Add PromoteSideEffectsToDecl transform

Fold both PromoteInitializersToConstVar and VarForDynamicIndex into this new transform, with a config to enable either type of transformation. This is almost a no-op change, except that VarForDynamicIndex required ForLoopToLoop, while this tranformation in PromoteInitializersToConstVar converts for-loops only as needed, so it doesn't do so when the expression is in the for-loop initializer. This transform will be extended to handle ensuring order of execution of expressions. Bug: tint:1300 Change-Id: I4d00984346a2c92b2d8563b459898f8f737589fd Reviewed-on: https://dawn-review.googlesource.com/c/tint/+/77140 Reviewed-by: Ben Clayton <bclayton@google.com> Kokoro: Kokoro <noreply+kokoro@google.com> Commit-Queue: Antonio Maiorano <amaiorano@google.com>
2022-01-24 15:14:39 +00:00 · 2022-01-24 15:14:39 +00:00 · 8db439d848
parent 2a31b8c1bc
commit 8db439d848
15 changed files with 1141 additions and 1095 deletions
--- a/src/BUILD.gn
+++ b/src/BUILD.gn
@ -465,8 +465,8 @@ libtint_source_set("libtint_core_all_src") {
    "transform/num_workgroups_from_uniform.h",
    "transform/pad_array_elements.cc",
    "transform/pad_array_elements.h",
-    "transform/promote_initializers_to_const_var.cc",
+    "transform/promote_side_effects_to_decl.cc",
-    "transform/promote_initializers_to_const_var.h",
+    "transform/promote_side_effects_to_decl.h",
    "transform/remove_phonies.cc",
    "transform/remove_phonies.h",
    "transform/remove_unreachable_statements.cc",
@ -483,8 +483,6 @@ libtint_source_set("libtint_core_all_src") {
    "transform/transform.h",
    "transform/unshadow.cc",
    "transform/unshadow.h",
    "transform/var_for_dynamic_index.cc",
    "transform/var_for_dynamic_index.h",
    "transform/vectorize_scalar_matrix_constructors.cc",
    "transform/vectorize_scalar_matrix_constructors.h",
    "transform/vertex_pulling.cc",
--- a/src/CMakeLists.txt
+++ b/src/CMakeLists.txt
@ -335,8 +335,8 @@ set(TINT_LIB_SRCS
  transform/num_workgroups_from_uniform.h
  transform/pad_array_elements.cc
  transform/pad_array_elements.h
-  transform/promote_initializers_to_const_var.cc
+  transform/promote_side_effects_to_decl.cc
-  transform/promote_initializers_to_const_var.h
+  transform/promote_side_effects_to_decl.h
  transform/remove_phonies.cc
  transform/remove_phonies.h
  transform/remove_unreachable_statements.cc
@ -355,8 +355,6 @@ set(TINT_LIB_SRCS
  transform/unshadow.h
  transform/vectorize_scalar_matrix_constructors.cc
  transform/vectorize_scalar_matrix_constructors.h
  transform/var_for_dynamic_index.cc
  transform/var_for_dynamic_index.h
  transform/vertex_pulling.cc
  transform/vertex_pulling.h
  transform/wrap_arrays_in_structs.cc
@ -991,7 +989,7 @@ if(TINT_BUILD_TESTS)
      transform/multiplanar_external_texture_test.cc
      transform/num_workgroups_from_uniform_test.cc
      transform/pad_array_elements_test.cc
-      transform/promote_initializers_to_const_var_test.cc
+      transform/promote_side_effects_to_decl_test.cc
      transform/remove_phonies_test.cc
      transform/remove_unreachable_statements_test.cc
      transform/renamer_test.cc
@ -1000,7 +998,6 @@ if(TINT_BUILD_TESTS)
      transform/single_entry_point_test.cc
      transform/test_helper.h
      transform/unshadow_test.cc
      transform/var_for_dynamic_index_test.cc
      transform/vectorize_scalar_matrix_constructors_test.cc
      transform/vertex_pulling_test.cc
      transform/wrap_arrays_in_structs_test.cc
--- a/src/transform/glsl.cc
+++ b/src/transform/glsl.cc
@ -27,7 +27,7 @@
 #include "src/transform/loop_to_for_loop.h"
 #include "src/transform/manager.h"
 #include "src/transform/pad_array_elements.h"
-#include "src/transform/promote_initializers_to_const_var.h"
+#include "src/transform/promote_side_effects_to_decl.h"
 #include "src/transform/remove_phonies.h"
 #include "src/transform/simplify_pointers.h"
 #include "src/transform/single_entry_point.h"
@ -75,7 +75,11 @@ Output Glsl::Run(const Program* in, const DataMap& inputs) {
  manager.Add<RemovePhonies>();
  manager.Add<CalculateArrayLength>();
  manager.Add<ExternalTextureTransform>();
-  manager.Add<PromoteInitializersToConstVar>();
+
  data.Add<PromoteSideEffectsToDecl::Config>(
      /* type_ctor_to_let */ true, /* dynamic_index_to_var */ false);
  manager.Add<PromoteSideEffectsToDecl>();
  manager.Add<PadArrayElements>();
  manager.Add<AddEmptyEntryPoint>();
  manager.Add<AddSpirvBlockDecoration>();
--- a/src/transform/promote_initializers_to_const_var.cc
+++ b/src/transform/promote_initializers_to_const_var.cc
@ -1,203 +0,0 @@
 // Copyright 2021 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/transform/promote_initializers_to_const_var.h"
 #include <unordered_map>
 #include <utility>
 #include "src/program_builder.h"
 #include "src/sem/block_statement.h"
 #include "src/sem/call.h"
 #include "src/sem/expression.h"
 #include "src/sem/for_loop_statement.h"
 #include "src/sem/statement.h"
 #include "src/sem/type_constructor.h"
 TINT_INSTANTIATE_TYPEINFO(tint::transform::PromoteInitializersToConstVar);
 namespace tint {
 namespace transform {
 namespace {
 /// Holds information about a for-loop that needs to be decomposed into a loop,
 /// so that initializer declaration statements can be inserted before the
 /// condition expression or continuing statement.
 struct LoopInfo {
  ast::StatementList cond_decls;
  ast::StatementList cont_decls;
 };
 }  // namespace
 PromoteInitializersToConstVar::PromoteInitializersToConstVar() = default;
 PromoteInitializersToConstVar::~PromoteInitializersToConstVar() = default;
 void PromoteInitializersToConstVar::Run(CloneContext& ctx,
                                        const DataMap&,
                                        DataMap&) {
  auto& sem = ctx.src->Sem();
  // Scan the AST nodes for array and structure initializers which
  // need to be promoted to their own constant declaration.
  // Note: Correct handling of nested expressions is guaranteed due to the
  // depth-first traversal of the ast::Node::Clone() methods:
  //
  // The inner-most initializers are traversed first, and they are hoisted
  // to const variables declared just above the statement of use. The outer
  // initializer will then be hoisted, inserting themselves between the
  // inner declaration and the statement of use. This pattern applies correctly
  // to any nested depth.
