vuctl.v
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/*
*************************************************************************
* *
* Copyright (C) 1994, Silicon Graphics, Inc. *
* *
* These coded instructions, statements, and computer programs contain *
* unpublished proprietary information of Silicon Graphics, Inc., and *
* are protected by Federal copyright law. They may not be disclosed *
* to third parties or copied or duplicated in any form, in whole or *
* in part, without the prior written consent of Silicon Graphics, Inc. *
* *
*************************************************************************
*/
// $Id: vuctl.v,v 1.1 2002/03/28 00:26:14 berndt Exp $
/*
*************************************************************************
* *
* Project Reality *
* *
* Module: vuctl *
* Description: vector unit control for all two vector unit *
* datapaths and two multipliers. *
* *
* Designer: Brian Ferguson *
* Date: 8/11/94 *
* *
*************************************************************************
*/
// vuctl.v: RSP vector unit control
`timescale 1ns / 10ps
`include "vopcodes.h"
module vuctl ( clk, reset_l,
su_instvld_rd, su_instvldk_rd,
su_vseqone_rd,
su_instelem_rd, su_instfunc_rd,
su_rdcmpcd_rd, su_rdcryout_rd, su_rdcmpcdad_rd,
su_wrcmpcd_wb, su_wrcryout_wb, su_wrcmpcdad_wb,
vdp_vs_sign0_mu, vdp_vt_sign0_mu,
vdp_vs_zero0_mu, vdp_vt_zero0_mu,
vdp_aluovr0_mu, vdp_aluco0_mu,
vdp_aluzero0_mu, vdp_aluone0_mu,
vdp_vs_sign1_mu, vdp_vt_sign1_mu,
vdp_vs_zero1_mu, vdp_vt_zero1_mu,
vdp_aluovr1_mu, vdp_aluco1_mu,
vdp_aluzero1_mu, vdp_aluone1_mu,
vdp_addlwco0_ac, vdp_addlwov0_ac,
vdp_csupco0_ac, vdp_addupco0_ac,
vdp_addlwco1_ac, vdp_addlwov1_ac,
vdp_csupco1_ac, vdp_addupco1_ac,
vmu_co_clal0_ac, vmu_co_clal1_ac,
vmu_co_clah0_ac, vmu_co_clah1_ac,
vdp_acc0bit15_wb, vdp_acc0bit21_wb,
vdp_acc0bit31_wb, vdp_acc0bit47_wb,
vdp_achizero0_wb, vdp_achione0_wb,
vdp_acmizero0_wb,
vdp_acc1bit15_wb, vdp_acc1bit21_wb,
vdp_acc1bit31_wb, vdp_acc1bit47_wb,
vdp_achizero1_wb, vdp_achione1_wb,
vdp_acmizero1_wb,
vct_couprsl0_mu, vct_smuprsl0_mu,
vct_colwrsl0_mu,
vct_couprsl1_mu, vct_smuprsl1_mu,
vct_colwrsl1_mu,
vct_smlwrsl0_mu,
vct_smlwrsl1_mu,
vct_sgnmplr_mu, vct_sgnmplcnd_mu,
vct_shftlftone0_mu, vct_shftlftone1_mu,
vct_aluctl0_mu, vct_alucin0_mu,
vct_alucmpvt0_mu,
vct_cmpvt0_mu,
vct_aluctl1_mu, vct_alucin1_mu,
vct_alucmpvt1_mu,
vct_cmpvt1_mu,
vct_instvld_ac,
vct_aclwsl0_ac,
vct_aclwsl1_ac,
vct_cslwcsl0_ac,
vct_cslwcsl1_ac,
vct_csupcen0_ac,
vct_csupcen1_ac,
vct_acmisl0_ac,
vct_acmisl1_ac,
vct_acupsl0_ac,
vct_acupsl1_ac,
vct_rndvlu0_ac,
vct_cslwasl0_ac, vct_cslwbsl0_ac,
vct_addlwci0_ac,
vct_csupasl0_ac, vct_csupbsl0_ac,
vct_incrdwn0_ac, vct_incrci0_ac,
vct_incrmxsl0_ac,
vct_rndvlu1_ac,
vct_cslwasl1_ac, vct_cslwbsl1_ac,
vct_addlwci1_ac,
vct_csupasl1_ac, vct_csupbsl1_ac,
vct_incrdwn1_ac, vct_incrci1_ac,
vct_incrmxsl1_ac,
vct_rsltsl0_wb, vct_rsltsl1_wb,
vct_clprslt0_wb, vct_clprslt1_wb,
su_cont_to_from,
/*
* The following signals are for register file address decoding
* only.
*/
su_vs_addr_rd,
vct_dvtypop_ac,
vct_vs_addr_ac
);
/*
* The following signals are the input signals to the
* vector unit control block.
*
* The first group are input signals to the control block
* which provide general control such as clocks, reset
* hold, instruction decoding and reading/writing the
* control registers.
*/
input clk; /* vu clock */
input reset_l; /* vu active low reset */
input su_instvld_rd; /* valid CP2 instruction for vu */
input su_instvldk_rd; /* valid CP2 instruction for vu with kill */
input su_vseqone_rd; /* vs field of instruction equal to 1 */
input [3:0] su_instelem_rd; /* element field of instruction */
input [5:0] su_instfunc_rd; /* function field of instruction */
input su_rdcmpcd_rd; /* read vector compare code register */
input su_rdcryout_rd; /* read vector carry out register */
input su_rdcmpcdad_rd; /* read vector compare add register */
input su_wrcmpcd_wb; /* write vector compare code register */
input su_wrcryout_wb; /* write vector carry out register */
input su_wrcmpcdad_wb; /* write vector compare add register */
/*
* The next group are input signals to the control block from
* the multiply stage of the vector unit datapaths.
*/
input vdp_vs_zero0_mu; /* vs operand is equal to zero vector 0 */
input vdp_vs_zero1_mu; /* vs operand is equal to zero vector 1 */
input vdp_vt_zero0_mu; /* vt operand is equal to zero vector 0 */
input vdp_vt_zero1_mu; /* vt operand is equal to zero vector 1 */
input vdp_vs_sign0_mu; /* vs sign bit from vector 0 */
input vdp_vs_sign1_mu; /* vs sign bit from vector 1 */
input vdp_vt_sign0_mu; /* vt sign bit from vector 0 */
input vdp_vt_sign1_mu; /* vt sign bit from vector 1 */
input vdp_aluovr0_mu; /* overflow bit from alu vector 0 */
input vdp_aluco0_mu; /* carry out from alu vector 0 */
input vdp_aluzero0_mu; /* alu result equal to zero vector 0 */
input vdp_aluone0_mu; /* alu result is equal to one vector 0 */
input vdp_aluovr1_mu; /* overflow bit from alu vector 1 */
input vdp_aluco1_mu; /* carry out from alu vector 1 */
input vdp_aluzero1_mu; /* alu result is equal to zero vector 1 */
input vdp_aluone1_mu; /* alu result is equal to one vector 1 */
/*
* The next group are input signals to the control block from
* the accumulate stage of the vector unit datapaths.
*/
input vdp_addlwco0_ac; /* carry out from low adder vector 0 */
input vdp_addlwov0_ac; /* overflow from low csa vector 0 */
input vdp_csupco0_ac; /* carry out from high csa vector 0 */
input vdp_addupco0_ac; /* carry out from high adder vector 0 */
input vdp_addlwco1_ac; /* carry out from low adder vector 1 */
input vdp_addlwov1_ac; /* overflow from low csa vector 1 */
input vdp_csupco1_ac; /* carry out from high csa vector 1 */
input vdp_addupco1_ac; /* carry out from high adder vector 1 */
input vmu_co_clal0_ac; /* carry out from 16 bit product of multiplier vector 0 */
input vmu_co_clal1_ac; /* carry out from 16 bit product of multiplier vector 1 */
input vmu_co_clah0_ac; /* false carry out from multiplier vector 0 */
input vmu_co_clah1_ac; /* false carry out from multiplier vector 1 */
/*
* The next group are input signals to the control block from
* the writeback stage of the vector unit datapaths.
*/
input vdp_acc0bit15_wb; /* bit 15 of accumulator used to determine sign vector 0 */
input vdp_acc0bit21_wb; /* bit 21 of accumulator used for macq vector 0 */
input vdp_acc0bit31_wb; /* bit 31 of accumulator used to determine sign vector 0 */
input vdp_acc0bit47_wb; /* bit 47 of accumulator used to determine sign vector 0 */
input vdp_achizero0_wb; /* 47:32 of accumulator equal zero vector 0 */
input vdp_acmizero0_wb; /* 31:16 of accumulator equal zero vector 0 */
input vdp_achione0_wb; /* 47:32 of accumulator equal one vector 0 */
input vdp_acc1bit15_wb; /* bit 15 of accumulator used to determine sign vector 1*/
input vdp_acc1bit21_wb; /* bit 21 of accumulator used for macq vector 1 */
input vdp_acc1bit31_wb; /* bit 31 of accumulator used to determine sign vector 1 */
input vdp_acc1bit47_wb; /* bit 47 of accumulator used to determine sign vector 1 */
input vdp_achizero1_wb; /* 47:32 of accumulator equal zero vector 1 */
input vdp_acmizero1_wb; /* 31:16 of accumulator equal zero vector 1 */
input vdp_achione1_wb; /* 47:32 of accumulator equal one vector 1 */
/*
* The following input signals are for register file address decoding
* only.
*/
input [4:0] su_vs_addr_rd; /* register number for vs read */
/*
* The following signals are the output signals for the
* vector unit control block.
*/
/*
* The first group are output control signals for the
* register file read stage of the vector unit datapath.
*/
/*
* The next group are output control signals for the
* multiply stage of the vector unit datapath.
