v16x32wrap.v
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// v16x32wrap.v v1 Frank Berndt
// wrapper around virage 16x32 modules, 512bits;
// :set tabstop=4
// output enables of virage sram are not used;
// read data come out of novea and hit ff in mi;
// serial mode is not implemented;
`timescale 1ns/1ns
module v16x32wrap (
sysclk, reset_l, v_time,
v_me, v_addr, v_in, v_we, v_out,
v_sclk, v_sme, v_si, v_so,
v_porst, v_vpp
);
// operational ports;
input sysclk; // system clock;
input reset_l; // system reset;
input v_time; // time base, 1us;
input v_me; // enable;
input v_we; // write enable;
input [15:2] v_addr; // address;
input [31:0] v_in; // write data;
output [31:0] v_out; // read data;
input v_sclk; // serial clock;
input v_sme; // serial mode control;
input v_si; // serial input;
output v_so; // serial output;
output v_porst; // power-on reset;
output v_vpp; // only for monitor pad;
// decode the major sub address spaces;
// read data mux controls;
wire v_sram; // virage sram space;
wire v_reg; // store controller register space;
wire v_ctrl; // control register space;
reg [4:2] v_rega; // register address;
reg [1:0] v_sel; // read mux controls;
assign v_sram = ~v_addr[15]; // sram space;
assign v_reg = (v_addr[15:14] == 2'b10); // store controller space;
assign v_ctrl = (v_addr[15:14] == 2'b11); // bypass and control;
always @(posedge sysclk)
begin
v_rega[4:2] <= v_addr[4:2];
v_sel[0] <= v_me & v_sram;
v_sel[1] <= v_me & v_reg;
end
// charge pump controls;
wire cp_rst; // charge pump reset;
wire cp_pe; // charge pump enable;
wire cp_vpprange; // charge pump vpp range;
wire [3:0] cp_vppsel; // charge pump vpp select;
wire cp_data; // charge pump unlock data;
wire cp_clke; // charge pump clock enable;
wire cp_porst; // charge pump power-on reset output;
wire cp_unlock; // charge pump unlock status;
// novea array controls;
wire nv_me; // novea sram enable;
wire nv_we; // novea write enable;
wire nv_recall; // novea recall control;
wire nv_store; // novea store control;
wire nv_comp; // comparator control;
wire [1:0] nv_mrcl; // noveal margin recall control;
wire [1:0] nv_tecc; // noveal cell select control;
wire [1:0] nv_bias; // noveal bias control;
wire nv_match; // novea match output;
wire nv_rcready; // novea recall ready output;
wire [31:0] nv_q; // novea read data;
assign nv_me = v_me & v_sram;
// virage store controller;
wire nms_ra; // parallel register access;
wire nms_pae; // parallel command enable;
wire nms_we; // nms novea write enable;
wire nms_ready; // nms is ready;
wire nms_pass; // nms command passed;
wire nms_keep; // nms in keep mode;
wire nms_rst; // nms cp reset;
wire nms_pe; // nms cp enable;
wire nms_data; // nms cp data;
wire nms_clke; // nms cp clock enable;
wire nms_vpprange; // nms cp vpp range;
wire [3:0] nms_vppsel; // nms cp vpp select;
wire nms_recall; // nms recall;
wire nms_store; // nms store;
wire nms_comp; // nms comparator control;
wire [1:0] nms_mrcl; // nms margin recall control;
wire [1:0] nms_tecc; // nms cell select control;
wire [1:0] nms_bias; // nms bias control;
wire [31:0] nms_q; // nms read data;
assign nms_ra = v_me & v_reg;
// virage control register;
// controls usage of store controller or direct cpu interface;
wire vctrl_we; // write to virage ctrl register;
