Bochs/bochs/cpu/xmm.h

707 lines
22 KiB
C

/////////////////////////////////////////////////////////////////////////
// $Id$
/////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2003-2018 Stanislav Shwartsman
// Written by Stanislav Shwartsman [sshwarts at sourceforge net]
//
// 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., 51 Franklin St, Fifth Floor, Boston, MA B 02110-1301 USA
//
/////////////////////////////////////////////////////////////////////////
#ifndef BX_SSE_EXTENSIONS_H
#define BX_SSE_EXTENSIONS_H
/* XMM REGISTER */
typedef
#if defined(_MSC_VER) && (_MSC_VER>=1300)
__declspec(align(16))
#endif
union bx_xmm_reg_t {
Bit8s xmm_sbyte[16];
Bit16s xmm_s16[8];
Bit32s xmm_s32[4];
Bit64s xmm_s64[2];
Bit8u xmm_ubyte[16];
Bit16u xmm_u16[8];
Bit32u xmm_u32[4];
Bit64u xmm_u64[2];
void clear() { xmm_u64[0] = xmm_u64[1] = 0; }
} BxPackedXmmRegister;
#ifdef BX_BIG_ENDIAN
#define xmm64s(i) xmm_s64[1 - (i)]
#define xmm32s(i) xmm_s32[3 - (i)]
#define xmm16s(i) xmm_s16[7 - (i)]
#define xmmsbyte(i) xmm_sbyte[15 - (i)]
#define xmmubyte(i) xmm_ubyte[15 - (i)]
#define xmm16u(i) xmm_u16[7 - (i)]
#define xmm32u(i) xmm_u32[3 - (i)]
#define xmm64u(i) xmm_u64[1 - (i)]
#else
#define xmm64s(i) xmm_s64[(i)]
#define xmm32s(i) xmm_s32[(i)]
#define xmm16s(i) xmm_s16[(i)]
#define xmmsbyte(i) xmm_sbyte[(i)]
#define xmmubyte(i) xmm_ubyte[(i)]
#define xmm16u(i) xmm_u16[(i)]
#define xmm32u(i) xmm_u32[(i)]
#define xmm64u(i) xmm_u64[(i)]
#endif
/* AVX REGISTER */
typedef
#if defined(_MSC_VER) && (_MSC_VER>=1300)
__declspec(align(32))
#endif
union bx_ymm_reg_t {
Bit8s ymm_sbyte[32];
Bit16s ymm_s16[16];
Bit32s ymm_s32[8];
Bit64s ymm_s64[4];
Bit8u ymm_ubyte[32];
Bit16u ymm_u16[16];
Bit32u ymm_u32[8];
Bit64u ymm_u64[4];
BxPackedXmmRegister ymm_v128[2];
void clear() {
ymm_v128[0].clear();
ymm_v128[1].clear();
}
} BxPackedYmmRegister;
#ifdef BX_BIG_ENDIAN
#define ymm64s(i) ymm_s64[3 - (i)]
#define ymm32s(i) ymm_s32[7 - (i)]
#define ymm16s(i) ymm_s16[15 - (i)]
#define ymmsbyte(i) ymm_sbyte[31 - (i)]
#define ymmubyte(i) ymm_ubyte[31 - (i)]
#define ymm16u(i) ymm_u16[15 - (i)]
#define ymm32u(i) ymm_u32[7 - (i)]
#define ymm64u(i) ymm_u64[3 - (i)]
#define ymm128(i) ymm_v128[1 - (i)]
#else
#define ymm64s(i) ymm_s64[(i)]
#define ymm32s(i) ymm_s32[(i)]
#define ymm16s(i) ymm_s16[(i)]
#define ymmsbyte(i) ymm_sbyte[(i)]
#define ymmubyte(i) ymm_ubyte[(i)]
#define ymm16u(i) ymm_u16[(i)]
#define ymm32u(i) ymm_u32[(i)]
#define ymm64u(i) ymm_u64[(i)]
#define ymm128(i) ymm_v128[(i)]
#endif
typedef
#if defined(_MSC_VER) && (_MSC_VER>=1300)
__declspec(align(64))
#endif
union bx_zmm_reg_t {
Bit8s zmm_sbyte[64];
Bit16s zmm_s16[32];
Bit32s zmm_s32[16];
Bit64s zmm_s64[8];
Bit8u zmm_ubyte[64];
Bit16u zmm_u16[32];
Bit32u zmm_u32[16];
Bit64u zmm_u64[8];
BxPackedXmmRegister zmm_v128[4];
BxPackedYmmRegister zmm_v256[2];
void clear() {
zmm_v256[0].clear();
zmm_v256[1].clear();
}
} BxPackedZmmRegister;
