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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libcpu/] [m68k/] [m68040/] [fpsp/] [do_func.S] - Blame information for rev 173

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//
//      $Id: do_func.S,v 1.2 2001-09-27 12:01:22 chris Exp $
//
//      do_func.sa 3.4 2/18/91
//
// Do_func performs the unimplemented operation.  The operation
// to be performed is determined from the lower 7 bits of the
// extension word (except in the case of fmovecr and fsincos).
// The opcode and tag bits form an index into a jump table in
// tbldo.sa.  Cases of zero, infinity and NaN are handled in
// do_func by forcing the default result.  Normalized and
// denormalized (there are no unnormalized numbers at this
// point) are passed onto the emulation code.
//
// CMDREG1B and STAG are extracted from the fsave frame
// and combined to form the table index.  The function called
// will start with a0 pointing to the ETEMP operand.  Dyadic
// functions can find FPTEMP at -12(a0).
//
// Called functions return their result in fp0.  Sincos returns
// sin(x) in fp0 and cos(x) in fp1.
//
 
//              Copyright (C) Motorola, Inc. 1990
//                      All Rights Reserved
//
//      THIS IS UNPUBLISHED PROPRIETARY SOURCE CODE OF MOTOROLA
//      The copyright notice above does not evidence any
//      actual or intended publication of such source code.
 
DO_FUNC:        //idnt    2,1 | Motorola 040 Floating Point Software Package
 
        |section        8
 
#include "fpsp.defs"
 
        |xref   t_dz2
        |xref   t_operr
        |xref   t_inx2
        |xref   t_resdnrm
        |xref   dst_nan
        |xref   src_nan
        |xref   nrm_set
        |xref   sto_cos
 
        |xref   tblpre
        |xref   slognp1,slogn,slog10,slog2
        |xref   slognd,slog10d,slog2d
        |xref   smod,srem
        |xref   sscale
        |xref   smovcr
 
PONE:   .long   0x3fff0000,0x80000000,0x00000000        //+1
MONE:   .long   0xbfff0000,0x80000000,0x00000000        //-1
PZERO:  .long   0x00000000,0x00000000,0x00000000        //+0
MZERO:  .long   0x80000000,0x00000000,0x00000000        //-0
PINF:   .long   0x7fff0000,0x00000000,0x00000000        //+inf
MINF:   .long   0xffff0000,0x00000000,0x00000000        //-inf
QNAN:   .long   0x7fff0000,0xffffffff,0xffffffff        //non-signaling nan
PPIBY2:  .long  0x3FFF0000,0xC90FDAA2,0x2168C235        //+PI/2
MPIBY2:  .long  0xbFFF0000,0xC90FDAA2,0x2168C235        //-PI/2
 
        .global do_func
do_func:
        clrb    CU_ONLY(%a6)
//
// Check for fmovecr.  It does not follow the format of fp gen
// unimplemented instructions.  The test is on the upper 6 bits;
// if they are $17, the inst is fmovecr.  Call entry smovcr
// directly.
//
        bfextu  CMDREG1B(%a6){#0:#6},%d0 //get opclass and src fields
        cmpil   #0x17,%d0               //if op class and size fields are $17,
//                              ;it is FMOVECR; if not, continue
        bnes    not_fmovecr
        jmp     smovcr          //fmovecr; jmp directly to emulation
 
not_fmovecr:
        movew   CMDREG1B(%a6),%d0
        andl    #0x7F,%d0
        cmpil   #0x38,%d0               //if the extension is >= $38,
        bge     serror          //it is illegal
        bfextu  STAG(%a6){#0:#3},%d1
        lsll    #3,%d0          //make room for STAG
        addl    %d1,%d0         //combine for final index into table
        leal    tblpre,%a1      //start of monster jump table
        movel   (%a1,%d0.w*4),%a1       //real target address
        leal    ETEMP(%a6),%a0  //a0 is pointer to src op
        movel   USER_FPCR(%a6),%d1
        andl    #0xFF,%d1               // discard all but rounding mode/prec
        fmovel  #0,%fpcr
        jmp     (%a1)
//
//      ERROR
//
        .global serror
serror:
        st      STORE_FLG(%a6)
        rts
//
// These routines load forced values into fp0.  They are called
// by index into tbldo.
//
// Load a signed zero to fp0 and set inex2/ainex
//
        .global snzrinx
snzrinx:
        btstb   #sign_bit,LOCAL_EX(%a0) //get sign of source operand
        bnes    ld_mzinx        //if negative, branch
        bsr     ld_pzero        //bsr so we can return and set inx
        bra     t_inx2          //now, set the inx for the next inst
ld_mzinx:
        bsr     ld_mzero        //if neg, load neg zero, return here
        bra     t_inx2          //now, set the inx for the next inst
//
// Load a signed zero to fp0; do not set inex2/ainex
//
        .global szero
szero:
        btstb   #sign_bit,LOCAL_EX(%a0) //get sign of source operand
        bne     ld_mzero        //if neg, load neg zero
        bra     ld_pzero        //load positive zero
//
// Load a signed infinity to fp0; do not set inex2/ainex
//
        .global sinf
sinf:
        btstb   #sign_bit,LOCAL_EX(%a0) //get sign of source operand
        bne     ld_minf                 //if negative branch
        bra     ld_pinf
//
// Load a signed one to fp0; do not set inex2/ainex
//
        .global sone
sone:
        btstb   #sign_bit,LOCAL_EX(%a0) //check sign of source
        bne     ld_mone
        bra     ld_pone
//
// Load a signed pi/2 to fp0; do not set inex2/ainex
//
        .global spi_2
spi_2:
        btstb   #sign_bit,LOCAL_EX(%a0) //check sign of source
        bne     ld_mpi2
        bra     ld_ppi2
//
// Load either a +0 or +inf for plus/minus operand
//
        .global szr_inf
szr_inf:
        btstb   #sign_bit,LOCAL_EX(%a0) //check sign of source
        bne     ld_pzero
        bra     ld_pinf
//
// Result is either an operr or +inf for plus/minus operand
// [Used by slogn, slognp1, slog10, and slog2]
//
        .global sopr_inf
sopr_inf:
        btstb   #sign_bit,LOCAL_EX(%a0) //check sign of source
        bne     t_operr
        bra     ld_pinf
//
//      FLOGNP1
//
        .global sslognp1
sslognp1:
        fmovemx (%a0),%fp0-%fp0
        fcmpb   #-1,%fp0
        fbgt    slognp1
        fbeq    t_dz2           //if = -1, divide by zero exception
        fmovel  #0,%FPSR                //clr N flag
        bra     t_operr         //take care of operands < -1
//
//      FETOXM1
//
        .global setoxm1i
setoxm1i:
        btstb   #sign_bit,LOCAL_EX(%a0) //check sign of source
        bne     ld_mone
        bra     ld_pinf
//
//      FLOGN
//
// Test for 1.0 as an input argument, returning +zero.  Also check
// the sign and return operr if negative.
//
        .global sslogn
sslogn:
        btstb   #sign_bit,LOCAL_EX(%a0)
        bne     t_operr         //take care of operands < 0
        cmpiw   #0x3fff,LOCAL_EX(%a0) //test for 1.0 input
        bne     slogn
        cmpil   #0x80000000,LOCAL_HI(%a0)
        bne     slogn
        tstl    LOCAL_LO(%a0)
        bne     slogn
        fmovex  PZERO,%fp0
        rts
 