*/
output [1:0] vct_couprsl0_mu; /* select for multiply upper carry out vector */
output [1:0] vct_couprsl1_mu; /* select for multiply upper carry out vector */
output [1:0] vct_smuprsl0_mu; /* select for multiply upper sum out vector */
output [1:0] vct_smuprsl1_mu; /* select for multiply upper sum out vector */
output [1:0] vct_colwrsl0_mu; /* selects for multiply lower carry out register */
output [1:0] vct_colwrsl1_mu; /* selects for multiply lower carry out register */
output [1:0] vct_smlwrsl0_mu; /* selects for multiply lower sum out vector 0 */
output [1:0] vct_smlwrsl1_mu; /* selects for multiply lower sum out vector 1 */
output vct_sgnmplr_mu; /* signed multiplier */
output vct_sgnmplcnd_mu; /* signed multiplicand */
output vct_shftlftone0_mu; /* shift left by 1 for MULF, MACF, MULU, MACU */
output vct_shftlftone1_mu; /* shift left by 1 for MULF, MACF, MULU, MACU */
output [2:0] vct_aluctl0_mu; /* control for alu vector 0 */
output vct_alucin0_mu; /* carry in to alu vector 0 */
output vct_alucmpvt0_mu; /* complement vt subtact in ALU - slice 0 */
output vct_cmpvt0_mu; /* complement vt for writing -VT for CH, CL, CR vector 0 */
output [2:0] vct_aluctl1_mu; /* control for alu vector 1 */
output vct_alucin1_mu; /* carry in to alu vector 1 */
output vct_alucmpvt1_mu; /* complement vt subtact in ALU - slice 1 */
output vct_cmpvt1_mu; /* complement vt for writing -VT for CH, CL, CR vector 1 */
/*
* The next group are output control signals for the
* accumulate stage of the vector unit datapath.
*/
output vct_instvld_ac; /* valid CP2 instruction in AC */
output [1:0] vct_aclwsl0_ac; /* selects input for lower mux of accumulator vector 0 */
output [1:0] vct_aclwsl1_ac; /* selects input for lower mux of accumulator vector 1 */
output vct_cslwcsl0_ac; /* select for input c of lower csa slice 0 */
output vct_cslwcsl1_ac; /* select for input c of lower csa slice 1 */
output vct_csupcen0_ac; /* input c enable for upper csa even vectors */
output vct_csupcen1_ac; /* input c enable for upper csa odd vectors */
output [1:0] vct_acmisl0_ac; /* selects input for middle mux of accumulator vector 0 */
output [1:0] vct_acmisl1_ac; /* selects input for middle mux of accumulator vector 1 */
output vct_incrmxsl0_ac; /* mux select for incrementer output vector 0 */
output vct_incrmxsl1_ac; /* mux select for incrementer output vector 1 */
output [1:0] vct_acupsl0_ac; /* selects input for upper mux of accumulator vector 0 */
output [1:0] vct_acupsl1_ac; /* selects input for upper mux of accumulator vector 1 */
output [3:0] vct_rndvlu0_ac; /* round value for multiplies/byte adds vector 0 */
output [1:0] vct_cslwasl0_ac; /* selects for input a of lower csa vector 0 */
output [1:0] vct_cslwbsl0_ac; /* selects for input b of lower csa vector 0 */
output vct_addlwci0_ac; /* carry in to lower adder vector 0 */
output [1:0] vct_csupasl0_ac; /* selects for input a of upper csa vector 0 */
output [1:0] vct_csupbsl0_ac; /* selects for input b of upper csa vector 0 */
output vct_incrdwn0_ac; /* increment/decrement control signal vector 0 */
output vct_incrci0_ac; /* increment/decrement enable signal vector 0 */
output [3:0] vct_rndvlu1_ac; /* round value for multiplies/byte adds vector 1 */
output [1:0] vct_cslwasl1_ac; /* selects for input a of lower csa vector 1 */
output [1:0] vct_cslwbsl1_ac; /* selects for input b of lower csa vector 1 */
output vct_addlwci1_ac; /* carry in to lower adder vector 1 */
output [1:0] vct_csupasl1_ac; /* selects for input a of upper csa vector 1 */
output [1:0] vct_csupbsl1_ac; /* selects for input b of upper csa vector 1 */
output vct_incrdwn1_ac; /* increment/decrement control signal vector 1 */
output vct_incrci1_ac; /* increment/decrement enable signal vector 1 */
/*
* The next group are output control signals for the
* write back stage of the vector unit datapath.
*/
output [2:0] vct_rsltsl0_wb; /* selects for result mux vector 0 */
output [2:0] vct_rsltsl1_wb; /* selects for result mux vector 1 */
output [2:0] vct_clprslt0_wb; /* clamp value for all clamping vector 0 */
output [2:0] vct_clprslt1_wb; /* clamp value for all clamping vector 1 */
/*
* The following output signals are for addressing the register file only.
*/
output vct_dvtypop_ac; /* divide or move type instruction in AC */
output [2:0] vct_vs_addr_ac; /* register number for vs read used as element field for div */
inout [3:0] su_cont_to_from; /* Data for moving to/from vector control registers. */
/*
* Pipechain for instruction valid, instruction function, vs and element fields.
*/
wire vct_instvld_mu; /* valid CP2 instruction in MU */
asdff #(1, 0) vctinstvldffmu (vct_instvld_mu, su_instvldk_rd, clk, reset_l );
asdff #(1, 0) vctinstvldffac (vct_instvld_ac, vct_instvld_mu, clk, reset_l );
wire [5:0] vct_instfunc_mu; /* function field of instruction in MU */
wire [5:0] vct_instfunc_ac; /* function field of instruction in AC */
asdffen #(6, 0) vctinstfuncffmu (vct_instfunc_mu, su_instfunc_rd, su_instvld_rd, clk, reset_l );
asdffen #(6, 0) vctinstfuncffac (vct_instfunc_ac, vct_instfunc_mu, vct_instvld_mu, clk, reset_l );
wire [2:0] vct_vs_addr_rd; /* vs field of instruction in RD */
wire [2:0] vct_vs_addr_mu; /* vs field of instruction in MU */
wire [2:0] vct_vs_addr_ac; /* vs field of instruction in AC */
assign vct_vs_addr_rd = su_vs_addr_rd[2:0];
asdffen #(3, 0) vctvsaddrffmu (vct_vs_addr_mu, vct_vs_addr_rd, su_instvld_rd, clk, reset_l );
asdffen #(3, 0) vctvsaddrffac (vct_vs_addr_ac, vct_vs_addr_mu, vct_instvld_mu, clk, reset_l );
wire [3:0] vct_instelem_mu; /* element field of instruction in MU */
wire [3:0] vct_instelem_ac; /* element field of instruction in AC */
asdffen #(4, 0) vctinstelemffmu (vct_instelem_mu, su_instelem_rd, su_instvld_rd, clk, reset_l );
asdffen #(4, 0) vctinstelemffac (vct_instelem_ac, vct_instelem_mu, vct_instvld_mu, clk, reset_l );
wire vct_vseqone_mu; /* vs field of instruction equal to 1 in MU */
wire vct_vseqone_ac; /* vs field of instruction equal to 1 in AC */
asdffen #(1, 0) vctvseqoneffmu (vct_vseqone_mu, su_vseqone_rd, su_instvld_rd, clk, reset_l );
asdffen #(1, 0) vctvseqoneffac (vct_vseqone_ac, vct_vseqone_mu, vct_instvld_mu, clk, reset_l );
/*
* Instruction decode of select instructions in the RD stage.
*/
wire vct_stgelcpop_rd; /* select compare LT, EQ, NEQ ot VGE instruction in MU stage */
assign vct_stgelcpop_rd = ( su_instfunc_rd == `VLT ) || ( su_instfunc_rd == `VEQ ) ||
( su_instfunc_rd == `VNE ) || ( su_instfunc_rd == `VGE ) ;
wire vct_stcrop_rd; /* -VT <= VS <= VT select instruction 1's comp */
assign vct_stcrop_rd = su_instvld_rd && ( su_instfunc_rd == `VCR ) ;
/*
* Instruction decode of add instructions in the RD stage.
*/
wire vct_subcop_rd; /* SUBC instruction in RD */
assign vct_subcop_rd = ( su_instfunc_rd == `VSUBC ) ;
wire vct_sbtypop_rd; /* Subtract type VS-VT instruction in RD */
assign vct_sbtypop_rd = (su_instfunc_rd == `VSUB) || (su_instfunc_rd == `VSUBC) ;
wire vct_absop_rd; /* ABS instruction in RD stage. */
wire vct_absop_mu; /* ABS instruction in MU stage. */
assign vct_absop_rd = ( su_instfunc_rd == `VABS ) ;
asdffen #(1, 0) vctabsopffmu (vct_absop_mu, vct_absop_rd, su_instvld_rd, clk, reset_l );
/*
* Instruction decoding for logical ops in MU stage.
