is<ast::IdentifierExpression>() ||
             (member_accessor && member_accessor->structure->Is<ast::IdentifierExpression>())) {
             // This is the simple case with no side effects, so we can just use the
             // original LHS expression directly.
             // Before:
             //     foo.bar += rhs;
             // After:
             //     foo.bar = foo.bar + rhs;
             new_lhs = [&]() { return ctx.Clone(lhs); };
         } else if (index_accessor && is_vec(index_accessor->object)) {
             // This is the case for vector component via an array accessor. We need
             // to capture a pointer to the vector and also the index value.
             // Before:
             //     v[idx()] += rhs;
             // After:
             //     let vec_ptr = &v;
             //     let index = idx();
             //     (*vec_ptr)[index] = (*vec_ptr)[index] + rhs;
             auto lhs_ptr = hoist_pointer_to(index_accessor->object);
             auto index = hoist_expr_to_let(index_accessor->index);
             new_lhs = [&, lhs_ptr, index]() { return b.IndexAccessor(b.Deref(lhs_ptr), index); };
         } else if (member_accessor && is_vec(member_accessor->structure)) {
             // This is the case for vector component via a member accessor. We just
             // need to capture a pointer to the vector.
             // Before:
             //     a[idx()].y += rhs;
             // After:
             //     let vec_ptr = &a[idx()];
             //     (*vec_ptr).y = (*vec_ptr).y + rhs;
             auto lhs_ptr = hoist_pointer_to(member_accessor->structure);
             new_lhs = [&, lhs_ptr]() {
                 return b.MemberAccessor(b.Deref(lhs_ptr), ctx.Clone(member_accessor->member));
             };
         } else {
             // For all other statements that may have side-effecting expressions, we
             // just need to capture a pointer to the whole LHS.
             // Before:
             //     a[idx()] += rhs;
             // After:
             //     let lhs_ptr = &a[idx()];
             //     (*lhs_ptr) = (*lhs_ptr) + rhs;
             auto lhs_ptr = hoist_pointer_to(lhs);
             new_lhs = [&, lhs_ptr]() { return b.Deref(lhs_ptr); };
         }

         // Replace the statement with a regular assignment statement.
         auto* value = b.create<ast::BinaryExpression>(op, new_lhs(), rhs);
         ctx.Replace(stmt, b.Assign(new_lhs(), value));
     }

     /// Finalize the transformation and clone the module.
     void Finalize() {
         hoist_to_decl_before.Apply();
         ctx.Clone();
     }
 };

 }  // namespace

 void ExpandCompoundAssignment::Run(CloneContext& ctx, const DataMap&, DataMap&) const {
     State state(ctx);
     for (auto* node : ctx.src->ASTNodes().Objects()) {
         if (auto* assign = node->As<ast::CompoundAssignmentStatement>()) {
             state.Expand(assign, assign->lhs, ctx.Clone(assign->rhs), assign->op);
         } else if (auto* inc_dec = node->As<ast::IncrementDecrementStatement>()) {
             // For increment/decrement statements, `i++` becomes `i = i + 1`.
             auto op = inc_dec->increment ? ast::BinaryOp::kAdd : ast::BinaryOp::kSubtract;
             state.Expand(inc_dec, inc_dec->lhs, ctx.dst->Expr(1_a), op);
         }
     }
     state.Finalize();
 }

 }  // namespace tint::transform
	// Copyright 2022 The Tint Authors.
	//
	// 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.

	#include "src/tint/transform/expand_compound_assignment.h"

	#include <utility>

	#include "src/tint/ast/compound_assignment_statement.h"
	#include "src/tint/ast/increment_decrement_statement.h"
	#include "src/tint/program_builder.h"
	#include "src/tint/sem/block_statement.h"
	#include "src/tint/sem/expression.h"
	#include "src/tint/sem/for_loop_statement.h"
	#include "src/tint/sem/statement.h"
	#include "src/tint/transform/utils/hoist_to_decl_before.h"

	TINT_INSTANTIATE_TYPEINFO(tint::transform::ExpandCompoundAssignment);

	using namespace tint::number_suffixes; // NOLINT

	namespace tint::transform {

	ExpandCompoundAssignment::ExpandCompoundAssignment() = default;

	ExpandCompoundAssignment::~ExpandCompoundAssignment() = default;

	bool ExpandCompoundAssignment::ShouldRun(const Program* program, const DataMap&) const {
	for (auto* node : program->ASTNodes().Objects()) {
	if (node->IsAnyOf<ast::CompoundAssignmentStatement, ast::IncrementDecrementStatement>()) {
	return true;
	}
	}
	return false;
	}

	namespace {

	/// Internal class used to collect statement expansions during the transform.
	class State {
	private:
	/// The clone context.
	CloneContext& ctx;

	/// The program builder.
	ProgramBuilder& b;

	/// The HoistToDeclBefore helper instance.
	HoistToDeclBefore hoist_to_decl_before;

	public:
	/// Constructor
	/// @param context the clone context
	explicit State(CloneContext& context) : ctx(context), b(*ctx.dst), hoist_to_decl_before(ctx) {}

