dawn-cmake/src/transform/vertex_pulling_transform.cc

// Copyright 2020 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/vertex_pulling_transform.h"

#include <utility>

#include "src/ast/array_accessor_expression.h"
#include "src/ast/assignment_statement.h"
#include "src/ast/binary_expression.h"
#include "src/ast/bitcast_expression.h"
#include "src/ast/decorated_variable.h"
#include "src/ast/member_accessor_expression.h"
#include "src/ast/scalar_constructor_expression.h"
#include "src/ast/stride_decoration.h"
#include "src/ast/struct.h"
#include "src/ast/struct_block_decoration.h"
#include "src/ast/struct_decoration.h"
#include "src/ast/struct_member.h"
#include "src/ast/struct_member_offset_decoration.h"
#include "src/ast/type/array_type.h"
#include "src/ast/type/f32_type.h"
#include "src/ast/type/i32_type.h"
#include "src/ast/type/struct_type.h"
#include "src/ast/type/u32_type.h"
#include "src/ast/type/vector_type.h"
#include "src/ast/type_constructor_expression.h"
#include "src/ast/uint_literal.h"
#include "src/ast/variable_decl_statement.h"

namespace tint {
namespace transform {
namespace {

static const char kVertexBufferNamePrefix[] = "_tint_pulling_vertex_buffer_";
static const char kStructBufferName[] = "_tint_vertex_data";
static const char kStructName[] = "TintVertexData";
static const char kPullingPosVarName[] = "_tint_pulling_pos";
static const char kDefaultVertexIndexName[] = "_tint_pulling_vertex_index";
static const char kDefaultInstanceIndexName[] = "_tint_pulling_instance_index";

}  // namespace

VertexPullingTransform::VertexPullingTransform(Context* ctx, ast::Module* mod)
    : Transformer(ctx, mod) {}

VertexPullingTransform::~VertexPullingTransform() = default;

void VertexPullingTransform::SetVertexState(
    std::unique_ptr<VertexStateDescriptor> vertex_state) {
  vertex_state_ = std::move(vertex_state);
}

void VertexPullingTransform::SetEntryPoint(std::string entry_point) {
  entry_point_name_ = std::move(entry_point);
}

void VertexPullingTransform::SetPullingBufferBindingSet(uint32_t number) {
  pulling_set_ = number;
}

bool VertexPullingTransform::Run() {
  // Check SetVertexState was called
  if (vertex_state_ == nullptr) {
    error_ = "SetVertexState not called";
    return false;
  }

  // Find entry point
  auto* func = mod_->FindFunctionByNameAndStage(entry_point_name_,
                                                ast::PipelineStage::kVertex);
  if (func == nullptr) {
    error_ = "Vertex stage entry point not found";
    return false;
  }

  // Save the vertex function
  auto* vertex_func = mod_->FindFunctionByName(func->name());

  // TODO(idanr): Need to check shader locations in descriptor cover all
  // attributes

  // TODO(idanr): Make sure we covered all error cases, to guarantee the
  // following stages will pass

  FindOrInsertVertexIndexIfUsed();
  FindOrInsertInstanceIndexIfUsed();
  ConvertVertexInputVariablesToPrivate();
  AddVertexStorageBuffers();
  AddVertexPullingPreamble(vertex_func);

  return true;
}

std::string VertexPullingTransform::GetVertexBufferName(uint32_t index) {
  return kVertexBufferNamePrefix + std::to_string(index);
}

void VertexPullingTransform::FindOrInsertVertexIndexIfUsed() {
  bool uses_vertex_step_mode = false;
  for (const VertexBufferLayoutDescriptor& buffer_layout :
       vertex_state_->vertex_buffers) {
    if (buffer_layout.step_mode == InputStepMode::kVertex) {
      uses_vertex_step_mode = true;
      break;
    }
  }
  if (!uses_vertex_step_mode) {
    return;
  }

  // Look for an existing vertex index builtin
  for (auto* v : mod_->global_variables()) {
    if (!v->Is<ast::DecoratedVariable>() ||
        v->storage_class() != ast::StorageClass::kInput) {
      continue;
    }

    for (auto* d : v->As<ast::DecoratedVariable>()->decorations()) {
      if (d->Is<ast::BuiltinDecoration>() &&
          d->As<ast::BuiltinDecoration>()->value() ==
              ast::Builtin::kVertexIdx) {
        vertex_index_name_ = v->name();
        return;
      }
    }
  }

