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authorRob Austein <sra@hactrn.net>2017-03-07 19:46:44 -0500
committerRob Austein <sra@hactrn.net>2017-03-07 19:46:44 -0500
commitab4638f70ee846de7398a3d78d467a9551e508cf (patch)
tree61c330bb0be48daa4faf3830abfa84c9e5f400d7 /rtl
parent9fa6e368879d30835880b3bb0e87c8cf13dd9874 (diff)
Promote code common to both ECDSA* cores to separate repository in core/ tree.
Pavel's two ECDSA base point multiplier cores share a fair amount of code. Maintenance issues aside, the duplication confused the Xilinx synthesis tools if one tried to build a single bitstream containing both cores, so we've separated the common code out into this library. The selection of files in this library was done by comparing the rtl trees of the two original core repositories using "diff -rqws" and selecting the files which diff reported as being identical. Also dealt with some cosmetic issues (indentation, Windows-isms, etc).
Diffstat (limited to 'rtl')
-rw-r--r--rtl/curve/curve_dbl_add_256.v874
-rw-r--r--rtl/curve/curve_mul_256.v720
-rw-r--r--rtl/curve/rom/brom_p256_delta.v68
-rw-r--r--rtl/curve/rom/brom_p256_g_x.v68
-rw-r--r--rtl/curve/rom/brom_p256_g_y.v68
-rw-r--r--rtl/curve/rom/brom_p256_h_x.v68
-rw-r--r--rtl/curve/rom/brom_p256_h_y.v68
-rw-r--r--rtl/curve/rom/brom_p256_one.v68
-rw-r--r--rtl/curve/rom/brom_p256_q.v68
-rw-r--r--rtl/curve/rom/brom_p256_zero.v70
-rw-r--r--rtl/curve/uop/uop_add_rom.v82
-rw-r--r--rtl/curve/uop/uop_conv_rom.v72
-rw-r--r--rtl/curve/uop/uop_dbl_rom.v68
-rw-r--r--rtl/curve/uop/uop_init_rom.v62
-rw-r--r--rtl/curve/uop_ecdsa.v4
-rw-r--r--rtl/ecdsa256.v160
-rw-r--r--rtl/ecdsa256_wrapper.v177
-rw-r--r--rtl/lowlevel/adder32_wrapper.v72
-rw-r--r--rtl/lowlevel/adder47_wrapper.v64
-rw-r--r--rtl/lowlevel/artix7/adder32_artix7.v118
-rw-r--r--rtl/lowlevel/artix7/adder47_artix7.v108
-rw-r--r--rtl/lowlevel/artix7/dsp48e1_wrapper.v248
-rw-r--r--rtl/lowlevel/artix7/mac16_artix7.v106
-rw-r--r--rtl/lowlevel/artix7/subtractor32_artix7.v188
-rw-r--r--rtl/lowlevel/ecdsa_lowlevel_settings.v34
-rw-r--r--rtl/lowlevel/generic/adder32_generic.v60
-rw-r--r--rtl/lowlevel/generic/adder47_generic.v54
-rw-r--r--rtl/lowlevel/generic/mac16_generic.v74
-rw-r--r--rtl/lowlevel/generic/subtractor32_generic.v134
-rw-r--r--rtl/lowlevel/mac16_wrapper.v70
-rw-r--r--rtl/lowlevel/subtractor32_wrapper.v138
-rw-r--r--rtl/modular/modular_adder.v522
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_copy.v296
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_init.v344
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_invert_compare.v572
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_invert_precalc.v816
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_invert_update.v514
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_reduce_precalc.v656
-rw-r--r--rtl/modular/modular_invertor/helper/modinv_helper_reduce_update.v306
-rw-r--r--rtl/modular/modular_invertor/modinv_clog2.v20
-rw-r--r--rtl/modular/modular_invertor/modular_invertor.v1888
-rw-r--r--rtl/modular/modular_multiplier_256.v402
-rw-r--r--rtl/modular/modular_reductor_256.v692
-rw-r--r--rtl/modular/modular_subtractor.v510
-rw-r--r--rtl/multiword/mw_comparator.v440
-rw-r--r--rtl/multiword/mw_mover.v350
-rw-r--r--rtl/util/bram_1rw_1ro_readfirst.v38
47 files changed, 4514 insertions, 8085 deletions
diff --git a/rtl/curve/curve_dbl_add_256.v b/rtl/curve/curve_dbl_add_256.v
deleted file mode 100644
index 8ef505d..0000000
--- a/rtl/curve/curve_dbl_add_256.v
+++ /dev/null
@@ -1,874 +0,0 @@
-//------------------------------------------------------------------------------
-//
-// curve_dbl_add_256.v
-// -----------------------------------------------------------------------------
-// Elliptic curve point adder and doubler.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module curve_dbl_add_256
- (
- clk, rst_n,
- ena, rdy,
- uop_addr, uop,