#ifdef BX_BIG_ENDIAN
#define zmm64s(i) zmm_s64[7 - (i)]
#define zmm32s(i) zmm_s32[15 - (i)]
#define zmm16s(i) zmm_s16[31 - (i)]
#define zmmsbyte(i) zmm_sbyte[63 - (i)]
#define zmmubyte(i) zmm_ubyte[63 - (i)]
#define zmm16u(i) zmm_u16[31 - (i)]
#define zmm32u(i) zmm_u32[15 - (i)]
#define zmm64u(i) zmm_u64[7 - (i)]
#define zmm128(i) zmm_v128[3 - (i)]
#define zmm256(i) zmm_v256[1 - (i)]
#else
#define zmm64s(i) zmm_s64[(i)]
#define zmm32s(i) zmm_s32[(i)]
#define zmm16s(i) zmm_s16[(i)]
#define zmmsbyte(i) zmm_sbyte[(i)]
#define zmmubyte(i) zmm_ubyte[(i)]
#define zmm16u(i) zmm_u16[(i)]
#define zmm32u(i) zmm_u32[(i)]
#define zmm64u(i) zmm_u64[(i)]
#define zmm128(i) zmm_v128[(i)]
#define zmm256(i) zmm_v256[(i)]
#endif
#if BX_SUPPORT_EVEX
# define vmm64s(i) zmm64s(i)
# define vmm32s(i) zmm32s(i)
# define vmm16s(i) zmm16s(i)
# define vmmsbyte(i) zmmsbyte(i)
# define vmmubyte(i) zmmubyte(i)
# define vmm16u(i) zmm16u(i)
# define vmm32u(i) zmm32u(i)
# define vmm64u(i) zmm64u(i)
# define vmm128(i) zmm128(i)
# define vmm256(i) zmm256(i)
#else
# if BX_SUPPORT_AVX
# define vmm64s(i) ymm64s(i)
# define vmm32s(i) ymm32s(i)
# define vmm16s(i) ymm16s(i)
# define vmmsbyte(i) ymmsbyte(i)
# define vmmubyte(i) ymmubyte(i)
# define vmm16u(i) ymm16u(i)
# define vmm32u(i) ymm32u(i)
# define vmm64u(i) ymm64u(i)
# define vmm128(i) ymm128(i)
# else
# define vmm64s(i) xmm64s(i)
# define vmm32s(i) xmm32s(i)
# define vmm16s(i) xmm16s(i)
# define vmmsbyte(i) xmmsbyte(i)
# define vmmubyte(i) xmmubyte(i)
# define vmm16u(i) xmm16u(i)
# define vmm32u(i) xmm32u(i)
# define vmm64u(i) xmm64u(i)
# endif
#endif
#if BX_SUPPORT_EVEX
typedef BxPackedZmmRegister BxPackedAvxRegister;
#else
#if BX_SUPPORT_AVX
typedef BxPackedYmmRegister BxPackedAvxRegister;
#endif
#endif
#define BYTE_ELEMENTS(vlen) (16 * (vlen))
#define WORD_ELEMENTS(vlen) (8 * (vlen))
#define DWORD_ELEMENTS(vlen) (4 * (vlen))
#define QWORD_ELEMENTS(vlen) (2 * (vlen))
/* ************ */
/* XMM REGISTER */
/* ************ */
#if BX_SUPPORT_AVX
/* read XMM register */
#define BX_READ_XMM_REG(index) (BX_CPU_THIS_PTR vmm[index].vmm128(0))
#else /* BX_SUPPORT_AVX */
/* read XMM register */
#define BX_READ_XMM_REG(index) (BX_CPU_THIS_PTR vmm[index])
#endif /* BX_SUPPORT_AVX */
/* read only high 64 bit of the register */
#define BX_READ_XMM_REG_HI_QWORD(index) \
(BX_CPU_THIS_PTR vmm[index].vmm64u(1))
/* read only low 64 bit of the register */
#define BX_READ_XMM_REG_LO_QWORD(index) \
(BX_CPU_THIS_PTR vmm[index].vmm64u(0))
/* read only low 32 bit of the register */
#define BX_READ_XMM_REG_LO_DWORD(index) \
(BX_CPU_THIS_PTR vmm[index].vmm32u(0))
/* read only low 16 bit of the register */
#define BX_READ_XMM_REG_LO_WORD(index) \
(BX_CPU_THIS_PTR vmm[index].vmm16u(0))
/* read only low 8 bit of the register */
#define BX_READ_XMM_REG_LO_BYTE(index) \
(BX_CPU_THIS_PTR vmm[index].vmmubyte(0))
/* short names for above macroses */
