diff options
Diffstat (limited to 'rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v')
-rw-r--r-- | rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v | 306 |
1 files changed, 153 insertions, 153 deletions
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v b/rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v index ea5b854..b6c63b2 100644 --- a/rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v +++ b/rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v @@ -1,153 +1,153 @@ -`timescale 1ns / 1ps
-
-module modinv_helper_reduce_update
- (
- clk, rst_n,
- ena, rdy,
-
- s_is_odd, k_is_nul,
-
- s_addr, s_wren, s_dout,
- u_addr, u_din,
- v_addr, v_din
- );
-
-
- //
- // Parameters
- //
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = BUFFER_NUM_WORDS + 3;
- localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
- input wire ena;
- output wire rdy;
-
- input wire s_is_odd;
- input wire k_is_nul; -
- output wire [BUFFER_ADDR_BITS-1:0] s_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_addr;
-
- output wire s_wren;
-
- output wire [ 32-1:0] s_dout;
-
- input wire [ 32-1:0] u_din;
- input wire [ 32-1:0] v_din;
-
-
- //
- // Counter
- //
- reg [PROC_CNT_BITS-1:0] proc_cnt;
-
- wire [PROC_CNT_BITS-1:0] proc_cnt_max = PROC_NUM_CYCLES - 1;
- wire [PROC_CNT_BITS-1:0] proc_cnt_zero = {PROC_CNT_BITS{1'b0}};
- wire [PROC_CNT_BITS-1:0] proc_cnt_next = (proc_cnt < proc_cnt_max) ?
- proc_cnt + 1'b1 : proc_cnt_zero;
-
- //
- // Addresses
- //
- reg [BUFFER_ADDR_BITS-1:0] addr_in;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_in_max = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_in_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_in_next = (addr_in < addr_in_max) ?
- addr_in + 1'b1 : addr_in_zero;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_out;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out_max = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out_next = (addr_out < addr_out_max) ?
- addr_out + 1'b1 : addr_out_zero;
-
- assign s_addr = addr_out;
- assign u_addr = addr_in;
- assign v_addr = addr_in;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Increment Logic
- //
- wire inc_addr_in;
- wire inc_addr_out;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_start = 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_stop = BUFFER_NUM_WORDS;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out_stop = BUFFER_NUM_WORDS + 1;
-
- assign inc_addr_in = (proc_cnt >= cnt_inc_addr_in_start) && (proc_cnt <= cnt_inc_addr_in_stop);
- assign inc_addr_out = (proc_cnt >= cnt_inc_addr_out_start) && (proc_cnt <= cnt_inc_addr_out_stop);
-
- always @(posedge clk) begin
- //
- if (inc_addr_in) addr_in <= addr_in_next;
- else addr_in <= addr_in_zero;
- //
- if (inc_addr_out) addr_out <= addr_out_next;
- else addr_out <= addr_out_zero;
- //
- end
-
- //
- // Write Enable Logic
- //
- wire wren_out;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out_stop = BUFFER_NUM_WORDS + 1;
-
- assign wren_out = (proc_cnt >= cnt_wren_out_start) && (proc_cnt <= cnt_wren_out_stop);
-
- assign s_wren = wren_out && !k_is_nul; //s_wren_allow && !v_eq_1 && !rdy;
-
-
- //
- // Data Logic
- //
- assign s_dout = s_is_odd ? v_din : u_din;
-
-
- //
- // Primary Counter Logic
- //
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) proc_cnt <= proc_cnt_zero;
- else begin
- if (!rdy) proc_cnt <= proc_cnt_next;
- else if (ena) proc_cnt <= proc_cnt_next;