        .global sslognd
sslognd:
        btstb   #sign_bit,LOCAL_EX(%a0)
        beq     slognd
        bra     t_operr         //take care of operands < 0
 
//
//      FLOG10
//
        .global sslog10
sslog10:
        btstb   #sign_bit,LOCAL_EX(%a0)
        bne     t_operr         //take care of operands < 0
        cmpiw   #0x3fff,LOCAL_EX(%a0) //test for 1.0 input
        bne     slog10
        cmpil   #0x80000000,LOCAL_HI(%a0)
        bne     slog10
        tstl    LOCAL_LO(%a0)
        bne     slog10
        fmovex  PZERO,%fp0
        rts
 
        .global sslog10d
sslog10d:
        btstb   #sign_bit,LOCAL_EX(%a0)
        beq     slog10d
        bra     t_operr         //take care of operands < 0
 
//
//      FLOG2
//
        .global sslog2
sslog2:
        btstb   #sign_bit,LOCAL_EX(%a0)
        bne     t_operr         //take care of operands < 0
        cmpiw   #0x3fff,LOCAL_EX(%a0) //test for 1.0 input
        bne     slog2
        cmpil   #0x80000000,LOCAL_HI(%a0)
        bne     slog2
        tstl    LOCAL_LO(%a0)
        bne     slog2
        fmovex  PZERO,%fp0
        rts
 
        .global sslog2d
sslog2d:
        btstb   #sign_bit,LOCAL_EX(%a0)
        beq     slog2d
        bra     t_operr         //take care of operands < 0
 
//
//      FMOD
//
pmodt:
//                              ;$21 fmod
//                              ;dtag,stag
        .long   smod            //  00,00  norm,norm = normal
        .long   smod_oper       //  00,01  norm,zero = nan with operr
        .long   smod_fpn        //  00,10  norm,inf  = fpn
        .long   smod_snan       //  00,11  norm,nan  = nan
        .long   smod_zro        //  01,00  zero,norm = +-zero
        .long   smod_oper       //  01,01  zero,zero = nan with operr
        .long   smod_zro        //  01,10  zero,inf  = +-zero
        .long   smod_snan       //  01,11  zero,nan  = nan
        .long   smod_oper       //  10,00  inf,norm  = nan with operr
        .long   smod_oper       //  10,01  inf,zero  = nan with operr
        .long   smod_oper       //  10,10  inf,inf   = nan with operr
        .long   smod_snan       //  10,11  inf,nan   = nan
        .long   smod_dnan       //  11,00  nan,norm  = nan
        .long   smod_dnan       //  11,01  nan,zero  = nan
        .long   smod_dnan       //  11,10  nan,inf   = nan
        .long   smod_dnan       //  11,11  nan,nan   = nan
 
        .global pmod
pmod:
        clrb    FPSR_QBYTE(%a6) // clear quotient field
        bfextu  STAG(%a6){#0:#3},%d0 //stag = d0
        bfextu  DTAG(%a6){#0:#3},%d1 //dtag = d1
 
//
// Alias extended denorms to norms for the jump table.
//
        bclrl   #2,%d0
        bclrl   #2,%d1
 
        lslb    #2,%d1
        orb     %d0,%d1         //d1{3:2} = dtag, d1{1:0} = stag
//                              ;Tag values:
//                              ;00 = norm or denorm
//                              ;01 = zero
//                              ;10 = inf
//                              ;11 = nan
        lea     pmodt,%a1
        movel   (%a1,%d1.w*4),%a1
        jmp     (%a1)
 
smod_snan:
        bra     src_nan
smod_dnan:
        bra     dst_nan
smod_oper:
        bra     t_operr
smod_zro:
        moveb   ETEMP(%a6),%d1  //get sign of src op
        moveb   FPTEMP(%a6),%d0 //get sign of dst op
        eorb    %d0,%d1         //get exor of sign bits
        btstl   #7,%d1          //test for sign
        beqs    smod_zsn        //if clr, do not set sign big
        bsetb   #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit
smod_zsn:
        btstl   #7,%d0          //test if + or -
        beq     ld_pzero        //if pos then load +0
        bra     ld_mzero        //else neg load -0
 
