source/Symbol/PostfixExpression.cpp - llvm-project/lldb - Git at Google

 //===-- PostfixExpression.cpp ---------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file implements support for postfix expressions found in several symbol
 //  file formats, and their conversion to DWARF.
 //
 //===----------------------------------------------------------------------===//

 #include "lldb/Symbol/PostfixExpression.h"
 #include "lldb/Core/dwarf.h"
 #include "lldb/Utility/Stream.h"
 #include "llvm/ADT/StringExtras.h"

 using namespace lldb_private;
 using namespace lldb_private::postfix;

 static llvm::Optional<BinaryOpNode::OpType>
 GetBinaryOpType(llvm::StringRef token) {
   if (token.size() != 1)
     return llvm::None;
   switch (token[0]) {
   case '@':
     return BinaryOpNode::Align;
   case '-':
     return BinaryOpNode::Minus;
   case '+':
     return BinaryOpNode::Plus;
   }
   return llvm::None;
 }

 static llvm::Optional<UnaryOpNode::OpType>
 GetUnaryOpType(llvm::StringRef token) {
   if (token == "^")
     return UnaryOpNode::Deref;
   return llvm::None;
 }

 Node *postfix::ParseOneExpression(llvm::StringRef expr,
                                   llvm::BumpPtrAllocator &alloc) {
   llvm::SmallVector<Node *, 4> stack;

   llvm::StringRef token;
   while (std::tie(token, expr) = getToken(expr), !token.empty()) {
     if (auto op_type = GetBinaryOpType(token)) {
       // token is binary operator
       if (stack.size() < 2)
         return nullptr;

       Node *right = stack.pop_back_val();
       Node *left = stack.pop_back_val();
       stack.push_back(MakeNode<BinaryOpNode>(alloc, *op_type, *left, *right));
       continue;
     }

     if (auto op_type = GetUnaryOpType(token)) {
       // token is unary operator
       if (stack.empty())
         return nullptr;

       Node *operand = stack.pop_back_val();
       stack.push_back(MakeNode<UnaryOpNode>(alloc, *op_type, *operand));
       continue;
     }

     int64_t value;
     if (to_integer(token, value, 10)) {
       // token is integer literal
       stack.push_back(MakeNode<IntegerNode>(alloc, value));
       continue;
     }

     stack.push_back(MakeNode<SymbolNode>(alloc, token));
   }

   if (stack.size() != 1)
     return nullptr;

   return stack.back();
 }

 std::vector<std::pair<llvm::StringRef, Node *>>
 postfix::ParseFPOProgram(llvm::StringRef prog, llvm::BumpPtrAllocator &alloc) {
   llvm::SmallVector<llvm::StringRef, 4> exprs;
   prog.split(exprs, '=');
   if (exprs.empty() || !exprs.back().trim().empty())
     return {};
   exprs.pop_back();

   std::vector<std::pair<llvm::StringRef, Node *>> result;
   for (llvm::StringRef expr : exprs) {
     llvm::StringRef lhs;
     std::tie(lhs, expr) = getToken(expr);
     Node *rhs = ParseOneExpression(expr, alloc);
     if (!rhs)
       return {};
     result.emplace_back(lhs, rhs);
   }
   return result;
 }

 namespace {
 class SymbolResolver : public Visitor<bool> {
 public:
   SymbolResolver(llvm::function_ref<Node *(SymbolNode &symbol)> replacer)
       : m_replacer(replacer) {}

   using Visitor<bool>::Dispatch;

 private:
   bool Visit(BinaryOpNode &binary, Node *&) override {
     return Dispatch(binary.Left()) && Dispatch(binary.Right());
   }

   bool Visit(InitialValueNode &, Node *&) override { return true; }
   bool Visit(IntegerNode &, Node *&) override { return true; }
   bool Visit(RegisterNode &, Node *&) override { return true; }

   bool Visit(SymbolNode &symbol, Node *&ref) override {
     if (Node *replacement = m_replacer(symbol)) {
       ref = replacement;
       if (replacement != &symbol)
         return Dispatch(ref);
       return true;
     }
     return false;
   }