reg nms_byp; // bypass virage store controller;
reg vnms_ready; // registered nms ready output;
reg vnms_pass; // registered nms pass output;
reg vnms_keep; // registered nms keep output;
reg [2:0] nms_cmd; // nms command;
reg vnv_rcready; // registered nv recall ready output;
reg vnv_match; // registered nv match output;
reg vnv_recall; // nv recall control;
reg vnv_store; // nv store control;
reg vnv_comp; // nv comp control;
reg [1:0] vnv_mrcl; // nv margin recall controls;
reg [1:0] vnv_tecc; // nv cell seelcts;
reg [1:0] vnv_bias; // nv bias controls;
reg vcp_rst; // cp reset;
reg vcp_pe; // cp enable;
reg vcp_data; // cp unlock data stream;
reg vcp_vpprange; // cp vpp range;
reg [3:0] vcp_vppsel; // cp vpp selects;
reg vcp_unlock; // cp unlock status;
reg vcp_clke; // cp clock enable;
reg [1:0] v_exec; // execute nms command;
assign vctrl_we = v_me & v_we & v_ctrl;
always @(posedge sysclk)
begin
if(reset_l == 1'b0) begin
nms_byp <= 1'b0;
nms_cmd <= 3'd0;
vnv_recall <= 1'b0;
vnv_store <= 1'b0;
vnv_comp <= 1'b0;
vnv_mrcl <= 2'd0;
vnv_tecc <= 2'd0;
vnv_bias <= 2'b01;
vcp_rst <= 1'b1;
vcp_pe <= 1'b0;
vcp_data <= 1'b0;
vcp_vpprange <= 1'b0;
vcp_vppsel <= 4'b0;
end else if(vctrl_we) begin
nms_byp <= v_in[31];
nms_cmd <= v_in[26:24];
vnv_recall <= v_in[21];
vnv_store <= v_in[20];
vnv_comp <= v_in[18];
vnv_mrcl <= v_in[17:16];
vnv_tecc <= v_in[15:14];
vnv_bias <= v_in[13:12];
vcp_rst <= v_in[11];
vcp_pe <= v_in[10];
vcp_data <= v_in[9];
vcp_vpprange <= v_in[8];
vcp_vppsel <= v_in[7:4];
end
vnms_ready <= nms_ready;
vnms_pass <= nms_pass;
vnms_keep <= nms_keep;
vnv_rcready <= nv_rcready;
vnv_match <= nv_match;
vcp_unlock <= cp_unlock;
vcp_clke <= vctrl_we & v_addr[12];
v_exec <= {2{reset_l}} & { v_exec[0], vctrl_we & v_addr[13] };
end
assign nms_pae = ~nms_byp & |v_exec;
// sum up read data bits;
wire [31:0] vctrl_out;
assign vctrl_out = {
nms_byp, vnms_ready, vnms_pass, vnms_keep, 1'b0, nms_cmd,
vnv_rcready, vnv_match, nv_recall, nv_store, 1'b0, nv_comp, nv_mrcl,
nv_tecc, nv_bias, cp_rst, cp_pe, cp_data, cp_vpprange,
cp_vppsel, 2'b0, vcp_unlock, cp_porst };
assign v_porst = cp_porst;
// bypass virage store controller;
assign cp_rst = nms_byp? vcp_rst : nms_rst;
assign cp_pe = nms_byp? vcp_pe : nms_pe;
assign cp_data = nms_byp? vcp_data : nms_data;
assign cp_clke = nms_byp? vcp_clke : nms_clke;
assign cp_vpprange = nms_byp? vcp_vpprange : nms_vpprange;
assign cp_vppsel = nms_byp? vcp_vppsel : nms_vppsel;
assign nv_we = nms_byp? v_we : nms_we;
assign nv_recall = nms_byp? vnv_recall : nms_recall;
assign nv_store = nms_byp? vnv_store : nms_store;
assign nv_comp = nms_byp? vnv_comp : nms_comp;
assign nv_mrcl = nms_byp? vnv_mrcl : nms_mrcl;
assign nv_tecc = nms_byp? vnv_tecc : nms_tecc;
assign nv_bias = nms_byp? vnv_bias : nms_bias;
// instantiate NEC super cell;
// contains charge pump and novea array;
// drive test bus signals inactive;
wire [21:0] nv_tbi; // test bus inputs;
wire [4:0] nv_tbo; // test bus outputs;
wire nv_test; // test mode;
wire nv_bunri; // test mode;
assign nv_tbi = 21'd0;
assign nv_test = 1'b0;
assign nv_bunri = 1'b0;
nms_sc_16x32 vsc (
.CLK(sysclk),
.RST(cp_rst),
.PE(cp_pe),
.VPPRANGE(cp_vpprange),
.VPPSEL3(cp_vppsel[3]),
.VPPSEL2(cp_vppsel[2]),
.VPPSEL1(cp_vppsel[1]),
.VPPSEL0(cp_vppsel[0]),
.D(cp_data),
.CLKE(cp_clke),
.STORE(nv_store),