smod_fpn:
        moveb   ETEMP(%a6),%d1  //get sign of src op
        moveb   FPTEMP(%a6),%d0 //get sign of dst op
        eorb    %d0,%d1         //get exor of sign bits
        btstl   #7,%d1          //test for sign
        beqs    smod_fsn        //if clr, do not set sign big
        bsetb   #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit
smod_fsn:
        tstb    DTAG(%a6)       //filter out denormal destination case
        bpls    smod_nrm        //
        leal    FPTEMP(%a6),%a0 //a0<- addr(FPTEMP)
        bra     t_resdnrm       //force UNFL(but exact) result
smod_nrm:
        fmovel USER_FPCR(%a6),%fpcr //use user's rmode and precision
        fmovex FPTEMP(%a6),%fp0 //return dest to fp0
        rts
 
//
//      FREM
//
premt:
//                              ;$25 frem
//                              ;dtag,stag
        .long   srem            //  00,00  norm,norm = normal
        .long   srem_oper       //  00,01  norm,zero = nan with operr
        .long   srem_fpn        //  00,10  norm,inf  = fpn
        .long   srem_snan       //  00,11  norm,nan  = nan
        .long   srem_zro        //  01,00  zero,norm = +-zero
        .long   srem_oper       //  01,01  zero,zero = nan with operr
        .long   srem_zro        //  01,10  zero,inf  = +-zero
        .long   srem_snan       //  01,11  zero,nan  = nan
        .long   srem_oper       //  10,00  inf,norm  = nan with operr
        .long   srem_oper       //  10,01  inf,zero  = nan with operr
        .long   srem_oper       //  10,10  inf,inf   = nan with operr
        .long   srem_snan       //  10,11  inf,nan   = nan
        .long   srem_dnan       //  11,00  nan,norm  = nan
        .long   srem_dnan       //  11,01  nan,zero  = nan
        .long   srem_dnan       //  11,10  nan,inf   = nan
        .long   srem_dnan       //  11,11  nan,nan   = nan
 
        .global prem
prem:
        clrb    FPSR_QBYTE(%a6)   //clear quotient field
        bfextu  STAG(%a6){#0:#3},%d0 //stag = d0
        bfextu  DTAG(%a6){#0:#3},%d1 //dtag = d1
//
// Alias extended denorms to norms for the jump table.
//
        bclr    #2,%d0
        bclr    #2,%d1
 
        lslb    #2,%d1
        orb     %d0,%d1         //d1{3:2} = dtag, d1{1:0} = stag
//                              ;Tag values:
//                              ;00 = norm or denorm
//                              ;01 = zero
//                              ;10 = inf
//                              ;11 = nan
        lea     premt,%a1
        movel   (%a1,%d1.w*4),%a1
        jmp     (%a1)
 
srem_snan:
        bra     src_nan
srem_dnan:
        bra     dst_nan
srem_oper:
        bra     t_operr
srem_zro:
        moveb   ETEMP(%a6),%d1  //get sign of src op
        moveb   FPTEMP(%a6),%d0 //get sign of dst op
        eorb    %d0,%d1         //get exor of sign bits
        btstl   #7,%d1          //test for sign
        beqs    srem_zsn        //if clr, do not set sign big
        bsetb   #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit
srem_zsn:
        btstl   #7,%d0          //test if + or -
        beq     ld_pzero        //if pos then load +0
        bra     ld_mzero        //else neg load -0
 
srem_fpn:
        moveb   ETEMP(%a6),%d1  //get sign of src op
        moveb   FPTEMP(%a6),%d0 //get sign of dst op
        eorb    %d0,%d1         //get exor of sign bits
        btstl   #7,%d1          //test for sign
        beqs    srem_fsn        //if clr, do not set sign big
        bsetb   #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit
srem_fsn:
        tstb    DTAG(%a6)       //filter out denormal destination case
        bpls    srem_nrm        //
        leal    FPTEMP(%a6),%a0 //a0<- addr(FPTEMP)
        bra     t_resdnrm       //force UNFL(but exact) result
srem_nrm:
        fmovel USER_FPCR(%a6),%fpcr //use user's rmode and precision
        fmovex FPTEMP(%a6),%fp0 //return dest to fp0
        rts
//
//      FSCALE
//
pscalet:
//                              ;$26 fscale
//                              ;dtag,stag
        .long   sscale          //  00,00  norm,norm = result
        .long   sscale          //  00,01  norm,zero = fpn
        .long   scl_opr         //  00,10  norm,inf  = nan with operr
        .long   scl_snan        //  00,11  norm,nan  = nan
        .long   scl_zro         //  01,00  zero,norm = +-zero
        .long   scl_zro         //  01,01  zero,zero = +-zero
        .long   scl_opr         //  01,10  zero,inf  = nan with operr
        .long   scl_snan        //  01,11  zero,nan  = nan
        .long   scl_inf         //  10,00  inf,norm  = +-inf
        .long   scl_inf         //  10,01  inf,zero  = +-inf
        .long   scl_opr         //  10,10  inf,inf   = nan with operr
        .long   scl_snan        //  10,11  inf,nan   = nan
        .long   scl_dnan        //  11,00  nan,norm  = nan
        .long   scl_dnan        //  11,01  nan,zero  = nan
        .long   scl_dnan        //  11,10  nan,inf   = nan
        .long   scl_dnan        //  11,11  nan,nan   = nan
 