*/
wire vct_vandop_rd; /* VAND instruction in RD */
wire vct_vandop_mu; /* VAND instruction in MU */
assign vct_vandop_rd = ( su_instfunc_rd == `VAND ) ;
asdffen #(1, 0) vctvandopffmu (vct_vandop_mu, vct_vandop_rd, su_instvld_rd, clk, reset_l );
wire vct_vnandop_rd; /* VNAND instruction in RD */
wire vct_vnandop_mu; /* VNAND instruction in MU */
assign vct_vnandop_rd = ( su_instfunc_rd == `VNAND ) ;
asdffen #(1, 0) vctvnandopffmu (vct_vnandop_mu, vct_vnandop_rd, su_instvld_rd, clk, reset_l );
wire vct_vorop_rd; /* VOR instruction in RD */
wire vct_vorop_mu; /* VOR instruction in MU */
assign vct_vorop_rd = ( su_instfunc_rd == `VOR ) ;
asdffen #(1, 0) vctvoropffmu (vct_vorop_mu, vct_vorop_rd, su_instvld_rd, clk, reset_l );
wire vct_vnorop_rd; /* VNOR instruction in RD */
wire vct_vnorop_mu; /* VNOR instruction in MU */
assign vct_vnorop_rd = ( su_instfunc_rd == `VNOR ) ;
asdffen #(1, 0) vctvnoropffmu (vct_vnorop_mu, vct_vnorop_rd, su_instvld_rd, clk, reset_l );
wire vct_vxorop_rd; /* VXOR instruction in RD */
wire vct_vxorop_mu; /* VXOR instruction in MU */
assign vct_vxorop_rd = ( su_instfunc_rd == `VXOR ) ;
asdffen #(1, 0) vctvxoropffmu (vct_vxorop_mu, vct_vxorop_rd, su_instvld_rd, clk, reset_l );
wire vct_vxnorop_rd; /* VXNOR instruction in RD */
wire vct_vxnorop_mu; /* VXNOR instruction in MU */
assign vct_vxnorop_rd = ( su_instfunc_rd == `VXNOR ) ;
asdffen #(1, 0) vctvxnoropffmu (vct_vxnorop_mu, vct_vxnorop_rd, su_instvld_rd, clk, reset_l );
/*
* The following is the code for the instruction decode in the
* MU stage.
*/
/*
* Instruction decoding for select ops in MU stage.
*/
wire vct_stcpop_mu; /* select compare instruction in MU stage */
assign vct_stcpop_mu = ( vct_instfunc_mu == `VLT ) || ( vct_instfunc_mu == `VEQ ) ||
( vct_instfunc_mu == `VNE ) || ( vct_instfunc_mu == `VGE ) ||
( vct_instfunc_mu == `VCH ) || ( vct_instfunc_mu == `VCR ) ||
( vct_instfunc_mu == `VCL ) ;
/*
* The data to the vector unit control register is a timing critical path therefore valid
* is taken into account at the instruction decode level to eliminate it from the critical
* timing of the data.
*/
wire vct_stltop_mu; /* VS < VT select instruction in MU stage */
assign vct_stltop_mu = vct_instvld_mu && ( vct_instfunc_mu == `VLT ) ;
wire vct_steqop_mu; /* VS == VT select instruction in MU stage */
assign vct_steqop_mu = vct_instvld_mu && ( vct_instfunc_mu == `VEQ ) ;
wire vct_stneop_mu; /* VS != VT select instruction in MU stage */
assign vct_stneop_mu = vct_instvld_mu && ( vct_instfunc_mu == `VNE ) ;
wire vct_stgeop_mu; /* VS >= VT select instruction in MU stage */
assign vct_stgeop_mu = vct_instvld_mu && ( vct_instfunc_mu == `VGE ) ;
/*
* The signals vct_stchop_mu, vct_stclop_mu and vct_stcrop_mu are decoded in the
* RD stage and then register so that they available early in the cycle for
* generating the vct_aluctl_mu and vct_alucin_mu signals. They need to be gated
* with vct_instvld_mu since su_instvld_rd does not taken into account killed
* instructions because of timing reasons.
*/
wire vct_stchop_rd; /* -VT <= VS <= VT select instruction 2's comp single precison */
wire vct_stchoprg_mu; /* -VT <= VS <= VT select instruction 2's comp single precison */
wire vct_stchop_mu; /* -VT <= VS <= VT select instruction 2's comp single precison */
assign vct_stchop_rd = su_instvld_rd && ( su_instfunc_rd == `VCH ) ;
asdff #(1, 0) vctstchopffmu (vct_stchoprg_mu, vct_stchop_rd, clk, reset_l );
assign vct_stchop_mu = vct_instvld_mu && vct_stchoprg_mu ;
wire vct_stchrop_rd; /* -VT <= VS <= VT select instruction 2's or 1's comp */
wire vct_stchroprg_mu; /* -VT <= VS <= VT select instruction 2's or 1's comp */
wire vct_stchrop_mu; /* -VT <= VS <= VT select instruction 2's or 1's comp */
assign vct_stchrop_rd = su_instvld_rd && ( vct_stchop_rd || vct_stcrop_rd ) ;
asdff #(1, 0) vctstchropffmu (vct_stchroprg_mu, vct_stchrop_rd, clk, reset_l );
assign vct_stchrop_mu = vct_instvld_mu && vct_stchroprg_mu ;
wire vct_stclop_rd; /* -VT<=VS<=VT select instruction 2's comp double precision*/
wire vct_stcloprg_mu; /* -VT<=VS<=VT select instruction 2's comp double precision*/
wire vct_stclop_mu; /* -VT<=VS<=VT select instruction 2's comp double precision*/
assign vct_stclop_rd = su_instvld_rd && ( su_instfunc_rd == `VCL ) ;
asdff #(1, 0) vctstclopffmu (vct_stcloprg_mu, vct_stclop_rd, clk, reset_l );
assign vct_stclop_mu = vct_instvld_mu && vct_stcloprg_mu ;
wire vct_stcroprg_mu; /* -VT<=VS<=VT select instruction 1's comp */
wire vct_stcrop_mu; /* -VT<=VS<=VT select instruction 1's comp */
asdff #(1, 0) vctstcropffmu (vct_stcroprg_mu, vct_stcrop_rd, clk, reset_l );
assign vct_stcrop_mu = vct_instvld_mu && vct_stcroprg_mu ;
wire vct_stmrgop_mu; /* MERGE select instruction in MU stage */
assign vct_stmrgop_mu = ( vct_instfunc_mu == `VMRG ) ;
/*
* Instruction decoding for adds and subtracts in MU stage.
*/
wire vct_addcop_mu; /* ADDC instruction in MU */
assign vct_addcop_mu = ( vct_instfunc_mu == `VADDC ) ;
wire vct_addop_rd; /* ADD instruction in RD */
wire vct_addop_mu; /* ADD instruction in MU */
wire vct_addop_ac; /* ADD instruction in AC */
assign vct_addop_rd = ( su_instfunc_rd == `VADD ) ;
asdffen #(1, 0) vctaddopffmu (vct_addop_mu, vct_addop_rd, su_instvld_rd, clk, reset_l );
asdffen #(1, 0) vctaddopffac (vct_addop_ac, vct_addop_mu, vct_instvld_mu, clk, reset_l );
wire vct_subcop_mu; /* SUBC instruction in MU */
assign vct_subcop_mu = ( vct_instfunc_mu == `VSUBC ) ;
wire vct_addspop_mu; /* Single precision add/sub instruction in MU */
assign vct_addspop_mu = ( vct_instfunc_mu == `VADD ) ||
( vct_instfunc_mu == `VSUB ) ;
wire vct_subop_rd; /* SUB instruction in RD */
wire vct_subop_mu; /* SUB instruction in MU */
wire vct_subop_ac; /* SUB instruction in AC */
assign vct_subop_rd = ( su_instfunc_rd == `VSUB ) ;
asdffen #(1, 0) vctsubopffmu (vct_subop_mu, vct_subop_rd, su_instvld_rd, clk, reset_l );
asdffen #(1, 0) vctsubopffac (vct_subop_ac, vct_subop_mu, vct_instvld_mu, clk, reset_l );
wire vct_substclop_rd; /* sub or -VT<=VS<=VT select op 2's comp double precision*/
wire vct_substclop_mu; /* sub or -VT<=VS<=VT select op 2's comp double precision*/
assign vct_substclop_rd = vct_stclop_rd || vct_subop_rd ;
asdffen #(1, 0) vctsubstclopffmu (vct_substclop_mu, vct_substclop_rd, su_instvld_rd, clk, reset_l );
/*
* Instruction decoding for multiplies in MU stage.