  // We didn't find a vertex index builtin, so create one
  vertex_index_name_ = kDefaultVertexIndexName;

  auto* var = create<ast::DecoratedVariable>(create<ast::Variable>(
      vertex_index_name_, ast::StorageClass::kInput, GetI32Type()));

  ast::VariableDecorationList decorations;
  decorations.push_back(
      create<ast::BuiltinDecoration>(ast::Builtin::kVertexIdx, Source{}));

  var->set_decorations(std::move(decorations));
  mod_->AddGlobalVariable(var);
}

void VertexPullingTransform::FindOrInsertInstanceIndexIfUsed() {
  bool uses_instance_step_mode = false;
  for (const VertexBufferLayoutDescriptor& buffer_layout :
       vertex_state_->vertex_buffers) {
    if (buffer_layout.step_mode == InputStepMode::kInstance) {
      uses_instance_step_mode = true;
      break;
    }
  }
  if (!uses_instance_step_mode) {
    return;
  }

  // Look for an existing instance index builtin
  for (auto* v : mod_->global_variables()) {
    if (!v->Is<ast::DecoratedVariable>() ||
        v->storage_class() != ast::StorageClass::kInput) {
      continue;
    }

    for (auto* d : v->As<ast::DecoratedVariable>()->decorations()) {
      if (d->Is<ast::BuiltinDecoration>() &&
          d->As<ast::BuiltinDecoration>()->value() ==
              ast::Builtin::kInstanceIdx) {
        instance_index_name_ = v->name();
        return;
      }
    }
  }

  // We didn't find an instance index builtin, so create one
  instance_index_name_ = kDefaultInstanceIndexName;

  auto* var = create<ast::DecoratedVariable>(create<ast::Variable>(
      instance_index_name_, ast::StorageClass::kInput, GetI32Type()));

  ast::VariableDecorationList decorations;
  decorations.push_back(
      create<ast::BuiltinDecoration>(ast::Builtin::kInstanceIdx, Source{}));

  var->set_decorations(std::move(decorations));
  mod_->AddGlobalVariable(var);
}

void VertexPullingTransform::ConvertVertexInputVariablesToPrivate() {
  for (auto*& v : mod_->global_variables()) {
    if (!v->Is<ast::DecoratedVariable>() ||
        v->storage_class() != ast::StorageClass::kInput) {
      continue;
    }

    for (auto* d : v->As<ast::DecoratedVariable>()->decorations()) {
      if (auto* l = d->As<ast::LocationDecoration>()) {
        uint32_t location = l->value();
        // This is where the replacement happens. Expressions use identifier
        // strings instead of pointers, so we don't need to update any other
        // place in the AST.
        v = create<ast::Variable>(v->name(), ast::StorageClass::kPrivate,
                                  v->type());
        location_to_var_[location] = v;
        break;
      }
    }
  }
}

void VertexPullingTransform::AddVertexStorageBuffers() {
  // TODO(idanr): Make this readonly https://github.com/gpuweb/gpuweb/issues/935
  // The array inside the struct definition
  auto internal_array = std::make_unique<ast::type::Array>(GetU32Type());
  ast::ArrayDecorationList ary_decos;
  ary_decos.push_back(create<ast::StrideDecoration>(4u, Source{}));
  internal_array->set_decorations(std::move(ary_decos));

  auto* internal_array_type = mod_->unique_type(std::move(internal_array));

  // Creating the struct type
  ast::StructMemberList members;
  ast::StructMemberDecorationList member_dec;
  member_dec.push_back(create<ast::StructMemberOffsetDecoration>(0u, Source{}));

  members.push_back(create<ast::StructMember>(
      kStructBufferName, internal_array_type, std::move(member_dec)));

  ast::StructDecorationList decos;
  decos.push_back(create<ast::StructBlockDecoration>(Source{}));

  auto* struct_type = mod_->create<ast::type::Struct>(
      kStructName, create<ast::Struct>(std::move(decos), std::move(members)));

  for (uint32_t i = 0; i < vertex_state_->vertex_buffers.size(); ++i) {
    // The decorated variable with struct type
    auto* var = create<ast::DecoratedVariable>(
        create<ast::Variable>(GetVertexBufferName(i),
                              ast::StorageClass::kStorageBuffer, struct_type));

    // Add decorations
    ast::VariableDecorationList decorations;
    decorations.push_back(create<ast::BindingDecoration>(i, Source{}));
    decorations.push_back(create<ast::SetDecoration>(pulling_set_, Source{}));
    var->set_decorations(std::move(decorations));

    mod_->AddGlobalVariable(var);
  }
  mod_->AddConstructedType(struct_type);
}

void VertexPullingTransform::AddVertexPullingPreamble(
    ast::Function* vertex_func) {
  // Assign by looking at the vertex descriptor to find attributes with matching
  // location.