  //
  // Depth-first traversal of the AST is guaranteed because AST nodes are fully
  // immutable and require their children to be constructed first so their
  // pointer can be passed to the parent's constructor.
  // For-loops that need to be decomposed to loops.
  std::unordered_map<const sem::ForLoopStatement*, LoopInfo> loops;
  for (auto* node : ctx.src->ASTNodes().Objects()) {
    if (auto* expr = node->As<ast::CallExpression>()) {
      auto* ctor = ctx.src->Sem().Get(expr);
      if (!ctor->Target()->Is<sem::TypeConstructor>()) {
        continue;
      }
      auto* sem_stmt = ctor->Stmt();
      if (!sem_stmt) {
        // Expression is outside of a statement. This usually means the
        // expression is part of a global (module-scope) constant declaration.
        // These must be constexpr, and so cannot contain the type of
        // expressions that must be sanitized.
        continue;
      }
      auto* stmt = sem_stmt->Declaration();
      if (auto* src_var_decl = stmt->As<ast::VariableDeclStatement>()) {
        if (src_var_decl->variable->constructor == expr) {
          // This statement is just a variable declaration with the initializer
          // as the constructor value. This is what we're attempting to
          // transform to, and so ignore.
          continue;
        }
      }
      auto* src_ty = ctor->Type();
      if (src_ty->IsAnyOf<sem::Array, sem::Struct>()) {
        // Create a new symbol for the let
        auto name = ctx.dst->Sym();
        // Construct the let that holds the hoisted initializer
        auto* let = ctx.dst->Const(name, nullptr, ctx.Clone(expr));
        // Construct the let declaration statement
        auto* let_decl = ctx.dst->Decl(let);
        // Replace the initializer expression with a reference to the let
        ctx.Replace(expr, ctx.dst->Expr(name));
        if (auto* fl = sem_stmt->As<sem::ForLoopStatement>()) {
          // Expression used in for-loop condition.
          // For-loop needs to be decomposed to a loop.
          loops[fl].cond_decls.emplace_back(let_decl);
          continue;
        }
        auto* parent = sem_stmt->Parent();  // The statement's parent
        if (auto* block = parent->As<sem::BlockStatement>()) {
          // Expression's statement sits in a block. Simple case.
          // Insert the let before the parent statement
          ctx.InsertBefore(block->Declaration()->statements, stmt, let_decl);
          continue;
        }
        if (auto* fl = parent->As<sem::ForLoopStatement>()) {
          // Expression is used in a for-loop. These require special care.
          if (fl->Declaration()->initializer == stmt) {
            // Expression used in for-loop initializer.
            // Insert the let above the for-loop.
            ctx.InsertBefore(fl->Block()->Declaration()->statements,
                             fl->Declaration(), let_decl);
            continue;
          }
          if (fl->Declaration()->continuing == stmt) {
            // Expression used in for-loop continuing.
            // For-loop needs to be decomposed to a loop.
            loops[fl].cont_decls.emplace_back(let_decl);
            continue;
          }
          TINT_ICE(Transform, ctx.dst->Diagnostics())
              << "unhandled use of expression in for-loop";
        }
        TINT_ICE(Transform, ctx.dst->Diagnostics())
            << "unhandled expression parent statement type: "
            << parent->TypeInfo().name;
      }
    }
  }
  if (!loops.empty()) {
    // At least one for-loop needs to be transformed into a loop.
    ctx.ReplaceAll(
        [&](const ast::ForLoopStatement* stmt) -> const ast::Statement* {
          if (auto* fl = sem.Get(stmt)) {
            if (auto it = loops.find(fl); it != loops.end()) {
              auto& info = it->second;
              auto* for_loop = fl->Declaration();
              // For-loop needs to be decomposed to a loop.
              // Build the loop body's statements.
              // Start with any let declarations for the conditional expression.
              auto body_stmts = info.cond_decls;
              // If the for-loop has a condition, emit this next as:
              //   if (!cond) { break; }
              if (auto* cond = for_loop->condition) {
                // !condition
                auto* not_cond = ctx.dst->create<ast::UnaryOpExpression>(
                    ast::UnaryOp::kNot, ctx.Clone(cond));
                // { break; }
                auto* break_body =
                    ctx.dst->Block(ctx.dst->create<ast::BreakStatement>());
                // if (!condition) { break; }
                body_stmts.emplace_back(ctx.dst->If(not_cond, break_body));
              }
              // Next emit the for-loop body
              for (auto* body_stmt : for_loop->body->statements) {
                body_stmts.emplace_back(ctx.Clone(body_stmt));
              }
              // Finally create the continuing block if there was one.
              const ast::BlockStatement* continuing = nullptr;
              if (auto* cont = for_loop->continuing) {
                // Continuing block starts with any let declarations used by the
                // continuing.
                auto cont_stmts = info.cont_decls;
                cont_stmts.emplace_back(ctx.Clone(cont));
                continuing = ctx.dst->Block(cont_stmts);
              }
              auto* body = ctx.dst->Block(body_stmts);
              auto* loop = ctx.dst->Loop(body, continuing);
              if (auto* init = for_loop->initializer) {
                return ctx.dst->Block(ctx.Clone(init), loop);
              }
              return loop;
            }
          }
          return nullptr;
        });
  }
  ctx.Clone();
 }
 }  // namespace transform
 }  // namespace tint
--- a/src/transform/promote_initializers_to_const_var_test.cc
+++ b/src/transform/promote_initializers_to_const_var_test.cc
@ -1,391 +0,0 @@
 // Copyright 2021 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/transform/promote_initializers_to_const_var.h"
 #include "src/transform/test_helper.h"
 namespace tint {
 namespace transform {
 namespace {
 using PromoteInitializersToConstVarTest = TransformTest;
 TEST_F(PromoteInitializersToConstVarTest, BasicArray) {
  auto* src = R"(
 fn f() {
  var f0 = 1.0;
  var f1 = 2.0;
  var f2 = 3.0;
  var f3 = 4.0;
  var i = array<f32, 4u>(f0, f1, f2, f3)[2];
 }
 )";
  auto* expect = R"(
 fn f() {
  var f0 = 1.0;
  var f1 = 2.0;
  var f2 = 3.0;
  var f3 = 4.0;
  let tint_symbol = array<f32, 4u>(f0, f1, f2, f3);
  var i = tint_symbol[2];
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, BasicStruct) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 };