        .global pscale
pscale:
        bfextu  STAG(%a6){#0:#3},%d0 //stag in d0
        bfextu  DTAG(%a6){#0:#3},%d1 //dtag in d1
        bclrl   #2,%d0          //alias  denorm into norm
        bclrl   #2,%d1          //alias  denorm into norm
        lslb    #2,%d1
        orb     %d0,%d1         //d1{4:2} = dtag, d1{1:0} = stag
//                              ;dtag values     stag values:
//                              ;000 = norm      00 = norm
//                              ;001 = zero      01 = zero
//                              ;010 = inf       10 = inf
//                              ;011 = nan       11 = nan
//                              ;100 = dnrm
//
//
        leal    pscalet,%a1     //load start of jump table
        movel   (%a1,%d1.w*4),%a1       //load a1 with label depending on tag
        jmp     (%a1)           //go to the routine
 
scl_opr:
        bra     t_operr
 
scl_dnan:
        bra     dst_nan
 
scl_zro:
        btstb   #sign_bit,FPTEMP_EX(%a6)        //test if + or -
        beq     ld_pzero                //if pos then load +0
        bra     ld_mzero                //if neg then load -0
scl_inf:
        btstb   #sign_bit,FPTEMP_EX(%a6)        //test if + or -
        beq     ld_pinf                 //if pos then load +inf
        bra     ld_minf                 //else neg load -inf
scl_snan:
        bra     src_nan
//
//      FSINCOS
//
        .global ssincosz
ssincosz:
        btstb   #sign_bit,ETEMP(%a6)    //get sign
        beqs    sincosp
        fmovex  MZERO,%fp0
        bras    sincoscom
sincosp:
        fmovex PZERO,%fp0
sincoscom:
        fmovemx PONE,%fp1-%fp1  //do not allow FPSR to be affected
        bra     sto_cos         //store cosine result
 
        .global ssincosi
ssincosi:
        fmovex QNAN,%fp1        //load NAN
        bsr     sto_cos         //store cosine result
        fmovex QNAN,%fp0        //load NAN
        bra     t_operr
 
        .global ssincosnan
ssincosnan:
        movel   ETEMP_EX(%a6),FP_SCR1(%a6)
        movel   ETEMP_HI(%a6),FP_SCR1+4(%a6)
        movel   ETEMP_LO(%a6),FP_SCR1+8(%a6)
        bsetb   #signan_bit,FP_SCR1+4(%a6)
        fmovemx FP_SCR1(%a6),%fp1-%fp1
        bsr     sto_cos
        bra     src_nan
//
// This code forces default values for the zero, inf, and nan cases
// in the transcendentals code.  The CC bits must be set in the
// stacked FPSR to be correctly reported.
//
//**Returns +PI/2
        .global ld_ppi2
ld_ppi2:
        fmovex PPIBY2,%fp0              //load +pi/2
        bra     t_inx2                  //set inex2 exc
 
//**Returns -PI/2
        .global ld_mpi2
ld_mpi2:
        fmovex MPIBY2,%fp0              //load -pi/2
        orl     #neg_mask,USER_FPSR(%a6)        //set N bit
        bra     t_inx2                  //set inex2 exc
 
//**Returns +inf
        .global ld_pinf
ld_pinf:
        fmovex PINF,%fp0                //load +inf
        orl     #inf_mask,USER_FPSR(%a6)        //set I bit
        rts
 
//**Returns -inf
        .global ld_minf
ld_minf:
        fmovex MINF,%fp0                //load -inf
        orl     #neg_mask+inf_mask,USER_FPSR(%a6)       //set N and I bits
        rts
 
//**Returns +1
        .global ld_pone
ld_pone:
        fmovex PONE,%fp0                //load +1
        rts
 
//**Returns -1
        .global ld_mone
ld_mone:
        fmovex MONE,%fp0                //load -1
        orl     #neg_mask,USER_FPSR(%a6)        //set N bit
        rts
 
//**Returns +0
        .global ld_pzero
ld_pzero:
        fmovex PZERO,%fp0               //load +0
        orl     #z_mask,USER_FPSR(%a6)  //set Z bit
        rts
 
//**Returns -0
        .global ld_mzero
ld_mzero:
        fmovex MZERO,%fp0               //load -0
        orl     #neg_mask+z_mask,USER_FPSR(%a6) //set N and Z bits
        rts
 
        |end

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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libcpu/] [m68k/] [m68040/] [fpsp/] [do_func.S] - Blame information for rev 173