*/
wire vct_mulfop_mu ; /* MULF instruction in MU stage. */
wire vct_macfop_mu ; /* MACF instruction in MU stage. */
wire vct_muluop_mu ; /* MULU instruction in MU stage. */
wire vct_macuop_mu ; /* MACU instruction in MU stage. */
wire vct_mulqop_mu ; /* MULQ instruction in MU stage. */
wire vct_macqop_mu ; /* MACQ instruction in MU stage. */
wire vct_mudlop_mu ; /* MUDL instruction in MU stage. */
wire vct_madlop_mu ; /* MADL instruction in MU stage. */
wire vct_mudmop_mu ; /* MUDM instruction in MU stage. */
wire vct_madmop_mu ; /* MADM instruction in MU stage. */
wire vct_mudnop_mu ; /* MUDN instruction in MU stage. */
wire vct_madnop_mu ; /* MADN instruction in MU stage. */
wire vct_mudhop_mu ; /* MUDH instruction in MU stage. */
wire vct_madhop_mu ; /* MADH instruction in MU stage. */
assign vct_mulfop_mu = ( vct_instfunc_mu == `VMULF ) ;
assign vct_macfop_mu = ( vct_instfunc_mu == `VMACF ) ;
assign vct_muluop_mu = ( vct_instfunc_mu == `VMULU ) ;
assign vct_macuop_mu = ( vct_instfunc_mu == `VMACU ) ;
assign vct_mulqop_mu = ( vct_instfunc_mu == `VMULQ ) ;
assign vct_macqop_mu = ( vct_instfunc_mu == `VMACQ ) ;
assign vct_mudlop_mu = ( vct_instfunc_mu == `VMUDL ) ;
assign vct_madlop_mu = ( vct_instfunc_mu == `VMADL ) ;
assign vct_mudmop_mu = ( vct_instfunc_mu == `VMUDM ) ;
assign vct_madmop_mu = ( vct_instfunc_mu == `VMADM ) ;
assign vct_mudnop_mu = ( vct_instfunc_mu == `VMUDN ) ;
assign vct_madnop_mu = ( vct_instfunc_mu == `VMADN ) ;
assign vct_mudhop_mu = ( vct_instfunc_mu == `VMUDH ) ;
assign vct_madhop_mu = ( vct_instfunc_mu == `VMADH ) ;
wire vct_multtypop_mu; /* Multiply type instruction not MACQ in MU stage. */
assign vct_multtypop_mu = vct_mulfop_mu || vct_macfop_mu ||
vct_muluop_mu || vct_macuop_mu ||
vct_mulqop_mu ||
vct_mudlop_mu || vct_madlop_mu ||
vct_mudmop_mu || vct_madmop_mu ||
vct_mudnop_mu || vct_madnop_mu ||
vct_mudhop_mu || vct_madhop_mu ;
wire vct_vs_sgnmu_mu; /* Multiply instruction with operand s signed */
assign vct_vs_sgnmu_mu = vct_mulfop_mu || vct_macfop_mu ||
vct_muluop_mu || vct_macuop_mu ||
vct_mulqop_mu || vct_macqop_mu ||
vct_mudmop_mu || vct_madmop_mu ||
vct_mudhop_mu || vct_madhop_mu ;
wire vct_vt_sgnmu_mu; /* Multiply instruction with operand t signed */
assign vct_vt_sgnmu_mu = vct_mulfop_mu || vct_macfop_mu ||
vct_muluop_mu || vct_macuop_mu ||
vct_mulqop_mu || vct_macqop_mu ||
vct_mudnop_mu || vct_madnop_mu ||
vct_mudhop_mu || vct_madhop_mu ;
wire vct_rndpop_mu; /* RNDP op in MU stage */
wire vct_rndnop_mu; /* RNDN op in MU stage */
wire vct_rndop_mu; /* Round op in MU stage */
wire vct_rndop_ac; /* Round op in AC stage */
assign vct_rndpop_mu = ( vct_instfunc_mu == `VRNDP ) ;
assign vct_rndnop_mu = ( vct_instfunc_mu == `VRNDN ) ;
assign vct_rndop_mu = vct_rndpop_mu || vct_rndnop_mu ;
asdffen #(1, 0) vctrndopac (vct_rndop_ac, vct_rndop_mu, vct_instvld_mu, clk, reset_l );
wire vct_dvnomovop_mu; /* Divide type op other than move in MU */
wire vct_dvnomovop_ac; /* Divide type op other than move in AC */
wire vct_divrsltsl_wb; /* Divide type op other than move in WB */
assign vct_dvnomovop_mu = ( vct_instfunc_mu == `VRCP ) || ( vct_instfunc_mu == `VRCPL ) ||
( vct_instfunc_mu == `VRCPH ) || ( vct_instfunc_mu == `VRSQ ) ||
( vct_instfunc_mu == `VRSQL ) || ( vct_instfunc_mu == `VRSQH ) ;
asdffen #(1, 0) vctdvnomovopac (vct_dvnomovop_ac, vct_dvnomovop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctdivrsltslwb (vct_divrsltsl_wb, vct_dvnomovop_ac, vct_instvld_ac, clk, reset_l );
wire vct_dvmovop_mu; /* Divide move op in MU */
wire vct_dvmovop_ac; /* Divide move op in AC */
assign vct_dvmovop_mu = ( vct_instfunc_mu == `VMOV ) ;
asdffen #(1, 0) vctdvmovopac (vct_dvmovop_ac, vct_dvmovop_mu, vct_instvld_mu, clk, reset_l );
wire vct_dvtypop_mu; /* divide or move type instruction in MU */
assign vct_dvtypop_mu = vct_dvnomovop_mu || vct_dvmovop_mu;
asdffen #(1, 0) vctdvtypopac (vct_dvtypop_ac, vct_dvtypop_mu, vct_instvld_mu, clk, reset_l );
/*
* Instruction decoding to determine loading of Vector carry out and vector compare code
* registers other than explicit move to control instruction.
*/
wire vct_cryoutld_mu; /* Load enable for vector carry out/equal register */
assign vct_cryoutld_mu = ( vct_instvld_mu &&
( vct_addcop_mu || vct_subcop_mu || /* actual setting of VCO bits */
vct_addspop_mu || vct_stcpop_mu || /* Clear VCO on select instructions */
vct_stmrgop_mu
)
) ||
su_wrcryout_wb ;
wire vct_cmpcdld_mu; /* Load enable for vector compare code register */
assign vct_cmpcdld_mu = ( vct_instvld_mu && vct_stcpop_mu ) || su_wrcmpcd_wb ;
wire vct_cmpcdadld_mu; /* Load enable for vector compare add register */
assign vct_cmpcdadld_mu = ( vct_instvld_mu &&
( vct_stcrop_mu || vct_stchop_mu || vct_stclop_mu )
) ||
su_wrcmpcdad_wb ;
/*
* The following is the code for the instruction decode in the
* AC stage.
*/
wire vct_absop_ac; /* ABS instruction in AC stage. */
asdffen #(1, 0) vctabsopffac (vct_absop_ac, vct_absop_mu, vct_instvld_mu, clk, reset_l );
wire vct_stcpop_ac; /* select compare/merge instruction in AC stage. */
assign vct_stcpop_ac = ( vct_instfunc_ac == `VLT ) || ( vct_instfunc_ac == `VEQ ) ||
( vct_instfunc_ac == `VNE ) || ( vct_instfunc_ac == `VGE ) ||
( vct_instfunc_ac == `VCH ) || ( vct_instfunc_ac == `VCR ) ||
( vct_instfunc_ac == `VCL ) || ( vct_instfunc_ac == `VMRG ) ;
wire vct_stchop_ac; /* -VT<=VS<=VT select op 2's comp single precison */
asdffen #(1, 0) vctstchopffac (vct_stchop_ac, vct_stchop_mu, vct_instvld_mu, clk, reset_l );
wire vct_stclop_ac; /* -VT<=VS<=VT select op 2's comp double precision*/
asdffen #(1, 0) vctstclopffac (vct_stclop_ac, vct_stclop_mu, vct_instvld_mu, clk, reset_l );
wire vct_stnclrdop_ac; /* Select instruction that is not CL, CLD or CR */
assign vct_stnclrdop_ac = ( vct_instfunc_ac == `VLT ) || ( vct_instfunc_ac == `VEQ ) ||
( vct_instfunc_ac == `VNE ) || ( vct_instfunc_ac == `VGE ) ||
( vct_instfunc_ac == `VMRG ) ;
wire vct_stclrdop_ac; /* Select instruction that is CL, CLD or CR */
assign vct_stclrdop_ac = ( vct_instfunc_ac == `VCH ) || ( vct_instfunc_ac == `VCL ) ||
( vct_instfunc_ac == `VCR ) ;
wire vct_mulfop_ac ; /* MULF instruction in AC stage. */
wire vct_macfop_ac ; /* MACF instruction in AC stage. */
wire vct_muluop_ac ; /* MULU instruction in AC stage. */
wire vct_macuop_ac ; /* MACU instruction in AC stage. */
wire vct_rndpop_ac ; /* RNDP instruction in AC stage. */
wire vct_rndnop_ac ; /* RNDN instruction in AC stage. */
wire vct_mulqop_ac ; /* MULQ instruction in AC stage. */
wire vct_macqop_ac ; /* MACQ instruction in AC stage. */
wire vct_mudlop_ac ; /* MUDL instruction in AC stage. */
wire vct_madlop_ac ; /* MADL instruction in AC stage. */
wire vct_mudmop_ac ; /* MUDM instruction in AC stage. */
wire vct_madmop_ac ; /* MADM instruction in AC stage. */
wire vct_mudnop_ac ; /* MUDN instruction in AC stage. */
wire vct_madnop_ac ; /* MADN instruction in AC stage. */
wire vct_mudhop_ac ; /* MUDH instruction in AC stage. */
wire vct_madhop_ac ; /* MADH instruction in AC stage. */
/*
* To improve timing many of the instruction decode signals are decoded in
* the multiply stage and piped along to the accumulator stage.
*/
asdffen #(1, 0) vctmulfopffac (vct_mulfop_ac, vct_mulfop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmacfopffac (vct_macfop_ac, vct_macfop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmuluopffac (vct_muluop_ac, vct_muluop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmacuopffac (vct_macuop_ac, vct_macuop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctrndpopffac (vct_rndpop_ac, vct_rndpop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctrndnopffac (vct_rndnop_ac, vct_rndnop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmulqopffac (vct_mulqop_ac, vct_mulqop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmacqopffac (vct_macqop_ac, vct_macqop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmudlopffac (vct_mudlop_ac, vct_mudlop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmadlopffac (vct_madlop_ac, vct_madlop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmudmopffac (vct_mudmop_ac, vct_mudmop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmadmopffac (vct_madmop_ac, vct_madmop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmudnopffac (vct_mudnop_ac, vct_mudnop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmadnopffac (vct_madnop_ac, vct_madnop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmudhopffac (vct_mudhop_ac, vct_mudhop_mu, vct_instvld_mu, clk, reset_l );
asdffen #(1, 0) vctmadhopffac (vct_madhop_ac, vct_madhop_mu, vct_instvld_mu, clk, reset_l );
/*
* Use multiply type op signal from the MU stage.