#define BX_XMM_REG_HI_QWORD BX_READ_XMM_REG_HI_QWORD
#define BX_XMM_REG_LO_QWORD BX_READ_XMM_REG_LO_QWORD
#define BX_XMM_REG_LO_DWORD BX_READ_XMM_REG_LO_DWORD
#define BX_XMM_REG BX_READ_XMM_REG
/* store only high 64 bit of the register, rest of the register unchanged */
#define BX_WRITE_XMM_REG_HI_QWORD(index, reg64) \
{ BX_CPU_THIS_PTR vmm[index].vmm64u(1) = (reg64); }
/* store only low 64 bit of the register, rest of the register unchanged */
#define BX_WRITE_XMM_REG_LO_QWORD(index, reg64) \
{ BX_CPU_THIS_PTR vmm[index].vmm64u(0) = (reg64); }
/* store only low 32 bit of the register, rest of the register unchanged */
#define BX_WRITE_XMM_REG_LO_DWORD(index, reg32) \
{ BX_CPU_THIS_PTR vmm[index].vmm32u(0) = (reg32); }
/* store only low 16 bit of the register, rest of the register unchanged */
#define BX_WRITE_XMM_REG_LO_WORD(index, reg16) \
{ BX_CPU_THIS_PTR vmm[index].vmm16u(0) = (reg16); }
/* store only low 8 bit of the register, rest of the register unchanged */
#define BX_WRITE_XMM_REG_LO_BYTE(index, reg8) \
{ BX_CPU_THIS_PTR vmm[index].vmmubyte(0) = (reg8); }
/* store XMM register, upper part of the YMM or ZMM register unchanged */
#define BX_WRITE_XMM_REG(index, reg) \
{ (BX_XMM_REG(index)) = (reg); }
/* clear XMM register, upper part of the YMM or ZMM register unchanged */
#define BX_CLEAR_XMM_REG(index) { BX_XMM_REG(index).clear(); }
/* ************ */
/* YMM REGISTER */
/* ************ */
#if BX_SUPPORT_AVX
#if BX_SUPPORT_EVEX
/* read YMM register */
#define BX_READ_YMM_REG(index) (BX_CPU_THIS_PTR vmm[index].vmm256(0))
/* clear upper part of the ZMM register */
#define BX_CLEAR_AVX_HIGH256(index) { BX_CPU_THIS_PTR vmm[index].vmm256(1).clear(); }
#else /* BX_SUPPORT_EVEX */
/* read YMM register */
#define BX_READ_YMM_REG(index) (BX_CPU_THIS_PTR vmm[index])
/* clear upper part of the ZMM register - no upper part ;) */
#define BX_CLEAR_AVX_HIGH256(index)
#endif /* BX_SUPPORT_EVEX */
#define BX_YMM_REG BX_READ_YMM_REG
/* clear upper part of AVX128 register */
#define BX_CLEAR_AVX_HIGH128(index) \
{ BX_CPU_THIS_PTR vmm[index].vmm128(1).clear(); \
BX_CLEAR_AVX_HIGH256(index); }
/* write YMM register and clear upper part of the AVX register */
#define BX_WRITE_YMM_REGZ(index, reg) \
{ (BX_READ_YMM_REG(index)) = (reg); BX_CLEAR_AVX_HIGH256(index); }
/* write XMM register and clear upper part of AVX register (if not SSE instruction) */
#define BX_WRITE_XMM_REGZ(index, reg, vlen) \
{ (BX_XMM_REG(index)) = (reg); \
if (vlen) BX_CLEAR_AVX_HIGH128(index); }
/* write XMM register while clearing upper part of the AVX register */
#define BX_WRITE_XMM_REG_CLEAR_HIGH(index, reg) \
{ BX_XMM_REG(index) = (reg); BX_CLEAR_AVX_HIGH128(index); }
#define BX_WRITE_XMM_REG_LO_QWORD_CLEAR_HIGH(index, reg64) \
{ BX_CPU_THIS_PTR vmm[index].vmm64u(0) = (reg64); \
BX_CPU_THIS_PTR vmm[index].vmm64u(1) = 0; BX_CLEAR_AVX_HIGH128(index); }
#else /* BX_SUPPORT_AVX */