   bool Visit(UnaryOpNode &unary, Node *&) override {
     return Dispatch(unary.Operand());
   }

   llvm::function_ref<Node *(SymbolNode &symbol)> m_replacer;
 };

 class DWARFCodegen : public Visitor<> {
 public:
   DWARFCodegen(Stream &stream) : m_out_stream(stream) {}

   using Visitor<>::Dispatch;

 private:
   void Visit(BinaryOpNode &binary, Node *&) override;

   void Visit(InitialValueNode &val, Node *&) override;

   void Visit(IntegerNode &integer, Node *&) override {
     m_out_stream.PutHex8(DW_OP_consts);
     m_out_stream.PutSLEB128(integer.GetValue());
     ++m_stack_depth;
   }

   void Visit(RegisterNode &reg, Node *&) override;

   void Visit(SymbolNode &symbol, Node *&) override {
     llvm_unreachable("Symbols should have been resolved by now!");
   }

   void Visit(UnaryOpNode &unary, Node *&) override;

   Stream &m_out_stream;

   /// The number keeping track of the evaluation stack depth at any given
   /// moment. Used for implementing InitialValueNodes. We start with
   /// m_stack_depth = 1, assuming that the initial value is already on the
   /// stack. This initial value will be the value of all InitialValueNodes. If
   /// the expression does not contain InitialValueNodes, then m_stack_depth is
   /// not used, and the generated expression will run correctly even without an
   /// initial value.
   size_t m_stack_depth = 1;
 };
 } // namespace

 void DWARFCodegen::Visit(BinaryOpNode &binary, Node *&) {
   Dispatch(binary.Left());
   Dispatch(binary.Right());

   switch (binary.GetOpType()) {
   case BinaryOpNode::Plus:
     m_out_stream.PutHex8(DW_OP_plus);
     // NOTE: can be optimized by using DW_OP_plus_uconst opcpode
     //       if right child node is constant value
     break;
   case BinaryOpNode::Minus:
     m_out_stream.PutHex8(DW_OP_minus);
     break;
   case BinaryOpNode::Align:
     // emit align operator a @ b as
     // a & ~(b - 1)
     // NOTE: implicitly assuming that b is power of 2
     m_out_stream.PutHex8(DW_OP_lit1);
     m_out_stream.PutHex8(DW_OP_minus);
     m_out_stream.PutHex8(DW_OP_not);

     m_out_stream.PutHex8(DW_OP_and);
     break;
   }
   --m_stack_depth; // Two pops, one push.
 }

 void DWARFCodegen::Visit(InitialValueNode &, Node *&) {
   // We never go below the initial stack, so we can pick the initial value from
   // the bottom of the stack at any moment.
   assert(m_stack_depth >= 1);
   m_out_stream.PutHex8(DW_OP_pick);
   m_out_stream.PutHex8(m_stack_depth - 1);
   ++m_stack_depth;
 }

 void DWARFCodegen::Visit(RegisterNode &reg, Node *&) {
   uint32_t reg_num = reg.GetRegNum();
   assert(reg_num != LLDB_INVALID_REGNUM);

   if (reg_num > 31) {
     m_out_stream.PutHex8(DW_OP_bregx);
     m_out_stream.PutULEB128(reg_num);
   } else
     m_out_stream.PutHex8(DW_OP_breg0 + reg_num);

   m_out_stream.PutSLEB128(0);
   ++m_stack_depth;
 }

 void DWARFCodegen::Visit(UnaryOpNode &unary, Node *&) {
   Dispatch(unary.Operand());

   switch (unary.GetOpType()) {
   case UnaryOpNode::Deref:
     m_out_stream.PutHex8(DW_OP_deref);
     break;
   }
   // Stack depth unchanged.
 }

 bool postfix::ResolveSymbols(
     Node *&node, llvm::function_ref<Node *(SymbolNode &)> replacer) {
   return SymbolResolver(replacer).Dispatch(node);
 }

 void postfix::ToDWARF(Node &node, Stream &stream) {
   Node *ptr = &node;
   DWARFCodegen(stream).Dispatch(ptr);
 }
	//===-- PostfixExpression.cpp ---------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements support for postfix expressions found in several symbol
	// file formats, and their conversion to DWARF.
	//
	//===----------------------------------------------------------------------===//