  // A block statement allowing us to use append instead of insert
  auto* block = create<ast::BlockStatement>();

  // Declare the |kPullingPosVarName| variable in the shader
  auto* pos_declaration =
      create<ast::VariableDeclStatement>(create<ast::Variable>(
          kPullingPosVarName, ast::StorageClass::kFunction, GetI32Type()));

  // |kPullingPosVarName| refers to the byte location of the current read. We
  // declare a variable in the shader to avoid having to reuse Expression
  // objects.
  block->append(pos_declaration);

  for (uint32_t i = 0; i < vertex_state_->vertex_buffers.size(); ++i) {
    const VertexBufferLayoutDescriptor& buffer_layout =
        vertex_state_->vertex_buffers[i];

    for (const VertexAttributeDescriptor& attribute_desc :
         buffer_layout.attributes) {
      auto it = location_to_var_.find(attribute_desc.shader_location);
      if (it == location_to_var_.end()) {
        continue;
      }
      auto* v = it->second;

      // Identifier to index by
      auto* index_identifier = create<ast::IdentifierExpression>(
          buffer_layout.step_mode == InputStepMode::kVertex
              ? vertex_index_name_
              : instance_index_name_);

      // An expression for the start of the read in the buffer in bytes
      auto* pos_value = create<ast::BinaryExpression>(
          ast::BinaryOp::kAdd,
          create<ast::BinaryExpression>(
              ast::BinaryOp::kMultiply, index_identifier,
              GenUint(static_cast<uint32_t>(buffer_layout.array_stride))),
          GenUint(static_cast<uint32_t>(attribute_desc.offset)));

      // Update position of the read
      auto* set_pos_expr = create<ast::AssignmentStatement>(
          CreatePullingPositionIdent(), pos_value);
      block->append(set_pos_expr);

      block->append(create<ast::AssignmentStatement>(
          create<ast::IdentifierExpression>(v->name()),
          AccessByFormat(i, attribute_desc.format)));
    }
  }

  vertex_func->body()->insert(0, block);
}

ast::Expression* VertexPullingTransform::GenUint(uint32_t value) {
  return create<ast::ScalarConstructorExpression>(
      create<ast::UintLiteral>(GetU32Type(), value));
}

ast::Expression* VertexPullingTransform::CreatePullingPositionIdent() {
  return create<ast::IdentifierExpression>(kPullingPosVarName);
}

ast::Expression* VertexPullingTransform::AccessByFormat(uint32_t buffer,
                                                        VertexFormat format) {
  // TODO(idanr): this doesn't account for the format of the attribute in the
  // shader. ex: vec<u32> in shader, and attribute claims VertexFormat::Float4
  // right now, we would try to assign a vec4<f32> to this attribute, but we
  // really need to assign a vec4<u32> by casting.
  // We could split this function to first do memory accesses and unpacking into
  // int/uint/float1-4/etc, then convert that variable to a var<in> with the
  // conversion defined in the WebGPU spec.
  switch (format) {
    case VertexFormat::kU32:
      return AccessU32(buffer, CreatePullingPositionIdent());
    case VertexFormat::kI32:
      return AccessI32(buffer, CreatePullingPositionIdent());
    case VertexFormat::kF32:
      return AccessF32(buffer, CreatePullingPositionIdent());
    case VertexFormat::kVec2F32:
      return AccessVec(buffer, 4, GetF32Type(), VertexFormat::kF32, 2);
    case VertexFormat::kVec3F32:
      return AccessVec(buffer, 4, GetF32Type(), VertexFormat::kF32, 3);
    case VertexFormat::kVec4F32:
      return AccessVec(buffer, 4, GetF32Type(), VertexFormat::kF32, 4);
    default:
      return nullptr;
  }
}