*/
wire vct_multtypop_ac; /* Multiply type op other than MACQ in AC */
asdffen #(1, 0) vctmulttypopffac (vct_multtypop_ac, vct_multtypop_mu, vct_instvld_mu, clk, reset_l );
wire vct_multndlop_mu; /* Multiply type op other than MACQ in MU */
wire vct_multndlop_ac; /* Multiply type op other than MACQ in AC */
assign vct_multndlop_mu = vct_mulfop_mu || vct_macfop_mu ||
vct_muluop_mu || vct_macuop_mu ||
vct_mulqop_mu ||
vct_mudmop_mu || vct_madmop_mu ||
vct_mudnop_mu || vct_madnop_mu ||
vct_mudhop_mu || vct_madhop_mu ;
asdffen #(1, 0) vctmultndlopffac (vct_multndlop_ac, vct_multndlop_mu, vct_instvld_mu, clk, reset_l );
wire vct_multactyp_mu; /* MACF, MACU, MADL, MADM, MADN, RNDP and RNDP type ops */
wire vct_multactyp_ac; /* MACF, MACU, MADL, MADM, MADN, RNDP and RNDP type ops */
assign vct_multactyp_mu = ( vct_macfop_mu || vct_macuop_mu ||
vct_madlop_mu || vct_madmop_mu ||
vct_madnop_mu || vct_rndpop_mu || vct_rndnop_mu
) ;
asdffen #(1, 0) vctmultactypopffac (vct_multactyp_ac, vct_multactyp_mu, vct_instvld_mu, clk, reset_l );
wire vct_multincop_mu; /* MACF, MACU, MADL, MADM and MADN type ops */
wire vct_multincop_ac; /* MACF, MACU, MADL, MADM and MADN type ops */
assign vct_multincop_mu = ( vct_macfop_mu || vct_macuop_mu ||
vct_madlop_mu || vct_madmop_mu ||
vct_madnop_mu
) ;
asdffen #(1, 0) vctmultincopffac (vct_multincop_ac, vct_multincop_mu, vct_instvld_mu, clk, reset_l );
wire vct_sarop_ac; /* SAR instruction in AC stage. */
assign vct_sarop_ac = vct_instfunc_ac == `VSAR ;
wire vct_addtypop_ac; /* Add type instruction in the AC stage */
assign vct_addtypop_ac = ( vct_instfunc_ac == `VADD ) || ( vct_instfunc_ac == `VSUB ) ||
( vct_instfunc_ac == `VADDC ) || ( vct_instfunc_ac == `VSUBC ) ||
( vct_instfunc_ac == `VABS ) ;
wire vct_logtypop_ac; /* logical type instruction in the WB stage */
assign vct_logtypop_ac = ( vct_instfunc_ac == `VAND ) || ( vct_instfunc_ac == `VNAND ) ||
( vct_instfunc_ac == `VOR ) || ( vct_instfunc_ac == `VNOR ) ||
( vct_instfunc_ac == `VXOR ) || ( vct_instfunc_ac == `VXNOR ) ;
/*
* The next group are output control signals for the
* multiply stage of the vector unit datapath.
*/
/*
* This code does the decoding of the instructions for generation of the selection
* between the various logical and add functions. The control that is data
* dependent such as on input signs is generated in vusl.
*/
wire [2:0] vct_aluctl_mu; /* control for selecting alu function */
assign vct_aluctl_mu[0] = vct_vandop_mu || vct_vorop_mu ||
vct_vxorop_mu || vct_rndop_mu ;
assign vct_aluctl_mu[1] = vct_vnandop_mu || vct_vorop_mu ||
vct_vxnorop_mu || vct_rndop_mu ;
assign vct_aluctl_mu[2] = vct_vnorop_mu || vct_vxorop_mu ||
vct_vxnorop_mu || vct_rndop_mu ;
assign vct_aluctl0_mu = vct_aluctl_mu ;
assign vct_aluctl1_mu = vct_aluctl_mu ;
/*
* Control for complementing the VT data for ALU subtracts and compares in the MU stage.
*/
wire vct_alucmpvt_rd; /* complement vt for subtact in ALU in RD stage */
wire vct_pralucmpvt_mu; /* complement vt for subtact in ALU in MU stage */
assign vct_alucmpvt_rd = vct_sbtypop_rd || vct_stgelcpop_rd ;
asdffen #(1, 0) vctalucmpvtffmu (vct_pralucmpvt_mu, vct_alucmpvt_rd, su_instvld_rd, clk, reset_l );
wire vct_aluprecin_rd; /* carry in to alu decoded subtract instructions */
assign vct_aluprecin_rd = vct_subcop_rd || vct_stgelcpop_rd ||
vct_stcrop_rd ;
/* for one's complement VS+VT+1<=0 or VS-VT>=0 */
/*
* The next portion of code handles the move from CP2 control registers by muxing between
* the vector compare code register, vector carry out register and the data from the
* store data port of the register file of vector 0. The store data port also provides the
* data for the move from CP2 registers.
*/
wire vct_cmpcdhi0_ac; /* high bit from Vector Compare code register - vector 0 */
wire vct_cmpcdhi1_ac; /* high bit from Vector Compare code register - vector 1 */
wire vct_cmpcdlo0_ac; /* low bit from Vector Compare code register - vector 0 */
wire vct_cmpcdlo1_ac; /* low bit from Vector Compare code register - vector 1 */
wire vct_cmpcdad0_ac; /* Flag for Vector Compare Add register - vector 0 */
wire vct_cmpcdad1_ac; /* Flag for Vector Compare Add register - vector 1 */
wire vct_opdneql0_ac; /* operands not equal flag from Vector Carry out register - vector 0 */
wire vct_opdneql1_ac; /* operands not equal flag from Vector Carry out register - vector 1 */
wire vct_cryout0_ac; /* carry out flag from Vector Carry out register - vector 0 */
wire vct_cryout1_ac; /* carry out flag from Vector Carry out register - vector 1 */
wire su_rdcmpcd_mu; /* read vector compare code register */
wire su_rdcryout_mu; /* read vector carry out register */
wire su_rdcmpcdad_mu; /* read vector compare add register */
wire [3:0] vct_contbus_mu; /* output control bus to tristate drivers */
wire vct_contbusen_mu; /* output enable to tristate drivers */
asdff #(1, 0) vctrdcmpcdffmu (su_rdcmpcd_mu, su_rdcmpcd_rd, clk, reset_l );
asdff #(1, 0) vctrdcryoutffmu (su_rdcryout_mu, su_rdcryout_rd, clk, reset_l );
asdff #(1, 0) vctrdcmpcdadffmu (su_rdcmpcdad_mu, su_rdcmpcdad_rd, clk, reset_l );
/* The following code was replaced with instantiated gates so that I could control
* the 3 state output driver and timing through the mux.
*/
/* This code was replaced by instantiated muxes for timing reasons.
*
* assign vct_contbus_mu = su_rdcryout_mu ?
* {
* vct_opdneql1_ac,vct_opdneql0_ac,
* vct_cryout1_ac,vct_cryout0_ac
* }
* : su_rdcmpcdad_mu ?
* {
* 2'h0,
* vct_cmpcdad1_ac,vct_cmpcdad0_ac
* }
* :
* {
* vct_cmpcdhi1_ac,vct_cmpcdhi0_ac,
* vct_cmpcdlo1_ac,vct_cmpcdlo0_ac
* } ;
*
*/
wire [3:0] vct_contbusin_ac; /* output of mux selecting between VCA and VCC */
mx21d1 vctcontbusmx0mu ( .z (vct_contbus_mu[0]),
.i0 (vct_contbusin_ac[0]),
.i1 (vct_cryout0_ac),
.s (su_rdcryout_mu)
) ;
mx21d1 vctcontbusmx1mu ( .z (vct_contbus_mu[1]),
.i0 (vct_contbusin_ac[1]),
.i1 (vct_cryout1_ac),
.s (su_rdcryout_mu)
) ;
mx21d1 vctcontbusmx2mu ( .z (vct_contbus_mu[2]),
.i0 (vct_contbusin_ac[2]),
.i1 (vct_opdneql0_ac),
.s (su_rdcryout_mu)
) ;
mx21d1 vctcontbusmx3mu ( .z (vct_contbus_mu[3]),
.i0 (vct_contbusin_ac[3]),
.i1 (vct_opdneql1_ac),
.s (su_rdcryout_mu)
) ;
mx21d1 vctcontbusin0mu ( .z (vct_contbusin_ac[0]),
.i0 (vct_cmpcdlo0_ac),
.i1 (vct_cmpcdad0_ac),
.s (su_rdcmpcdad_mu)
) ;
mx21d1 vctcontbusin1mu ( .z (vct_contbusin_ac[1]),
.i0 (vct_cmpcdlo1_ac),
.i1 (vct_cmpcdad1_ac),
.s (su_rdcmpcdad_mu)
) ;
assign vct_contbusin_ac[2] = vct_cmpcdhi0_ac && !su_rdcmpcdad_mu ;
assign vct_contbusin_ac[3] = vct_cmpcdhi1_ac && !su_rdcmpcdad_mu ;
assign vct_contbusen_mu = su_rdcryout_mu || su_rdcmpcdad_mu || su_rdcmpcd_mu ;
nt01d5 vctcontbus0nt (
.z (su_cont_to_from[0]),
.oe (vct_contbusen_mu),
.i (vct_contbus_mu[0])
) ;
nt01d5 vctcontbus1nt (
.z (su_cont_to_from[1]),
.oe (vct_contbusen_mu),
.i (vct_contbus_mu[1])
) ;
nt01d5 vctcontbus2nt (
.z (su_cont_to_from[2]),
.oe (vct_contbusen_mu),
.i (vct_contbus_mu[2])
) ;
nt01d5 vctcontbus3nt (
.z (su_cont_to_from[3]),
.oe (vct_contbusen_mu),
.i (vct_contbus_mu[3])
) ;
wire [1:0] vct_couprsl_mu; /* select for multiply upper carry out vector */
assign vct_couprsl_mu[0] = !reset_l ||
( vct_instvld_mu && vct_multtypop_mu ) ||
( vct_instvld_mu && vct_dvtypop_mu ) ; // zero value for MOVE
assign vct_couprsl_mu[1] = !reset_l ||
( vct_instvld_mu && !vct_multtypop_mu ) ;
assign vct_couprsl0_mu = vct_couprsl_mu ;
assign vct_couprsl1_mu = vct_couprsl_mu ;
wire [1:0] vct_smuprsl_mu; /* select for multiply upper sum out vector */
assign vct_smuprsl_mu[0] = !reset_l ||
( vct_instvld_mu && vct_multtypop_mu ) ||
( vct_instvld_mu && !vct_multtypop_mu &&
!( vct_stcpop_mu || vct_stmrgop_mu )
) ;
assign vct_smuprsl_mu[1] = !reset_l ||
( vct_instvld_mu &&
( vct_stcpop_mu || vct_stmrgop_mu )
) ||
( vct_instvld_mu && !vct_multtypop_mu &&
!( vct_stcpop_mu || vct_stmrgop_mu )
) ;
assign vct_smuprsl0_mu = vct_smuprsl_mu ;
assign vct_smuprsl1_mu = vct_smuprsl_mu ;
wire [1:0] vct_colwrsl_mu; /* selects for multiply lower carry out register */
assign vct_colwrsl_mu[0] = !reset_l ||
( vct_instvld_mu && vct_multtypop_mu ) ||
( vct_instvld_mu && vct_dvtypop_mu ) ; // zero value for MOVE
assign vct_colwrsl_mu[1] = !reset_l ||
( vct_instvld_mu && !vct_multtypop_mu ) ; // zero value for MOVE
assign vct_colwrsl0_mu = vct_colwrsl_mu ;
assign vct_colwrsl1_mu = vct_colwrsl_mu ;
/*
* We need unique selects for low sum register to handle the case
* of VS=0 for VABS instruction.