Line No.	Rev	Author	Line
1	30	unneback	`//`
2			`// $Id: do_func.S,v 1.2 2001-09-27 12:01:22 chris Exp $`
3			`//`
4			`// do_func.sa 3.4 2/18/91`
5			`//`
6			`// Do_func performs the unimplemented operation. The operation`
7			`// to be performed is determined from the lower 7 bits of the`
8			`// extension word (except in the case of fmovecr and fsincos).`
9			`// The opcode and tag bits form an index into a jump table in`
10			`// tbldo.sa. Cases of zero, infinity and NaN are handled in`
11			`// do_func by forcing the default result. Normalized and`
12			`// denormalized (there are no unnormalized numbers at this`
13			`// point) are passed onto the emulation code.`
14			`//`
15			`// CMDREG1B and STAG are extracted from the fsave frame`
16			`// and combined to form the table index. The function called`
17			`// will start with a0 pointing to the ETEMP operand. Dyadic`
18			`// functions can find FPTEMP at -12(a0).`
19			`//`
20			`// Called functions return their result in fp0. Sincos returns`
21			`// sin(x) in fp0 and cos(x) in fp1.`
22			`//`
23
24			`// Copyright (C) Motorola, Inc. 1990`
25			`// All Rights Reserved`
26			`//`
27			`// THIS IS UNPUBLISHED PROPRIETARY SOURCE CODE OF MOTOROLA`
28			`// The copyright notice above does not evidence any`
29			`// actual or intended publication of such source code.`
30
31			`DO_FUNC: //idnt 2,1 \| Motorola 040 Floating Point Software Package`
32
33			`\|section 8`
34
35			`#include "fpsp.defs"`
36
37			`\|xref t_dz2`
38			`\|xref t_operr`
39			`\|xref t_inx2`
40			`\|xref t_resdnrm`
41			`\|xref dst_nan`
42			`\|xref src_nan`
43			`\|xref nrm_set`
44			`\|xref sto_cos`
45
46			`\|xref tblpre`
47			`\|xref slognp1,slogn,slog10,slog2`
48			`\|xref slognd,slog10d,slog2d`
49			`\|xref smod,srem`
50			`\|xref sscale`
51			`\|xref smovcr`
52
53			`PONE: .long 0x3fff0000,0x80000000,0x00000000 //+1`
54			`MONE: .long 0xbfff0000,0x80000000,0x00000000 //-1`
55			`PZERO: .long 0x00000000,0x00000000,0x00000000 //+0`
56			`MZERO: .long 0x80000000,0x00000000,0x00000000 //-0`
57			`PINF: .long 0x7fff0000,0x00000000,0x00000000 //+inf`
58			`MINF: .long 0xffff0000,0x00000000,0x00000000 //-inf`
59			`QNAN: .long 0x7fff0000,0xffffffff,0xffffffff //non-signaling nan`
60			`PPIBY2: .long 0x3FFF0000,0xC90FDAA2,0x2168C235 //+PI/2`
61			`MPIBY2: .long 0xbFFF0000,0xC90FDAA2,0x2168C235 //-PI/2`
62
63			`.global do_func`
64			`do_func:`
65			`clrb CU_ONLY(%a6)`
66			`//`
67			`// Check for fmovecr. It does not follow the format of fp gen`
68			`// unimplemented instructions. The test is on the upper 6 bits;`
69			`// if they are $17, the inst is fmovecr. Call entry smovcr`
70			`// directly.`
71			`//`
72			`bfextu CMDREG1B(%a6){#0:#6},%d0 //get opclass and src fields`
73			`cmpil #0x17,%d0 //if op class and size fields are $17,`
74			`// ;it is FMOVECR; if not, continue`
75			`bnes not_fmovecr`
76			`jmp smovcr //fmovecr; jmp directly to emulation`
77
78			`not_fmovecr:`
79			`movew CMDREG1B(%a6),%d0`
80			`andl #0x7F,%d0`
81			`cmpil #0x38,%d0 //if the extension is >= $38,`
82			`bge serror //it is illegal`
83			`bfextu STAG(%a6){#0:#3},%d1`
84			`lsll #3,%d0 //make room for STAG`
85			`addl %d1,%d0 //combine for final index into table`
86			`leal tblpre,%a1 //start of monster jump table`
87			`movel (%a1,%d0.w*4),%a1 //real target address`
88			`leal ETEMP(%a6),%a0 //a0 is pointer to src op`
89			`movel USER_FPCR(%a6),%d1`
90			`andl #0xFF,%d1 // discard all but rounding mode/prec`
91			`fmovel #0,%fpcr`
92			`jmp (%a1)`
93			`//`
94			`// ERROR`
95			`//`
96			`.global serror`
97			`serror:`
98			`st STORE_FLG(%a6)`
99			`rts`
100			`//`
101			`// These routines load forced values into fp0. They are called`
102			`// by index into tbldo.`
103			`//`
104			`// Load a signed zero to fp0 and set inex2/ainex`
105			`//`
106			`.global snzrinx`
107			`snzrinx:`
108			`btstb #sign_bit,LOCAL_EX(%a0) //get sign of source operand`
109			`bnes ld_mzinx //if negative, branch`
110			`bsr ld_pzero //bsr so we can return and set inx`
111			`bra t_inx2 //now, set the inx for the next inst`
112			`ld_mzinx:`
113			`bsr ld_mzero //if neg, load neg zero, return here`
114			`bra t_inx2 //now, set the inx for the next inst`
115			`//`
116			`// Load a signed zero to fp0; do not set inex2/ainex`
117			`//`
118			`.global szero`
119			`szero:`
120			`btstb #sign_bit,LOCAL_EX(%a0) //get sign of source operand`
121			`bne ld_mzero //if neg, load neg zero`
122			`bra ld_pzero //load positive zero`