ast::Expression* VertexPullingTransform::AccessU32(uint32_t buffer,
                                                   ast::Expression* pos) {
  // Here we divide by 4, since the buffer is uint32 not uint8. The input buffer
  // has byte offsets for each attribute, and we will convert it to u32 indexes
  // by dividing. Then, that element is going to be read, and if needed,
  // unpacked into an appropriate variable. All reads should end up here as a
  // base case.
  return create<ast::ArrayAccessorExpression>(
      create<ast::MemberAccessorExpression>(
          create<ast::IdentifierExpression>(GetVertexBufferName(buffer)),
          create<ast::IdentifierExpression>(kStructBufferName)),
      create<ast::BinaryExpression>(ast::BinaryOp::kDivide, pos, GenUint(4)));
}

ast::Expression* VertexPullingTransform::AccessI32(uint32_t buffer,
                                                   ast::Expression* pos) {
  // as<T> reinterprets bits
  return create<ast::BitcastExpression>(GetI32Type(), AccessU32(buffer, pos));
}

ast::Expression* VertexPullingTransform::AccessF32(uint32_t buffer,
                                                   ast::Expression* pos) {
  // as<T> reinterprets bits
  return create<ast::BitcastExpression>(GetF32Type(), AccessU32(buffer, pos));
}

ast::Expression* VertexPullingTransform::AccessPrimitive(uint32_t buffer,
                                                         ast::Expression* pos,
                                                         VertexFormat format) {
  // This function uses a position expression to read, rather than using the
  // position variable. This allows us to read from offset positions relative to
  // |kPullingPosVarName|. We can't call AccessByFormat because it reads only
  // from the position variable.
  switch (format) {
    case VertexFormat::kU32:
      return AccessU32(buffer, pos);
    case VertexFormat::kI32:
      return AccessI32(buffer, pos);
    case VertexFormat::kF32:
      return AccessF32(buffer, pos);
    default:
      return nullptr;
  }
}

ast::Expression* VertexPullingTransform::AccessVec(uint32_t buffer,
                                                   uint32_t element_stride,
                                                   ast::type::Type* base_type,
                                                   VertexFormat base_format,
                                                   uint32_t count) {
  ast::ExpressionList expr_list;
  for (uint32_t i = 0; i < count; ++i) {
    // Offset read position by element_stride for each component
    auto* cur_pos = create<ast::BinaryExpression>(ast::BinaryOp::kAdd,
                                                  CreatePullingPositionIdent(),
                                                  GenUint(element_stride * i));
    expr_list.push_back(AccessPrimitive(buffer, cur_pos, base_format));
  }

  return create<ast::TypeConstructorExpression>(
      mod_->create<ast::type::Vector>(base_type, count), std::move(expr_list));
}

ast::type::Type* VertexPullingTransform::GetU32Type() {
  return mod_->create<ast::type::U32>();
}

ast::type::Type* VertexPullingTransform::GetI32Type() {
  return mod_->create<ast::type::I32>();
}

ast::type::Type* VertexPullingTransform::GetF32Type() {
  return mod_->create<ast::type::F32>();
}

VertexBufferLayoutDescriptor::VertexBufferLayoutDescriptor() = default;

VertexBufferLayoutDescriptor::VertexBufferLayoutDescriptor(
    uint64_t in_array_stride,
    InputStepMode in_step_mode,
    std::vector<VertexAttributeDescriptor> in_attributes)
    : array_stride(in_array_stride),
      step_mode(in_step_mode),
      attributes(std::move(in_attributes)) {}

VertexBufferLayoutDescriptor::VertexBufferLayoutDescriptor(
    const VertexBufferLayoutDescriptor& other)
    : array_stride(other.array_stride),
      step_mode(other.step_mode),
      attributes(other.attributes) {}

VertexBufferLayoutDescriptor::~VertexBufferLayoutDescriptor() = default;

VertexStateDescriptor::VertexStateDescriptor() = default;

VertexStateDescriptor::VertexStateDescriptor(
    std::vector<VertexBufferLayoutDescriptor> in_vertex_buffers)
    : vertex_buffers(std::move(in_vertex_buffers)) {}

VertexStateDescriptor::VertexStateDescriptor(const VertexStateDescriptor& other)
    : vertex_buffers(other.vertex_buffers) {}

VertexStateDescriptor::~VertexStateDescriptor() = default;

}  // namespace transform
}  // namespace tint