*/
wire [1:0] vct_prsmlwrsl_mu; /* selects for multiply lower sum out all vectors */
assign vct_prsmlwrsl_mu[0] = ( vct_instvld_mu && vct_multtypop_mu ) ;
assign vct_prsmlwrsl_mu[1] = vct_stcpop_mu || vct_stmrgop_mu || vct_dvtypop_mu ;
/* select or merge or divide op */
/*
* Control signals for the multiplier are decoded in the RD stage and then registered for timing
* reasons.
*/
/*
* Easier to figure out if operand should be unsigned and then complement to produce control signal.
*/
wire vct_sgnmplr_rd; /* signed multiplier */
assign vct_sgnmplr_rd = !( ( su_instfunc_rd == `VMUDL ) || ( su_instfunc_rd == `VMADL ) ||
( su_instfunc_rd == `VMUDN ) || ( su_instfunc_rd == `VMADN )
) ;
asdffen #(1, 0) vctsgnmplrffmu (vct_sgnmplr_mu, vct_sgnmplr_rd, su_instvld_rd, clk, reset_l );
/*
* Easier to figure out if operand should be unsigned and then complement to produce control signal.
*/
wire vct_sgnmplcnd_rd; /* signed multiplicand */
assign vct_sgnmplcnd_rd = !( ( su_instfunc_rd == `VMUDL ) || ( su_instfunc_rd == `VMADL ) ||
( su_instfunc_rd == `VMUDM ) || ( su_instfunc_rd == `VMADM )
) ;
asdffen #(1, 0) vctsgnmplcndffmu (vct_sgnmplcnd_mu, vct_sgnmplcnd_rd, su_instvld_rd, clk, reset_l );
wire vct_shftlftone_rd; /* shift left by 1 for MULF, MACF, MULU, MACU */
wire vct_shftlftone_mu; /* shift left by 1 for MULF, MACF, MULU, MACU */
assign vct_shftlftone_rd = ( su_instfunc_rd == `VMULF ) || ( su_instfunc_rd == `VMACF ) ||
( su_instfunc_rd == `VMULU ) || ( su_instfunc_rd == `VMACU ) ;
asdffen #(1, 0) vctshftlftoneffmu (vct_shftlftone_mu, vct_shftlftone_rd, su_instvld_rd, clk, reset_l );
assign vct_shftlftone0_mu = vct_shftlftone_mu ;
assign vct_shftlftone1_mu = vct_shftlftone_mu ;
/*
* The next group are output control signals for the
* accumulate stage of the vector unit datapath.
*/
wire [1:0] vct_cslwasl_mu; /* MU stage mux select signals for input a of lower CSA */
wire [1:0] vct_cslwasl_ac; /* AC stage mux select signals for input a of lower CSA */
assign vct_cslwasl_mu[0] = vct_macfop_mu || vct_macuop_mu ||
vct_rndpop_mu || vct_rndnop_mu ||
vct_madlop_mu || vct_madmop_mu ||
vct_madnop_mu ||
vct_mulfop_mu || vct_muluop_mu ||
vct_mulqop_mu ;
assign vct_cslwasl_mu[1] = vct_macqop_mu || vct_madhop_mu ||
vct_mulfop_mu || vct_muluop_mu ||
vct_mulqop_mu ;
asdffen #(2, 0) vctprcslwaslrgac (vct_cslwasl_ac, vct_cslwasl_mu, vct_instvld_mu, clk, reset_l );
assign vct_cslwasl0_ac = vct_cslwasl_ac ;
assign vct_cslwasl1_ac = vct_cslwasl_ac ;
/*
* Unless it is a multiply or round instruction then the above mux produces zero to
* allow the data from the registers to be passed through the accumulate adder.
*/
wire vct_precslwb_mu; /* MU stage mux select signals for input b of lower CSA */
wire [2:0] vct_prcslwbsl_mu; /* MU stage mux select signals for input b of lower CSA */
wire [2:0] vct_prcslwbsl_ac; /* AC stage mux select signals for input b of lower CSA */
assign vct_precslwb_mu = vct_mudlop_mu || vct_madlop_mu ||
( !vct_macqop_mu && !vct_rndpop_mu && !vct_rndnop_mu &&
!vct_absop_mu && !vct_stcpop_mu && !vct_stmrgop_mu &&
!vct_mudlop_mu && !vct_madlop_mu
) ;
assign vct_prcslwbsl_mu[0] = ( vct_rndpop_mu && !vct_vseqone_mu ) ||
vct_precslwb_mu ;
assign vct_prcslwbsl_mu[1] = ( vct_rndnop_mu && !vct_vseqone_mu ) ||
vct_precslwb_mu ;
assign vct_prcslwbsl_mu[2] = vct_macqop_mu || vct_mudlop_mu || vct_madlop_mu ;
asdffen #(3, 0) vctcslwbslrgac (vct_prcslwbsl_ac, vct_prcslwbsl_mu, vct_instvld_mu, clk, reset_l );
wire vct_cslwcsl_mu; /* select for input c of lower csa all vectors */
wire vct_cslwcsl_ac; /* select for input c of lower csa all vectors */
assign vct_cslwcsl_mu = vct_mudlop_mu || vct_madlop_mu ;
asdffen #(1, 0) vctcslwcslffac (vct_cslwcsl_ac, vct_cslwcsl_mu, vct_instvld_mu, clk, reset_l );
assign vct_cslwcsl0_ac = vct_cslwcsl_ac ;
assign vct_cslwcsl1_ac = vct_cslwcsl_ac ;
wire [1:0] vct_csupasl_mu; /* MU stage mux select signals for input a of upper CSA */
wire [1:0] vct_csupasl_ac; /* AC stage mux select signals for input a of upper CSA */
assign vct_csupasl_mu[0] = vct_macfop_mu || vct_macuop_mu ||
vct_rndpop_mu || vct_rndnop_mu ||
vct_madlop_mu || vct_madmop_mu ||
vct_madnop_mu ;
assign vct_csupasl_mu[1] = vct_macqop_mu || vct_madhop_mu ;
asdffen #(2, 0) vctcsupaslffac (vct_csupasl_ac, vct_csupasl_mu, vct_instvld_mu, clk, reset_l );
assign vct_csupasl0_ac = vct_csupasl_ac ;
assign vct_csupasl1_ac = vct_csupasl_ac ;
wire [1:0] vct_prcsupbsl_ac; /* AC stage mux select signals for input b of upper CSA */
assign vct_prcsupbsl_ac[0] = vct_multndlop_ac ;
assign vct_prcsupbsl_ac[1] = vct_macqop_ac ;
wire vct_prcsupcen_ac; /* pre decoding of input c enable for upper csa all vectors */
assign vct_prcsupcen_ac = !vct_cslwcsl_ac ;
/*
* assign vct_prcsupcen_ac = !(vct_mudlop_ac || vct_madlop_ac) ;
*/
wire [1:0] vct_praclwsl_ac; /* selects input for lower mux of accumulator all vectors */
assign vct_praclwsl_ac[0] = !vct_sarop_ac && !vct_stcpop_ac &&
!vct_mulqop_ac && !vct_macqop_ac && /* zero or hold due to << 16 */
!vct_mudhop_ac && !vct_madhop_ac ; /* zero or hold due to << 16 */
assign vct_praclwsl_ac[1] = vct_mulqop_ac || vct_mudhop_ac ; /* zero lower 16 bit due to << 16 */
/*
* This change was made to prevent the accumulator updating bits 16 to 47
* on instruction which do not load or accumulate ie. any now multiply
* instruction. This was to allow the upper 32 bits of the accumulator
* to be used for testin.
*
* assign vct_pracmisl_ac[0] = vct_sarop_ac ;
*/
wire [1:0] vct_acmisl_ac; /* selects input for middle mux of accumulator */
assign vct_acmisl_ac[0] = !reset_l ||
( vct_instvld_ac &&
( vct_mulfop_ac || vct_macfop_ac ||
vct_muluop_ac || vct_macuop_ac ||
vct_rndpop_ac || vct_rndnop_ac ||
vct_mudlop_ac || vct_madlop_ac ||
vct_mudmop_ac || vct_madmop_ac ||
vct_mudnop_ac || vct_madnop_ac
)
) ;
assign vct_acmisl_ac[1] = !reset_l ||
( vct_instvld_ac &&
( vct_mulqop_ac || vct_macqop_ac ||
vct_mudhop_ac || vct_madhop_ac
)
) ;
assign vct_acmisl0_ac = vct_acmisl_ac ;
assign vct_acmisl1_ac = vct_acmisl_ac ;
wire [1:0] vct_pracupsl_ac; /* selects input for upper mux of accumulator all vectors */
/*
* This change was made to prevent the accumulator updating bits 16 to 47
* on instruction which do not load or accumulate ie. any now multiply
* instruction. This was to allow the upper 32 bits of the accumulator
* to be used for testin.
