/* hp2100_cpu7.c: HP 1000 VIS and SIGNAL/1000 microcode | |
Copyright (c) 2008, Holger Veit | |
Copyright (c) 2006-2008, J. David Bryan | |
Permission is hereby granted, free of charge, to any person obtaining a | |
copy of this software and associated documentation files (the "Software"), | |
to deal in the Software without restriction, including without limitation | |
the rights to use, copy, modify, merge, publish, distribute, sublicense, | |
and/or sell copies of the Software, and to permit persons to whom the | |
Software is furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL | |
THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER | |
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN | |
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of the authors shall not be | |
used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from the authors. | |
CPU7 Vector Instruction Set and SIGNAL firmware | |
11-Sep-08 JDB Moved microcode function prototypes to hp2100_cpu1.h | |
05-Sep-08 JDB Removed option-present tests (now in UIG dispatchers) | |
30-Apr-08 JDB Updated SIGNAL code from Holger | |
24-Apr-08 HV Implemented SIGNAL | |
20-Apr-08 JDB Updated comments | |
26-Feb-08 HV Implemented VIS | |
Primary references: | |
- HP 1000 M/E/F-Series Computers Technical Reference Handbook | |
(5955-0282, Mar-1980) | |
- HP 1000 M/E/F-Series Computers Engineering and Reference Documentation | |
(92851-90001, Mar-1981) | |
- Macro/1000 Reference Manual (92059-90001, Dec-1992) | |
Additional references are listed with the associated firmware | |
implementations, as are the HP option model numbers pertaining to the | |
applicable CPUs. | |
*/ | |
#include "hp2100_defs.h" | |
#include "hp2100_cpu.h" | |
#include "hp2100_cpu1.h" | |
#if defined (HAVE_INT64) /* int64 support available */ | |
#include "hp2100_fp1.h" | |
static const OP zero = { { 0, 0, 0, 0, 0 } }; /* DEC 0.0D0 */ | |
/* Vector Instruction Set | |
The VIS provides instructions that operate on one-dimensional arrays of | |
floating-point values. Both single- and double-precision operations are | |
supported. VIS uses the F-Series floating-point processor to handle the | |
floating-point math. | |
Option implementation by CPU was as follows: | |
2114 2115 2116 2100 1000-M 1000-E 1000-F | |
------ ------ ------ ------ ------ ------ ------ | |
N/A N/A N/A N/A N/A N/A 12824A | |
The routines are mapped to instruction codes as follows: | |
Single-Precision Double-Precision | |
Instr. Opcode Subcod Instr. Opcode Subcod Description | |
------ ------ ------ ------ ------ ------ ----------------------------- | |
VADD 101460 000000 DVADD 105460 004002 Vector add | |
VSUB 101460 000020 DVSUB 105460 004022 Vector subtract | |
VMPY 101460 000040 DVMPY 105460 004042 Vector multiply | |
VDIV 101460 000060 DVDIV 105460 004062 Vector divide | |
VSAD 101460 000400 DVSAD 105460 004402 Scalar-vector add | |
VSSB 101460 000420 DVSSB 105460 004422 Scalar-vector subtract | |
VSMY 101460 000440 DVSMY 105460 004442 Scalar-vector multiply | |
VSDV 101460 000460 DVSDV 105460 004462 Scalar-vector divide | |
VPIV 101461 0xxxxx DVPIV 105461 0xxxxx Vector pivot | |
VABS 101462 0xxxxx DVABS 105462 0xxxxx Vector absolute value | |
VSUM 101463 0xxxxx DVSUM 105463 0xxxxx Vector sum | |
VNRM 101464 0xxxxx DVNRM 105464 0xxxxx Vector norm | |
VDOT 101465 0xxxxx DVDOT 105465 0xxxxx Vector dot product | |
VMAX 101466 0xxxxx DVMAX 105466 0xxxxx Vector maximum value | |
VMAB 101467 0xxxxx DVMAB 105467 0xxxxx Vector maximum absolute value | |
VMIN 101470 0xxxxx DVMIN 105470 0xxxxx Vector minimum value | |
VMIB 101471 0xxxxx DVMIB 105471 0xxxxx Vector minimum absolute value | |
VMOV 101472 0xxxxx DVMOV 105472 0xxxxx Vector move | |
VSWP 101473 0xxxxx DVSWP 105473 0xxxxx Vector swap | |
.ERES 101474 -- -- -- -- Resolve array element address | |
.ESEG 101475 -- -- -- -- Load MSEG maps | |
.VSET 101476 -- -- -- -- Vector setup | |
[test] -- -- -- 105477 -- [self test] | |
Instructions use IR bit 11 to select single- or double-precision format. The | |