/* write XMM register while clearing upper part of AVX register */
#define BX_WRITE_XMM_REG_CLEAR_HIGH(index, reg) \
BX_WRITE_XMM_REG(index, reg)
/* write XMM register while clearing upper part of AVX register */
#define BX_WRITE_XMM_REGZ(index, reg, vlen) \
BX_WRITE_XMM_REG(index, reg)
#endif /* BX_SUPPORT_AVX */
/* ************ */
/* AVX REGISTER */
/* ************ */
// vector length independent accessors, i.e. access YMM when no EVEX was compiled in
// or ZMM when EVEX support was compiled in
/* read AVX register */
#define BX_READ_AVX_REG(index) (BX_CPU_THIS_PTR vmm[index])
#define BX_AVX_REG BX_READ_AVX_REG
/* write AVX register */
#define BX_WRITE_AVX_REG(index, reg) { (BX_CPU_THIS_PTR vmm[index]) = (reg); }
/* read AVX register lane */
#define BX_READ_AVX_REG_LANE(index, line) \
(BX_CPU_THIS_PTR vmm[index].vmm128(line))
/* write AVX register and potentialy clear upper part of the register */
#define BX_WRITE_YMM_REGZ_VLEN(index, reg256, vlen) \
{ (BX_YMM_REG(index)) = (reg256); \
if (vlen == BX_VL256) { BX_CLEAR_AVX_HIGH256(index); } \
else if (vlen == BX_VL128) { BX_CLEAR_AVX_HIGH128(index); } \
}
/* clear upper part of the AVX register */
#define BX_CLEAR_AVX_REGZ(index, vlen) \
{ if ((vlen) == BX_VL256) { BX_CLEAR_AVX_HIGH256(index); } \
else if ((vlen) == BX_VL128) { BX_CLEAR_AVX_HIGH128(index); } \
}
/* write AVX register and potentialy clear upper part of the register */
#define BX_WRITE_AVX_REGZ(index, reg, vlen) \
{ BX_CPU_THIS_PTR vmm[index] = (reg); \
BX_CLEAR_AVX_REGZ(index, vlen); \
}
/* clear AVX register */
#define BX_CLEAR_AVX_REG(index) { BX_CPU_THIS_PTR vmm[index].clear(); }
#if BX_SUPPORT_EVEX
/* read upper 256-bit part of ZMM register */
#define BX_READ_ZMM_REG_HI(index) \
(BX_CPU_THIS_PTR vmm[index].vmm256(1))
#endif
BX_CPP_INLINE int is_clear(const BxPackedXmmRegister *r)
{
return (r->xmm64u(0) | r->xmm64u(1)) == 0;
}
#if BX_SUPPORT_EVEX
// implement SAE and EVEX encoded rounding control
BX_CPP_INLINE void softfloat_status_word_rc_override(float_status_t &status, bxInstruction_c *i)
{
/* must be VL512 otherwise EVEX.LL encodes vector length */
if (i->modC0() && i->getEvexb()) {
status.float_rounding_mode = i->getRC();
status.float_suppress_exception = float_all_exceptions_mask;
status.float_exception_masks = float_all_exceptions_mask;
}
}
#else
#define softfloat_status_word_rc_override(status, i)
#endif
/* convert float32 NaN number to QNaN */
BX_CPP_INLINE float32 convert_to_QNaN(float32 op)
{
return op | 0x7FC00000;
}
/* convert float64 NaN number to QNaN */
BX_CPP_INLINE float64 convert_to_QNaN(float64 op)
{
return op | BX_CONST64(0x7FF8000000000000);
}
/* MXCSR REGISTER */
/* 31|30|29|28|27|26|25|24|23|22|21|20|19|18|17|16
* ==|==|=====|==|==|==|==|==|==|==|==|==|==|==|== (reserved)
* 0| 0| 0| 0| 0| 0| 0| 0| 0| 0| 0| 0| 0| 0|MM| 0
*
* 15|14|13|12|11|10| 9| 8| 7| 6| 5| 4| 3| 2| 1| 0
* ==|==|=====|==|==|==|==|==|==|==|==|==|==|==|==
