///////////////////////////////////////////////////////////////////////// // $Id: i387.h,v 1.30 2005-06-06 20:14:49 vruppert Exp $ ///////////////////////////////////////////////////////////////////////// // // Copyright (c) 2004 Stanislav Shwartsman // Written by Stanislav Shwartsman // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2 of the License, or (at your option) any later version. // // This library 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 // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // #ifndef _BX_I387_RELATED_EXTENSIONS_H_ #define _BX_I387_RELATED_EXTENSIONS_H_ #if BX_SUPPORT_FPU #include "fpu/softfloat.h" #define BX_FPU_REG(index) \ (BX_CPU_THIS_PTR the_i387.st_space[index]) #if defined(NEED_CPU_REG_SHORTCUTS) #define FPU_PARTIAL_STATUS (BX_CPU_THIS_PTR the_i387.swd) #define FPU_CONTROL_WORD (BX_CPU_THIS_PTR the_i387.cwd) #define FPU_TAG_WORD (BX_CPU_THIS_PTR the_i387.twd) #define FPU_TOS (BX_CPU_THIS_PTR the_i387.tos) #endif #include "fpu/tag_w.h" #include "fpu/status_w.h" #include "fpu/control_w.h" extern int FPU_tagof(const floatx80 ®); // // Minimal i387 structure // struct BOCHSAPI i387_t { i387_t() {} public: void init(); // used by FINIT/FNINIT instructions void reset(); // called on CPU reset int is_IA_masked() const { return (cwd & FPU_CW_Invalid); } Bit16u get_control_word() const { return cwd; } Bit16u get_tag_word() const { return twd; } Bit16u get_status_word() const { return (swd & ~FPU_SW_Top & 0xFFFF) | ((tos << 11) & FPU_SW_Top); } Bit16u get_partial_status() const { return swd; } void FPU_pop (); void FPU_push(); void FPU_settagi(int tag, int stnr); int FPU_gettagi(int stnr); floatx80 FPU_read_regi(int stnr) { return st_space[(tos+stnr) & 7]; } void FPU_save_regi(floatx80 reg, int tag, int stnr); void FPU_save_regi(floatx80 reg, int stnr) { FPU_save_regi(reg, FPU_tagof(reg), stnr); } public: Bit16u cwd; // control word Bit16u swd; // status word Bit16u twd; // tag word Bit16u foo; // last instruction opcode bx_address fip; bx_address fdp; Bit16u fcs; Bit16u fds; floatx80 st_space[8]; unsigned char tos; unsigned char align1; unsigned char align2; unsigned char align3; }; #define IS_TAG_EMPTY(i) \ ((BX_CPU_THIS_PTR the_i387.FPU_gettagi(i)) == FPU_Tag_Empty) #define BX_READ_FPU_REG(i) \ (BX_CPU_THIS_PTR the_i387.FPU_read_regi(i)) #define BX_WRITE_FPU_REGISTER_AND_TAG(value, tag, i) \ BX_CPU_THIS_PTR the_i387.FPU_save_regi((value), (tag), (i)); #define BX_WRITE_FPU_REG(value, i) \ BX_CPU_THIS_PTR the_i387.FPU_save_regi((value), (i)); BX_CPP_INLINE int i387_t::FPU_gettagi(int stnr) { return (twd >> (((stnr+tos) & 7)*2)) & 3; } BX_CPP_INLINE void i387_t::FPU_settagi(int tag, int stnr) { int regnr = (stnr + tos) & 7; twd &= ~(3 << (regnr*2)); twd |= (tag & 