 fn f() {
  var x = S(1, 2.0, vec3<f32>()).b;
 }
 )";
  auto* expect = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 }
 fn f() {
  let tint_symbol = S(1, 2.0, vec3<f32>());
  var x = tint_symbol.b;
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, ArrayInForLoopInit) {
  auto* src = R"(
 fn f() {
  var insert_after = 1;
  for(var i = array<f32, 4u>(0.0, 1.0, 2.0, 3.0)[2]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var insert_after = 1;
  let tint_symbol = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
  for(var i = tint_symbol[2]; ; ) {
    break;
  }
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, StructInForLoopInit) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 };
 fn f() {
  var insert_after = 1;
  for(var x = S(1, 2.0, vec3<f32>()).b; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 }
 fn f() {
  var insert_after = 1;
  let tint_symbol = S(1, 2.0, vec3<f32>());
  for(var x = tint_symbol.b; ; ) {
    break;
  }
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, ArrayInForLoopCond) {
  auto* src = R"(
 fn f() {
  var f = 1.0;
  for(; f == array<f32, 1u>(f)[0]; f = f + 1.0) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var f = 1.0;
  loop {
    let tint_symbol = array<f32, 1u>(f);
    if (!((f == tint_symbol[0]))) {
      break;
    }
    var marker = 1;
    continuing {
      f = (f + 1.0);
    }
  }
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, ArrayInForLoopCont) {
  auto* src = R"(
 fn f() {
  var f = 0.0;
  for(; f < 10.0; f = f + array<f32, 1u>(1.0)[0]) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var f = 0.0;
  loop {
    if (!((f < 10.0))) {
      break;
    }
    var marker = 1;
    continuing {
      let tint_symbol = array<f32, 1u>(1.0);
      f = (f + tint_symbol[0]);
    }
  }
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, ArrayInForLoopInitCondCont) {
  auto* src = R"(
 fn f() {
  for(var f = array<f32, 1u>(0.0)[0];
      f < array<f32, 1u>(1.0)[0];
      f = f + array<f32, 1u>(2.0)[0]) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  let tint_symbol = array<f32, 1u>(0.0);
  {
    var f = tint_symbol[0];
    loop {
      let tint_symbol_1 = array<f32, 1u>(1.0);
      if (!((f < tint_symbol_1[0]))) {
        break;
      }
      var marker = 1;
      continuing {
        let tint_symbol_2 = array<f32, 1u>(2.0);
        f = (f + tint_symbol_2[0]);
      }
    }
  }
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, ArrayInArrayArray) {
  auto* src = R"(
 fn f() {
  var i = array<array<f32, 2u>, 2u>(array<f32, 2u>(1.0, 2.0), array<f32, 2u>(3.0, 4.0))[0][1];
 }
 )";
  auto* expect = R"(
 fn f() {
  let tint_symbol = array<f32, 2u>(1.0, 2.0);
  let tint_symbol_1 = array<f32, 2u>(3.0, 4.0);
  let tint_symbol_2 = array<array<f32, 2u>, 2u>(tint_symbol, tint_symbol_1);
  var i = tint_symbol_2[0][1];
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, StructNested) {
  auto* src = R"(
 struct S1 {
  a : i32;
 };
 struct S2 {
  a : i32;
  b : S1;
  c : i32;
 };
 struct S3 {
  a : S2;
 };
 fn f() {
  var x = S3(S2(1, S1(2), 3)).a.b.a;
 }
 )";
  auto* expect = R"(
 struct S1 {
  a : i32;
 }
 struct S2 {
  a : i32;
  b : S1;
  c : i32;
 }
 struct S3 {
  a : S2;
 }
 fn f() {
  let tint_symbol = S1(2);
  let tint_symbol_1 = S2(1, tint_symbol, 3);
  let tint_symbol_2 = S3(tint_symbol_1);
  var x = tint_symbol_2.a.b.a;
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, Mixed) {
  auto* src = R"(
 struct S1 {
  a : i32;
 };
 struct S2 {
  a : array<S1, 3u>;
 };
 fn f() {
  var x = S2(array<S1, 3u>(S1(1), S1(2), S1(3))).a[1].a;
 }
 )";
  auto* expect = R"(
 struct S1 {
  a : i32;
 }
 struct S2 {
  a : array<S1, 3u>;
 }
 fn f() {
  let tint_symbol = S1(1);
  let tint_symbol_1 = S1(2);
  let tint_symbol_2 = S1(3);
  let tint_symbol_3 = array<S1, 3u>(tint_symbol, tint_symbol_1, tint_symbol_2);
  let tint_symbol_4 = S2(tint_symbol_3);
  var x = tint_symbol_4.a[1].a;
 }
 )";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, NoChangeOnVarDecl) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : i32;
 }
 fn f() {
  var local_arr = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
  var local_str = S(1, 2.0, 3);
 }
 let module_arr : array<f32, 4u> = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
 let module_str : S = S(1, 2.0, 3);
 )";
  auto* expect = src;
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteInitializersToConstVarTest, EmptyModule) {
  auto* src = "";
  auto* expect = "";
  auto got = Run<PromoteInitializersToConstVar>(src);
  EXPECT_EQ(expect, str(got));
 }
 }  // namespace
 }  // namespace transform
 }  // namespace tint
--- a/src/transform/promote_side_effects_to_decl.cc
+++ b/src/transform/promote_side_effects_to_decl.cc
@ -0,0 +1,320 @@
 // Copyright 2021 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/transform/promote_side_effects_to_decl.h"
 #include <string>
 #include <unordered_map>
 #include <utility>
 #include "src/program_builder.h"
 #include "src/sem/block_statement.h"
 #include "src/sem/call.h"
 #include "src/sem/expression.h"
 #include "src/sem/for_loop_statement.h"
 #include "src/sem/statement.h"
 #include "src/sem/type_constructor.h"
 TINT_INSTANTIATE_TYPEINFO(tint::transform::PromoteSideEffectsToDecl);
 TINT_INSTANTIATE_TYPEINFO(tint::transform::PromoteSideEffectsToDecl::Config);
 namespace tint {
 namespace transform {
 /// Private implementation of PromoteSideEffectsToDecl transform
 class PromoteSideEffectsToDecl::State {
 private:
  CloneContext& ctx;
  const Config& cfg;
  ProgramBuilder& b;
  /// Holds information about a for-loop that needs to be decomposed into a
  /// loop, so that declaration statements can be inserted before the condition
  /// expression or continuing statement.
  struct LoopInfo {
    ast::StatementList cond_decls;
    ast::StatementList cont_decls;
  };
  // For-loops that need to be decomposed to loops.
  std::unordered_map<const sem::ForLoopStatement*, LoopInfo> loops;
  // Inserts `decl` before `sem_expr`, possibly marking a for-loop to be
  // converted to a loop.
  bool InsertBefore(const sem::Expression* sem_expr,
                    const ast::VariableDeclStatement* decl) {
    auto* sem_stmt = sem_expr->Stmt();
    auto* stmt = sem_stmt->Declaration();
    if (auto* fl = sem_stmt->As<sem::ForLoopStatement>()) {
      // Expression used in for-loop condition.
      // For-loop needs to be decomposed to a loop.
      loops[fl].cond_decls.emplace_back(decl);
      return true;
    }
    auto* parent = sem_stmt->Parent();  // The statement's parent
    if (auto* block = parent->As<sem::BlockStatement>()) {
      // Expression's statement sits in a block. Simple case.
