runtime/llvm_codegen/codegen/dart.h - sdk.git - Git at Google

 // Copyright (c) 2019, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_
 #define RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_

 #include <memory>
 #include <vector>
 #include <string>

 #include "llvm/ADT/StringRef.h"
 #include "llvm/IR/IRBuilder.h"
 #include "llvm/IR/Module.h"
 #include "llvm/IR/ValueSymbolTable.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/WithColor.h"

 // Ensure to use our own zone.
 #include "custom_zone.h"
 #include "vm/compiler/backend/sexpression.h"

 // This file introduces several representations that exist between
 // S-Expressions and llvm IR. To explain how each part is intended
 // to be roughly translated using these I'll provide a mapping
 // showing how each part is translated.

 // At a high level two translations are very seamless:
 //
 // (function foo ...) -> DartFunction -> llvm::Function*
 // (block B ...) -> DartBlock -> (sort of) llvm::BasicBlock*
 //
 // Internally within a function constants are given names and are then used in
 // blocks. Each block additionally defines more names. Each of these names
 // needs to be mapped to a DartValue (more on that later) so a context to help
 // keep track of these name to DartValue mappings called a
 // DartBasicBlockBuilder exists. It is only used for to aid in the
 // (block B ...) -> DartBlock translation which is in turn used in the
 // (function foo ...) -> DartFunction translation. DartFunctions and DartBlocks
 // can be seen as validated representations of their S-Expression forms.

 // Within a DartBlock we have DartInstructions. Each DartInstruction either
 // has some effect (like calling a function or updating a value) or defines
 // a new name mapping it to a DartValue later. DartValues are referenced as
 // arguments to DartInstructions and map to llvm::Value*s. DartInstructions
 // have no analogue which they're directly translated to in code but they
 // do closely correspond mentally to llvm::Instruction*. The challenge is that
 // a DartInstruction might map to a near arbitrary number of llvm Instructions
 // and that mapping is very dependent on context. So instead of mapping them
 // to objects DartInstructions just know how to add their llvm Instructions to
 // an llvm::BasicBlock. These instructions might reference a verity of context
 // and so BasicBlockBuilder is passed in to provide them with this context.
 // Each DartInstruction is expected to already hold each DartValue that it
 // needs as previously supplied by the DartBasicBlockBuilder on construction.

 // An additional issue arises when translating DartInstructions into llvm IR.
 // Many require introducing control flow when lowered to the level of llvm IR
 // but this requires using multiple llvm::BasicBlock for a single DartBlock.
 // Luckily each DartInstruction that is not a terminator is expected to make it
 // possible for all non-exceptional control flow paths to wind up at a single
 // basic block. Since BasicBlockBuilder keeps track of a "current" basic block
 // via llvm::IRBuilder we simply ensure that after generating many blocks we
 // end each instruction which requires new basic blocks on this final basic
 // block that all generated blocks flow into. A picture better explains this:

 // Say you have a DartBlock B_1 it would then be mapped to llvm blocks that
 // look like this:
 //
 //                          B_1
 //                          / \
 //                         /   \
 //                 B_1_left    B_1_right
 //                         \   /
 //                          \ /
 //                         B_1_0
 //
 // And then we go on adding to B_1_0 as if it were the end of B_1 from before.

 // Each DartValue knows how to map itself to an llvm::Value. In llvm a Value
 // is really just anything you can give a name to in the IR but a DartValue
 // is intended to be more specific, it's a compile time representation of a
 // object, be it an integer, a tagged SMI, a pointer to a Dart Object, etc...
 // its intended to correspond to some actual object that we're computing on.

