src/tint/ast/transform/preserve_padding.cc - dawn - 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/ast/transform/preserve_padding.h"

 #include <unordered_set>
 #include <utility>

 #include "src/tint/program_builder.h"
 #include "src/tint/sem/struct.h"
 #include "src/tint/switch.h"
 #include "src/tint/type/reference.h"
 #include "src/tint/utils/map.h"
 #include "src/tint/utils/vector.h"

 TINT_INSTANTIATE_TYPEINFO(tint::ast::transform::PreservePadding);

 using namespace tint::number_suffixes;  // NOLINT

 namespace tint::ast::transform {

 PreservePadding::PreservePadding() = default;

 PreservePadding::~PreservePadding() = default;

 /// The PIMPL state for the PreservePadding transform
 struct PreservePadding::State {
     /// Constructor
     /// @param src the source Program
     explicit State(const Program* src) : ctx{&b, src, /* auto_clone_symbols */ true} {}

     /// The main function for the transform.
     /// @returns the ApplyResult
     ApplyResult Run() {
         // Gather a list of assignments that need to be transformed.
         std::unordered_set<const AssignmentStatement*> assignments_to_transform;
         for (auto* node : ctx.src->ASTNodes().Objects()) {
             Switch(
                 node,  //
                 [&](const AssignmentStatement* assign) {
                     auto* ty = sem.GetVal(assign->lhs)->Type();
                     if (assign->lhs->Is<PhonyExpression>()) {
                         // Ignore phony assignment.
                         return;
                     }
                     if (ty->As<type::Reference>()->AddressSpace() !=
                         builtin::AddressSpace::kStorage) {
                         // We only care about assignments that write to variables in the storage
                         // address space, as nothing else is host-visible.
                         return;
                     }
                     if (HasPadding(ty->UnwrapRef())) {
                         // The assigned type has padding bytes, so we need to decompose the writes.
                         assignments_to_transform.insert(assign);
                     }
                 },
                 [&](const Enable* enable) {
                     // Check if the full pointer parameters extension is already enabled.
                     if (enable->HasExtension(
                             builtin::Extension::kChromiumExperimentalFullPtrParameters)) {
                         ext_enabled = true;
                     }
                 });
         }
         if (assignments_to_transform.empty()) {
             return SkipTransform;
         }

         // Replace all assignments that include padding with decomposed versions.
         ctx.ReplaceAll([&](const AssignmentStatement* assign) -> const Statement* {
             if (!assignments_to_transform.count(assign)) {
                 return nullptr;
             }
             auto* ty = sem.GetVal(assign->lhs)->Type()->UnwrapRef();
             return MakeAssignment(ty, ctx.Clone(assign->lhs), ctx.Clone(assign->rhs));
         });

         ctx.Clone();
         return Program(std::move(b));
     }

     /// Create a statement that will perform the assignment `lhs = rhs`, creating and using helper
     /// functions to decompose the assignment into element-wise copies if needed.
     /// @param ty the type of the assignment
     /// @param lhs the lhs expression (in the destination program)
     /// @param rhs the rhs expression (in the destination program)
     /// @returns the statement that performs the assignment
     const Statement* MakeAssignment(const type::Type* ty,
                                     const Expression* lhs,
                                     const Expression* rhs) {
         if (!HasPadding(ty)) {
             // No padding - use a regular assignment.
             return b.Assign(lhs, rhs);
         }

         // Call (and create if necessary) a helper function that assigns a composite using the
         // statements in `body`. The helper will have the form:
         //   fn assign_helper_T(dest : ptr<storage, T, read_write>, value : T) {
         //     <body>
         //   }
         // It will be called by passing a pointer to the original LHS:
         //   assign_helper_T(&lhs, rhs);
         //
         // Since this requires passing pointers to the storage address space, this will also enable
         // the chromium_experimental_full_ptr_parameters extension.
         const char* kDestParamName = "dest";
         const char* kValueParamName = "value";
         auto call_helper = [&](auto&& body) {
             EnableExtension();
             auto helper = helpers.GetOrCreate(ty, [&]() {
                 auto helper_name = b.Symbols().New("assign_and_preserve_padding");
                 utils::Vector<const Parameter*, 2> params = {
                     b.Param(kDestParamName,
                             b.ty.pointer(CreateASTTypeFor(ctx, ty), builtin::AddressSpace::kStorage,
                                          builtin::Access::kReadWrite)),
                     b.Param(kValueParamName, CreateASTTypeFor(ctx, ty)),
                 };
                 b.Func(helper_name, params, b.ty.void_(), body());
                 return helper_name;
             });
             return b.CallStmt(b.Call(helper, b.AddressOf(lhs), rhs));
         };