123			`//`
124			`// Load a signed infinity to fp0; do not set inex2/ainex`
125			`//`
126			`.global sinf`
127			`sinf:`
128			`btstb #sign_bit,LOCAL_EX(%a0) //get sign of source operand`
129			`bne ld_minf //if negative branch`
130			`bra ld_pinf`
131			`//`
132			`// Load a signed one to fp0; do not set inex2/ainex`
133			`//`
134			`.global sone`
135			`sone:`
136			`btstb #sign_bit,LOCAL_EX(%a0) //check sign of source`
137			`bne ld_mone`
138			`bra ld_pone`
139			`//`
140			`// Load a signed pi/2 to fp0; do not set inex2/ainex`
141			`//`
142			`.global spi_2`
143			`spi_2:`
144			`btstb #sign_bit,LOCAL_EX(%a0) //check sign of source`
145			`bne ld_mpi2`
146			`bra ld_ppi2`
147			`//`
148			`// Load either a +0 or +inf for plus/minus operand`
149			`//`
150			`.global szr_inf`
151			`szr_inf:`
152			`btstb #sign_bit,LOCAL_EX(%a0) //check sign of source`
153			`bne ld_pzero`
154			`bra ld_pinf`
155			`//`
156			`// Result is either an operr or +inf for plus/minus operand`
157			`// [Used by slogn, slognp1, slog10, and slog2]`
158			`//`
159			`.global sopr_inf`
160			`sopr_inf:`
161			`btstb #sign_bit,LOCAL_EX(%a0) //check sign of source`
162			`bne t_operr`
163			`bra ld_pinf`
164			`//`
165			`// FLOGNP1`
166			`//`
167			`.global sslognp1`
168			`sslognp1:`
169			`fmovemx (%a0),%fp0-%fp0`
170			`fcmpb #-1,%fp0`
171			`fbgt slognp1`
172			`fbeq t_dz2 //if = -1, divide by zero exception`
173			`fmovel #0,%FPSR //clr N flag`
174			`bra t_operr //take care of operands < -1`
175			`//`
176			`// FETOXM1`
177			`//`
178			`.global setoxm1i`
179			`setoxm1i:`
180			`btstb #sign_bit,LOCAL_EX(%a0) //check sign of source`
181			`bne ld_mone`
182			`bra ld_pinf`
183			`//`
184			`// FLOGN`
185			`//`
186			`// Test for 1.0 as an input argument, returning +zero. Also check`
187			`// the sign and return operr if negative.`
188			`//`
189			`.global sslogn`
190			`sslogn:`
191			`btstb #sign_bit,LOCAL_EX(%a0)`
192			`bne t_operr //take care of operands < 0`
193			`cmpiw #0x3fff,LOCAL_EX(%a0) //test for 1.0 input`
194			`bne slogn`
195			`cmpil #0x80000000,LOCAL_HI(%a0)`
196			`bne slogn`
197			`tstl LOCAL_LO(%a0)`
198			`bne slogn`
199			`fmovex PZERO,%fp0`
200			`rts`
201
202			`.global sslognd`
203			`sslognd:`
204			`btstb #sign_bit,LOCAL_EX(%a0)`
205			`beq slognd`
206			`bra t_operr //take care of operands < 0`
207
208			`//`
209			`// FLOG10`
210			`//`
211			`.global sslog10`
212			`sslog10:`
213			`btstb #sign_bit,LOCAL_EX(%a0)`
214			`bne t_operr //take care of operands < 0`
215			`cmpiw #0x3fff,LOCAL_EX(%a0) //test for 1.0 input`
216			`bne slog10`
217			`cmpil #0x80000000,LOCAL_HI(%a0)`
218			`bne slog10`
219			`tstl LOCAL_LO(%a0)`
220			`bne slog10`
221			`fmovex PZERO,%fp0`
222			`rts`
223
224			`.global sslog10d`
225			`sslog10d:`
226			`btstb #sign_bit,LOCAL_EX(%a0)`
227			`beq slog10d`
228			`bra t_operr //take care of operands < 0`
229
230			`//`
231			`// FLOG2`
232			`//`
233			`.global sslog2`
234			`sslog2:`
235			`btstb #sign_bit,LOCAL_EX(%a0)`
236			`bne t_operr //take care of operands < 0`
237			`cmpiw #0x3fff,LOCAL_EX(%a0) //test for 1.0 input`
238			`bne slog2`
239			`cmpil #0x80000000,LOCAL_HI(%a0)`
240			`bne slog2`
241			`tstl LOCAL_LO(%a0)`
242			`bne slog2`
243			`fmovex PZERO,%fp0`
244			`rts`
245
246			`.global sslog2d`
247			`sslog2d:`
248			`btstb #sign_bit,LOCAL_EX(%a0)`
249			`beq slog2d`
250			`bra t_operr //take care of operands < 0`
251
252			`//`
253			`// FMOD`
254			`//`
255			`pmodt:`
256			`// ;$21 fmod`
257			`// ;dtag,stag`
258			`.long smod // 00,00 norm,norm = normal`
259			`.long smod_oper // 00,01 norm,zero = nan with operr`
260			`.long smod_fpn // 00,10 norm,inf = fpn`
261			`.long smod_snan // 00,11 norm,nan = nan`
262			`.long smod_zro // 01,00 zero,norm = +-zero`
263			`.long smod_oper // 01,01 zero,zero = nan with operr`
264			`.long smod_zro // 01,10 zero,inf = +-zero`
265			`.long smod_snan // 01,11 zero,nan = nan`
266			`.long smod_oper // 10,00 inf,norm = nan with operr`
267			`.long smod_oper // 10,01 inf,zero = nan with operr`
268			`.long smod_oper // 10,10 inf,inf = nan with operr`
269			`.long smod_snan // 10,11 inf,nan = nan`
270			`.long smod_dnan // 11,00 nan,norm = nan`
271			`.long smod_dnan // 11,01 nan,zero = nan`
272			`.long smod_dnan // 11,10 nan,inf = nan`
273			`.long smod_dnan // 11,11 nan,nan = nan`
274
275			`.global pmod`
276			`pmod:`
277			`clrb FPSR_QBYTE(%a6) // clear quotient field`