 // Class FunctionBuilder provides functionality for building
 // and LLVM function object including the ability to add a
 // named basic block, find an existing block, get the current
 // context/module and additionally retrieve llvm Values valid
 // in the current function.
 class FunctionBuilder {
  public:
   FunctionBuilder(llvm::LLVMContext& ctx,
                   llvm::Module& mod,
                   llvm::Function& func)
       : ctx_(ctx), mod_(mod), func_(func) {}
   llvm::LLVMContext& Context() { return ctx_; }
   llvm::Module& Module() { return mod_; }
   llvm::Value* GetSymbolValue(llvm::StringRef name) {
     auto* symtab = func_.getValueSymbolTable();
     return symtab->lookup(name);
   }
   llvm::BasicBlock* AddBasicBlock() {
     return llvm::BasicBlock::Create(ctx_, "", &func_);
   }
   llvm::BasicBlock* AddBasicBlock(llvm::StringRef name) {
     auto* bb = llvm::BasicBlock::Create(ctx_, name, &func_);
     basic_blocks_[name] = bb;
     return bb;
   }
   llvm::BasicBlock* GetBasicBlock(llvm::StringRef name) const {
     auto iter = basic_blocks_.find(name);
     if (iter != basic_blocks_.end()) return iter->getValue();
     return nullptr;
   }

  private:
   llvm::LLVMContext& ctx_;
   llvm::Module& mod_;
   llvm::Function& func_;
   llvm::StringMap<llvm::BasicBlock*> basic_blocks_;
 };

 class BasicBlockBuilder;

 // TODO(jakehehrlich): Make this architecture dependent
 // Class DartThreadObject is used as a high level object for generating
 // code that reads fields from the thread object.
 class DartThreadObject {
  public:
   explicit DartThreadObject(BasicBlockBuilder& bb_builder)
       : bb_builder_(bb_builder) {}

   // StackLimit returns an llvm::Value representing the stack limit
   // of the thread object.
   llvm::Value* StackLimit() const;

  private:
   static constexpr intptr_t kThreadStackLimitOffset = 72;

   BasicBlockBuilder& bb_builder_;

   // GetOffset returns an llvm::Value* representing a pointer to a particular
   // field of the thread object. It adds the specified offset to the thread
   // pointer, and then casts to the specified type.
   llvm::Value* GetOffset(llvm::Type* type, intptr_t offset) const;
 };

 class DartValue;

 // A class for keeping track of the basic block state and SSA values.
 // This is similar to IRBuilder but also keeps track of the argument stack and
 // basic block names.
 class BasicBlockBuilder {
  public:
   BasicBlockBuilder(llvm::BasicBlock* bb, FunctionBuilder& fb)
       : fb_(fb), top_(bb), builder_(bb), thread_object_(*this) {}
   llvm::LLVMContext& Context() { return fb_.Context(); }
   llvm::Module& Module() { return fb_.Module(); }
   llvm::IRBuilder<>& Builder() { return builder_; }
   const DartThreadObject& ThreadObject() { return thread_object_; }
   llvm::BasicBlock* AddBasicBlock() { return fb_.AddBasicBlock(); }
   llvm::BasicBlock* GetBasicBlock(llvm::StringRef Name) const {
     return fb_.GetBasicBlock(Name);
   }
   llvm::Value* GetSymbolValue(llvm::StringRef name) const {
     return fb_.GetBasicBlock(name);
   }
   llvm::Value* GetValue(const DartValue* v);
   void PushArgument(llvm::Value* v) { stack_.push_back(v); }
   llvm::Value* PopArgument() {
     llvm::Value* out = stack_.back();
     stack_.pop_back();
     return out;
   }

  private:
   FunctionBuilder& fb_;
   llvm::BasicBlock* top_;
   llvm::SmallVector<llvm::Value*, 16> stack_;
   llvm::IRBuilder<> builder_;
   llvm::DenseMap<const DartValue*, llvm::Value*> values_;
   DartThreadObject thread_object_;
 };

 // Class DartValue represents an SSA value from the Dart SSA
 // such that it can be converted into an llvm::Value*.
 class DartValue {
  public:
   virtual ~DartValue() {}
   virtual llvm::Value* Make(BasicBlockBuilder& bb_builder) const = 0;
   virtual llvm::Type* GetType(BasicBlockBuilder& bb_builder) const = 0;
 };