         return Switch(
             ty,  //
             [&](const type::Array* arr) {
                 // Call a helper function that uses a loop to assigns each element separately.
                 return call_helper([&]() {
                     utils::Vector<const Statement*, 8> body;
                     auto* idx = b.Var("i", b.Expr(0_u));
                     body.Push(
                         b.For(b.Decl(idx), b.LessThan(idx, u32(arr->ConstantCount().value())),
                               b.Assign(idx, b.Add(idx, 1_u)),
                               b.Block(MakeAssignment(arr->ElemType(),
                                                      b.IndexAccessor(b.Deref(kDestParamName), idx),
                                                      b.IndexAccessor(kValueParamName, idx)))));
                     return body;
                 });
             },
             [&](const type::Matrix* mat) {
                 // Call a helper function that assigns each column separately.
                 return call_helper([&]() {
                     utils::Vector<const Statement*, 4> body;
                     for (uint32_t i = 0; i < mat->columns(); i++) {
                         body.Push(MakeAssignment(mat->ColumnType(),
                                                  b.IndexAccessor(b.Deref(kDestParamName), u32(i)),
                                                  b.IndexAccessor(kValueParamName, u32(i))));
                     }
                     return body;
                 });
             },
             [&](const type::Struct* str) {
                 // Call a helper function that assigns each member separately.
                 return call_helper([&]() {
                     utils::Vector<const Statement*, 8> body;
                     for (auto member : str->Members()) {
                         auto name = member->Name().Name();
                         body.Push(MakeAssignment(member->Type(),
                                                  b.MemberAccessor(b.Deref(kDestParamName), name),
                                                  b.MemberAccessor(kValueParamName, name)));
                     }
                     return body;
                 });
             },
             [&](Default) {
                 TINT_ICE(Transform, b.Diagnostics()) << "unhandled type with padding";
                 return nullptr;
             });
     }

     /// Checks if a type contains padding bytes.
     /// @param ty the type to check
     /// @returns true if `ty` (or any of its contained types) have padding bytes
     bool HasPadding(const type::Type* ty) {
         return Switch(
             ty,  //
             [&](const type::Array* arr) {
                 auto* elem_ty = arr->ElemType();
                 if (elem_ty->Size() % elem_ty->Align() > 0) {
                     return true;
                 }
                 return HasPadding(elem_ty);
             },
             [&](const type::Matrix* mat) {
                 auto* col_ty = mat->ColumnType();
                 if (mat->ColumnStride() > col_ty->Size()) {
                     return true;
                 }
                 return HasPadding(col_ty);
             },
             [&](const type::Struct* str) {
                 uint32_t current_offset = 0;
                 for (auto* member : str->Members()) {
                     if (member->Offset() > current_offset) {
                         return true;
                     }
                     if (HasPadding(member->Type())) {
                         return true;
                     }
                     current_offset += member->Type()->Size();
                 }
                 return (current_offset < str->Size());
             },
             [&](Default) { return false; });
     }

     /// Enable the full pointer parameters extension, if we have not already done so.
     void EnableExtension() {
         if (!ext_enabled) {
             b.Enable(builtin::Extension::kChromiumExperimentalFullPtrParameters);
             ext_enabled = true;
         }
     }

   private:
     /// The program builder
     ProgramBuilder b;
     /// The clone context
     CloneContext ctx;
     /// Alias to the semantic info in ctx.src
     const sem::Info& sem = ctx.src->Sem();
     /// Alias to the symbols in ctx.src
     const SymbolTable& sym = ctx.src->Symbols();
     /// Flag to track whether we have already enabled the full pointer parameters extension.
     bool ext_enabled = false;
     /// Map of semantic types to their assignment helper functions.
     utils::Hashmap<const type::Type*, Symbol, 8> helpers;
 };