3) << (regnr*2); } BX_CPP_INLINE void i387_t::FPU_push(void) { tos--; } BX_CPP_INLINE void i387_t::FPU_pop(void) { twd |= 3 << ((tos & 7)*2); tos++; } BX_CPP_INLINE void i387_t::FPU_save_regi(floatx80 reg, int tag, int stnr) { st_space[(stnr+tos) & 7] = reg; FPU_settagi(tag, stnr); } #include BX_CPP_INLINE void i387_t::init() { cwd = 0x037F; swd = 0; tos = 0; twd = 0xFFFF; foo = 0; fip = 0; fcs = 0; fds = 0; fdp = 0; } BX_CPP_INLINE void i387_t::reset() { cwd = 0x0040; swd = 0; tos = 0; twd = 0x5555; foo = 0; fip = 0; fcs = 0; fds = 0; fdp = 0; memset(st_space, 0, sizeof(floatx80)*8); } #if BX_SUPPORT_MMX typedef union bx_packed_mmx_reg_t { Bit8s _sbyte[8]; Bit16s _s16[4]; Bit32s _s32[2]; Bit64s _s64; Bit8u _ubyte[8]; Bit16u _u16[4]; Bit32u _u32[2]; Bit64u _u64; } BxPackedMmxRegister; #ifdef BX_BIG_ENDIAN #define mmx64s(i) _s64 #define mmx32s(i) _s32[1 - (i)] #define mmx16s(i) _s16[3 - (i)] #define mmxsbyte(i) _sbyte[7 - (i)] #define mmxubyte(i) _ubyte[7 - (i)] #define mmx16u(i) _u16[3 - (i)] #define mmx32u(i) _u32[1 - (i)] #define mmx64u _u64 #else #define mmx64s(i) _s64 #define mmx32s(i) _s32[(i)] #define mmx16s(i) _s16[(i)] #define mmxsbyte(i) _sbyte[(i)] #define mmxubyte(i) _ubyte[(i)] #define mmx16u(i) _u16[(i)] #define mmx32u(i) _u32[(i)] #define mmx64u _u64 #endif /* for compatability with already written code */ #define MMXSB0(reg) (reg.mmxsbyte(0)) #define MMXSB1(reg) (reg.mmxsbyte(1)) #define MMXSB2(reg) (reg.mmxsbyte(2)) #define MMXSB3(reg) (reg.mmxsbyte(3)) #define MMXSB4(reg) (reg.mmxsbyte(4)) #define MMXSB5(reg) (reg.mmxsbyte(5)) #define MMXSB6(reg) (reg.mmxsbyte(6)) #define MMXSB7(reg) (reg.mmxsbyte(7)) #define MMXSW0(reg) (reg.mmx16s(0)) #define MMXSW1(reg) (reg.mmx16s(1)) #define MMXSW2(reg) (reg.mmx16s(2)) #define MMXSW3(reg) (reg.mmx16s(3)) #define MMXSD0(reg) (reg.mmx32s(0)) #define MMXSD1(reg) (reg.mmx32s(1)) #define MMXSQ(reg) (reg.mmx64s) #define MMXUQ(reg) (reg.mmx64u) #define MMXUD0(reg) (reg.mmx32u(0)) #define MMXUD1(reg) (reg.mmx32u(1)) #define MMXUW0(reg) (reg.mmx16u(0)) #define MMXUW1(reg) (reg.mmx16u(1)) #define MMXUW2(reg) (reg.mmx16u(2)) #define MMXUW3(reg) (reg.mmx16u(3)) #define MMXUB0(reg) (reg.mmxubyte(0)) #define MMXUB1(reg) (reg.mmxubyte(1)) #define MMXUB2(reg) (reg.mmxubyte(2)) #define MMXUB3(reg) (reg.mmxubyte(3)) #define MMXUB4(reg) (reg.mmxubyte(4)) #define MMXUB5(reg) (reg.mmxubyte(5)) #define MMXUB6(reg) (reg.mmxubyte(6)) #define MMXUB7(reg) (reg.mmxubyte(7)) #define BX_MMX_REG(index) (BX_FPU_REG(index).fraction) #define BX_READ_MMX_REG(index) \ (*((const BxPackedMmxRegister*)(&(BX_MMX_REG(index))))) #define BX_WRITE_MMX_REG(index, value) \ { \ (BX_FPU_REG(index)).fraction = MMXUQ(value); \ (BX_FPU_REG(index)).exp = 0xffff; \ } #endif /* BX_SUPPORT_MMX */ #endif /* BX_SUPPORT_FPU */ #endif