 // Class DartBasicBlockBuilder provides helpful context for going
 // from an S-Expression basic block to a DartBlock. It just lets
 // one lookup DartValue's by name at this time.
 class DartBasicBlockBuilder {
  public:
   void AddDef(llvm::StringRef name, const DartValue* v) { defs_[name] = v; }
   const DartValue* GetDef(llvm::StringRef name) const {
     auto iter = defs_.find(name);
     if (iter != defs_.end()) return iter->getValue();
     return nullptr;
   }

  private:
   llvm::StringMap<const DartValue*> defs_;
 };

 // A DartConstant is a DartValue for a constant.
 class DartConstant : public DartValue {
  public:
   std::string str;
   enum class Type { String };
   Type type;

   llvm::Value* Make(BasicBlockBuilder& bb_builder) const override;
   llvm::Type* GetType(BasicBlockBuilder& bb_builder) const override;
 };

 // Class DartInstruction represents a step within a DartBasicBlock.
 // CheckStackOverflow or PushArgument are instructions. They contain
 // DartValues as arguments typically. SSA definitions are also
 // DartInstructions which assign DartValues to names in the function's
 // context.
 class DartInstruction {
  public:
   virtual ~DartInstruction();
   virtual void Build(BasicBlockBuilder& bb_builder) const = 0;
 };

 // Class InstCheckStackOverflow is a DartInstruction that represents
 // an instance of a CheckStackOverflow instruction.
 class InstCheckStackOverflow : public DartInstruction {
  public:
   InstCheckStackOverflow() {}
   ~InstCheckStackOverflow() override {}
   void Build(BasicBlockBuilder& bb_builder) const override;
   static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
       dart::SExpList* inst,
       DartBasicBlockBuilder& bb_builder);
 };

 // Class InstPushArgument is a DartInstruction that represents
 // and instance of a PushArgument Instruction.
 class InstPushArgument : public DartInstruction {
  public:
   explicit InstPushArgument(const DartValue* arg) : arg_(arg) {}
   ~InstPushArgument() override {}
   void Build(BasicBlockBuilder& bb_builder) const override;
   static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
       dart::SExpList* inst,
       DartBasicBlockBuilder& bb_builder);

  private:
   const DartValue* arg_;
 };

 // Class InstStaticCall is a DartInstruction that represents a
 // StaticCall instruction.
 class InstStaticCall : public DartInstruction {
  public:
   InstStaticCall(const DartValue* func, size_t args_len)
       : function_(func), args_len_(args_len) {}
   ~InstStaticCall() override {}
   void Build(BasicBlockBuilder& bb_builder) const override;
   static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
       dart::SExpList* inst,
       DartBasicBlockBuilder& bb_builder);

  private:
   const DartValue* function_;
   size_t args_len_;
 };

 // Class InstReturn is a DartInstruction that represents a Return
 // instruction.
 class InstReturn : public DartInstruction {
  public:
   InstReturn() {}
   ~InstReturn() override {}
   void Build(BasicBlockBuilder& bb_builder) const override;
   static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
       dart::SExpList* inst,
       DartBasicBlockBuilder& bb_builder);
 };

 // Class DartBlock represents a validated basic block as parsed from
 // a (block ...) S-Expression.
 struct DartBlock {
   std::string name;
   std::vector<std::unique_ptr<DartInstruction>> instructions;
 };

 // Class DartFunction represents a validated function parsed from a
 // (function ...) S-Expression.
 struct DartFunction {
   std::string name;
   DartBlock* normal_entry;
   llvm::StringMap<DartConstant> constants;
   llvm::StringMap<DartBlock> blocks;
 };

 // MakeFunction takes an S-Expression and an environment of externally
 // defined DartValues and produces a DartFunction corresponding to the
 // S-Expression if everything is valid. If something about the syntax
 // of the S-Expression is invalid then the llvm::Expected will hold an
 // error explaining the issue.
 llvm::Expected<DartFunction> MakeFunction(
     dart::Zone* zone,
     dart::SExpression* sexpr,
     const llvm::StringMap<const DartValue*>& env);