      // Insert the decl before the parent statement
      ctx.InsertBefore(block->Declaration()->statements, stmt, decl);
      return true;
    }
    if (auto* fl = parent->As<sem::ForLoopStatement>()) {
      // Expression is used in a for-loop. These require special care.
      if (fl->Declaration()->initializer == stmt) {
        // Expression used in for-loop initializer.
        // Insert the let above the for-loop.
        ctx.InsertBefore(fl->Block()->Declaration()->statements,
                         fl->Declaration(), decl);
        return true;
      }
      if (fl->Declaration()->continuing == stmt) {
        // Expression used in for-loop continuing.
        // For-loop needs to be decomposed to a loop.
        loops[fl].cont_decls.emplace_back(decl);
        return true;
      }
      TINT_ICE(Transform, b.Diagnostics())
          << "unhandled use of expression in for-loop";
      return false;
    }
    TINT_ICE(Transform, b.Diagnostics())
        << "unhandled expression parent statement type: "
        << parent->TypeInfo().name;
    return false;
  }
  // Hoists array and structure initializers to a constant variable, declared
  // just before the statement of usage.
  bool TypeConstructorToLet(const ast::CallExpression* expr) {
    auto* ctor = ctx.src->Sem().Get(expr);
    if (!ctor->Target()->Is<sem::TypeConstructor>()) {
      return true;
    }
    auto* sem_stmt = ctor->Stmt();
    if (!sem_stmt) {
      // Expression is outside of a statement. This usually means the
      // expression is part of a global (module-scope) constant declaration.
      // These must be constexpr, and so cannot contain the type of
      // expressions that must be sanitized.
      return true;
    }
    auto* stmt = sem_stmt->Declaration();
    if (auto* src_var_decl = stmt->As<ast::VariableDeclStatement>()) {
      if (src_var_decl->variable->constructor == expr) {
        // This statement is just a variable declaration with the
        // initializer as the constructor value. This is what we're
        // attempting to transform to, and so ignore.
        return true;
      }
    }
    auto* src_ty = ctor->Type();
    if (!src_ty->IsAnyOf<sem::Array, sem::Struct>()) {
      // We only care about array and struct initializers
      return true;
    }
    // Construct the let that holds the hoisted initializer
    auto name = b.Sym();
    auto* let = b.Const(name, nullptr, ctx.Clone(expr));
    auto* let_decl = b.Decl(let);
    if (!InsertBefore(ctor, let_decl)) {
      return false;
    }
    // Replace the initializer expression with a reference to the let
    ctx.Replace(expr, b.Expr(name));
    return true;
  }
  // Extracts array and matrix values that are dynamically indexed to a
  // temporary `var` local that is then indexed.
  bool DynamicIndexToVar(const ast::IndexAccessorExpression* access_expr) {
    auto* index_expr = access_expr->index;
    auto* object_expr = access_expr->object;
    auto& sem = ctx.src->Sem();
    if (sem.Get(index_expr)->ConstantValue()) {
      // Index expression resolves to a compile time value.
      // As this isn't a dynamic index, we can ignore this.
      return true;
    }
    auto* indexed = sem.Get(object_expr);
    if (!indexed->Type()->IsAnyOf<sem::Array, sem::Matrix>()) {
      // We only care about array and matrices.
      return true;
    }
    // Construct a `var` declaration to hold the value in memory.
    // TODO(bclayton): group multiple accesses in the same object.
    // e.g. arr[i] + arr[i+1] // Don't create two vars for this
    auto var_name = b.Symbols().New("var_for_index");
    auto* var_decl = b.Decl(b.Var(var_name, nullptr, ctx.Clone(object_expr)));
    if (!InsertBefore(indexed, var_decl)) {
      return false;
    }
    // Replace the original index expression with the new `var`.
    ctx.Replace(object_expr, b.Expr(var_name));
    return true;
  }
  // Converts any for-loops marked for conversion to loops, inserting
  // registered declaration statements before the condition or continuing
  // statement.
  void ForLoopsToLoops() {
    if (loops.empty()) {
      return;
    }
    // At least one for-loop needs to be transformed into a loop.
    ctx.ReplaceAll(
        [&](const ast::ForLoopStatement* stmt) -> const ast::Statement* {
          auto& sem = ctx.src->Sem();
          if (auto* fl = sem.Get(stmt)) {
            if (auto it = loops.find(fl); it != loops.end()) {
              auto& info = it->second;
              auto* for_loop = fl->Declaration();
              // For-loop needs to be decomposed to a loop.
              // Build the loop body's statements.
              // Start with any let declarations for the conditional
              // expression.
              auto body_stmts = info.cond_decls;
              // If the for-loop has a condition, emit this next as:
              //   if (!cond) { break; }
              if (auto* cond = for_loop->condition) {
                // !condition
                auto* not_cond = b.create<ast::UnaryOpExpression>(
                    ast::UnaryOp::kNot, ctx.Clone(cond));
                // { break; }
                auto* break_body = b.Block(b.create<ast::BreakStatement>());
                // if (!condition) { break; }
                body_stmts.emplace_back(b.If(not_cond, break_body));
              }
              // Next emit the for-loop body
              for (auto* body_stmt : for_loop->body->statements) {
                body_stmts.emplace_back(ctx.Clone(body_stmt));
              }
              // Finally create the continuing block if there was one.
              const ast::BlockStatement* continuing = nullptr;
              if (auto* cont = for_loop->continuing) {
                // Continuing block starts with any let declarations used by
                // the continuing.
                auto cont_stmts = info.cont_decls;
                cont_stmts.emplace_back(ctx.Clone(cont));
                continuing = b.Block(cont_stmts);
              }
              auto* body = b.Block(body_stmts);
              auto* loop = b.Loop(body, continuing);
              if (auto* init = for_loop->initializer) {
                return b.Block(ctx.Clone(init), loop);
              }
              return loop;
            }
          }
          return nullptr;
        });
  }
 public:
  /// Constructor
  /// @param ctx_in the CloneContext primed with the input program and
  /// @param cfg_in the transform config
  /// ProgramBuilder
  explicit State(CloneContext& ctx_in, const Config& cfg_in)
      : ctx(ctx_in), cfg(cfg_in), b(*ctx_in.dst) {}
  /// Runs the transform
  void Run() {
    // Scan the AST nodes for expressions that need to be promoted to their own
    // constant or variable declaration.
    // Note: Correct handling of nested expressions is guaranteed due to the
    // depth-first traversal of the ast::Node::Clone() methods:
    //
    // The inner-most expressions are traversed first, and they are hoisted
    // to variables declared just above the statement of use. The outer
    // expression will then be hoisted, inserting themselves between the
    // inner declaration and the statement of use. This pattern applies
    // correctly to any nested depth.