	/// Replace `stmt` with a regular assignment statement of the form:
	/// lhs = lhs op rhs
	/// The LHS expression will only be evaluated once, and any side effects will
	/// be hoisted to `let` declarations above the assignment statement.
	/// @param stmt the statement to replace
	/// @param lhs the lhs expression from the source statement
	/// @param rhs the rhs expression in the destination module
	/// @param op the binary operator
	void Expand(const ast::Statement* stmt,
	const ast::Expression* lhs,
	const ast::Expression* rhs,
	ast::BinaryOp op) {
	// Helper function to create the new LHS expression. This will be called
	// twice when building the non-compound assignment statement, so must
	// not produce expressions that cause side effects.
	std::function<const ast::Expression*()> new_lhs;

	// Helper function to create a variable that is a pointer to `expr`.
	auto hoist_pointer_to = [&](const ast::Expression* expr) {
	auto name = b.Sym();
	auto* ptr = b.AddressOf(ctx.Clone(expr));
	auto* decl = b.Decl(b.Let(name, nullptr, ptr));
	hoist_to_decl_before.InsertBefore(ctx.src->Sem().Get(stmt), decl);
	return name;
	};

	// Helper function to hoist `expr` to a let declaration.
	auto hoist_expr_to_let = [&](const ast::Expression* expr) {
	auto name = b.Sym();
	auto* decl = b.Decl(b.Let(name, nullptr, ctx.Clone(expr)));
	hoist_to_decl_before.InsertBefore(ctx.src->Sem().Get(stmt), decl);
	return name;
	};

	// Helper function that returns `true` if the type of `expr` is a vector.
	auto is_vec = [&](const ast::Expression* expr) {
	return ctx.src->Sem().Get(expr)->Type()->UnwrapRef()->Is<sem::Vector>();
	};

	// Hoist the LHS expression subtree into local constants to produce a new
	// LHS that we can evaluate twice.
	// We need to special case compound assignments to vector components since
	// we cannot take the address of a vector component.
	auto* index_accessor = lhs->As<ast::IndexAccessorExpression>();
	auto* member_accessor = lhs->As<ast::MemberAccessorExpression>();
	if (lhs->Is<ast::IdentifierExpression>() \|\|
	(member_accessor && member_accessor->structure->Is<ast::IdentifierExpression>())) {
	// This is the simple case with no side effects, so we can just use the
	// original LHS expression directly.
	// Before:
	// foo.bar += rhs;
	// After:
	// foo.bar = foo.bar + rhs;
	new_lhs = [&]() { return ctx.Clone(lhs); };
	} else if (index_accessor && is_vec(index_accessor->object)) {
	// This is the case for vector component via an array accessor. We need
	// to capture a pointer to the vector and also the index value.
	// Before:
	// v[idx()] += rhs;
	// After:
	// let vec_ptr = &v;
	// let index = idx();
	// (vec_ptr)[index] = (vec_ptr)[index] + rhs;
	auto lhs_ptr = hoist_pointer_to(index_accessor->object);
	auto index = hoist_expr_to_let(index_accessor->index);
	new_lhs = [&, lhs_ptr, index]() { return b.IndexAccessor(b.Deref(lhs_ptr), index); };
	} else if (member_accessor && is_vec(member_accessor->structure)) {
	// This is the case for vector component via a member accessor. We just
	// need to capture a pointer to the vector.
	// Before:
	// a[idx()].y += rhs;
	// After:
	// let vec_ptr = &a[idx()];
	// (vec_ptr).y = (vec_ptr).y + rhs;
	auto lhs_ptr = hoist_pointer_to(member_accessor->structure);
	new_lhs = [&, lhs_ptr]() {
	return b.MemberAccessor(b.Deref(lhs_ptr), ctx.Clone(member_accessor->member));
	};
	} else {
	// For all other statements that may have side-effecting expressions, we
	// just need to capture a pointer to the whole LHS.
	// Before:
	// a[idx()] += rhs;
	// After:
	// let lhs_ptr = &a[idx()];
	// (lhs_ptr) = (lhs_ptr) + rhs;
	auto lhs_ptr = hoist_pointer_to(lhs);
	new_lhs = [&, lhs_ptr]() { return b.Deref(lhs_ptr); };
	}

	// Replace the statement with a regular assignment statement.
	auto* value = b.create<ast::BinaryExpression>(op, new_lhs(), rhs);
	ctx.Replace(stmt, b.Assign(new_lhs(), value));
	}

	/// Finalize the transformation and clone the module.
	void Finalize() {
	hoist_to_decl_before.Apply();
	ctx.Clone();
	}
	};

	} // namespace

	void ExpandCompoundAssignment::Run(CloneContext& ctx, const DataMap&, DataMap&) const {
	State state(ctx);
	for (auto* node : ctx.src->ASTNodes().Objects()) {
	if (auto* assign = node->As<ast::CompoundAssignmentStatement>()) {
	state.Expand(assign, assign->lhs, ctx.Clone(assign->rhs), assign->op);
	} else if (auto* inc_dec = node->As<ast::IncrementDecrementStatement>()) {
	// For increment/decrement statements, `i++` becomes `i = i + 1`.
	auto op = inc_dec->increment ? ast::BinaryOp::kAdd : ast::BinaryOp::kSubtract;
	state.Expand(inc_dec, inc_dec->lhs, ctx.dst->Expr(1_a), op);
	}
	}
	state.Finalize();
	}

	} // namespace tint::transform