 #endif  // RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_
	// Copyright (c) 2019, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_
	#define RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_

	#include <memory>
	#include <vector>
	#include <string>

	#include "llvm/ADT/StringRef.h"
	#include "llvm/IR/IRBuilder.h"
	#include "llvm/IR/Module.h"
	#include "llvm/IR/ValueSymbolTable.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/WithColor.h"

	// Ensure to use our own zone.
	#include "custom_zone.h"
	#include "vm/compiler/backend/sexpression.h"

	// This file introduces several representations that exist between
	// S-Expressions and llvm IR. To explain how each part is intended
	// to be roughly translated using these I'll provide a mapping
	// showing how each part is translated.

	// At a high level two translations are very seamless:
	//
	// (function foo ...) -> DartFunction -> llvm::Function*
	// (block B ...) -> DartBlock -> (sort of) llvm::BasicBlock*
	//
	// Internally within a function constants are given names and are then used in
	// blocks. Each block additionally defines more names. Each of these names
	// needs to be mapped to a DartValue (more on that later) so a context to help
	// keep track of these name to DartValue mappings called a
	// DartBasicBlockBuilder exists. It is only used for to aid in the
	// (block B ...) -> DartBlock translation which is in turn used in the
	// (function foo ...) -> DartFunction translation. DartFunctions and DartBlocks
	// can be seen as validated representations of their S-Expression forms.

	// Within a DartBlock we have DartInstructions. Each DartInstruction either
	// has some effect (like calling a function or updating a value) or defines
	// a new name mapping it to a DartValue later. DartValues are referenced as
	// arguments to DartInstructions and map to llvm::Value*s. DartInstructions
	// have no analogue which they're directly translated to in code but they
	// do closely correspond mentally to llvm::Instruction*. The challenge is that
	// a DartInstruction might map to a near arbitrary number of llvm Instructions
	// and that mapping is very dependent on context. So instead of mapping them
	// to objects DartInstructions just know how to add their llvm Instructions to
	// an llvm::BasicBlock. These instructions might reference a verity of context
	// and so BasicBlockBuilder is passed in to provide them with this context.
	// Each DartInstruction is expected to already hold each DartValue that it
	// needs as previously supplied by the DartBasicBlockBuilder on construction.

	// An additional issue arises when translating DartInstructions into llvm IR.
	// Many require introducing control flow when lowered to the level of llvm IR
	// but this requires using multiple llvm::BasicBlock for a single DartBlock.
	// Luckily each DartInstruction that is not a terminator is expected to make it
	// possible for all non-exceptional control flow paths to wind up at a single
	// basic block. Since BasicBlockBuilder keeps track of a "current" basic block
	// via llvm::IRBuilder we simply ensure that after generating many blocks we
	// end each instruction which requires new basic blocks on this final basic
	// block that all generated blocks flow into. A picture better explains this:

	// Say you have a DartBlock B_1 it would then be mapped to llvm blocks that
	// look like this:
	//
	// B_1
	// / \
	// / \
	// B_1_left B_1_right
	// \ /
	// \ /
	// B_1_0
	//
	// And then we go on adding to B_1_0 as if it were the end of B_1 from before.

	// Each DartValue knows how to map itself to an llvm::Value. In llvm a Value
	// is really just anything you can give a name to in the IR but a DartValue
	// is intended to be more specific, it's a compile time representation of a
	// object, be it an integer, a tagged SMI, a pointer to a Dart Object, etc...
	// its intended to correspond to some actual object that we're computing on.