* FZ| R C |PM|UM|OM|ZM|DM|IM|DZ|PE|UE|OE|ZE|DE|IE
*/
/* MXCSR REGISTER FIELDS DESCRIPTION */
/*
* IE 0 Invalid-Operation Exception 0
* DE 1 Denormalized-Operand Exception 0
* ZE 2 Zero-Divide Exception 0
* OE 3 Overflow Exception 0
* UE 4 Underflow Exception 0
* PE 5 Precision Exception 0
* DZ 6 Denormals are Zeros 0
* IM 7 Invalid-Operation Exception Mask 1
* DM 8 Denormalized-Operand Exception Mask 1
* ZM 9 Zero-Divide Exception Mask 1
* OM 10 Overflow Exception Mask 1
* UM 11 Underflow Exception Mask 1
* PM 12 Precision Exception Mask 1
* RC 13-14 Floating-Point Rounding Control 00
* FZ 15 Flush-to-Zero for Masked Underflow 0
* RZ 16 Reserved 0
* MM 17 Misaligned Exception Mask 0
*/
#define MXCSR_EXCEPTIONS 0x0000003F
#define MXCSR_DAZ 0x00000040
#define MXCSR_MASKED_EXCEPTIONS 0x00001F80
#define MXCSR_ROUNDING_CONTROL 0x00006000
#define MXCSR_FLUSH_MASKED_UNDERFLOW 0x00008000
#define MXCSR_MISALIGNED_EXCEPTION_MASK 0x00020000
#define MXCSR_IE 0x00000001
#define MXCSR_DE 0x00000002
#define MXCSR_ZE 0x00000004
#define MXCSR_OE 0x00000008
#define MXCSR_UE 0x00000010
#define MXCSR_PE 0x00000020
#define MXCSR_IM 0x00000080
#define MXCSR_DM 0x00000100
#define MXCSR_ZM 0x00000200
#define MXCSR_OM 0x00000400
#define MXCSR_UM 0x00000800
#define MXCSR_PM 0x00001000
#define MXCSR_RESET 0x00001F80 /* reset value of the MXCSR register */
struct BOCHSAPI bx_mxcsr_t
{
Bit32u mxcsr;
bx_mxcsr_t (Bit32u val = MXCSR_RESET)
: mxcsr(val) {}
#define IMPLEMENT_MXCSR_ACCESSOR(name, bitmask, bitnum) \
int get_##name () const { \
return (mxcsr & (bitmask)) >> (bitnum); \
}
IMPLEMENT_MXCSR_ACCESSOR(exceptions_masks, MXCSR_MASKED_EXCEPTIONS, 7);
IMPLEMENT_MXCSR_ACCESSOR(DAZ, MXCSR_DAZ, 6);
IMPLEMENT_MXCSR_ACCESSOR(rounding_mode, MXCSR_ROUNDING_CONTROL, 13);
IMPLEMENT_MXCSR_ACCESSOR(flush_masked_underflow, MXCSR_FLUSH_MASKED_UNDERFLOW, 15);
IMPLEMENT_MXCSR_ACCESSOR(MM, MXCSR_MISALIGNED_EXCEPTION_MASK, 17);
IMPLEMENT_MXCSR_ACCESSOR(IE, MXCSR_IE, 0);
IMPLEMENT_MXCSR_ACCESSOR(DE, MXCSR_DE, 1);
IMPLEMENT_MXCSR_ACCESSOR(ZE, MXCSR_ZE, 2);
IMPLEMENT_MXCSR_ACCESSOR(OE, MXCSR_OE, 3);
IMPLEMENT_MXCSR_ACCESSOR(UE, MXCSR_UE, 4);
IMPLEMENT_MXCSR_ACCESSOR(PE, MXCSR_PE, 5);
IMPLEMENT_MXCSR_ACCESSOR(IM, MXCSR_IM, 7);
IMPLEMENT_MXCSR_ACCESSOR(DM, MXCSR_DM, 8);
IMPLEMENT_MXCSR_ACCESSOR(ZM, MXCSR_ZM, 9);
IMPLEMENT_MXCSR_ACCESSOR(OM, MXCSR_OM, 10);
IMPLEMENT_MXCSR_ACCESSOR(UM, MXCSR_UM, 11);
IMPLEMENT_MXCSR_ACCESSOR(PM, MXCSR_PM, 12);
void set_exceptions(int status) {
mxcsr |= (status & MXCSR_EXCEPTIONS);
}
void mask_all_exceptions() {
mxcsr |= (MXCSR_MASKED_EXCEPTIONS);
}
};
#if defined(NEED_CPU_REG_SHORTCUTS)
#define MXCSR (BX_CPU_THIS_PTR mxcsr)
#define BX_MXCSR_REGISTER (BX_CPU_THIS_PTR mxcsr.mxcsr)
#define MXCSR_MASK (BX_CPU_THIS_PTR mxcsr_mask)
#endif
/* INTEGER SATURATION */
/*
* SaturateWordSToByteS converts a signed 16-bit value to a signed
* 8-bit value. If the signed 16-bit value is less than -128, it is