double-precision instruction names begin with "D" (e.g., DVADD vs. VADD). | |
Most VIS instructions are two words in length, with a sub-opcode immediately | |
following the primary opcode. | |
Notes: | |
1. The .VECT (101460) and .DVCT (105460) opcodes preface a single- or | |
double-precision arithmetic operation that is determined by the | |
sub-opcode value. The remainder of the dual-precision sub-opcode values | |
are "don't care," except for requiring a zero in bit 15. | |
2. The VIS uses the hardware FPP of the F-Series. FPP malfunctions are | |
detected by the VIS firmware and are indicated by a memory-protect | |
violation and setting the overflow flag. Under simulation, | |
malfunctions cannot occur. | |
Additional references: | |
- 12824A Vector Instruction Set User's Manual (12824-90001, Jun-1979). | |
- VIS Microcode Source (12824-18059, revision 3). | |
*/ | |
/* implemented in hp2100_cpu5.c (RTE-IV EMA functions) */ | |
extern t_stat cpu_ema_eres(uint32* rtn,uint32 dtbl,uint32 atbl, t_bool debug); | |
extern t_stat cpu_ema_eseg(uint32* rtn,uint32 ir,uint32 tbl, t_bool debug); | |
extern t_stat cpu_ema_vset(uint32* rtn,OPS op, t_bool debug); | |
static const OP_PAT op_vis[16] = { | |
OP_N, OP_AAKAKAKK,OP_AKAKK, OP_AAKK, /* .VECT VPIV VABS VSUM */ | |
OP_AAKK, OP_AAKAKK, OP_AAKK, OP_AAKK, /* VNRM VDOT VMAX VMAB */ | |
OP_AAKK, OP_AAKK, OP_AKAKK, OP_AKAKK, /* VMIN VMIB VMOV VSWP */ | |
OP_AA, OP_A, OP_AAACCC,OP_N /* .ERES .ESEG .VSET [test] */ | |
}; | |
static const t_bool op_ftnret[16] = { | |
FALSE, TRUE, TRUE, TRUE, | |
TRUE, TRUE, TRUE, TRUE, | |
TRUE, TRUE, TRUE, TRUE, | |
FALSE, TRUE, TRUE, FALSE, | |
}; | |
/* handle the scalar/vector base ops */ | |
static void vis_svop(uint32 subcode, OPS op, OPSIZE opsize) | |
{ | |
OP v1,v2; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
OP s = ReadOp(op[0].word,opsize); | |
uint32 v1addr = op[1].word; | |
int16 ix1 = INT16(op[2].word) * delta; | |
uint32 v2addr = op[3].word; | |
int16 ix2 = INT16(op[4].word) * delta; | |
int16 i, n = INT16(op[5].word); | |
uint32 fpuop = (subcode & 060) | (opsize==fp_f ? 0 : 2); | |
if (n <= 0) return; | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
(void)fp_exec(fpuop, &v2, s ,v1); | |
WriteOp(v2addr, v2, opsize); | |
v1addr += ix1; | |
v2addr += ix2; | |
} | |
} | |
/* handle the vector/vector base ops */ | |
static void vis_vvop(uint32 subcode, OPS op,OPSIZE opsize) | |
{ | |
OP v1,v2,v3; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 v1addr = op[0].word; | |
int32 ix1 = INT16(op[1].word) * delta; | |
uint32 v2addr = op[2].word; | |
int32 ix2 = INT16(op[3].word) * delta; | |
uint32 v3addr = op[4].word; | |
int32 ix3 = INT16(op[5].word) * delta; | |
int16 i, n = INT16(op[6].word); | |
uint32 fpuop = (subcode & 060) | (opsize==fp_f ? 0 : 2); | |
if (n <= 0) return; | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
v2 = ReadOp(v2addr, opsize); | |
(void)fp_exec(fpuop, &v3, v1 ,v2); | |
WriteOp(v3addr, v3, opsize); | |
v1addr += ix1; | |
v2addr += ix2; | |
v3addr += ix3; | |
} | |
} | |
#define GET_MSIGN(op) ((op)->fpk[0] & 0100000) | |
static void vis_abs(OP* in, uint32 opsize) | |
{ | |
uint32 sign = GET_MSIGN(in); /* get sign */ | |
if (sign) (void)fp_pcom(in, opsize); /* if negative, make positive */ | |
} | |
static void vis_minmax(OPS op,OPSIZE opsize,t_bool domax,t_bool doabs) | |
{ | |
OP v1,vmxmn,res; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 mxmnaddr = op[0].word; | |
uint32 v1addr = op[1].word; | |
int16 ix1 = INT16(op[2].word) * delta; | |
int16 n = INT16(op[3].word); | |
int16 i,mxmn,sign; | |
int32 subop = 020 | (opsize==fp_f ? 0 : 2); | |
if (n <= 0) return; | |
mxmn = 0; /* index of maxmin element */ | |
vmxmn = ReadOp(v1addr,opsize); /* initialize with first element */ | |
if (doabs) vis_abs(&vmxmn,opsize); /* ABS(v[1]) if requested */ | |
for (i = 0; i<n; i++) { | |
v1 = ReadOp(v1addr,opsize); /* get v[i] */ | |
if (doabs) vis_abs(&v1,opsize); /* build ABS(v[i]) if requested */ | |