	// Class FunctionBuilder provides functionality for building
	// and LLVM function object including the ability to add a
	// named basic block, find an existing block, get the current
	// context/module and additionally retrieve llvm Values valid
	// in the current function.
	class FunctionBuilder {
	public:
	FunctionBuilder(llvm::LLVMContext& ctx,
	llvm::Module& mod,
	llvm::Function& func)
	: ctx_(ctx), mod_(mod), func_(func) {}
	llvm::LLVMContext& Context() { return ctx_; }
	llvm::Module& Module() { return mod_; }
	llvm::Value* GetSymbolValue(llvm::StringRef name) {
	auto* symtab = func_.getValueSymbolTable();
	return symtab->lookup(name);
	}
	llvm::BasicBlock* AddBasicBlock() {
	return llvm::BasicBlock::Create(ctx_, "", &func_);
	}
	llvm::BasicBlock* AddBasicBlock(llvm::StringRef name) {
	auto* bb = llvm::BasicBlock::Create(ctx_, name, &func_);
	basic_blocks_[name] = bb;
	return bb;
	}
	llvm::BasicBlock* GetBasicBlock(llvm::StringRef name) const {
	auto iter = basic_blocks_.find(name);
	if (iter != basic_blocks_.end()) return iter->getValue();
	return nullptr;
	}

	private:
	llvm::LLVMContext& ctx_;
	llvm::Module& mod_;
	llvm::Function& func_;
	llvm::StringMap<llvm::BasicBlock*> basic_blocks_;
	};

	class BasicBlockBuilder;

	// TODO(jakehehrlich): Make this architecture dependent
	// Class DartThreadObject is used as a high level object for generating
	// code that reads fields from the thread object.
	class DartThreadObject {
	public:
	explicit DartThreadObject(BasicBlockBuilder& bb_builder)
	: bb_builder_(bb_builder) {}

	// StackLimit returns an llvm::Value representing the stack limit
	// of the thread object.
	llvm::Value* StackLimit() const;

	private:
	static constexpr intptr_t kThreadStackLimitOffset = 72;

	BasicBlockBuilder& bb_builder_;

	// GetOffset returns an llvm::Value* representing a pointer to a particular
	// field of the thread object. It adds the specified offset to the thread
	// pointer, and then casts to the specified type.
	llvm::Value* GetOffset(llvm::Type* type, intptr_t offset) const;
	};

	class DartValue;

	// A class for keeping track of the basic block state and SSA values.
	// This is similar to IRBuilder but also keeps track of the argument stack and
	// basic block names.
	class BasicBlockBuilder {
	public:
	BasicBlockBuilder(llvm::BasicBlock* bb, FunctionBuilder& fb)
	: fb_(fb), top_(bb), builder_(bb), thread_object_(*this) {}
	llvm::LLVMContext& Context() { return fb_.Context(); }
	llvm::Module& Module() { return fb_.Module(); }
	llvm::IRBuilder<>& Builder() { return builder_; }
	const DartThreadObject& ThreadObject() { return thread_object_; }
	llvm::BasicBlock* AddBasicBlock() { return fb_.AddBasicBlock(); }
	llvm::BasicBlock* GetBasicBlock(llvm::StringRef Name) const {
	return fb_.GetBasicBlock(Name);
	}
	llvm::Value* GetSymbolValue(llvm::StringRef name) const {
	return fb_.GetBasicBlock(name);
	}
	llvm::Value* GetValue(const DartValue* v);
	void PushArgument(llvm::Value* v) { stack_.push_back(v); }
	llvm::Value* PopArgument() {
	llvm::Value* out = stack_.back();
	stack_.pop_back();
	return out;
	}

	private:
	FunctionBuilder& fb_;
	llvm::BasicBlock* top_;
	llvm::SmallVector<llvm::Value*, 16> stack_;
	llvm::IRBuilder<> builder_;
	llvm::DenseMap<const DartValue, llvm::Value> values_;
	DartThreadObject thread_object_;
	};

	// Class DartValue represents an SSA value from the Dart SSA
	// such that it can be converted into an llvm::Value*.
	class DartValue {
	public:
	virtual ~DartValue() {}
	virtual llvm::Value* Make(BasicBlockBuilder& bb_builder) const = 0;
	virtual llvm::Type* GetType(BasicBlockBuilder& bb_builder) const = 0;
	};