 Transform::ApplyResult PreservePadding::Apply(const Program* program,
                                               const DataMap&,
                                               DataMap&) const {
     return State(program).Run();
 }

 }  // namespace tint::ast::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/ast/transform/preserve_padding.h"

	#include <unordered_set>
	#include <utility>

	#include "src/tint/program_builder.h"
	#include "src/tint/sem/struct.h"
	#include "src/tint/switch.h"
	#include "src/tint/type/reference.h"
	#include "src/tint/utils/map.h"
	#include "src/tint/utils/vector.h"

	TINT_INSTANTIATE_TYPEINFO(tint::ast::transform::PreservePadding);

	using namespace tint::number_suffixes; // NOLINT

	namespace tint::ast::transform {

	PreservePadding::PreservePadding() = default;

	PreservePadding::~PreservePadding() = default;

	/// The PIMPL state for the PreservePadding transform
	struct PreservePadding::State {
	/// Constructor
	/// @param src the source Program
	explicit State(const Program* src) : ctx{&b, src, /* auto_clone_symbols */ true} {}

	/// The main function for the transform.
	/// @returns the ApplyResult
	ApplyResult Run() {
	// Gather a list of assignments that need to be transformed.
	std::unordered_set<const AssignmentStatement*> assignments_to_transform;
	for (auto* node : ctx.src->ASTNodes().Objects()) {
	Switch(
	node, //
	[&](const AssignmentStatement* assign) {
	auto* ty = sem.GetVal(assign->lhs)->Type();
	if (assign->lhs->Is<PhonyExpression>()) {
	// Ignore phony assignment.
	return;
	}
	if (ty->As<type::Reference>()->AddressSpace() !=
	builtin::AddressSpace::kStorage) {
	// We only care about assignments that write to variables in the storage
	// address space, as nothing else is host-visible.
	return;
	}
	if (HasPadding(ty->UnwrapRef())) {
	// The assigned type has padding bytes, so we need to decompose the writes.
	assignments_to_transform.insert(assign);
	}
	},
	[&](const Enable* enable) {
	// Check if the full pointer parameters extension is already enabled.
	if (enable->HasExtension(
	builtin::Extension::kChromiumExperimentalFullPtrParameters)) {
	ext_enabled = true;
	}
	});
	}
	if (assignments_to_transform.empty()) {
	return SkipTransform;
	}

	// Replace all assignments that include padding with decomposed versions.
	ctx.ReplaceAll([&](const AssignmentStatement* assign) -> const Statement* {
	if (!assignments_to_transform.count(assign)) {
	return nullptr;
	}
	auto* ty = sem.GetVal(assign->lhs)->Type()->UnwrapRef();
	return MakeAssignment(ty, ctx.Clone(assign->lhs), ctx.Clone(assign->rhs));
	});

	ctx.Clone();
	return Program(std::move(b));
	}

	/// Create a statement that will perform the assignment `lhs = rhs`, creating and using helper
	/// functions to decompose the assignment into element-wise copies if needed.
	/// @param ty the type of the assignment
	/// @param lhs the lhs expression (in the destination program)
	/// @param rhs the rhs expression (in the destination program)
	/// @returns the statement that performs the assignment
	const Statement* MakeAssignment(const type::Type* ty,
	const Expression* lhs,
	const Expression* rhs) {
	if (!HasPadding(ty)) {
	// No padding - use a regular assignment.
	return b.Assign(lhs, rhs);
	}

	// Call (and create if necessary) a helper function that assigns a composite using the
	// statements in `body`. The helper will have the form:
	// fn assign_helper_T(dest : ptr<storage, T, read_write>, value : T) {
	// <body>
	// }
	// It will be called by passing a pointer to the original LHS:
	// assign_helper_T(&lhs, rhs);
	//
	// Since this requires passing pointers to the storage address space, this will also enable
	// the chromium_experimental_full_ptr_parameters extension.
	const char* kDestParamName = "dest";
	const char* kValueParamName = "value";
	auto call_helper = [&](auto&& body) {
	EnableExtension();
	auto helper = helpers.GetOrCreate(ty, [&]() {
	auto helper_name = b.Symbols().New("assign_and_preserve_padding");
	utils::Vector<const Parameter*, 2> params = {
	b.Param(kDestParamName,
	b.ty.pointer(CreateASTTypeFor(ctx, ty), builtin::AddressSpace::kStorage,
	builtin::Access::kReadWrite)),
	b.Param(kValueParamName, CreateASTTypeFor(ctx, ty)),
	};
	b.Func(helper_name, params, b.ty.void_(), body());
	return helper_name;
	});
	return b.CallStmt(b.Call(helper, b.AddressOf(lhs), rhs));
	};