	#include "lldb/Symbol/PostfixExpression.h"
	#include "lldb/Core/dwarf.h"
	#include "lldb/Utility/Stream.h"
	#include "llvm/ADT/StringExtras.h"

	using namespace lldb_private;
	using namespace lldb_private::postfix;

	static llvm::Optional<BinaryOpNode::OpType>
	GetBinaryOpType(llvm::StringRef token) {
	if (token.size() != 1)
	return llvm::None;
	switch (token[0]) {
	case '@':
	return BinaryOpNode::Align;
	case '-':
	return BinaryOpNode::Minus;
	case '+':
	return BinaryOpNode::Plus;
	}
	return llvm::None;
	}

	static llvm::Optional<UnaryOpNode::OpType>
	GetUnaryOpType(llvm::StringRef token) {
	if (token == "^")
	return UnaryOpNode::Deref;
	return llvm::None;
	}

	Node *postfix::ParseOneExpression(llvm::StringRef expr,
	llvm::BumpPtrAllocator &alloc) {
	llvm::SmallVector<Node *, 4> stack;

	llvm::StringRef token;
	while (std::tie(token, expr) = getToken(expr), !token.empty()) {
	if (auto op_type = GetBinaryOpType(token)) {
	// token is binary operator
	if (stack.size() < 2)
	return nullptr;

	Node *right = stack.pop_back_val();
	Node *left = stack.pop_back_val();
	stack.push_back(MakeNode<BinaryOpNode>(alloc, op_type, left, *right));
	continue;
	}

	if (auto op_type = GetUnaryOpType(token)) {
	// token is unary operator
	if (stack.empty())
	return nullptr;

	Node *operand = stack.pop_back_val();
	stack.push_back(MakeNode<UnaryOpNode>(alloc, op_type, operand));
	continue;
	}

	int64_t value;
	if (to_integer(token, value, 10)) {
	// token is integer literal
	stack.push_back(MakeNode<IntegerNode>(alloc, value));
	continue;
	}

	stack.push_back(MakeNode<SymbolNode>(alloc, token));
	}

	if (stack.size() != 1)
	return nullptr;

	return stack.back();
	}

	std::vector<std::pair<llvm::StringRef, Node *>>
	postfix::ParseFPOProgram(llvm::StringRef prog, llvm::BumpPtrAllocator &alloc) {
	llvm::SmallVector<llvm::StringRef, 4> exprs;
	prog.split(exprs, '=');
	if (exprs.empty() \|\| !exprs.back().trim().empty())
	return {};
	exprs.pop_back();

	std::vector<std::pair<llvm::StringRef, Node *>> result;
	for (llvm::StringRef expr : exprs) {
	llvm::StringRef lhs;
	std::tie(lhs, expr) = getToken(expr);
	Node *rhs = ParseOneExpression(expr, alloc);
	if (!rhs)
	return {};
	result.emplace_back(lhs, rhs);
	}
	return result;
	}

	namespace {
	class SymbolResolver : public Visitor<bool> {
	public:
	SymbolResolver(llvm::function_ref<Node *(SymbolNode &symbol)> replacer)
	: m_replacer(replacer) {}

	using Visitor<bool>::Dispatch;

	private:
	bool Visit(BinaryOpNode &binary, Node *&) override {
	return Dispatch(binary.Left()) && Dispatch(binary.Right());
	}

	bool Visit(InitialValueNode &, Node *&) override { return true; }
	bool Visit(IntegerNode &, Node *&) override { return true; }
	bool Visit(RegisterNode &, Node *&) override { return true; }

	bool Visit(SymbolNode &symbol, Node *&ref) override {
	if (Node *replacement = m_replacer(symbol)) {
	ref = replacement;
	if (replacement != &symbol)
	return Dispatch(ref);
	return true;
	}
	return false;
	}