    //
    // Depth-first traversal of the AST is guaranteed because AST nodes are
    // fully immutable and require their children to be constructed first so
    // their pointer can be passed to the parent's constructor.
    for (auto* node : ctx.src->ASTNodes().Objects()) {
      if (cfg.type_ctor_to_let) {
        if (auto* call_expr = node->As<ast::CallExpression>()) {
          if (!TypeConstructorToLet(call_expr)) {
            return;
          }
        }
      }
      if (cfg.dynamic_index_to_var) {
        if (auto* access_expr = node->As<ast::IndexAccessorExpression>()) {
          if (!DynamicIndexToVar(access_expr)) {
            return;
          }
        }
      }
    }
    ForLoopsToLoops();
    ctx.Clone();
  }
 };
 PromoteSideEffectsToDecl::PromoteSideEffectsToDecl() = default;
 PromoteSideEffectsToDecl::~PromoteSideEffectsToDecl() = default;
 void PromoteSideEffectsToDecl::Run(CloneContext& ctx,
                                   const DataMap& inputs,
                                   DataMap&) {
  auto* cfg = inputs.Get<Config>();
  if (cfg == nullptr) {
    ctx.dst->Diagnostics().add_error(
        diag::System::Transform,
        "missing transform data for " + std::string(TypeInfo().name));
    return;
  }
  State state(ctx, *cfg);
  state.Run();
 }
 PromoteSideEffectsToDecl::Config::Config(bool type_ctor_to_let_in,
                                         bool dynamic_index_to_var_in)
    : type_ctor_to_let(type_ctor_to_let_in),
      dynamic_index_to_var(dynamic_index_to_var_in) {}
 PromoteSideEffectsToDecl::Config::~Config() = default;
 }  // namespace transform
 }  // namespace tint
--- a/src/transform/promote_initializers_to_const_var.h
+++ b/src/transform/promote_initializers_to_const_var.h
@ -12,27 +12,46 @@
 // See the License for the specific language governing permissions and
 // limitations under the License.
-#ifndef SRC_TRANSFORM_PROMOTE_INITIALIZERS_TO_CONST_VAR_H_
+#ifndef SRC_TRANSFORM_PROMOTE_SIDE_EFFECTS_TO_DECL_H_
-#define SRC_TRANSFORM_PROMOTE_INITIALIZERS_TO_CONST_VAR_H_
+#define SRC_TRANSFORM_PROMOTE_SIDE_EFFECTS_TO_DECL_H_
 #include "src/transform/transform.h"
 namespace tint {
 namespace transform {
-/// A transform that hoists the array and structure initializers to a constant
+/// A transform that hoists expressions with side-effects to a variable
-/// variable, declared just before the statement of usage. This transform may
+/// declaration just before the statement of usage. This transform may also
-/// also decompose for-loops into loops so that let declarations can be emitted
+/// decompose for-loops into loops so that let declarations can be emitted
 /// before loop condition expressions and/or continuing statements.
 /// @see crbug.com/tint/406
-class PromoteInitializersToConstVar
+class PromoteSideEffectsToDecl
-    : public Castable<PromoteInitializersToConstVar, Transform> {
+    : public Castable<PromoteSideEffectsToDecl, Transform> {
 public:
  /// Constructor
-  PromoteInitializersToConstVar();
+  PromoteSideEffectsToDecl();
  /// Destructor
-  ~PromoteInitializersToConstVar() override;
+  ~PromoteSideEffectsToDecl() override;
  /// Configuration options for the transform.
  struct Config : public Castable<Config, Data> {
    /// Constructor
    /// @param type_ctor_to_let whether to hoist type constructor expressions
    /// to a let
    /// @param dynamic_index_to_var whether to hoist dynamic indexed
    /// expressions to a var
    Config(bool type_ctor_to_let, bool dynamic_index_to_var);
    /// Destructor
    ~Config() override;
    /// Whether to hoist type constructor expressions to a let
    const bool type_ctor_to_let;
    /// Whether to hoist dynamic indexed expressions to a var
    const bool dynamic_index_to_var;
  };
 protected:
  /// Runs the transform using the CloneContext built for transforming a
@ -42,9 +61,12 @@ class PromoteInitializersToConstVar
  /// @param inputs optional extra transform-specific input data
  /// @param outputs optional extra transform-specific output data
  void Run(CloneContext& ctx, const DataMap& inputs, DataMap& outputs) override;
 private:
  class State;
 };
 }  // namespace transform
 }  // namespace tint
-#endif  // SRC_TRANSFORM_PROMOTE_INITIALIZERS_TO_CONST_VAR_H_
+#endif  // SRC_TRANSFORM_PROMOTE_SIDE_EFFECTS_TO_DECL_H_
--- a/src/transform/promote_side_effects_to_decl_test.cc
+++ b/src/transform/promote_side_effects_to_decl_test.cc
@ -0,0 +1,756 @@
 // Copyright 2021 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/transform/promote_side_effects_to_decl.h"
 #include "src/transform/test_helper.h"
 namespace tint {
 namespace transform {
 namespace {
 using PromoteSideEffectsToDeclTest = TransformTest;
 TEST_F(PromoteSideEffectsToDeclTest, EmptyModule) {
  auto* src = "";
  auto* expect = "";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_BasicArray) {
  auto* src = R"(
 fn f() {
  var f0 = 1.0;
  var f1 = 2.0;
  var f2 = 3.0;
  var f3 = 4.0;
  var i = array<f32, 4u>(f0, f1, f2, f3)[2];
 }
 )";
  auto* expect = R"(
 fn f() {
  var f0 = 1.0;
  var f1 = 2.0;
  var f2 = 3.0;
  var f3 = 4.0;
  let tint_symbol = array<f32, 4u>(f0, f1, f2, f3);
  var i = tint_symbol[2];
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_BasicStruct) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 };
 fn f() {
  var x = S(1, 2.0, vec3<f32>()).b;
 }
 )";
  auto* expect = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 }
 fn f() {
  let tint_symbol = S(1, 2.0, vec3<f32>());
  var x = tint_symbol.b;
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_ArrayInForLoopInit) {
  auto* src = R"(
 fn f() {
  var insert_after = 1;
  for(var i = array<f32, 4u>(0.0, 1.0, 2.0, 3.0)[2]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var insert_after = 1;
  let tint_symbol = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
  for(var i = tint_symbol[2]; ; ) {
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_StructInForLoopInit) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 };
 fn f() {
  var insert_after = 1;
  for(var x = S(1, 2.0, vec3<f32>()).b; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 struct S {
  a : i32;
  b : f32;
  c : vec3<f32>;
 }
 fn f() {
  var insert_after = 1;
  let tint_symbol = S(1, 2.0, vec3<f32>());
  for(var x = tint_symbol.b; ; ) {
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_ArrayInForLoopCond) {
  auto* src = R"(
 fn f() {
  var f = 1.0;
  for(; f == array<f32, 1u>(f)[0]; f = f + 1.0) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var f = 1.0;
  loop {
    let tint_symbol = array<f32, 1u>(f);
    if (!((f == tint_symbol[0]))) {
      break;
    }
    var marker = 1;
    continuing {
      f = (f + 1.0);
    }
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_ArrayInForLoopCont) {
  auto* src = R"(
 fn f() {
  var f = 0.0;
  for(; f < 10.0; f = f + array<f32, 1u>(1.0)[0]) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var f = 0.0;
  loop {
    if (!((f < 10.0))) {
      break;
    }
    var marker = 1;
    continuing {
      let tint_symbol = array<f32, 1u>(1.0);
      f = (f + tint_symbol[0]);
    }
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_ArrayInForLoopInitCondCont) {
  auto* src = R"(
 fn f() {
  for(var f = array<f32, 1u>(0.0)[0];
      f < array<f32, 1u>(1.0)[0];
      f = f + array<f32, 1u>(2.0)[0]) {
    var marker = 1;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  let tint_symbol = array<f32, 1u>(0.0);