278			`bfextu STAG(%a6){#0:#3},%d0 //stag = d0`
279			`bfextu DTAG(%a6){#0:#3},%d1 //dtag = d1`
280
281			`//`
282			`// Alias extended denorms to norms for the jump table.`
283			`//`
284			`bclrl #2,%d0`
285			`bclrl #2,%d1`
286
287			`lslb #2,%d1`
288			`orb %d0,%d1 //d1{3:2} = dtag, d1{1:0} = stag`
289			`// ;Tag values:`
290			`// ;00 = norm or denorm`
291			`// ;01 = zero`
292			`// ;10 = inf`
293			`// ;11 = nan`
294			`lea pmodt,%a1`
295			`movel (%a1,%d1.w*4),%a1`
296			`jmp (%a1)`
297
298			`smod_snan:`
299			`bra src_nan`
300			`smod_dnan:`
301			`bra dst_nan`
302			`smod_oper:`
303			`bra t_operr`
304			`smod_zro:`
305			`moveb ETEMP(%a6),%d1 //get sign of src op`
306			`moveb FPTEMP(%a6),%d0 //get sign of dst op`
307			`eorb %d0,%d1 //get exor of sign bits`
308			`btstl #7,%d1 //test for sign`
309			`beqs smod_zsn //if clr, do not set sign big`
310			`bsetb #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit`
311			`smod_zsn:`
312			`btstl #7,%d0 //test if + or -`
313			`beq ld_pzero //if pos then load +0`
314			`bra ld_mzero //else neg load -0`
315
316			`smod_fpn:`
317			`moveb ETEMP(%a6),%d1 //get sign of src op`
318			`moveb FPTEMP(%a6),%d0 //get sign of dst op`
319			`eorb %d0,%d1 //get exor of sign bits`
320			`btstl #7,%d1 //test for sign`
321			`beqs smod_fsn //if clr, do not set sign big`
322			`bsetb #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit`
323			`smod_fsn:`
324			`tstb DTAG(%a6) //filter out denormal destination case`
325			`bpls smod_nrm //`
326			`leal FPTEMP(%a6),%a0 //a0<- addr(FPTEMP)`
327			`bra t_resdnrm //force UNFL(but exact) result`
328			`smod_nrm:`
329			`fmovel USER_FPCR(%a6),%fpcr //use user's rmode and precision`
330			`fmovex FPTEMP(%a6),%fp0 //return dest to fp0`
331			`rts`
332
333			`//`
334			`// FREM`
335			`//`
336			`premt:`
337			`// ;$25 frem`
338			`// ;dtag,stag`
339			`.long srem // 00,00 norm,norm = normal`
340			`.long srem_oper // 00,01 norm,zero = nan with operr`
341			`.long srem_fpn // 00,10 norm,inf = fpn`
342			`.long srem_snan // 00,11 norm,nan = nan`
343			`.long srem_zro // 01,00 zero,norm = +-zero`
344			`.long srem_oper // 01,01 zero,zero = nan with operr`
345			`.long srem_zro // 01,10 zero,inf = +-zero`
346			`.long srem_snan // 01,11 zero,nan = nan`
347			`.long srem_oper // 10,00 inf,norm = nan with operr`
348			`.long srem_oper // 10,01 inf,zero = nan with operr`
349			`.long srem_oper // 10,10 inf,inf = nan with operr`
350			`.long srem_snan // 10,11 inf,nan = nan`
351			`.long srem_dnan // 11,00 nan,norm = nan`
352			`.long srem_dnan // 11,01 nan,zero = nan`
353			`.long srem_dnan // 11,10 nan,inf = nan`
354			`.long srem_dnan // 11,11 nan,nan = nan`
355
356			`.global prem`
357			`prem:`
358			`clrb FPSR_QBYTE(%a6) //clear quotient field`
359			`bfextu STAG(%a6){#0:#3},%d0 //stag = d0`
360			`bfextu DTAG(%a6){#0:#3},%d1 //dtag = d1`
361			`//`
362			`// Alias extended denorms to norms for the jump table.`
363			`//`
364			`bclr #2,%d0`
365			`bclr #2,%d1`
366
367			`lslb #2,%d1`
368			`orb %d0,%d1 //d1{3:2} = dtag, d1{1:0} = stag`
369			`// ;Tag values:`
370			`// ;00 = norm or denorm`
371			`// ;01 = zero`
372			`// ;10 = inf`
373			`// ;11 = nan`
374			`lea premt,%a1`
375			`movel (%a1,%d1.w*4),%a1`
376			`jmp (%a1)`
377
378			`srem_snan:`
379			`bra src_nan`
380			`srem_dnan:`
381			`bra dst_nan`
382			`srem_oper:`
383			`bra t_operr`
384			`srem_zro:`
385			`moveb ETEMP(%a6),%d1 //get sign of src op`
386			`moveb FPTEMP(%a6),%d0 //get sign of dst op`
387			`eorb %d0,%d1 //get exor of sign bits`
388			`btstl #7,%d1 //test for sign`
389			`beqs srem_zsn //if clr, do not set sign big`
390			`bsetb #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit`
391			`srem_zsn:`
392			`btstl #7,%d0 //test if + or -`
393			`beq ld_pzero //if pos then load +0`
394			`bra ld_mzero //else neg load -0`
395
396			`srem_fpn:`
397			`moveb ETEMP(%a6),%d1 //get sign of src op`
398			`moveb FPTEMP(%a6),%d0 //get sign of dst op`
399			`eorb %d0,%d1 //get exor of sign bits`
400			`btstl #7,%d1 //test for sign`
401			`beqs srem_fsn //if clr, do not set sign big`
402			`bsetb #q_sn_bit,FPSR_QBYTE(%a6) //set q-byte sign bit`
403			`srem_fsn:`
404			`tstb DTAG(%a6) //filter out denormal destination case`
405			`bpls srem_nrm //`
406			`leal FPTEMP(%a6),%a0 //a0<- addr(FPTEMP)`
407			`bra t_resdnrm //force UNFL(but exact) result`
408			`srem_nrm:`
409			`fmovel USER_FPCR(%a6),%fpcr //use user's rmode and precision`