	return Switch(
	ty, //
	[&](const type::Array* arr) {
	// Call a helper function that uses a loop to assigns each element separately.
	return call_helper([&]() {
	utils::Vector<const Statement*, 8> body;
	auto* idx = b.Var("i", b.Expr(0_u));
	body.Push(
	b.For(b.Decl(idx), b.LessThan(idx, u32(arr->ConstantCount().value())),
	b.Assign(idx, b.Add(idx, 1_u)),
	b.Block(MakeAssignment(arr->ElemType(),
	b.IndexAccessor(b.Deref(kDestParamName), idx),
	b.IndexAccessor(kValueParamName, idx)))));
	return body;
	});
	},
	[&](const type::Matrix* mat) {
	// Call a helper function that assigns each column separately.
	return call_helper([&]() {
	utils::Vector<const Statement*, 4> body;
	for (uint32_t i = 0; i < mat->columns(); i++) {
	body.Push(MakeAssignment(mat->ColumnType(),
	b.IndexAccessor(b.Deref(kDestParamName), u32(i)),
	b.IndexAccessor(kValueParamName, u32(i))));
	}
	return body;
	});
	},
	[&](const type::Struct* str) {
	// Call a helper function that assigns each member separately.
	return call_helper([&]() {
	utils::Vector<const Statement*, 8> body;
	for (auto member : str->Members()) {
	auto name = member->Name().Name();
	body.Push(MakeAssignment(member->Type(),
	b.MemberAccessor(b.Deref(kDestParamName), name),
	b.MemberAccessor(kValueParamName, name)));
	}
	return body;
	});
	},
	[&](Default) {
	TINT_ICE(Transform, b.Diagnostics()) << "unhandled type with padding";
	return nullptr;
	});
	}

	/// Checks if a type contains padding bytes.
	/// @param ty the type to check
	/// @returns true if `ty` (or any of its contained types) have padding bytes
	bool HasPadding(const type::Type* ty) {
	return Switch(
	ty, //
	[&](const type::Array* arr) {
	auto* elem_ty = arr->ElemType();
	if (elem_ty->Size() % elem_ty->Align() > 0) {
	return true;
	}
	return HasPadding(elem_ty);
	},
	[&](const type::Matrix* mat) {
	auto* col_ty = mat->ColumnType();
	if (mat->ColumnStride() > col_ty->Size()) {
	return true;
	}
	return HasPadding(col_ty);
	},
	[&](const type::Struct* str) {
	uint32_t current_offset = 0;
	for (auto* member : str->Members()) {
	if (member->Offset() > current_offset) {
	return true;
	}
	if (HasPadding(member->Type())) {
	return true;
	}
	current_offset += member->Type()->Size();
	}
	return (current_offset < str->Size());
	},
	[&](Default) { return false; });
	}

	/// Enable the full pointer parameters extension, if we have not already done so.
	void EnableExtension() {
	if (!ext_enabled) {
	b.Enable(builtin::Extension::kChromiumExperimentalFullPtrParameters);
	ext_enabled = true;
	}
	}

	private:
	/// The program builder
	ProgramBuilder b;
	/// The clone context
	CloneContext ctx;
	/// Alias to the semantic info in ctx.src
	const sem::Info& sem = ctx.src->Sem();
	/// Alias to the symbols in ctx.src
	const SymbolTable& sym = ctx.src->Symbols();
	/// Flag to track whether we have already enabled the full pointer parameters extension.
	bool ext_enabled = false;
	/// Map of semantic types to their assignment helper functions.
	utils::Hashmap<const type::Type*, Symbol, 8> helpers;
	};

	Transform::ApplyResult PreservePadding::Apply(const Program* program,
	const DataMap&,
	DataMap&) const {
	return State(program).Run();
	}

	} // namespace tint::ast::transform