(void)fp_exec(subop,&res,vmxmn,v1); /* subtract vmxmn - v1[i] */ | |
sign = GET_MSIGN(&res); /* !=0 if vmxmn < v1[i] */ | |
if ((domax && sign) || /* new max value found */ | |
(!domax && !sign)) { /* new min value found */ | |
mxmn = i; | |
vmxmn = v1; /* save the new max/min value */ | |
} | |
v1addr += ix1; /* point to next element */ | |
} | |
res.word = mxmn+1; /* adjust to one-based FTN array */ | |
WriteOp(mxmnaddr, res, in_s); /* save result */ | |
} | |
static void vis_vpiv(OPS op, OPSIZE opsize) | |
{ | |
OP s,v1,v2,v3; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 saddr = op[0].word; | |
uint32 v1addr = op[1].word; | |
int16 ix1 = INT16(op[2].word) * delta; | |
uint32 v2addr = op[3].word; | |
int16 ix2 = INT16(op[4].word) * delta; | |
uint32 v3addr = op[5].word; | |
int16 ix3 = INT16(op[6].word) * delta; | |
int16 i, n = INT16(op[7].word); | |
int16 oplen = opsize==fp_f ? 0 : 2; | |
if (n <= 0) return; | |
s = ReadOp(saddr,opsize); | |
/* calculates v3[k] = s * v1[i] + v2[j] for incrementing i,j,k */ | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
(void)fp_exec(040+oplen, ACCUM, s ,v1); /* ACCU := s*v1 */ | |
v2 = ReadOp(v2addr, opsize); | |
(void)fp_exec(004+oplen,&v3,v2,NOP); /* v3 := v2 + s*v1 */ | |
WriteOp(v3addr, v3, opsize); /* write result */ | |
v1addr += ix1; /* forward to next array elements */ | |
v2addr += ix2; | |
v3addr += ix3; | |
} | |
} | |
static void vis_vabs(OPS op, OPSIZE opsize) | |
{ | |
OP v1; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 v1addr = op[0].word; | |
int16 ix1 = INT16(op[1].word) * delta; | |
uint32 v2addr = op[2].word; | |
int32 ix2 = INT16(op[3].word) * delta; | |
int16 i,n = INT16(op[4].word); | |
if (n <= 0) return; | |
/* calculates v2[j] = ABS(v1[i]) for incrementing i,j */ | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
vis_abs(&v1,opsize); /* make absolute value */ | |
WriteOp(v2addr, v1, opsize); /* write result */ | |
v1addr += ix1; /* forward to next array elements */ | |
v2addr += ix2; | |
} | |
} | |
static void vis_trunc(OP* out, OP in) | |
{ | |
/* Note there is fp_trun(), but this doesn't seem to do the same conversion | |
* as the original code does */ | |
out->fpk[0] = in.fpk[0]; | |
out->fpk[1] = (in.fpk[1] & 0177400) | (in.fpk[3] & 0377); | |
} | |
static void vis_vsmnm(OPS op,OPSIZE opsize,t_bool doabs) | |
{ | |
uint32 fpuop; | |
OP v1,sumnrm = zero; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 saddr = op[0].word; | |
uint32 v1addr = op[1].word; | |
int16 ix1 = INT16(op[2].word) * delta; | |
int16 i,n = INT16(op[3].word); | |
if (n <= 0) return; | |
/* calculates sumnrm = sumnrm + DBLE(v1[i]) resp DBLE(ABS(v1[i])) for incrementing i */ | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
if (opsize==fp_f) (void)fp_cvt(&v1,fp_f,fp_t); /* cvt to DBLE(v1) */ | |
fpuop = (doabs && GET_MSIGN(&v1)) ? 022 : 002; /* use subtract for NRM && V1<0 */ | |
(void)fp_exec(fpuop,&sumnrm, sumnrm, v1); /* accumulate */ | |
v1addr += ix1; /* forward to next array elements */ | |
} | |
if (opsize==fp_f) | |
(void)vis_trunc(&sumnrm,sumnrm); /* truncate to SNGL(sumnrm) */ | |
WriteOp(saddr, sumnrm, opsize); /* write result */ | |
} | |
static void vis_vdot(OPS op,OPSIZE opsize) | |
{ | |
OP v1,v2,dot = zero; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 daddr = op[0].word; | |
uint32 v1addr = op[1].word; | |
int16 ix1 = INT16(op[2].word) * delta; | |
uint32 v2addr = op[3].word; | |
int16 ix2 = INT16(op[4].word) * delta; | |
int16 i,n = INT16(op[5].word); | |
if (n <= 0) return; | |
/* calculates dot = dot + v1[i]*v2[j] for incrementing i,j */ | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
if (opsize==fp_f) (void)fp_cvt(&v1,fp_f,fp_t); /* cvt to DBLE(v1) */ | |
v2 = ReadOp(v2addr, opsize); | |
if (opsize==fp_f) (void)fp_cvt(&v2,fp_f,fp_t); /* cvt to DBLE(v2) */ | |
(void)fp_exec(042,ACCUM, v1, v2); /* ACCU := v1 * v2 */ | |
(void)fp_exec(006,&dot,dot,NOP); /* dot := dot + v1*v2 */ | |
v1addr += ix1; /* forward to next array elements */ | |
v2addr += ix2; | |
} | |