* represented by the saturated value -128 (0x80). If it is greater
* than 127, it is represented by the saturated value 127 (0x7F).
*/
BX_CPP_INLINE Bit8s BX_CPP_AttrRegparmN(1) SaturateWordSToByteS(Bit16s value)
{
if(value < -128) return -128;
if(value > 127) return 127;
return (Bit8s) value;
}
/*
* SaturateQwordSToByteS converts a signed 32-bit value to a signed
* 8-bit value. If the signed 32-bit value is less than -128, it is
* represented by the saturated value -128 (0x80). If it is greater
* than 127, it is represented by the saturated value 127 (0x7F).
*/
BX_CPP_INLINE Bit8s BX_CPP_AttrRegparmN(1) SaturateDwordSToByteS(Bit32s value)
{
if(value < -128) return -128;
if(value > 127) return 127;
return (Bit8s) value;
}
/*
* SaturateQwordSToByteS converts a signed 64-bit value to a signed
* 8-bit value. If the signed 64-bit value is less than -128, it is
* represented by the saturated value -128 (0x80). If it is greater
* than 127, it is represented by the saturated value 127 (0x7F).
*/
BX_CPP_INLINE Bit8s BX_CPP_AttrRegparmN(1) SaturateQwordSToByteS(Bit64s value)
{
if(value < -128) return -128;
if(value > 127) return 127;
return (Bit8s) value;
}
/*
* SaturateQwordSToWordS converts a signed 64-bit value to a signed
* 16-bit value. If the signed 64-bit value is less than -32768, it is
* represented by the saturated value -32768 (0x8000). If it is greater
* than 32767, it is represented by the saturated value 32767 (0x7FFF).
*/
BX_CPP_INLINE Bit16s BX_CPP_AttrRegparmN(1) SaturateQwordSToWordS(Bit64s value)
{
if(value < -32768) return -32768;
if(value > 32767) return 32767;
return (Bit16s) value;
}
/*
* SaturateDwordSToWordS converts a signed 32-bit value to a signed
* 16-bit value. If the signed 32-bit value is less than -32768, it is
* represented by the saturated value -32768 (0x8000). If it is greater
* than 32767, it is represented by the saturated value 32767 (0x7FFF).
*/
BX_CPP_INLINE Bit16s BX_CPP_AttrRegparmN(1) SaturateDwordSToWordS(Bit32s value)
{
if(value < -32768) return -32768;
if(value > 32767) return 32767;
return (Bit16s) value;
}
/*
* SaturateQwordSToDwordS converts a signed 64-bit value to a signed
* 32-bit value. If the signed 64-bit value is less than -2147483648, it
* is represented by the saturated value -2147483648 (0x80000000). If it
* is greater than 2147483647, it is represented by the saturated value
* 2147483647 (0x7FFFFFFF).
*/
BX_CPP_INLINE Bit32s BX_CPP_AttrRegparmN(1) SaturateQwordSToDwordS(Bit64s value)
{
if(value < BX_CONST64(-2147483648)) return BX_CONST64(-2147483648);
if(value > 2147483647) return 2147483647;
return (Bit32s) value;
}
/*
* SaturateWordSToByteU converts a signed 16-bit value to an unsigned
* 8-bit value. If the signed 16-bit value is less than zero it is
* represented by the saturated value zero (0x00). If it is greater than
* 255 it is represented by the saturated value 255 (0xFF).