*
* assign vct_pracupsl_ac[0] = vct_sarop_ac ;
*/
assign vct_pracupsl_ac[0] = ( vct_mulfop_ac || vct_muluop_ac ||
vct_mudlop_ac || vct_mudmop_ac ||
vct_mudnop_ac
) ;
assign vct_pracupsl_ac[1] = ( vct_mulqop_ac || vct_macqop_ac ||
vct_mudhop_ac || vct_madhop_ac
) ;
/*
* The next group are output control signals for the
* write back stage of the vector unit datapath.
*/
wire vct_acchighsl_ac; /* select high portion of accumulator */
wire vct_acchighsl_wb; /* select high portion of accumulator */
assign vct_acchighsl_ac = vct_sarop_ac && ( vct_instelem_ac == 4'h8) ;
asdffen #(1, 0) vctacchighslwb (vct_acchighsl_wb, vct_acchighsl_ac, vct_instvld_ac, clk, reset_l );
wire vct_accmidsl_ac; /* select mid portion of accumulator */
wire vct_accmidsl_wb; /* select mid portion of accumulator */
assign vct_accmidsl_ac = ( vct_sarop_ac && ( vct_instelem_ac == 4'h9) ) ||
vct_mulfop_ac || vct_macfop_ac ||
vct_muluop_ac || vct_macuop_ac ||
vct_rndpop_ac || vct_rndnop_ac ||
vct_mudmop_ac || vct_madmop_ac ||
vct_mudhop_ac || vct_madhop_ac ;
asdffen #(1, 0) vctaccmidslwb (vct_accmidsl_wb, vct_accmidsl_ac, vct_instvld_ac, clk, reset_l );
wire vct_acclowsl_ac; /* select low portion of accumulator */
wire vct_acclowsl_wb; /* select low portion of accumulator */
assign vct_acclowsl_ac = ( vct_sarop_ac && ( vct_instelem_ac == 4'ha) ) ||
vct_mudlop_ac || vct_madlop_ac ||
vct_mudnop_ac || vct_madnop_ac ||
vct_addtypop_ac || vct_stcpop_ac ||
vct_logtypop_ac || vct_dvmovop_ac ;
asdffen #(1, 0) vctacclowslwb (vct_acclowsl_wb, vct_acclowsl_ac, vct_instvld_ac, clk, reset_l );
/*
* Note that SAR instruction should be vct_sarop_wb && vct_instelem_wb[0] for
* reading the low portion of the accumulator but this is covered within the
* add instructions.
*/
wire vct_accshftsl_ac; /* select shifted high/mid portion of accumulator */
wire vct_accshftsl_wb; /* select shifted high/mid portion of accumulator */
assign vct_accshftsl_ac = ( vct_mulqop_ac || vct_macqop_ac ) ;
asdffen #(1, 0) vctaccshftslwb (vct_accshftsl_wb, vct_accshftsl_ac, vct_instvld_ac, clk, reset_l );
wire vct_clpsgn16_ac; /* instruction requiring signed clamping on 15 to 0 */
wire vct_clpsgn16_wb; /* instruction requiring signed clamping on 15 to 0 */
assign vct_clpsgn16_ac = vct_mudlop_ac || vct_madlop_ac ||
vct_mudnop_ac || vct_madnop_ac ;
asdffen #(1, 0) vctclpsgn16ffwb (vct_clpsgn16_wb, vct_clpsgn16_ac, vct_instvld_ac, clk, reset_l );
wire vct_clpsgn31_ac; /* instruction requiring signed clamping on 31 to MSB */
wire vct_clpsgn31_wb; /* instruction requiring signed clamping on 31 to MSB */
assign vct_clpsgn31_ac = vct_mulfop_ac || vct_macfop_ac ||
vct_rndpop_ac || vct_rndnop_ac ||
vct_mudmop_ac || vct_madmop_ac ||
vct_mudhop_ac || vct_madhop_ac ;
asdffen #(1, 0) vctclpsgn31ffwb (vct_clpsgn31_wb, vct_clpsgn31_ac, vct_instvld_ac, clk, reset_l );
wire vct_clpsgn32_ac; /* instruction requiring signed clamping on 32 to MSB */
wire vct_clpsgn32_wb; /* instruction requiring signed clamping on 32 to MSB */
assign vct_clpsgn32_ac = vct_mulqop_ac || vct_macqop_ac ;
asdffen #(1, 0) vctclpsgn32ffwb (vct_clpsgn32_wb, vct_clpsgn32_ac, vct_instvld_ac, clk, reset_l );
wire vct_clpuns31_ac; /* instruction requiring unsigned clamping on 31 to MSB */
wire vct_clpuns31_wb; /* instruction requiring unsigned clamping on 31 to MSB */
assign vct_clpuns31_ac = vct_muluop_ac || vct_macuop_ac ;
asdffen #(1, 0) vctclpuns31pffwb (vct_clpuns31_wb, vct_clpuns31_ac, vct_instvld_ac, clk, reset_l );
wire vct_adscl16op_ac; /* 16 bit ADD, SUB or ABS instruction in WB */
wire vct_adscl16op_wb; /* 16 bit ADD, SUB or ABS instruction in WB */
assign vct_adscl16op_ac = vct_addop_ac || vct_subop_ac || vct_absop_ac ;
asdffen #(1, 0) vctadscl16fopffwb (vct_adscl16op_wb, vct_adscl16op_ac, vct_instvld_ac, clk, reset_l );
vuctlsl vuctlsl0 ( .clk (clk),
.reset_l (reset_l),
.su_instvld_rd (su_instvld_rd),
.vct_pralucmpvt_mu (vct_pralucmpvt_mu),
.vct_instvld_mu (vct_instvld_mu),
.vct_addcop_mu (vct_addcop_mu),
.vct_subcop_mu (vct_subcop_mu),
.vct_addop_mu (vct_addop_mu),
.vct_subop_mu (vct_subop_mu),
.vct_vs_sgnmu_mu (vct_vs_sgnmu_mu),
.vct_vt_sgnmu_mu (vct_vt_sgnmu_mu),
.vct_stltop_mu (vct_stltop_mu),
.vct_steqop_mu (vct_steqop_mu),
.vct_stneop_mu (vct_stneop_mu),
.vct_stgeop_mu (vct_stgeop_mu),
.vct_stchop_mu (vct_stchop_mu),
.vct_stclop_mu (vct_stclop_mu),
.vct_stcrop_mu (vct_stcrop_mu),
.vct_stchrop_mu (vct_stchrop_mu),
.vct_substclop_mu (vct_substclop_mu),
.vct_absop_mu (vct_absop_mu),
.vct_rndpop_mu (vct_rndpop_mu),
.vct_rndnop_mu (vct_rndnop_mu),
.vct_rndop_mu (vct_rndop_mu),
.vct_mulqop_mu (vct_mulqop_mu),
.vct_mulfop_mu (vct_mulfop_mu),
.vct_muluop_mu (vct_muluop_mu),
.vct_vseqone_mu (vct_vseqone_mu),
.vct_aluprecin_rd (vct_aluprecin_rd),
.vct_cryoutld_mu (vct_cryoutld_mu),
.vct_cmpcdld_mu (vct_cmpcdld_mu),
.vct_cmpcdadld_mu (vct_cmpcdadld_mu),
.vdp_vs_zero_mu (vdp_vs_zero0_mu),
.vdp_vt_zero_mu (vdp_vt_zero0_mu),
.vdp_vs_sign_mu (vdp_vs_sign0_mu),
.vdp_vt_sign_mu (vdp_vt_sign0_mu),
.vdp_aluovr_mu (vdp_aluovr0_mu),
.vdp_aluco_mu (vdp_aluco0_mu),
.vdp_aluzero_mu (vdp_aluzero0_mu),
.vdp_aluone_mu (vdp_aluone0_mu),
.vct_prsmlwrsl_mu (vct_prsmlwrsl_mu),
.vct_instvld_ac (vct_instvld_ac),
.vct_prcslwbsl_ac (vct_prcslwbsl_ac),
.vct_prcsupbsl_ac (vct_prcsupbsl_ac),
.vct_prcsupcen_ac (vct_prcsupcen_ac),
.vct_stnclrdop_ac (vct_stnclrdop_ac),
.vct_stclrdop_ac (vct_stclrdop_ac),
.vct_stchop_ac (vct_stchop_ac),
.vct_stclop_ac (vct_stclop_ac),
.vct_macqop_ac (vct_macqop_ac),
.vct_mudlop_ac (vct_mudlop_ac),
.vct_madlop_ac (vct_madlop_ac),
.vct_mulfop_ac (vct_mulfop_ac),
.vct_muluop_ac (vct_muluop_ac),
.vct_rndpop_ac (vct_rndpop_ac),
.vct_rndnop_ac (vct_rndnop_ac),
.vct_rndop_ac (vct_rndop_ac),
.vct_multtypop_ac (vct_multtypop_ac),
.vct_absop_ac (vct_absop_ac),
.vct_vseqone_ac (vct_vseqone_ac),