410			`fmovex FPTEMP(%a6),%fp0 //return dest to fp0`
411			`rts`
412			`//`
413			`// FSCALE`
414			`//`
415			`pscalet:`
416			`// ;$26 fscale`
417			`// ;dtag,stag`
418			`.long sscale // 00,00 norm,norm = result`
419			`.long sscale // 00,01 norm,zero = fpn`
420			`.long scl_opr // 00,10 norm,inf = nan with operr`
421			`.long scl_snan // 00,11 norm,nan = nan`
422			`.long scl_zro // 01,00 zero,norm = +-zero`
423			`.long scl_zro // 01,01 zero,zero = +-zero`
424			`.long scl_opr // 01,10 zero,inf = nan with operr`
425			`.long scl_snan // 01,11 zero,nan = nan`
426			`.long scl_inf // 10,00 inf,norm = +-inf`
427			`.long scl_inf // 10,01 inf,zero = +-inf`
428			`.long scl_opr // 10,10 inf,inf = nan with operr`
429			`.long scl_snan // 10,11 inf,nan = nan`
430			`.long scl_dnan // 11,00 nan,norm = nan`
431			`.long scl_dnan // 11,01 nan,zero = nan`
432			`.long scl_dnan // 11,10 nan,inf = nan`
433			`.long scl_dnan // 11,11 nan,nan = nan`
434
435			`.global pscale`
436			`pscale:`
437			`bfextu STAG(%a6){#0:#3},%d0 //stag in d0`
438			`bfextu DTAG(%a6){#0:#3},%d1 //dtag in d1`
439			`bclrl #2,%d0 //alias denorm into norm`
440			`bclrl #2,%d1 //alias denorm into norm`
441			`lslb #2,%d1`
442			`orb %d0,%d1 //d1{4:2} = dtag, d1{1:0} = stag`
443			`// ;dtag values stag values:`
444			`// ;000 = norm 00 = norm`
445			`// ;001 = zero 01 = zero`
446			`// ;010 = inf 10 = inf`
447			`// ;011 = nan 11 = nan`
448			`// ;100 = dnrm`
449			`//`
450			`//`
451			`leal pscalet,%a1 //load start of jump table`
452			`movel (%a1,%d1.w*4),%a1 //load a1 with label depending on tag`
453			`jmp (%a1) //go to the routine`
454
455			`scl_opr:`
456			`bra t_operr`
457
458			`scl_dnan:`
459			`bra dst_nan`
460
461			`scl_zro:`
462			`btstb #sign_bit,FPTEMP_EX(%a6) //test if + or -`
463			`beq ld_pzero //if pos then load +0`
464			`bra ld_mzero //if neg then load -0`
465			`scl_inf:`
466			`btstb #sign_bit,FPTEMP_EX(%a6) //test if + or -`
467			`beq ld_pinf //if pos then load +inf`
468			`bra ld_minf //else neg load -inf`
469			`scl_snan:`
470			`bra src_nan`
471			`//`
472			`// FSINCOS`
473			`//`
474			`.global ssincosz`
475			`ssincosz:`
476			`btstb #sign_bit,ETEMP(%a6) //get sign`
477			`beqs sincosp`
478			`fmovex MZERO,%fp0`
479			`bras sincoscom`
480			`sincosp:`
481			`fmovex PZERO,%fp0`
482			`sincoscom:`
483			`fmovemx PONE,%fp1-%fp1 //do not allow FPSR to be affected`
484			`bra sto_cos //store cosine result`
485
486			`.global ssincosi`
487			`ssincosi:`
488			`fmovex QNAN,%fp1 //load NAN`
489			`bsr sto_cos //store cosine result`
490			`fmovex QNAN,%fp0 //load NAN`
491			`bra t_operr`
492
493			`.global ssincosnan`
494			`ssincosnan:`
495			`movel ETEMP_EX(%a6),FP_SCR1(%a6)`
496			`movel ETEMP_HI(%a6),FP_SCR1+4(%a6)`
497			`movel ETEMP_LO(%a6),FP_SCR1+8(%a6)`
498			`bsetb #signan_bit,FP_SCR1+4(%a6)`
499			`fmovemx FP_SCR1(%a6),%fp1-%fp1`
500			`bsr sto_cos`
501			`bra src_nan`
502			`//`
503			`// This code forces default values for the zero, inf, and nan cases`
504			`// in the transcendentals code. The CC bits must be set in the`
505			`// stacked FPSR to be correctly reported.`
506			`//`
507			`//**Returns +PI/2`
508			`.global ld_ppi2`
509			`ld_ppi2:`
510			`fmovex PPIBY2,%fp0 //load +pi/2`
511			`bra t_inx2 //set inex2 exc`
512
513			`//**Returns -PI/2`
514			`.global ld_mpi2`
515			`ld_mpi2:`
516			`fmovex MPIBY2,%fp0 //load -pi/2`
517			`orl #neg_mask,USER_FPSR(%a6) //set N bit`
518			`bra t_inx2 //set inex2 exc`
519
520			`//**Returns +inf`
521			`.global ld_pinf`
522			`ld_pinf:`
523			`fmovex PINF,%fp0 //load +inf`
524			`orl #inf_mask,USER_FPSR(%a6) //set I bit`
525			`rts`
526
527			`//**Returns -inf`
528			`.global ld_minf`
529			`ld_minf:`
530			`fmovex MINF,%fp0 //load -inf`
531			`orl #neg_mask+inf_mask,USER_FPSR(%a6) //set N and I bits`
532			`rts`
533
534			`//**Returns +1`
535			`.global ld_pone`
536			`ld_pone:`
537			`fmovex PONE,%fp0 //load +1`
538			`rts`
539
540			`//**Returns -1`
541			`.global ld_mone`
542			`ld_mone:`
543			`fmovex MONE,%fp0 //load -1`
544			`orl #neg_mask,USER_FPSR(%a6) //set N bit`
545			`rts`
546
547			`//**Returns +0`
548			`.global ld_pzero`
549			`ld_pzero:`
550			`fmovex PZERO,%fp0 //load +0`
551			`orl #z_mask,USER_FPSR(%a6) //set Z bit`
552			`rts`
553
554			`//**Returns -0`
555			`.global ld_mzero`
556			`ld_mzero:`
557			`fmovex MZERO,%fp0 //load -0`
558			`orl #neg_mask+z_mask,USER_FPSR(%a6) //set N and Z bits`
559			`rts`
560
561			`\|end`