if (opsize==fp_f) | |
(void)vis_trunc(&dot,dot); /* truncate to SNGL(sumnrm) */ | |
WriteOp(daddr, dot, opsize); /* write result */ | |
} | |
static void vis_movswp(OPS op, OPSIZE opsize, t_bool doswp) | |
{ | |
OP v1,v2; | |
int16 delta = opsize==fp_f ? 2 : 4; | |
uint32 v1addr = op[0].word; | |
int16 ix1 = INT16(op[1].word) * delta; | |
uint32 v2addr = op[2].word; | |
int16 ix2 = INT16(op[3].word) * delta; | |
int16 i,n = INT16(op[4].word); | |
if (n <= 0) return; | |
for (i=0; i<n; i++) { | |
v1 = ReadOp(v1addr, opsize); | |
v2 = ReadOp(v2addr, opsize); | |
WriteOp(v2addr, v1, opsize); /* v2 := v1 */ | |
if (doswp) WriteOp(v1addr, v2, opsize); /* v1 := v2 */ | |
v1addr += ix1; /* forward to next array elements */ | |
v2addr += ix2; | |
} | |
} | |
t_stat cpu_vis (uint32 IR, uint32 intrq) | |
{ | |
t_stat reason = SCPE_OK; | |
OPS op; | |
OP ret; | |
uint32 entry, rtn, rtn1 = 0, subcode = 0; | |
OP_PAT pattern; | |
OPSIZE opsize; | |
t_bool debug = DEBUG_PRI (cpu_dev, DEB_VIS); | |
opsize = (IR & 004000) ? fp_t : fp_f; /* double or single precision */ | |
entry = IR & 017; /* mask to entry point */ | |
pattern = op_vis[entry]; | |
if (entry==0) { /* retrieve sub opcode */ | |
ret = ReadOp (PC, in_s); /* get it */ | |
subcode = ret.word; | |
if (subcode & 0100000) /* special property of ucode */ | |
subcode = AR; /* for reentry */ | |
PC = (PC + 1) & VAMASK; /* bump to real argument list */ | |
pattern = (subcode & 0400) ? OP_AAKAKK : OP_AKAKAKK; /* scalar or vector operation */ | |
} | |
if (pattern != OP_N) | |
if (op_ftnret[entry]) { /* most VIS instrs ignore RTN addr */ | |
ret = ReadOp(PC, in_s); | |
rtn = rtn1 = ret.word; /* but save it just in case */ | |
PC = (PC + 1) & VAMASK; /* move to next argument */ | |
} | |
if (reason = cpu_ops (pattern, op, intrq)) /* get instruction operands */ | |
return reason; | |
if (debug) { /* debugging? */ | |
fprintf (sim_deb, ">>CPU VIS: IR = %06o/%06o (", /* print preamble and IR */ | |
IR, subcode); | |
fprint_sym (sim_deb, err_PC, (t_value *) &IR, /* print instruction mnemonic */ | |
NULL, SWMASK('M')); | |
fprintf (sim_deb, "), P = %06o", err_PC); /* print location */ | |
fprint_ops (pattern, op); /* print operands */ | |
fputc ('\n', sim_deb); /* terminate line */ | |
} | |
switch (entry) { /* decode IR<3:0> */ | |
case 000: /* .VECT (OP_special) */ | |
if (subcode & 0400) | |
vis_svop(subcode,op,opsize); /* scalar/vector op */ | |
else | |
vis_vvop(subcode,op,opsize); /* vector/vector op */ | |
break; | |
case 001: /* VPIV (OP_(A)AAKAKAKK) */ | |
vis_vpiv(op,opsize); | |
break; | |
case 002: /* VABS (OP_(A)AKAKK) */ | |
vis_vabs(op,opsize); | |
break; | |
case 003: /* VSUM (OP_(A)AAKK) */ | |
vis_vsmnm(op,opsize,FALSE); | |
break; | |
case 004: /* VNRM (OP_(A)AAKK) */ | |
vis_vsmnm(op,opsize,TRUE); | |
break; | |
case 005: /* VDOT (OP_(A)AAKAKK) */ | |
vis_vdot(op,opsize); | |
break; | |
case 006: /* VMAX (OP_(A)AAKK) */ | |
vis_minmax(op,opsize,TRUE,FALSE); | |
break; | |
case 007: /* VMAB (OP_(A)AAKK) */ | |
vis_minmax(op,opsize,TRUE,TRUE); | |
break; | |
case 010: /* VMIN (OP_(A)AAKK) */ | |
vis_minmax(op,opsize,FALSE,FALSE); | |
break; | |
case 011: /* VMIB (OP_(A)AAKK) */ | |
vis_minmax(op,opsize,FALSE,TRUE); | |
break; | |
case 012: /* VMOV (OP_(A)AKAKK) */ | |
vis_movswp(op,opsize,FALSE); | |
break; | |
case 013: /* VSWP (OP_(A)AKAKK) */ | |
vis_movswp(op,opsize,TRUE); | |
break; | |
case 014: /* .ERES (OP_(A)AA) */ | |
reason = cpu_ema_eres(&rtn,op[2].word,PC,debug); /* handle the ERES instruction */ | |
PC = rtn; | |
if (debug) | |
fprintf (sim_deb, | |
">>CPU VIS: return .ERES: AR = %06o, BR = %06o, rtn=%s\n", | |
AR, BR, PC==op[0].word ? "error" : "good"); | |
break; | |
case 015: /* .ESEG (OP_(A)A) */ | |
reason = cpu_ema_eseg(&rtn,IR,op[0].word,debug); /* handle the ESEG instruction */ | |
PC = rtn; | |
if (debug) | |
fprintf (sim_deb, | |
">>CPU VIS: return .ESEG: AR = %06o , BR = %06o, rtn=%s\n", | |
AR, BR, rtn==rtn1 ? "error" : "good"); | |
break; | |
case 016: /* .VSET (OP_(A)AAACCC) */ | |