	bool Visit(UnaryOpNode &unary, Node *&) override {
	return Dispatch(unary.Operand());
	}

	llvm::function_ref<Node *(SymbolNode &symbol)> m_replacer;
	};

	class DWARFCodegen : public Visitor<> {
	public:
	DWARFCodegen(Stream &stream) : m_out_stream(stream) {}

	using Visitor<>::Dispatch;

	private:
	void Visit(BinaryOpNode &binary, Node *&) override;

	void Visit(InitialValueNode &val, Node *&) override;

	void Visit(IntegerNode &integer, Node *&) override {
	m_out_stream.PutHex8(DW_OP_consts);
	m_out_stream.PutSLEB128(integer.GetValue());
	++m_stack_depth;
	}

	void Visit(RegisterNode &reg, Node *&) override;

	void Visit(SymbolNode &symbol, Node *&) override {
	llvm_unreachable("Symbols should have been resolved by now!");
	}

	void Visit(UnaryOpNode &unary, Node *&) override;

	Stream &m_out_stream;

	/// The number keeping track of the evaluation stack depth at any given
	/// moment. Used for implementing InitialValueNodes. We start with
	/// m_stack_depth = 1, assuming that the initial value is already on the
	/// stack. This initial value will be the value of all InitialValueNodes. If
	/// the expression does not contain InitialValueNodes, then m_stack_depth is
	/// not used, and the generated expression will run correctly even without an
	/// initial value.
	size_t m_stack_depth = 1;
	};
	} // namespace

	void DWARFCodegen::Visit(BinaryOpNode &binary, Node *&) {
	Dispatch(binary.Left());
	Dispatch(binary.Right());

	switch (binary.GetOpType()) {
	case BinaryOpNode::Plus:
	m_out_stream.PutHex8(DW_OP_plus);
	// NOTE: can be optimized by using DW_OP_plus_uconst opcpode
	// if right child node is constant value
	break;
	case BinaryOpNode::Minus:
	m_out_stream.PutHex8(DW_OP_minus);
	break;
	case BinaryOpNode::Align:
	// emit align operator a @ b as
	// a & ~(b - 1)
	// NOTE: implicitly assuming that b is power of 2
	m_out_stream.PutHex8(DW_OP_lit1);
	m_out_stream.PutHex8(DW_OP_minus);
	m_out_stream.PutHex8(DW_OP_not);

	m_out_stream.PutHex8(DW_OP_and);
	break;
	}
	--m_stack_depth; // Two pops, one push.
	}

	void DWARFCodegen::Visit(InitialValueNode &, Node *&) {
	// We never go below the initial stack, so we can pick the initial value from
	// the bottom of the stack at any moment.
	assert(m_stack_depth >= 1);
	m_out_stream.PutHex8(DW_OP_pick);
	m_out_stream.PutHex8(m_stack_depth - 1);
	++m_stack_depth;
	}

	void DWARFCodegen::Visit(RegisterNode &reg, Node *&) {
	uint32_t reg_num = reg.GetRegNum();
	assert(reg_num != LLDB_INVALID_REGNUM);

	if (reg_num > 31) {
	m_out_stream.PutHex8(DW_OP_bregx);
	m_out_stream.PutULEB128(reg_num);
	} else
	m_out_stream.PutHex8(DW_OP_breg0 + reg_num);

	m_out_stream.PutSLEB128(0);
	++m_stack_depth;
	}

	void DWARFCodegen::Visit(UnaryOpNode &unary, Node *&) {
	Dispatch(unary.Operand());

	switch (unary.GetOpType()) {
	case UnaryOpNode::Deref:
	m_out_stream.PutHex8(DW_OP_deref);
	break;
	}
	// Stack depth unchanged.
	}

	bool postfix::ResolveSymbols(
	Node &node, llvm::function_ref<Node (SymbolNode &)> replacer) {
	return SymbolResolver(replacer).Dispatch(node);
	}

	void postfix::ToDWARF(Node &node, Stream &stream) {
	Node *ptr = &node;
	DWARFCodegen(stream).Dispatch(ptr);
	}