- end
-
-
-endmodule
+`timescale 1ns / 1ps + +module modinv_helper_reduce_update + ( + clk, rst_n, + ena, rdy, + + s_is_odd, k_is_nul, + + s_addr, s_wren, s_dout, + u_addr, u_din, + v_addr, v_din + ); + + + // + // Parameters + // + parameter BUFFER_NUM_WORDS = 9; + parameter BUFFER_ADDR_BITS = 4; + + + // + // clog2 + // +`include "../modinv_clog2.v" + + + // + // Constants + // + localparam PROC_NUM_CYCLES = BUFFER_NUM_WORDS + 3; + localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES); + + + // + // Ports + // + input wire clk; + input wire rst_n; + input wire ena; + output wire rdy; + + input wire s_is_odd; + input wire k_is_nul; + + output wire [BUFFER_ADDR_BITS-1:0] s_addr; + output wire [BUFFER_ADDR_BITS-1:0] u_addr; + output wire [BUFFER_ADDR_BITS-1:0] v_addr; + + output wire s_wren; + + output wire [ 32-1:0] s_dout; + + input wire [ 32-1:0] u_din; + input wire [ 32-1:0] v_din; + + + // + // Counter + // + reg [PROC_CNT_BITS-1:0] proc_cnt; + + wire [PROC_CNT_BITS-1:0] proc_cnt_max = PROC_NUM_CYCLES - 1; + wire [PROC_CNT_BITS-1:0] proc_cnt_zero = {PROC_CNT_BITS{1'b0}}; + wire [PROC_CNT_BITS-1:0] proc_cnt_next = (proc_cnt < proc_cnt_max) ? + proc_cnt + 1'b1 : proc_cnt_zero; + + // + // Addresses + // + reg [BUFFER_ADDR_BITS-1:0] addr_in; + + wire [BUFFER_ADDR_BITS-1:0] addr_in_max = BUFFER_NUM_WORDS - 1; + wire [BUFFER_ADDR_BITS-1:0] addr_in_zero = {BUFFER_ADDR_BITS{1'b0}}; + wire [BUFFER_ADDR_BITS-1:0] addr_in_next = (addr_in < addr_in_max) ? + addr_in + 1'b1 : addr_in_zero; + + reg [BUFFER_ADDR_BITS-1:0] addr_out; + + wire [BUFFER_ADDR_BITS-1:0] addr_out_max = BUFFER_NUM_WORDS - 1; + wire [BUFFER_ADDR_BITS-1:0] addr_out_zero = {BUFFER_ADDR_BITS{1'b0}}; + wire [BUFFER_ADDR_BITS-1:0] addr_out_next = (addr_out < addr_out_max) ? + addr_out + 1'b1 : addr_out_zero; + + assign s_addr = addr_out; + assign u_addr = addr_in; + assign v_addr = addr_in; + + + // + // Ready Flag + // + assign rdy = (proc_cnt == proc_cnt_zero); + + + // + // Address Increment Logic + // + wire inc_addr_in; + wire inc_addr_out; + + wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_start = 1; + wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_stop = BUFFER_NUM_WORDS; + + wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out_start = 2; + wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out_stop = BUFFER_NUM_WORDS + 1; + + assign inc_addr_in = (proc_cnt >= cnt_inc_addr_in_start) && (proc_cnt <= cnt_inc_addr_in_stop); + assign inc_addr_out = (proc_cnt >= cnt_inc_addr_out_start) && (proc_cnt <= cnt_inc_addr_out_stop); + + always @(posedge clk) begin + // + if (inc_addr_in) addr_in <= addr_in_next; + else addr_in <= addr_in_zero; + // + if (inc_addr_out) addr_out <= addr_out_next; + else addr_out <= addr_out_zero; + // + end + + // + // Write Enable Logic + // + wire wren_out; + + wire [PROC_CNT_BITS-1:0] cnt_wren_out_start = 2; + wire [PROC_CNT_BITS-1:0] cnt_wren_out_stop = BUFFER_NUM_WORDS + 1; + + assign wren_out = (proc_cnt >= cnt_wren_out_start) && (proc_cnt <= cnt_wren_out_stop); + + assign s_wren = wren_out && !k_is_nul; //s_wren_allow && !v_eq_1 && !rdy; + + + // + // Data Logic + // + assign s_dout = s_is_odd ? v_din : u_din; + + + // + // Primary Counter Logic + // + always @(posedge clk or negedge rst_n) + // + if (rst_n == 1'b0) proc_cnt <= proc_cnt_zero; + else begin + if (!rdy) proc_cnt <= proc_cnt_next; + else if (ena) proc_cnt <= proc_cnt_next; + end + + +endmodule |