reason = cpu_ema_vset(&rtn,op,debug); | |
PC = rtn; | |
if (debug) | |
fprintf (sim_deb, ">>CPU VIS: return .VSET: AR = %06o BR = %06o, rtn=%s\n", | |
AR, BR, | |
rtn==rtn1 ? "error" : (rtn==(rtn1+1) ? "hard" : "easy") ); | |
break; | |
case 017: /* [test] (OP_N) */ | |
XR = 3; /* firmware revision */ | |
SR = 0102077; /* test passed code */ | |
PC = (PC + 1) & VAMASK; /* P+2 return for firmware w/VIS */ | |
break; | |
default: /* others undefined */ | |
reason = stop_inst; | |
} | |
return reason; | |
} | |
/* SIGNAL/1000 Instructions | |
The SIGNAL/1000 instructions provide fast Fourier transforms and complex | |
arithmetic. They utilize the F-Series floating-point processor and the | |
Vector Instruction Set. | |
Option implementation by CPU was as follows: | |
2114 2115 2116 2100 1000-M 1000-E 1000-F | |
------ ------ ------ ------ ------ ------ ------ | |
N/A N/A N/A N/A N/A N/A 92835A | |
The routines are mapped to instruction codes as follows: | |
Instr. 1000-F Description | |
------ ------ ---------------------------------------------- | |
BITRV 105600 Bit reversal | |
BTRFY 105601 Butterfly algorithm | |
UNSCR 105602 Unscramble for phasor MPY | |
PRSCR 105603 Unscramble for phasor MPY | |
BITR1 105604 Swap two elements in array (alternate format) | |
BTRF1 105605 Butterfly algorithm (alternate format) | |
.CADD 105606 Complex number addition | |
.CSUB 105607 Complex number subtraction | |
.CMPY 105610 Complex number multiplication | |
.CDIV 105611 Complex number division | |
CONJG 105612 Complex conjugate | |
..CCM 105613 Complex complement | |
AIMAG 105614 Return imaginary part | |
CMPLX 105615 Form complex number | |
[nop] 105616 [no operation] | |
[test] 105617 [self test] | |
Notes: | |
1. SIGNAL/1000 ROM data are available from Bitsavers. | |
Additional references (documents unavailable): | |
- HP Signal/1000 User Reference and Installation Manual (92835-90002). | |
- SIGNAL/1000 Microcode Source (92835-18075, revision 2). | |
*/ | |
#define RE(x) (x+0) | |
#define IM(x) (x+2) | |
static const OP_PAT op_signal[16] = { | |
OP_AAKK, OP_AAFFKK, OP_AAFFKK,OP_AAFFKK, /* BITRV BTRFY UNSCR PRSCR */ | |
OP_AAAKK, OP_AAAFFKK,OP_AAA, OP_AAA, /* BITR1 BTRF1 .CADD .CSUB */ | |
OP_AAA, OP_AAA, OP_AAA, OP_A, /* .CMPY .CDIV CONJG ..CCM */ | |
OP_AA, OP_AAFF, OP_N, OP_N /* AIMAG CMPLX --- [test]*/ | |
}; | |
/* complex addition helper */ | |
static void sig_caddsub(uint32 addsub,OPS op) | |
{ | |
OP a,b,c,d,p1,p2; | |
a = ReadOp(RE(op[1].word), fp_f); /* read 1st op */ | |
b = ReadOp(IM(op[1].word), fp_f); | |
c = ReadOp(RE(op[2].word), fp_f); /* read 2nd op */ | |
d = ReadOp(IM(op[2].word), fp_f); | |
(void)fp_exec(addsub,&p1, a, c); /* add real */ | |
(void)fp_exec(addsub,&p2, b, d); /* add imag */ | |
WriteOp(RE(op[0].word), p1, fp_f); /* write result */ | |
WriteOp(IM(op[0].word), p2, fp_f); /* write result */ | |
} | |
/* butterfly operation helper */ | |
static void sig_btrfy(uint32 re,uint32 im,OP wr,OP wi,uint32 k, uint32 n2) | |
{ | |
/* | |
* v(k)-------->o-->o----> v(k) | |
* \ / | |
* x | |
* / \ | |
* v(k+N/2)---->o-->o----> v(k+N/2) | |
* Wn -1 | |
* | |
*/ | |
OP p1,p2,p3,p4; | |
OP v1r = ReadOp(re+k, fp_f); /* read v1 */ | |
OP v1i = ReadOp(im+k, fp_f); | |
OP v2r = ReadOp(re+k+n2, fp_f); /* read v2 */ | |
OP v2i = ReadOp(im+k+n2, fp_f); | |
/* (p1,p2) := cmul(w,v2) */ | |
(void)fp_exec(040, &p1, wr, v2r); /* S7,8 p1 := wr*v2r */ | |
(void)fp_exec(040, ACCUM, wi, v2i); /* ACCUM := wi*v2i */ | |
(void)fp_exec(024, &p1, p1, NOP); /* S7,S8 p1 := wr*v2r-wi*v2i ==real(w*v2) */ | |
(void)fp_exec(040, &p2, wi, v2r); /* S9,10 p2 := wi*v2r */ | |
(void)fp_exec(040, ACCUM, wr, v2i); /* ACCUM := wr*v2i */ | |
(void)fp_exec(004, &p2, p2, NOP); /* S9,10 p2 := wi*v2r+wr*v2i ==imag(w*v2) */ | |
/* v2 := v1 - (p1,p2) */ | |
(void)fp_exec(020, &p3, v1r, p1); /* v2r := v1r-real(w*v2) */ | |
(void)fp_exec(020, &p4, v1i, p2); /* v2i := v1i-imag(w*v2) */ | |
WriteOp(re+k+n2, p3, fp_f); /* write v2r */ | |
WriteOp(im+k+n2, p4, fp_f); /* write v2i */ | |
