integer_load_instruction.cpp

浙江大学的悟空嵌入式系统模拟器

/* -*- C++ -*- */

/**
 *  Copyright (c) 2005 Zhejiang University, P.R.China
 *
 *  This program is free software; you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation; either version 2 of the License, or
 *  (at your option) any later version.
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program; if not, write to the Free Software
 *  Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */ 


///==================================================
/**
 * @file        Integer_Load_Instruction.h
 * @brief       
 * @author      Chenfeng Zhou <ini_autumn@163.com> 
 *
 * Created    : <2005-02-24 12:58:27 by Cheney Chow>
 * Last update: <2005-05-26 20:41:06 by Cheney Chow>
 *
 * $Id: Integer_Load_Instruction.cpp,v 1.1 2005/06/16 06:01:46 qilj Exp $
 */
///==================================================

#include "Instr_Flag.h"
#include "Instr_Declare.h"
#include "Parser.h"
#include "Register.h"
#include "Types.h"
#include "Reg_Utils.h"
#include "Utils/Debug.h"
#include "MMU.h"


/**
 * If there's a data page fault, we exit immediately;
 * including the multi-load instructions;
 */

namespace PPC {

	PPC_INSTRUCTION_IMPL(op_lbz)
 	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_Address_T start = (A? REG_TO_INT(REG(A)) : 0) + imm;
		Core::Bytecode_Type buffer;
		Core::u8 val;

		PPC_TRACE_1("lbz", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 1, buffer))
			PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(D).convert_from_int(val);
    }

	PPC_INSTRUCTION_IMPL(op_lbzu)
	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_ASSERT( (A != 0) && (A != D) );

		PPC_Address_T start = REG_TO_INT(REG(A)) + imm;
		Core::Bytecode_Type buffer;
		Core::u8 val;

		PPC_TRACE_1("lbzu", (Core::u32*)start);

		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 1, buffer) )
			PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(A).convert_from_int(REG_TO_INT(REG(A)) + imm);
		REG(D).convert_from_int(val);
	}

	PPC_INSTRUCTION_IMPL(op_lbzux)
	{
		PPC_s32 D, A, B;

		X_Form_Parser::parse_x(instr, D, A, B);

		PPC_ASSERT( (A != 0) && (A != D) );

		PPC_Address_T start = REG_TO_INT(REG(A)) + REG_TO_INT(REG(B));
		Core::Bytecode_Type buffer;
		Core::u8 val;

		PPC_TRACE_1("lbzux", (Core::u32*)start);

		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 1, buffer))
			PPC_TRACE_RETURN("mmu access fault\n");
		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(A).convert_from_int(REG_TO_INT(REG(A)) + REG_TO_INT(REG(B)));
		REG(D).convert_from_int(val);
	}

	PPC_INSTRUCTION_IMPL(op_lbzx)
	{
		PPC_s32 D, A, B;

		X_Form_Parser::parse_x(instr, D, A, B);

		PPC_Address_T start = (A? REG_TO_INT(REG(A)) : 0) + REG_TO_INT(REG(B));
		Core::Bytecode_Type buffer;
		Core::u8 val;
		
		PPC_TRACE_1("lbzx", (Core::u32*)start);

		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 1, buffer))
			PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(D).convert_from_int(val);
	}

	PPC_INSTRUCTION_IMPL(op_lha)
	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_Address_T start = (A? REG_TO_INT(REG(A)) : 0) + imm;
		Core::Bytecode_Type buffer;
		Core::u16 val;
        
		PPC_TRACE_1("lha", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");
        
		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		// REG(D)'s high 16 bit is filled with the most significant bit of val
		REG(D).convert_from_int( (val & 0x8000)? (val | 0xffff0000) : val );
	}

	PPC_INSTRUCTION_IMPL(op_lhau)
	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_ASSERT(A != 0);

		PPC_Address_T start = REG_TO_INT(REG(A)) + imm;
		Core::Bytecode_Type buffer;
		Core::u16 val;

        PPC_TRACE_1("lhau", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");
        
		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(A).convert_from_int(REG_TO_INT(REG(A)) + imm);
		REG(D).convert_from_int( (val & 0x8000)? (val | 0xffff0000) : val );
	}

	PPC_INSTRUCTION_IMPL(op_lhaux)
	{
		PPC_s32 D, A, B;

		X_Form_Parser::parse_x(instr, D, A, B);

		PPC_ASSERT(A != 0);

		PPC_Address_T start = REG_TO_INT(REG(A)) + REG_TO_INT(REG(B));
		Core::Bytecode_Type buffer;
		Core::u16 val;

        PPC_TRACE_1("lhaux", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(A).convert_from_int(REG_TO_INT(REG(A)) + REG_TO_INT(REG(B)));
		REG(D).convert_from_int( (val & 0x8000)? (val | 0xffff0000) : val );
	}

	PPC_INSTRUCTION_IMPL(op_lhax)
	{
		PPC_s32 D, A, B;

		X_Form_Parser::parse_x(instr, D, A, B);

		PPC_ASSERT(A != 0);

		PPC_Address_T start = (A? REG_TO_INT(REG(A)) : 0) + REG_TO_INT(REG(B));
		Core::Bytecode_Type buffer;
		Core::u16 val;
        
        PPC_TRACE_1("lhax", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(D).convert_from_int( (val & 0x8000)? (val | 0xffff0000) : val );
	}

	PPC_INSTRUCTION_IMPL(op_lhz)
	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_Address_T start = (A? REG_TO_INT(REG(A)) : 0) + imm;
		Core::Bytecode_Type buffer;
		Core::u16 val;

        PPC_TRACE_1("lhz", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(D).convert_from_int(val);
	}

	PPC_INSTRUCTION_IMPL(op_lhzu)
	{
		PPC_s32 D, A;
		PPC_u32 imm;

		D_Form_Parser::parse_simm (instr, D, A, imm);

		PPC_ASSERT(A != 0);

		PPC_Address_T start = REG_TO_INT(REG(A)) + imm;
		Core::Bytecode_Type buffer;
		Core::u16 val;

        PPC_TRACE_1("lhzu", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))
            PPC_TRACE_RETURN("mmu access fault\n");

		Core::Wukong_Get_System().convert_from_bytecode(buffer, val);

		REG(A).convert_from_int(REG_TO_INT(REG(A)) + imm);
		REG(D).convert_from_int(val);
	}

	PPC_INSTRUCTION_IMPL(op_lhzux)
	{
		PPC_s32 D, A, B;

		X_Form_Parser::parse_x(instr, D, A, B);

		PPC_ASSERT(A != 0);

		PPC_Address_T start = REG_TO_INT(REG(A)) + REG_TO_INT(REG(B));
		Core::Bytecode_Type buffer;
		Core::u16 val;

        PPC_TRACE_1("lhzux", (Core::u32*)start);
        
		if (MMU::ACCESS_FAULT == GET_MMU().access(Core::Memory_32Bit::MEMORY_READ, start, 2, buffer))