/*---------------------------------------------------------------------------+ | poly.h | | $Id: poly.h,v 1.4 2001-10-06 03:53:46 bdenney Exp $ | | | Header file for the FPU-emu poly*.c source files. | | | | Copyright (C) 1994,1999 | | W. Metzenthen, 22 Parker St, Ormond, Vic 3163, | | Australia. E-mail billm@melbpc.org.au | | | | Declarations and definitions for functions operating on Xsig (12-byte | | extended-significand) quantities. | | | +---------------------------------------------------------------------------*/ #ifndef _POLY_H #define _POLY_H /* This 12-byte structure is used to improve the accuracy of computation of transcendental functions. Intended to be used to get results better than 8-byte computation allows. 9-byte would probably be sufficient. */ typedef struct { #ifdef EMU_BIG_ENDIAN u32 msw; u32 midw; u32 lsw; #else u32 lsw; u32 midw; u32 msw; #endif } GCC_ATTRIBUTE((packed)) Xsig; asmlinkage void mul64(u64 const *a, u64 const *b, u64 *result); asmlinkage void polynomial_Xsig(Xsig *, const u64 *x, const u64 terms[], const int n); asmlinkage void mul32_Xsig(Xsig *, const u32 mult); asmlinkage void mul64_Xsig(Xsig *, const u64 *mult); asmlinkage void mul_Xsig_Xsig(Xsig *dest, const Xsig *mult); asmlinkage void shr_Xsig(Xsig *, const int n); asmlinkage int round_Xsig(Xsig *); asmlinkage int norm_Xsig(Xsig *); asmlinkage void div_Xsig(const Xsig *x1, const Xsig *x2, Xsig *dest); /* Macro to extract the most significant 32 bits from a 64bit quantity */ #ifdef EMU_BIG_ENDIAN #define LL_MSW(x) (((u32 *)&x)[0]) #else #define LL_MSW(x) (((u32 *)&x)[1]) #endif /* Macro to initialize an Xsig struct */ #ifdef EMU_BIG_ENDIAN #define MK_XSIG(a,b,c) { a, b, c } #else #define MK_XSIG(a,b,c) { c, b, a } #endif /* Macro to access the 8 ms bytes of an Xsig as a 64bit quantity */ #ifdef EMU_BIG_ENDIAN #define XSIG_LL(x) (*(u64 *)&x.msw) #else #define XSIG_LL(x) (*(u64 *)&x.midw) #endif /* Need to run gcc with optimizations on to get these to actually be in-line. */ /* Multiply two fixed-point 32 bit numbers, producing a 32 bit result. The answer is the ms word of the product. */ BX_C_INLINE u32 mul_32_32(const u32 arg1, const u32 arg2) { #ifdef NO_ASSEMBLER return (((u64)arg1) * arg2) >> 32; #else /* Some versions of gcc make it difficult to stop eax from being clobbered. Merely specifying that it is used doesn't work... */ int retval; asm volatile ("mull %2; movl %%edx,%%eax" \ :"=a" (retval) \ :"0" (arg1), "g" (arg2) \ :"dx"); return retval; #endif } /* Add the 12 byte Xsig x2 to Xsig dest, with no checks for overflow. */ BX_C_INLINE void add_Xsig_Xsig(Xsig *dest, const Xsig *x2) { #ifdef NO_ASSEMBLER dest->lsw += x2->lsw; if ( dest->lsw < x2->lsw ) { dest->midw ++; if ( dest->midw == 0 ) dest->msw ++; } dest->midw += x2->midw; if ( dest->midw < x2->midw ) { dest->msw ++; } dest->msw += x2->msw; #else asm volatile ("movl %1,%%edi; movl %2,%%esi; movl (%%esi),%%eax; addl %%eax,(%%edi); movl 4(%%esi),%%eax; adcl %%eax,4(%%edi); movl 8(%%esi),%%eax; adcl %%eax,8(%%edi);" :"=g" (*dest):"g" (dest), "g" (x2) :"ax","si","di"); #endif } /* Add the 12 byte Xsig x2 to Xsig dest, adjust exp if overflow occurs. */ BX_C_INLINE void add_two_Xsig(Xsig *dest, const Xsig *x2, s32 *exp) { #ifdef NO_ASSEMBLER int ovfl = 0; dest->lsw += x2->lsw; if ( dest->lsw < x2->lsw ) { dest->midw ++; if ( dest->midw == 0 ) { dest->msw ++; if ( dest->msw == 0 ) ovfl = 1; } } dest->midw += x2->midw; if ( dest->midw < x2->midw ) { dest->msw ++; if ( dest->msw == 0 ) ovfl = 1; } dest->msw += x2->msw; if ( dest->msw < x2->msw ) ovfl = 1; if ( ovfl ) { (*exp) ++; dest->lsw >>= 1; if ( dest->midw & 1 ) dest->lsw |= 0x80000000; dest->midw >>= 1; if ( dest->msw & 1 ) dest->midw |= 0x80000000; dest->msw >>= 1; dest->msw |= 0x80000000; } #else /* Note: the constraints in the asm statement didn't always work properly with gcc 2.5.8. Changing from using edi to using ecx got around the problem, but keep fingers crossed! */ asm volatile ("movl %2,%%ecx; movl %3,%%esi; movl (%%esi),%%eax; addl %%eax,(%%ecx); movl 4(%%esi),%%eax; adcl %%eax,4(%%ecx); movl 8(%%esi),%%eax; adcl %%eax,8(%%ecx); jnc 0f; rcrl 8(%%ecx); rcrl 4(%%ecx); rcrl (%%ecx) movl %4,%%ecx; incl (%%ecx) movl $1,%%eax; jmp 1f; 0: xorl %%eax,%%eax; 1:" :"=g" (*exp), "=g" (*dest) :"g" (dest), "g" (x2), "g" (exp) :"cx","si","ax"); #endif } /* Negate the 12 byte Xsig */ BX_C_INLINE void negate_Xsig(Xsig *x) { #ifdef NO_ASSEMBLER x->lsw = ~x->lsw; x->midw = ~x->midw; x->msw = ~x->msw; x->lsw ++; if ( x->lsw == 0 ) { x->midw ++; if ( x->midw == 0 ) x->msw ++; } #else /* Negate (subtract from 1.0) the 12 byte Xsig */ /* This is faster in a loop on my 386 than using the "neg" instruction. */ asm volatile("movl %1,%%esi; " "xorl %%ecx,%%ecx; " "movl %%ecx,%%eax; subl (%%esi),%%eax; movl %%eax,(%%esi); " "movl %%ecx,%%eax; sbbl 4(%%esi),%%eax; movl %%eax,4(%%esi); " "movl %%ecx,%%eax; sbbl 8(%%esi),%%eax; movl %%eax,8(%%esi); " :"=g" (*x):"g" (x):"si","ax","cx"); #endif } #endif /* _POLY_H */