/* v1 := v1 + (p1,p2) */ | |
(void)fp_exec(0, &p3, v1r, p1); /* v1r := v1r+real(w*v2) */ | |
(void)fp_exec(0, &p4, v1i, p2); /* v1i := v1i+imag(w*v2) */ | |
WriteOp(re+k, p3, fp_f); /* write v1r */ | |
WriteOp(im+k, p4, fp_f); /* write v1i */ | |
O = 0; | |
} | |
/* helper for bit reversal | |
* idx is 0-based already */ | |
static void sig_bitrev(uint32 re,uint32 im, uint32 idx, uint32 log2n, int sz) | |
{ | |
uint32 i, org=idx, rev = 0; | |
OP v1r,v1i,v2r,v2i; | |
for (i=0; i<log2n; i++) { /* swap bits of idx */ | |
rev = (rev<<1) | (org & 1); /* into rev */ | |
org >>= 1; | |
} | |
if (rev < idx) return; /* avoid swapping same pair twice in loop */ | |
idx *= sz; /* adjust for element size */ | |
rev *= sz; /* (REAL*4 vs COMPLEX*8) */ | |
v1r = ReadOp(re+idx, fp_f); /* read 1st element */ | |
v1i = ReadOp(im+idx, fp_f); | |
v2r = ReadOp(re+rev, fp_f); /* read 2nd element */ | |
v2i = ReadOp(im+rev, fp_f); | |
WriteOp(re+idx, v2r, fp_f); /* swap elements */ | |
WriteOp(im+idx, v2i, fp_f); | |
WriteOp(re+rev, v1r, fp_f); | |
WriteOp(im+rev, v1i, fp_f); | |
} | |
/* helper for PRSCR/UNSCR */ | |
static OP sig_scadd(uint32 oper,t_bool addh, OP a, OP b) | |
{ | |
OP r; | |
static const OP plus_half = { { 0040000, 0000000 } }; /* DEC +0.5 */ | |
(void)fp_exec(oper,&r,a,b); /* calculate r := a +/- b */ | |
if (addh) (void)fp_exec(044,&r,plus_half,NOP); /* if addh set, multiply by 0.5 */ | |
return r; | |
} | |
/* complex multiply helper */ | |
static void sig_cmul(OP *r, OP *i, OP a, OP b, OP c, OP d) | |
{ | |
OP p; | |
(void)fp_exec(040, &p , a, c); /* p := ac */ | |
(void)fp_exec(040, ACCUM, b, d); /* ACCUM := bd */ | |
(void)fp_exec(024, r, p , NOP); /* real := ac-bd */ | |
(void)fp_exec(040, &p, a, d); /* p := ad */ | |
(void)fp_exec(040, ACCUM, b, c); /* ACCUM := bc */ | |
(void)fp_exec(004, i, p, NOP); /* imag := ad+bc */ | |
} | |
t_stat cpu_signal (uint32 IR, uint32 intrq) | |
{ | |
t_stat reason = SCPE_OK; | |
OPS op; | |
OP a,b,c,d,p1,p2,p3,p4,m1,m2,wr,wi; | |
uint32 entry, v, idx1, idx2; | |
int32 exc, exd; | |
t_bool debug = DEBUG_PRI (cpu_dev, DEB_SIG); | |
entry = IR & 017; /* mask to entry point */ | |
if (op_signal[entry] != OP_N) | |
if (reason = cpu_ops (op_signal[entry], op, intrq)) /* get instruction operands */ | |
return reason; | |
if (debug) { /* debugging? */ | |
fprintf (sim_deb, ">>CPU SIG: IR = %06o (", IR); /* print preamble and IR */ | |
fprint_sym (sim_deb, err_PC, (t_value *) &IR, /* print instruction mnemonic */ | |
NULL, SWMASK('M')); | |
fprintf (sim_deb, "), P = %06o", err_PC); /* print location */ | |
fprint_ops (op_signal[entry], op); /* print operands */ | |
fputc ('\n', sim_deb); /* terminate line */ | |
} | |
switch (entry) { /* decode IR<3:0> */ | |
case 000: /* BITRV (OP_AAKK) */ | |
/* BITRV | |
* bit reversal for FFT | |
* JSB BITRV | |
* DEF ret(,I) return address | |
* DEF vect,I base address of array | |
* DEF idx,I index bitmap to be reversed (one-based) | |
* DEF nbits,I number of bits of index | |
* | |
* Given a complex*8 vector of nbits (power of 2), this calculates: | |
* swap( vect[idx], vect[rev(idx)]) where rev(i) is the bitreversed value of i */ | |
sig_bitrev(op[1].word, op[1].word+2, op[2].word-1, op[3].word, 4); | |
PC = op[0].word & VAMASK; | |
break; | |
case 001: /* BTRFY (OP_AAFFKK) */ | |
/* BTRFY - butterfly operation | |
* JSB BTRFY | |
* DEF ret(,I) return address | |
* DEF vect(,I) complex*8 vector | |
* DEF wr,I real part of W | |
* DEF wi,I imag part of W | |
* DEF node,I index of 1st op (1 based) | |
* DEF lmax,I offset to 2nd op (0 based) */ | |
sig_btrfy(op[1].word, op[1].word+2, | |
op[2], op[3], | |
2*(op[4].word-1), 2*op[5].word); | |
PC = op[0].word & VAMASK; | |
break; | |
case 002: /* UNSCR (OP_AAFFKK) */ | |
/* UNSCR unscramble for phasor MPY | |
* JSB UNSCR | |
* DEF ret(,I) | |
* DEF vector,I | |
* DEF WR | |
* DEF WI | |
* DEF idx1,I | |
* DEF idx2,I */ | |
v = op[1].word; | |
idx1 = 2 * (op[4].word - 1); | |
idx2 = 2 * (op[5].word - 1); | |
wr = op[2]; /* read WR */ | |