  {
    var f = tint_symbol[0];
    loop {
      let tint_symbol_1 = array<f32, 1u>(1.0);
      if (!((f < tint_symbol_1[0]))) {
        break;
      }
      var marker = 1;
      continuing {
        let tint_symbol_2 = array<f32, 1u>(2.0);
        f = (f + tint_symbol_2[0]);
      }
    }
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_ArrayInArrayArray) {
  auto* src = R"(
 fn f() {
  var i = array<array<f32, 2u>, 2u>(array<f32, 2u>(1.0, 2.0), array<f32, 2u>(3.0, 4.0))[0][1];
 }
 )";
  auto* expect = R"(
 fn f() {
  let tint_symbol = array<f32, 2u>(1.0, 2.0);
  let tint_symbol_1 = array<f32, 2u>(3.0, 4.0);
  let tint_symbol_2 = array<array<f32, 2u>, 2u>(tint_symbol, tint_symbol_1);
  var i = tint_symbol_2[0][1];
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_StructNested) {
  auto* src = R"(
 struct S1 {
  a : i32;
 };
 struct S2 {
  a : i32;
  b : S1;
  c : i32;
 };
 struct S3 {
  a : S2;
 };
 fn f() {
  var x = S3(S2(1, S1(2), 3)).a.b.a;
 }
 )";
  auto* expect = R"(
 struct S1 {
  a : i32;
 }
 struct S2 {
  a : i32;
  b : S1;
  c : i32;
 }
 struct S3 {
  a : S2;
 }
 fn f() {
  let tint_symbol = S1(2);
  let tint_symbol_1 = S2(1, tint_symbol, 3);
  let tint_symbol_2 = S3(tint_symbol_1);
  var x = tint_symbol_2.a.b.a;
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_Mixed) {
  auto* src = R"(
 struct S1 {
  a : i32;
 };
 struct S2 {
  a : array<S1, 3u>;
 };
 fn f() {
  var x = S2(array<S1, 3u>(S1(1), S1(2), S1(3))).a[1].a;
 }
 )";
  auto* expect = R"(
 struct S1 {
  a : i32;
 }
 struct S2 {
  a : array<S1, 3u>;
 }
 fn f() {
  let tint_symbol = S1(1);
  let tint_symbol_1 = S1(2);
  let tint_symbol_2 = S1(3);
  let tint_symbol_3 = array<S1, 3u>(tint_symbol, tint_symbol_1, tint_symbol_2);
  let tint_symbol_4 = S2(tint_symbol_3);
  var x = tint_symbol_4.a[1].a;
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, TypeCtorToLet_NoChangeOnVarDecl) {
  auto* src = R"(
 struct S {
  a : i32;
  b : f32;
  c : i32;
 }
 fn f() {
  var local_arr = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
  var local_str = S(1, 2.0, 3);
 }
 let module_arr : array<f32, 4u> = array<f32, 4u>(0.0, 1.0, 2.0, 3.0);
 let module_str : S = S(1, 2.0, 3);
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ true,
                                             /* dynamic_index_to_var */ false);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_ArrayIndexDynamic) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 4>(1, 2, 3, 4);
  let x = p[i];
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 4>(1, 2, 3, 4);
  var var_for_index = p;
  let x = var_for_index[i];
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_MatrixIndexDynamic) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[i];
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  var var_for_index = p;
  let x = var_for_index[i];
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_ArrayIndexDynamicChain) {
  auto* src = R"(
 fn f() {
  var i : i32;
  var j : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  let x = p[i][j];
 }
 )";
  // TODO(bclayton): Optimize this case:
  // This output is not as efficient as it could be.
  // We only actually need to hoist the inner-most array to a `var`
  // (`var_for_index`), as later indexing operations will be working with
  // references, not values.
  auto* expect = R"(
 fn f() {
  var i : i32;
  var j : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  var var_for_index = p;
  var var_for_index_1 = var_for_index[i];
  let x = var_for_index_1[j];
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest,
       DynamicIndexToVar_ArrayIndexInForLoopInit) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  for(let x = p[i]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  var var_for_index = p;
  for(let x = var_for_index[i]; ; ) {
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest,
       DynamicIndexToVar_MatrixIndexInForLoopInit) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  for(let x = p[i]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  var var_for_index = p;
  for(let x = var_for_index[i]; ; ) {
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest,
       DynamicIndexToVar_ArrayIndexInForLoopCond) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 2>(1, 2);
  for(; p[i] < 3; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 2>(1, 2);
  loop {
    var var_for_index = p;
    if (!((var_for_index[i] < 3))) {
      break;
    }
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest,
       DynamicIndexToVar_MatrixIndexInForLoopCond) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  for(; p[i].x < 3.0; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  loop {
    var var_for_index = p;
    if (!((var_for_index[i].x < 3.0))) {
      break;
    }
    break;
  }
 }
 )";
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_ArrayIndexLiteral) {
  auto* src = R"(
 fn f() {
  let p = array<i32, 4>(1, 2, 3, 4);
  let x = p[1];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_MatrixIndexLiteral) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[1];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_ArrayIndexConstantLet) {
  auto* src = R"(
 fn f() {
  let p = array<i32, 4>(1, 2, 3, 4);
  let c = 1;
  let x = p[c];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_MatrixIndexConstantLet) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let c = 1;
  let x = p[c];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest, DynamicIndexToVar_ArrayIndexLiteralChain) {
  auto* src = R"(
 fn f() {
  let a = array<i32, 2>(1, 2);
  let b = array<i32, 2>(3, 4);
  let p = array<array<i32, 2>, 2>(a, b);
  let x = p[0][1];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(PromoteSideEffectsToDeclTest,
       DynamicIndexToVar_MatrixIndexLiteralChain) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[0][1];
 }
 )";
  auto* expect = src;
  DataMap data;
  data.Add<PromoteSideEffectsToDecl::Config>(/* type_ctor_to_let */ false,
                                             /* dynamic_index_to_var */ true);
  auto got = Run<PromoteSideEffectsToDecl>(src, data);
  EXPECT_EQ(expect, str(got));
 }
 }  // namespace
 }  // namespace transform
 }  // namespace tint
--- a/src/transform/var_for_dynamic_index.cc
+++ b/src/transform/var_for_dynamic_index.cc
@ -1,91 +0,0 @@
 // Copyright 2021 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/transform/var_for_dynamic_index.h"
 #include <utility>
 #include "src/program_builder.h"
 #include "src/sem/array.h"
 #include "src/sem/block_statement.h"
 #include "src/sem/expression.h"
 #include "src/sem/statement.h"
 #include "src/transform/for_loop_to_loop.h"
 namespace tint {
 namespace transform {
 VarForDynamicIndex::VarForDynamicIndex() = default;
 VarForDynamicIndex::~VarForDynamicIndex() = default;
 void VarForDynamicIndex::Run(CloneContext& ctx, const DataMap&, DataMap&) {
  ProgramBuilder out;
  if (!Requires<ForLoopToLoop>(ctx)) {
    return;
  }
  auto& sem = ctx.src->Sem();
  for (auto* node : ctx.src->ASTNodes().Objects()) {
    if (auto* access_expr = node->As<ast::IndexAccessorExpression>()) {
      // Found an array accessor expression
      auto* index_expr = access_expr->index;
      auto* object_expr = access_expr->object;
      if (sem.Get(index_expr)->ConstantValue()) {
        // Index expression resolves to a compile time value.