	// Class DartBasicBlockBuilder provides helpful context for going
	// from an S-Expression basic block to a DartBlock. It just lets
	// one lookup DartValue's by name at this time.
	class DartBasicBlockBuilder {
	public:
	void AddDef(llvm::StringRef name, const DartValue* v) { defs_[name] = v; }
	const DartValue* GetDef(llvm::StringRef name) const {
	auto iter = defs_.find(name);
	if (iter != defs_.end()) return iter->getValue();
	return nullptr;
	}

	private:
	llvm::StringMap<const DartValue*> defs_;
	};

	// A DartConstant is a DartValue for a constant.
	class DartConstant : public DartValue {
	public:
	std::string str;
	enum class Type { String };
	Type type;

	llvm::Value* Make(BasicBlockBuilder& bb_builder) const override;
	llvm::Type* GetType(BasicBlockBuilder& bb_builder) const override;
	};

	// Class DartInstruction represents a step within a DartBasicBlock.
	// CheckStackOverflow or PushArgument are instructions. They contain
	// DartValues as arguments typically. SSA definitions are also
	// DartInstructions which assign DartValues to names in the function's
	// context.
	class DartInstruction {
	public:
	virtual ~DartInstruction();
	virtual void Build(BasicBlockBuilder& bb_builder) const = 0;
	};

	// Class InstCheckStackOverflow is a DartInstruction that represents
	// an instance of a CheckStackOverflow instruction.
	class InstCheckStackOverflow : public DartInstruction {
	public:
	InstCheckStackOverflow() {}
	~InstCheckStackOverflow() override {}
	void Build(BasicBlockBuilder& bb_builder) const override;
	static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
	dart::SExpList* inst,
	DartBasicBlockBuilder& bb_builder);
	};

	// Class InstPushArgument is a DartInstruction that represents
	// and instance of a PushArgument Instruction.
	class InstPushArgument : public DartInstruction {
	public:
	explicit InstPushArgument(const DartValue* arg) : arg_(arg) {}
	~InstPushArgument() override {}
	void Build(BasicBlockBuilder& bb_builder) const override;
	static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
	dart::SExpList* inst,
	DartBasicBlockBuilder& bb_builder);

	private:
	const DartValue* arg_;
	};

	// Class InstStaticCall is a DartInstruction that represents a
	// StaticCall instruction.
	class InstStaticCall : public DartInstruction {
	public:
	InstStaticCall(const DartValue* func, size_t args_len)
	: function_(func), args_len_(args_len) {}
	~InstStaticCall() override {}
	void Build(BasicBlockBuilder& bb_builder) const override;
	static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
	dart::SExpList* inst,
	DartBasicBlockBuilder& bb_builder);

	private:
	const DartValue* function_;
	size_t args_len_;
	};

	// Class InstReturn is a DartInstruction that represents a Return
	// instruction.
	class InstReturn : public DartInstruction {
	public:
	InstReturn() {}
	~InstReturn() override {}
	void Build(BasicBlockBuilder& bb_builder) const override;
	static llvm::Expected<std::unique_ptr<DartInstruction>> Construct(
	dart::SExpList* inst,
	DartBasicBlockBuilder& bb_builder);
	};

	// Class DartBlock represents a validated basic block as parsed from
	// a (block ...) S-Expression.
	struct DartBlock {
	std::string name;
	std::vector<std::unique_ptr<DartInstruction>> instructions;
	};

	// Class DartFunction represents a validated function parsed from a
	// (function ...) S-Expression.
	struct DartFunction {
	std::string name;
	DartBlock* normal_entry;
	llvm::StringMap<DartConstant> constants;
	llvm::StringMap<DartBlock> blocks;
	};

	// MakeFunction takes an S-Expression and an environment of externally
	// defined DartValues and produces a DartFunction corresponding to the
	// S-Expression if everything is valid. If something about the syntax
	// of the S-Expression is invalid then the llvm::Expected will hold an
	// error explaining the issue.
	llvm::Expected<DartFunction> MakeFunction(
	dart::Zone* zone,
	dart::SExpression* sexpr,
	const llvm::StringMap<const DartValue*>& env);

	#endif // RUNTIME_LLVM_CODEGEN_CODEGEN_DART_H_