wi = op[3]; /* read WI */ | |
p1 = ReadOp(RE(v + idx1), fp_f); /* S1 VR[idx1] */ | |
p2 = ReadOp(RE(v + idx2), fp_f); /* S2 VR[idx2] */ | |
p3 = ReadOp(IM(v + idx1), fp_f); /* S9 VI[idx1] */ | |
p4 = ReadOp(IM(v + idx2), fp_f); /* S10 VI[idx2] */ | |
c = sig_scadd(000, TRUE, p3, p4); /* S5,6 0.5*(p3+p4) */ | |
d = sig_scadd(020, TRUE, p2, p1); /* S7,8 0.5*(p2-p1) */ | |
sig_cmul(&m1, &m2, wr, wi, c, d); /* (WR,WI) * (c,d) */ | |
c = sig_scadd(000, TRUE, p1, p2); /* 0.5*(p1+p2) */ | |
d = sig_scadd(020, TRUE, p3, p4); /* 0.5*(p3-p4) */ | |
(void)fp_exec(000, &p1, c, m1); /* VR[idx1] := 0.5*(p1+p2) + real(W*(c,d)) */ | |
WriteOp(RE(v + idx1), p1, fp_f); | |
(void)fp_exec(000, &p2, d, m2); /* VI[idx1] := 0.5*(p3-p4) + imag(W*(c,d)) */ | |
WriteOp(IM(v + idx1), p2, fp_f); | |
(void)fp_exec(020, &p1, c, m1); /* VR[idx2] := 0.5*(p1+p2) - imag(W*(c,d)) */ | |
WriteOp(RE(v + idx2), p1, fp_f); | |
(void)fp_exec(020, &p2, d, m2); /* VI[idx2] := 0.5*(p3-p4) - imag(W*(c,d)) */ | |
WriteOp(IM(v + idx2), p2, fp_f); | |
PC = op[0].word & VAMASK; | |
break; | |
case 003: /* PRSCR (OP_AAFFKK) */ | |
/* PRSCR unscramble for phasor MPY | |
* JSB PRSCR | |
* DEF ret(,I) | |
* DEF vector,I | |
* DEF WR | |
* DEF WI | |
* DEF idx1,I | |
* DEF idx2,I */ | |
v = op[1].word; | |
idx1 = 2 * (op[4].word - 1); | |
idx2 = 2 * (op[5].word - 1); | |
wr = op[2]; /* read WR */ | |
wi = op[3]; /* read WI */ | |
p1 = ReadOp(RE(v + idx1), fp_f); /* VR[idx1] */ | |
p2 = ReadOp(RE(v + idx2), fp_f); /* VR[idx2] */ | |
p3 = ReadOp(IM(v + idx1), fp_f); /* VI[idx1] */ | |
p4 = ReadOp(IM(v + idx2), fp_f); /* VI[idx2] */ | |
c = sig_scadd(020, FALSE, p1, p2); /* p1-p2 */ | |
d = sig_scadd(000, FALSE, p3, p4); /* p3+p4 */ | |
sig_cmul(&m1,&m2, wr, wi, c, d); /* (WR,WI) * (c,d) */ | |
c = sig_scadd(000, FALSE, p1, p2); /* p1+p2 */ | |
d = sig_scadd(020, FALSE, p3,p4); /* p3-p4 */ | |
(void)fp_exec(020, &p1, c, m2); /* VR[idx1] := (p1-p2) - imag(W*(c,d)) */ | |
WriteOp(RE(v + idx1), p1, fp_f); | |
(void)fp_exec(000, &p2, d, m1); /* VI[idx1] := (p3-p4) + real(W*(c,d)) */ | |
WriteOp(IM(v + idx1), p2, fp_f); | |
(void)fp_exec(000, &p1, c, m2); /* VR[idx2] := (p1+p2) + imag(W*(c,d)) */ | |
WriteOp(RE(v + idx2), p1, fp_f); | |
(void)fp_exec(020, &p2, m1, d); /* VI[idx2] := imag(W*(c,d)) - (p3-p4) */ | |
WriteOp(IM(v + idx2), p2, fp_f); | |
PC = op[0].word & VAMASK; | |
break; | |
case 004: /* BITR1 (OP_AAAKK) */ | |
/* BITR1 | |
* bit reversal for FFT, alternative version | |
* JSB BITR1 | |
* DEF ret(,I) return address if already swapped | |
* DEF revect,I base address of real vect | |
* DEF imvect,I base address of imag vect | |
* DEF idx,I index bitmap to be reversed (one-based) | |
* DEF nbits,I number of bits of index | |
* | |
* Given a complex*8 vector of nbits (power of 2), this calculates: | |
* swap( vect[idx], vect[rev(idx)]) where rev(i) is the bitreversed value of i | |
* | |
* difference to BITRV is that BITRV uses complex*8, and BITR1 uses separate real*4 | |
* vectors for Real and Imag parts */ | |
sig_bitrev(op[1].word, op[2].word, op[3].word-1, op[4].word, 2); | |
PC = op[0].word & VAMASK; | |
break; | |
case 005: /* BTRF1 (OP_AAAFFKK) */ | |
/* BTRF1 - butterfly operation with real*4 vectors | |
* JSB BTRF1 | |
* DEF ret(,I) return address | |
* DEF rvect,I real part of vector | |
* DEF ivect,I imag part of vector | |
* DEF wr,I real part of W | |
* DEF wi,I imag part of W | |
* DEF node,I index (1 based) | |
* DEF lmax,I index (0 based) */ | |
sig_btrfy(op[1].word, op[2].word, | |
op[3], op[4], | |
op[5].word-1, op[6].word); | |
PC = op[0].word & VAMASK; | |
break; | |
case 006: /* .CADD (OP_AAA) */ | |
/* .CADD Complex addition | |
* JSB .CADD | |
* DEF result,I | |
* DEF oprd1,I | |
* DEF oprd2,I | |
* complex addition is: (a+bi) + (c+di) => (a+c) + (b+d)i */ | |
sig_caddsub(000,op); | |
break; | |
case 007: /* .CSUB (OP_AAA) */ | |
/* .CSUB Complex subtraction | |
* JSB .CSUB | |
* DEF result,I | |
* DEF oprd1,I | |
* DEF oprd2,I | |
* complex subtraction is: (a+bi) - (c+di) => (a - c) + (b - d)i */ | |