        // As this isn't a dynamic index, we can ignore this.
        continue;
      }
      auto* indexed = sem.Get(object_expr);
      if (!indexed->Type()->IsAnyOf<sem::Array, sem::Matrix>()) {
        // This transform currently only cares about array and matrices.
        continue;
      }
      // Construct a `var` declaration to hold the value in memory.
      // TODO(bclayton): group multiple accesses in the same object.
      // e.g. arr[i] + arr[i+1] // Don't create two vars for this
      auto var_name = ctx.dst->Symbols().New("var_for_index");
      auto* var_decl = ctx.dst->Decl(
          ctx.dst->Var(var_name, nullptr, ctx.Clone(object_expr)));
      // Statement that owns the expression
      auto* stmt = indexed->Stmt();
      // Block that owns the statement
      auto* block = stmt->Parent()->As<sem::BlockStatement>();
      if (!block) {
        TINT_ICE(Transform, ctx.dst->Diagnostics())
            << "statement parent was not a block";
        continue;
      }
      // Insert the `var` declaration before the statement that performs the
      // indexing. Note that for indexing chains, AST node ordering guarantees
      // that the inner-most index variable will be placed first in the block.
      ctx.InsertBefore(block->Declaration()->statements, stmt->Declaration(),
                       var_decl);
      // Replace the original index expression with the new `var`.
      ctx.Replace(object_expr, ctx.dst->Expr(var_name));
    }
  }
  ctx.Clone();
 }
 }  // namespace transform
 }  // namespace tint
--- a/src/transform/var_for_dynamic_index.h
+++ b/src/transform/var_for_dynamic_index.h
@ -1,49 +0,0 @@
 // Copyright 2021 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.
 #ifndef SRC_TRANSFORM_VAR_FOR_DYNAMIC_INDEX_H_
 #define SRC_TRANSFORM_VAR_FOR_DYNAMIC_INDEX_H_
 #include "src/transform/transform.h"
 namespace tint {
 namespace transform {
 /// A transform that extracts array and matrix values that are dynamically
 /// indexed to a temporary `var` local before performing the index. This
 /// transform is used by the SPIR-V writer as there is no SPIR-V instruction
 /// that can dynamically index a non-pointer composite.
 /// Requires the ForLoopToLoop transform to be run first.
 class VarForDynamicIndex : public Transform {
 public:
  /// Constructor
  VarForDynamicIndex();
  /// Destructor
  ~VarForDynamicIndex() override;
 protected:
  /// Runs the transform using the CloneContext built for transforming a
  /// program. Run() is responsible for calling Clone() on the CloneContext.
  /// @param ctx the CloneContext primed with the input program and
  /// ProgramBuilder
  /// @param inputs optional extra transform-specific input data
  /// @param outputs optional extra transform-specific output data
  void Run(CloneContext& ctx, const DataMap& inputs, DataMap& outputs) override;
 };
 }  // namespace transform
 }  // namespace tint
 #endif  // SRC_TRANSFORM_VAR_FOR_DYNAMIC_INDEX_H_
--- a/src/transform/var_for_dynamic_index_test.cc
+++ b/src/transform/var_for_dynamic_index_test.cc
@ -1,327 +0,0 @@
 // Copyright 2021 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/transform/var_for_dynamic_index.h"
 #include "src/transform/for_loop_to_loop.h"
 #include "src/transform/test_helper.h"
 namespace tint {
 namespace transform {
 namespace {
 using VarForDynamicIndexTest = TransformTest;
 TEST_F(VarForDynamicIndexTest, EmptyModule) {
  auto* src = "";
  auto* expect = "";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexDynamic) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 4>(1, 2, 3, 4);
  let x = p[i];
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 4>(1, 2, 3, 4);
  var var_for_index = p;
  let x = var_for_index[i];
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexDynamic) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[i];
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  var var_for_index = p;
  let x = var_for_index[i];
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexDynamicChain) {
  auto* src = R"(
 fn f() {
  var i : i32;
  var j : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  let x = p[i][j];
 }
 )";
  // TODO(bclayton): Optimize this case:
  // This output is not as efficient as it could be.
  // We only actually need to hoist the inner-most array to a `var`
  // (`var_for_index`), as later indexing operations will be working with
  // references, not values.