*/
BX_CPP_INLINE Bit8u BX_CPP_AttrRegparmN(1) SaturateWordSToByteU(Bit16s value)
{
if(value < 0) return 0;
if(value > 255) return 255;
return (Bit8u) value;
}
/*
* SaturateDwordSToWordU converts a signed 32-bit value to an unsigned
* 16-bit value. If the signed 32-bit value is less than zero, it is
* represented by the saturated value zero (0x0000). If it is greater
* than 65535, it is represented by the saturated value 65535 (0xFFFF).
*/
BX_CPP_INLINE Bit16u BX_CPP_AttrRegparmN(1) SaturateDwordSToWordU(Bit32s value)
{
if(value < 0) return 0;
if(value > 65535) return 65535;
return (Bit16u) value;
}
/*
* SaturateQwordSToDwordU converts a signed 64-bit value to an unsigned
* 32-bit value. If the signed 64-bit value is less than zero, it is
* represented by the saturated value zero (0x00000000). If it is greater
* than 4294967295, it is represented by the saturated value 4294967295
* (0xFFFFFFFF).
*/
BX_CPP_INLINE Bit32u BX_CPP_AttrRegparmN(1) SaturateQwordSToDwordU(Bit64s value)
{
if(value < 0) return 0;
if(value > BX_CONST64(4294967295)) return BX_CONST64(4294967295);
return (Bit32u) value;
}
/*
* SaturateWordUToByteU converts an unsigned 16-bit value to unsigned
* 8-bit value. If the unsigned 16-bit value is greater than 255, it is
* represented by the saturated value 255 (0xFF).
*/
BX_CPP_INLINE Bit8u BX_CPP_AttrRegparmN(1) SaturateWordUToByteU(Bit16u value)
{
if(value > 255) return 255;
return (Bit8u) value;
}
/*
* SaturateDWordUToByteU converts an unsigned 32-bit value to unsigned
* 8-bit value. If the unsigned 32-bit value is greater than 255, it is
* represented by the saturated value 255 (0xFF).
*/
BX_CPP_INLINE Bit8u BX_CPP_AttrRegparmN(1) SaturateDwordUToByteU(Bit32u value)
{
if(value > 255) return 255;
return (Bit8u) value;
}
/*
* SaturateQWordUToByteU converts an unsigned 64-bit value to unsigned
* 8-bit value. If the unsigned 64-bit value is greater than 255, it is
* represented by the saturated value 255 (0xFF).
*/
BX_CPP_INLINE Bit8u BX_CPP_AttrRegparmN(1) SaturateQwordUToByteU(Bit64u value)
{
if(value > 255) return 255;
return (Bit8u) value;
}
/*
* SaturateQwordUToWordU converts an unsigned 64-bit value to unsigned
* 16-bit value. If the unsigned 64-bit value is greater than 65535,
* it is represented by the saturated value 65535 (0xFFFF).
*/
BX_CPP_INLINE Bit16u BX_CPP_AttrRegparmN(1) SaturateQwordUToWordU(Bit64u value)
{
if(value > 65535) return 65535;
return (Bit16u) value;
}
/*
* SaturateDwordUToWordU converts an unsigned 32-bit value to unsigned
* 16-bit value. If the unsigned 32-bit value is greater than 65535,
* it is represented by the saturated value 65535 (0xFFFF).
*/
BX_CPP_INLINE Bit16u BX_CPP_AttrRegparmN(1) SaturateDwordUToWordU(Bit32u value)
{
if(value > 65535) return 65535;
return (Bit16u) value;
}
/*
* SaturateQwordUToDwordU converts an unsigned 64-bit value to unsigned
* 32-bit value. If the unsigned 64-bit value is greater than 4294967295,
* it is represented by the saturated value 4294967295 (0xFFFFFFFF).
*/
BX_CPP_INLINE Bit32u BX_CPP_AttrRegparmN(1) SaturateQwordUToDwordU(Bit64u value)
{
if(value > BX_CONST64(4294967295)) return BX_CONST64(4294967295);
return (Bit32u) value;
}
#endif