.vdp_addlwco_ac (vdp_addlwco0_ac),
.vdp_addlwov_ac (vdp_addlwov0_ac),
.vdp_csupco_ac (vdp_csupco0_ac),
.vdp_addupco_ac (vdp_addupco0_ac),
.vmu_co_clal_ac (vmu_co_clal0_ac),
.vmu_co_clah_ac (vmu_co_clah0_ac),
.vct_praclwsl_ac (vct_praclwsl_ac),
.vct_pracupsl_ac (vct_pracupsl_ac),
.vct_multactyp_ac (vct_multactyp_ac),
.vct_multincop_ac (vct_multincop_ac),
.su_wrcmpcd_wb (su_wrcmpcd_wb),
.su_wrcryout_wb (su_wrcryout_wb),
.su_wrcmpcdad_wb (su_wrcmpcdad_wb),
.su_datainlo_wb (su_cont_to_from[0]),
.su_datainhi_wb (su_cont_to_from[2]),
.vdp_accbit15_wb (vdp_acc0bit15_wb),
.vdp_accbit21_wb (vdp_acc0bit21_wb),
.vdp_accbit31_wb (vdp_acc0bit31_wb),
.vdp_accbit47_wb (vdp_acc0bit47_wb),
.vdp_acchizero_wb (vdp_achizero0_wb),
.vdp_accmizero_wb (vdp_acmizero0_wb),
.vdp_acchione_wb (vdp_achione0_wb),
.vct_acchighsl_wb (vct_acchighsl_wb),
.vct_accmidsl_wb (vct_accmidsl_wb),
.vct_acclowsl_wb (vct_acclowsl_wb),
.vct_accshftsl_wb (vct_accshftsl_wb),
.vct_divrsltsl_wb (vct_divrsltsl_wb),
.vct_clpsgn31_wb (vct_clpsgn31_wb),
.vct_clpsgn16_wb (vct_clpsgn16_wb),
.vct_clpsgn32_wb (vct_clpsgn32_wb),
.vct_clpuns31_wb (vct_clpuns31_wb),
.vct_adscl16op_wb (vct_adscl16op_wb),
.vct_alucin_mu (vct_alucin0_mu),
.vct_alucmpvt_mu (vct_alucmpvt0_mu),
.vct_compvt_mu (vct_cmpvt0_mu),
.vct_smlwrsl_mu (vct_smlwrsl0_mu),
.vct_cryout_ac (vct_cryout0_ac),
.vct_opdneql_ac (vct_opdneql0_ac),
.vct_cmpcdlo_ac (vct_cmpcdlo0_ac),
.vct_cmpcdhi_ac (vct_cmpcdhi0_ac),
.vct_cmpcdad_ac (vct_cmpcdad0_ac),
.vct_rndvlu_ac (vct_rndvlu0_ac),
.vct_cslwbsl_ac (vct_cslwbsl0_ac),
.vct_addlwci_ac (vct_addlwci0_ac),
.vct_csupbsl_ac (vct_csupbsl0_ac),
.vct_csupcen_ac (vct_csupcen0_ac),
.vct_incrdwn_ac (vct_incrdwn0_ac),
.vct_incrci_ac (vct_incrci0_ac),
.vct_incrmxsl_ac (vct_incrmxsl0_ac),
.vct_aclwsl_ac (vct_aclwsl0_ac),
.vct_acupsl_ac (vct_acupsl0_ac),
.vct_rsltsl_wb (vct_rsltsl0_wb),
.vct_clprslt_wb (vct_clprslt0_wb)
);
vuctlsl vuctlsl1 ( .clk (clk),
.reset_l (reset_l),
.su_instvld_rd (su_instvld_rd),
.vct_pralucmpvt_mu (vct_pralucmpvt_mu),
.vct_instvld_mu (vct_instvld_mu),
.vct_addcop_mu (vct_addcop_mu),
.vct_subcop_mu (vct_subcop_mu),
.vct_addop_mu (vct_addop_mu),
.vct_subop_mu (vct_subop_mu),
.vct_vs_sgnmu_mu (vct_vs_sgnmu_mu),
.vct_vt_sgnmu_mu (vct_vt_sgnmu_mu),
.vct_stltop_mu (vct_stltop_mu),
.vct_steqop_mu (vct_steqop_mu),
.vct_stneop_mu (vct_stneop_mu),
.vct_stgeop_mu (vct_stgeop_mu),
.vct_stchop_mu (vct_stchop_mu),
.vct_stclop_mu (vct_stclop_mu),
.vct_stcrop_mu (vct_stcrop_mu),
.vct_stchrop_mu (vct_stchrop_mu),
.vct_substclop_mu (vct_substclop_mu),
.vct_absop_mu (vct_absop_mu),
.vct_rndpop_mu (vct_rndpop_mu),
.vct_rndnop_mu (vct_rndnop_mu),
.vct_rndop_mu (vct_rndop_mu),
.vct_mulqop_mu (vct_mulqop_mu),
.vct_mulfop_mu (vct_mulfop_mu),
.vct_muluop_mu (vct_muluop_mu),
.vct_vseqone_mu (vct_vseqone_mu),
.vct_aluprecin_rd (vct_aluprecin_rd),
.vct_cryoutld_mu (vct_cryoutld_mu),
.vct_cmpcdld_mu (vct_cmpcdld_mu),
.vct_cmpcdadld_mu (vct_cmpcdadld_mu),
.vdp_vs_zero_mu (vdp_vs_zero1_mu),
.vdp_vt_zero_mu (vdp_vt_zero1_mu),
.vdp_vs_sign_mu (vdp_vs_sign1_mu),
.vdp_vt_sign_mu (vdp_vt_sign1_mu),
.vdp_aluovr_mu (vdp_aluovr1_mu),
.vdp_aluco_mu (vdp_aluco1_mu),
.vdp_aluzero_mu (vdp_aluzero1_mu),
.vdp_aluone_mu (vdp_aluone1_mu),
.vct_prsmlwrsl_mu (vct_prsmlwrsl_mu),
.vct_instvld_ac (vct_instvld_ac),
.vct_prcslwbsl_ac (vct_prcslwbsl_ac),
.vct_prcsupbsl_ac (vct_prcsupbsl_ac),
.vct_prcsupcen_ac (vct_prcsupcen_ac),
.vct_stnclrdop_ac (vct_stnclrdop_ac),
.vct_stclrdop_ac (vct_stclrdop_ac),
.vct_stchop_ac (vct_stchop_ac),
.vct_stclop_ac (vct_stclop_ac),
.vct_macqop_ac (vct_macqop_ac),
.vct_mudlop_ac (vct_mudlop_ac),
.vct_madlop_ac (vct_madlop_ac),
.vct_mulfop_ac (vct_mulfop_ac),
.vct_muluop_ac (vct_muluop_ac),
.vct_rndpop_ac (vct_rndpop_ac),
.vct_rndnop_ac (vct_rndnop_ac),
.vct_rndop_ac (vct_rndop_ac),
.vct_multtypop_ac (vct_multtypop_ac),
.vct_absop_ac (vct_absop_ac),
.vct_vseqone_ac (vct_vseqone_ac),
.vdp_addlwco_ac (vdp_addlwco1_ac),
.vdp_addlwov_ac (vdp_addlwov1_ac),
.vdp_csupco_ac (vdp_csupco1_ac),
.vdp_addupco_ac (vdp_addupco1_ac),
.vmu_co_clal_ac (vmu_co_clal1_ac),
.vmu_co_clah_ac (vmu_co_clah1_ac),
.vct_praclwsl_ac (vct_praclwsl_ac),
.vct_pracupsl_ac (vct_pracupsl_ac),
.vct_multactyp_ac (vct_multactyp_ac),
.vct_multincop_ac (vct_multincop_ac),
.su_wrcmpcd_wb (su_wrcmpcd_wb),
.su_wrcryout_wb (su_wrcryout_wb),
.su_wrcmpcdad_wb (su_wrcmpcdad_wb),
.su_datainlo_wb (su_cont_to_from[1]),
.su_datainhi_wb (su_cont_to_from[3]),
.vdp_accbit15_wb (vdp_acc1bit15_wb),
.vdp_accbit21_wb (vdp_acc1bit21_wb),
.vdp_accbit31_wb (vdp_acc1bit31_wb),
.vdp_accbit47_wb (vdp_acc1bit47_wb),
.vdp_acchizero_wb (vdp_achizero1_wb),
.vdp_accmizero_wb (vdp_acmizero1_wb),
.vdp_acchione_wb (vdp_achione1_wb),
.vct_acchighsl_wb (vct_acchighsl_wb),
.vct_accmidsl_wb (vct_accmidsl_wb),
.vct_acclowsl_wb (vct_acclowsl_wb),
.vct_accshftsl_wb (vct_accshftsl_wb),
.vct_divrsltsl_wb (vct_divrsltsl_wb),
.vct_clpsgn31_wb (vct_clpsgn31_wb),
.vct_clpsgn16_wb (vct_clpsgn16_wb),
.vct_clpsgn32_wb (vct_clpsgn32_wb),
.vct_clpuns31_wb (vct_clpuns31_wb),
.vct_adscl16op_wb (vct_adscl16op_wb),
.vct_alucin_mu (vct_alucin1_mu),
.vct_alucmpvt_mu (vct_alucmpvt1_mu),
.vct_compvt_mu (vct_cmpvt1_mu),
.vct_smlwrsl_mu (vct_smlwrsl1_mu),
.vct_cryout_ac (vct_cryout1_ac),
.vct_opdneql_ac (vct_opdneql1_ac),
.vct_cmpcdlo_ac (vct_cmpcdlo1_ac),
.vct_cmpcdhi_ac (vct_cmpcdhi1_ac),
.vct_cmpcdad_ac (vct_cmpcdad1_ac),
.vct_rndvlu_ac (vct_rndvlu1_ac),
.vct_cslwbsl_ac (vct_cslwbsl1_ac),
.vct_addlwci_ac (vct_addlwci1_ac),
.vct_csupbsl_ac (vct_csupbsl1_ac),
.vct_csupcen_ac (vct_csupcen1_ac),
.vct_incrdwn_ac (vct_incrdwn1_ac),
.vct_incrci_ac (vct_incrci1_ac),
.vct_incrmxsl_ac (vct_incrmxsl1_ac),
.vct_aclwsl_ac (vct_aclwsl1_ac),
.vct_acupsl_ac (vct_acupsl1_ac),
.vct_rsltsl_wb (vct_rsltsl1_wb),
.vct_clprslt_wb (vct_clprslt1_wb)
);
endmodule