  auto* expect = R"(
 fn f() {
  var i : i32;
  var j : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  var var_for_index = p;
  var var_for_index_1 = var_for_index[i];
  let x = var_for_index_1[j];
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexInForLoopInit) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  for(let x = p[i]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  {
    var var_for_index = p;
    let x = var_for_index[i];
    loop {
      break;
    }
  }
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexInForLoopInit) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  for(let x = p[i]; ; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  {
    var var_for_index = p;
    let x = var_for_index[i];
    loop {
      break;
    }
  }
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexInForLoopCond) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 2>(1, 2);
  for(; p[i] < 3; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = array<i32, 2>(1, 2);
  loop {
    var var_for_index = p;
    if (!((var_for_index[i] < 3))) {
      break;
    }
    break;
  }
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexInForLoopCond) {
  auto* src = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  for(; p[i].x < 3.0; ) {
    break;
  }
 }
 )";
  auto* expect = R"(
 fn f() {
  var i : i32;
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  loop {
    var var_for_index = p;
    if (!((var_for_index[i].x < 3.0))) {
      break;
    }
    break;
  }
 }
 )";
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexLiteral) {
  auto* src = R"(
 fn f() {
  let p = array<i32, 4>(1, 2, 3, 4);
  let x = p[1];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexLiteral) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[1];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexConstantLet) {
  auto* src = R"(
 fn f() {
  let p = array<i32, 4>(1, 2, 3, 4);
  let c = 1;
  let x = p[c];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexConstantLet) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let c = 1;
  let x = p[c];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, ArrayIndexLiteralChain) {
  auto* src = R"(
 fn f() {
  let p = array<array<i32, 2>, 2>(array<i32, 2>(1, 2), array<i32, 2>(3, 4));
  let x = p[0][1];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 TEST_F(VarForDynamicIndexTest, MatrixIndexLiteralChain) {
  auto* src = R"(
 fn f() {
  let p = mat2x2(1.0, 2.0, 3.0, 4.0);
  let x = p[0][1];
 }
 )";
  auto* expect = src;
  auto got = Run<ForLoopToLoop, VarForDynamicIndex>(src);
  EXPECT_EQ(expect, str(got));
 }
 }  // namespace
 }  // namespace transform
 }  // namespace tint
--- a/src/writer/hlsl/generator_impl.cc
+++ b/src/writer/hlsl/generator_impl.cc
@ -57,7 +57,7 @@
 #include "src/transform/manager.h"
 #include "src/transform/num_workgroups_from_uniform.h"
 #include "src/transform/pad_array_elements.h"
-#include "src/transform/promote_initializers_to_const_var.h"
+#include "src/transform/promote_side_effects_to_decl.h"
 #include "src/transform/remove_phonies.h"
 #include "src/transform/simplify_pointers.h"
 #include "src/transform/unshadow.h"
@ -191,7 +191,11 @@ SanitizedResult Sanitize(
  // will be transformed by CalculateArrayLength
  manager.Add<transform::CalculateArrayLength>();
  manager.Add<transform::ExternalTextureTransform>();
-  manager.Add<transform::PromoteInitializersToConstVar>();
+
  data.Add<transform::PromoteSideEffectsToDecl::Config>(
      /* type_ctor_to_let */ true, /* dynamic_index_to_var */ false);
  manager.Add<transform::PromoteSideEffectsToDecl>();
  manager.Add<transform::PadArrayElements>();
  manager.Add<transform::AddEmptyEntryPoint>();
--- a/src/writer/msl/generator_impl.cc
+++ b/src/writer/msl/generator_impl.cc
@ -63,7 +63,7 @@
 #include "src/transform/manager.h"
 #include "src/transform/module_scope_var_to_entry_point_param.h"
 #include "src/transform/pad_array_elements.h"
-#include "src/transform/promote_initializers_to_const_var.h"
+#include "src/transform/promote_side_effects_to_decl.h"
 #include "src/transform/remove_phonies.h"
 #include "src/transform/simplify_pointers.h"
 #include "src/transform/unshadow.h"
@ -124,7 +124,7 @@ SanitizedResult Sanitize(
    bool disable_workgroup_init,
    const ArrayLengthFromUniformOptions& array_length_from_uniform) {
  transform::Manager manager;
-  transform::DataMap internal_inputs;
+  transform::DataMap data;
  // Build the config for the internal ArrayLengthFromUniform transform.
  transform::ArrayLengthFromUniform::Config array_length_from_uniform_cfg(
@ -162,7 +162,11 @@ SanitizedResult Sanitize(
  }
  manager.Add<transform::CanonicalizeEntryPointIO>();
  manager.Add<transform::ExternalTextureTransform>();
-  manager.Add<transform::PromoteInitializersToConstVar>();
+
  data.Add<transform::PromoteSideEffectsToDecl::Config>(
      /* type_ctor_to_let */ true, /* dynamic_index_to_var */ false);
  manager.Add<transform::PromoteSideEffectsToDecl>();
  manager.Add<transform::VectorizeScalarMatrixConstructors>();
  manager.Add<transform::WrapArraysInStructs>();
  manager.Add<transform::PadArrayElements>();
@ -172,11 +176,11 @@ SanitizedResult Sanitize(
  // it assumes that the form of the array length argument is &var.array.
  manager.Add<transform::ArrayLengthFromUniform>();
  manager.Add<transform::ModuleScopeVarToEntryPointParam>();
-  internal_inputs.Add<transform::ArrayLengthFromUniform::Config>(
+  data.Add<transform::ArrayLengthFromUniform::Config>(
      std::move(array_length_from_uniform_cfg));
-  internal_inputs.Add<transform::CanonicalizeEntryPointIO::Config>(
+  data.Add<transform::CanonicalizeEntryPointIO::Config>(
      std::move(entry_point_io_cfg));
-  auto out = manager.Run(in, internal_inputs);
+  auto out = manager.Run(in, data);
  SanitizedResult result;
  result.program = std::move(out.program);
--- a/src/writer/spirv/builder.cc
+++ b/src/writer/spirv/builder.cc
@ -47,10 +47,10 @@
 #include "src/transform/fold_constants.h"
 #include "src/transform/for_loop_to_loop.h"
 #include "src/transform/manager.h"
 #include "src/transform/promote_side_effects_to_decl.h"
 #include "src/transform/remove_unreachable_statements.h"
 #include "src/transform/simplify_pointers.h"
 #include "src/transform/unshadow.h"
 #include "src/transform/var_for_dynamic_index.h"
 #include "src/transform/vectorize_scalar_matrix_constructors.h"
 #include "src/transform/zero_init_workgroup_memory.h"
 #include "src/utils/defer.h"
@ -271,7 +271,10 @@ SanitizedResult Sanitize(const Program* in,
  manager.Add<transform::CanonicalizeEntryPointIO>();
  manager.Add<transform::AddEmptyEntryPoint>();
  manager.Add<transform::AddSpirvBlockDecoration>();
-  manager.Add<transform::VarForDynamicIndex>();
+
  data.Add<transform::PromoteSideEffectsToDecl::Config>(
      /* type_ctor_to_let */ false, /* dynamic_index_to_var */ true);
  manager.Add<transform::PromoteSideEffectsToDecl>();
  data.Add<transform::CanonicalizeEntryPointIO::Config>(
      transform::CanonicalizeEntryPointIO::Config(
--- a/test/BUILD.gn
+++ b/test/BUILD.gn
@ -320,7 +320,7 @@ tint_unittests_source_set("tint_unittests_transform_src") {
    "../src/transform/multiplanar_external_texture_test.cc",
    "../src/transform/num_workgroups_from_uniform_test.cc",
    "../src/transform/pad_array_elements_test.cc",
-    "../src/transform/promote_initializers_to_const_var_test.cc",
+    "../src/transform/promote_side_effects_to_decl_test.cc",
    "../src/transform/remove_phonies_test.cc",
    "../src/transform/remove_unreachable_statements_test.cc",
    "../src/transform/renamer_test.cc",
@ -330,7 +330,6 @@ tint_unittests_source_set("tint_unittests_transform_src") {
    "../src/transform/test_helper.h",
    "../src/transform/transform_test.cc",
    "../src/transform/unshadow_test.cc",
    "../src/transform/var_for_dynamic_index_test.cc",
    "../src/transform/vectorize_scalar_matrix_constructors_test.cc",
    "../src/transform/vertex_pulling_test.cc",
    "../src/transform/wrap_arrays_in_structs_test.cc",