sig_caddsub(020,op); | |
break; | |
case 010: /* .CMUL (OP_AAA) */ | |
/* .CMPY Complex multiplication | |
* call: | |
* JSB .CMPY | |
* DEF result,I | |
* DEF oprd1,I | |
* DEF oprd2,I | |
* complex multiply is: (a+bi)*(c+di) => (ac-bd) + (ad+bc)i */ | |
a = ReadOp(RE(op[1].word), fp_f); /* read 1st op */ | |
b = ReadOp(IM(op[1].word), fp_f); | |
c = ReadOp(RE(op[2].word), fp_f); /* read 2nd op */ | |
d = ReadOp(IM(op[2].word), fp_f); | |
sig_cmul(&p1, &p2, a, b, c, d); | |
WriteOp(RE(op[0].word), p1, fp_f); /* write real result */ | |
WriteOp(IM(op[0].word), p2, fp_f); /* write imag result */ | |
break; | |
case 011: /* .CDIV (OP_AAA) */ | |
/* .CDIV Complex division | |
* call: | |
* JSB .CDIV | |
* DEF result,I | |
* DEF oprd1,I | |
* DEF oprd2,I | |
* complex division is: (a+bi)/(c+di) => ((ac+bd) + (bc-ad)i)/(c^2+d^2) */ | |
a = ReadOp(RE(op[1].word), fp_f); /* read 1st op */ | |
b = ReadOp(IM(op[1].word), fp_f); | |
c = ReadOp(RE(op[2].word), fp_f); /* read 2nd op */ | |
d = ReadOp(IM(op[2].word), fp_f); | |
(void)fp_unpack (NULL, &exc, c, fp_f); /* get exponents */ | |
(void)fp_unpack (NULL, &exd, d, fp_f); | |
if (exc < exd) { /* ensure c/d < 1 */ | |
p1 = a; a = c; c = p1; /* swap dividend and divisor */ | |
p1 = b; b = d; d = p1; | |
} | |
(void)fp_exec(060, &p1, d, c); /* p1,accu := d/c */ | |
(void)fp_exec(044, ACCUM, d, NOP); /* ACCUM := dd/c */ | |
(void)fp_exec(004, &p2, c, NOP); /* p2 := c + dd/c */ | |
(void)fp_exec(040, ACCUM, b, p1); /* ACCUM := bd/c */ | |
(void)fp_exec(004, ACCUM, a, NOP); /* ACCUM := a + bd/c */ | |
(void)fp_exec(070, &p3, NOP, p2); /* p3 := (a+bd/c)/(c+dd/c) == (ac+bd)/(cc+dd) */ | |
WriteOp(RE(op[0].word), p3, fp_f); /* Write real result */ | |
(void)fp_exec(040, ACCUM, a, p1); /* ACCUM := ad/c */ | |
(void)fp_exec(030, ACCUM, NOP, b); /* ACCUM := ad/c - b */ | |
if (exd < exc) { /* was not swapped? */ | |
(void)fp_exec(024, ACCUM, zero, NOP); /* ACCUM := -ACCUM */ | |
} | |
(void)fp_exec(070, &p3, NOP, p2); /* p3 := (b-ad/c)/(c+dd/c) == (bc-ad)/cc+dd) */ | |
WriteOp(IM(op[0].word), p3, fp_f); /* Write imag result */ | |
break; | |
case 012: /* CONJG (OP_AAA) */ | |
/* CONJG build A-Bi from A+Bi | |
* call: | |
* JSB CONJG | |
* DEF RTN | |
* DEF res,I result | |
* DEF arg,I input argument */ | |
a = ReadOp(RE(op[2].word), fp_f); /* read real */ | |
b = ReadOp(IM(op[2].word), fp_f); /* read imag */ | |
(void)fp_pcom(&b, fp_f); /* negate imag */ | |
WriteOp(RE(op[1].word), a, fp_f); /* write real */ | |
WriteOp(IM(op[1].word), b, fp_f); /* write imag */ | |
break; | |
case 013: /* ..CCM (OP_A) */ | |
/* ..CCM complement complex | |
* call | |
* JSB ..CCM | |
* DEF arg | |
* build (-RE,-IM) | |
*/ | |
v = op[0].word; | |
a = ReadOp(RE(v), fp_f); /* read real */ | |
b = ReadOp(IM(v), fp_f); /* read imag */ | |
(void)fp_pcom(&a, fp_f); /* negate real */ | |
(void)fp_pcom(&b, fp_f); /* negate imag */ | |
WriteOp(RE(v), a, fp_f); /* write real */ | |
WriteOp(IM(v), b, fp_f); /* write imag */ | |
break; | |
case 014: /* AIMAG (OP_AA) */ | |
/* AIMAG return the imaginary part in AB | |
* JSB AIMAG | |
* DEF *+2 | |
* DEF cplx(,I) | |
* returns: AB imaginary part of complex number */ | |
a = ReadOp(IM(op[1].word), fp_f); /* read imag */ | |
AR = a.fpk[0]; /* move MSB to A */ | |
BR = a.fpk[1]; /* move LSB to B */ | |
break; | |
case 015: /* CMPLX (OP_AFF) */ | |
/* CMPLX form a complex number | |
* JSB CMPLX | |
* DEF *+4 | |
* DEF result,I complex number | |
* DEF repart,I real value | |
* DEF impart,I imaginary value */ | |
WriteOp(RE(op[1].word), op[2], fp_f); /* write real part */ | |
WriteOp(IM(op[1].word), op[3], fp_f); /* write imag part */ | |
break; | |
case 017: /* [slftst] (OP_N) */ | |
XR = 2; /* firmware revision */ | |
SR = 0102077; /* test passed code */ | |
PC = (PC + 1) & VAMASK; /* P+2 return for firmware w/SIGNAL1000 */ | |
break; | |
case 016: /* invalid */ | |
default: /* others undefined */ | |
reason = stop_inst; | |
} | |
return reason; | |
} | |
#endif /* end of int64 support */ |