.VPP(v_vpp),
.PORST(cp_porst),
.UNLOCK(cp_unlock),
.ADR3(v_addr[5]),
.ADR2(v_addr[4]),
.ADR1(v_addr[3]),
.ADR0(v_addr[2]),
.D31(v_in[31]),
.D30(v_in[30]),
.D29(v_in[29]),
.D28(v_in[28]),
.D27(v_in[27]),
.D26(v_in[26]),
.D25(v_in[25]),
.D24(v_in[24]),
.D23(v_in[23]),
.D22(v_in[22]),
.D21(v_in[21]),
.D20(v_in[20]),
.D19(v_in[19]),
.D18(v_in[18]),
.D17(v_in[17]),
.D16(v_in[16]),
.D15(v_in[15]),
.D14(v_in[14]),
.D13(v_in[13]),
.D12(v_in[12]),
.D11(v_in[11]),
.D10(v_in[10]),
.D9(v_in[9]),
.D8(v_in[8]),
.D7(v_in[7]),
.D6(v_in[6]),
.D5(v_in[5]),
.D4(v_in[4]),
.D3(v_in[3]),
.D2(v_in[2]),
.D1(v_in[1]),
.D0(v_in[0]),
.ME(nv_me),
.WE(nv_we),
.SI(v_si),
.SME(v_sme),
.SCLK(v_sclk),
.SO(v_so),
.RECALL(nv_recall),
.COMP(nv_comp),
.MRCL0(nv_mrcl[0]),
.MRCL1(nv_mrcl[1]),
.TECC0(nv_tecc[0]),
.TECC1(nv_tecc[1]),
.BIAS0(nv_bias[0]),
.BIAS1(nv_bias[1]),
.Q31(nv_q[31]),
.Q30(nv_q[30]),
.Q29(nv_q[29]),
.Q28(nv_q[28]),
.Q27(nv_q[27]),
.Q26(nv_q[26]),
.Q25(nv_q[25]),
.Q24(nv_q[24]),
.Q23(nv_q[23]),
.Q22(nv_q[22]),
.Q21(nv_q[21]),
.Q20(nv_q[20]),
.Q19(nv_q[19]),
.Q18(nv_q[18]),
.Q17(nv_q[17]),
.Q16(nv_q[16]),
.Q15(nv_q[15]),
.Q14(nv_q[14]),
.Q13(nv_q[13]),
.Q12(nv_q[12]),
.Q11(nv_q[11]),
.Q10(nv_q[10]),
.Q9(nv_q[9]),
.Q8(nv_q[8]),
.Q7(nv_q[7]),
.Q6(nv_q[6]),
.Q5(nv_q[5]),
.Q4(nv_q[4]),
.Q3(nv_q[3]),
.Q2(nv_q[2]),
.Q1(nv_q[1]),
.Q0(nv_q[0]),
.MATCH(nv_match),
.RCREADY(nv_rcready),
.TEST(nv_test),
.BUNRI(nv_bunri),
.TBI21(nv_tbi[21]),
.TBI20(nv_tbi[20]),
.TBI19(nv_tbi[19]),
.TBI18(nv_tbi[18]),
.TBI17(nv_tbi[17]),
.TBI16(nv_tbi[16]),
.TBI15(nv_tbi[15]),
.TBI14(nv_tbi[14]),
.TBI13(nv_tbi[13]),
.TBI12(nv_tbi[12]),
.TBI11(nv_tbi[11]),
.TBI10(nv_tbi[10]),
.TBI9(nv_tbi[9]),
.TBI8(nv_tbi[8]),
.TBI7(nv_tbi[7]),
.TBI6(nv_tbi[6]),
.TBI5(nv_tbi[5]),
.TBI4(nv_tbi[4]),
.TBI3(nv_tbi[3]),
.TBI2(nv_tbi[2]),
.TBI1(nv_tbi[1]),
.TBI0(nv_tbi[0]),
.TBO4(nv_tbo[4]),
.TBO3(nv_tbo[3]),
.TBO2(nv_tbo[2]),
.TBO1(nv_tbo[1]),
.TBO0(nv_tbo[0])
);
// instantiate store controller;
// can be bypassed if it does not work;
wire nms_wrck; // serial clock;
wire nms_wsi; // serial data input;
wire nms_updatewr;
wire nms_shiftwr;
wire nms_selectwir;
assign nms_wrck = 1'b0;
assign nms_wsi = 1'b0;
assign nms_updatewr = 1'b0;
assign nms_shiftwr = 1'b0;
assign nms_selectwir = 1'b0;
nvco_nc15gfh_16x32 nms (
.SYS_CK(sysclk),
.TIME_B(v_time),
.WRSTN(reset_l),
.WRCK(nms_wrck),
.WSI(nms_wsi),
.UpdateWR(nms_updatewr),
.ShiftWR(nms_shiftwr),
.SelectWIR(nms_selectwir),
.PAE_p(nms_pae),
.PA_p(nms_cmd),
.RCREADY(nv_rcready),
.SO_NV(v_so),
.MATCH(nv_match),
.UNLOCK(cp_unlock),
.PORST(cp_porst),
.ADR_p({ 1'b0, v_rega }),
.D_p(v_in),
.RA_p(nms_ra),
.WE_p(v_we),
.ME_p(v_me),
.OE_p(1'b1),
.WSO(),
.NMS_READY(nms_ready),
.NMS_PASS(nms_pass),
.KEEP_ON(nms_keep),
.RST_i(nms_rst),
.PE(nms_pe),
.VPPRANGE(nms_vpprange),
.VPPSEL(nms_vppsel),
.UDATA(nms_data),
.PCLKE(nms_clke),
.SI_NV(),
.SME_NV(),
.STORE(nms_store),
.COMP(nms_comp),
.RECALL(nms_recall),
.MRCL0(nms_mrcl[0]),
.MRCL1(nms_mrcl[1]),
.TECC0(nms_tecc[0]),
.TECC1(nms_tecc[1]),
.BIAS0(nms_bias[0]),
.BIAS1(nms_bias[1]),
.Q(nms_q),
.WE_NV(nms_we),
.OE_NV(),
.ME_NV(),
.CLK(),
.SCLK_NV(),
.ADR_NV(),
.D_NV()
);
// read data mux;
// select array data, ctrl register or nms reagister data;
assign v_out = v_sel[0]? nv_q : v_sel[1]? { 24'd0, nms_q[7:0] } : vctrl_out;
endmodule