- px_addr, py_addr, pz_addr, rx_addr, ry_addr, rz_addr, q_addr, v_addr,
- rx_wren, ry_wren, rz_wren,
- px_din, py_din, pz_din,
- rx_din, ry_din, rz_din,
- rx_dout, ry_dout, rz_dout, q_din, v_din
- );
-
-
- //
- // Microcode
- //
-`include "uop_ecdsa.v"
-
-
- //
- // Constants
- //
- localparam WORD_COUNTER_WIDTH = 3; // 0 .. 7
- localparam OPERAND_NUM_WORDS = 8; // 8 * 32 = 256
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output reg [ 6-1: 0] uop_addr;
- input wire [20-1: 0] uop;
-
- output reg [WORD_COUNTER_WIDTH-1:0] px_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] py_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] pz_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] rx_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] ry_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] rz_addr;
- output reg [WORD_COUNTER_WIDTH-1:0] v_addr;
- output wire [WORD_COUNTER_WIDTH-1:0] q_addr;
-
- output wire rx_wren;
- output wire ry_wren;
- output wire rz_wren;
-
- input wire [ 32-1:0] px_din;
- input wire [ 32-1:0] py_din;
- input wire [ 32-1:0] pz_din;
- input wire [ 32-1:0] rx_din;
- input wire [ 32-1:0] ry_din;
- input wire [ 32-1:0] rz_din;
- output wire [ 32-1:0] rx_dout;
- output wire [ 32-1:0] ry_dout;
- output wire [ 32-1:0] rz_dout;
- input wire [ 32-1:0] q_din;
- input wire [ 32-1:0] v_din;
-
-
- //
- // Microcode
- //
- wire [ 4: 0] uop_opcode = uop[19:15];
- wire [ 4: 0] uop_src_a = uop[14:10];
- wire [ 4: 0] uop_src_b = uop[ 9: 5];
- wire [ 2: 0] uop_dst = uop[ 4: 2];
- wire [ 1: 0] uop_exec = uop[ 1: 0];
-
-
- //
- // Multi-Word Comparator
- //
- wire mw_cmp_ena;
- wire mw_cmp_rdy;
-
- wire mw_cmp_out_l;
- wire mw_cmp_out_e;
- wire mw_cmp_out_g;
-
- wire [WORD_COUNTER_WIDTH-1:0] mw_cmp_addr_xy;
-
- wire [ 32-1:0] mw_cmp_din_x;
- wire [ 32-1:0] mw_cmp_din_y;
-
- // flags
- reg flag_pz_is_zero;
- reg flag_t1_is_zero;
- reg flag_t2_is_zero;
-
- mw_comparator #
- (
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH),
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS)
- )
- mw_comparator_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (mw_cmp_ena),
- .rdy (mw_cmp_rdy),
-
- .xy_addr (mw_cmp_addr_xy),
- .x_din (mw_cmp_din_x),
- .y_din (mw_cmp_din_y),
-
- .cmp_l (mw_cmp_out_l),
- .cmp_e (mw_cmp_out_e),
- .cmp_g (mw_cmp_out_g)
- );
-
-
- //
- // Modular Adder
- //
- wire mod_add_ena;
- wire mod_add_rdy;
-
- wire [WORD_COUNTER_WIDTH-1:0] mod_add_addr_ab;
- wire [WORD_COUNTER_WIDTH-1:0] mod_add_addr_n;
- wire [WORD_COUNTER_WIDTH-1:0] mod_add_addr_s;
- wire mod_add_wren_s;
-
- wire [ 32-1:0] mod_add_din_a;
- wire [ 32-1:0] mod_add_din_b;
- wire [ 32-1:0] mod_add_din_n;
- wire [ 32-1:0] mod_add_dout_s;
-
- assign mod_add_din_n = q_din;
-
- modular_adder #
- (
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH),
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS)
- )
- modular_adder_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (mod_add_ena),
- .rdy (mod_add_rdy),
-
- .ab_addr (mod_add_addr_ab),
- .n_addr (mod_add_addr_n),
- .s_addr (mod_add_addr_s),
- .s_wren (mod_add_wren_s),
-
- .a_din (mod_add_din_a),
- .b_din (mod_add_din_b),
- .n_din (mod_add_din_n),
- .s_dout (mod_add_dout_s)
- );
-
-
- //
- // Modular Subtractor
- //
- wire mod_sub_ena;
- wire mod_sub_rdy;
-
- wire [WORD_COUNTER_WIDTH-1:0] mod_sub_addr_ab;
- wire [WORD_COUNTER_WIDTH-1:0] mod_sub_addr_n;
- wire [WORD_COUNTER_WIDTH-1:0] mod_sub_addr_d;
- wire mod_sub_wren_d;
-
- wire [ 32-1:0] mod_sub_din_a;
- wire [ 32-1:0] mod_sub_din_b;
- wire [ 32-1:0] mod_sub_din_n;
- wire [ 32-1:0] mod_sub_dout_d;
-
- assign mod_sub_din_n = q_din;
-
- modular_subtractor #
- (
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH),
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS)
- )
- modular_subtractor_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (mod_sub_ena),
- .rdy (mod_sub_rdy),
-
- .ab_addr (mod_sub_addr_ab),
- .n_addr (mod_sub_addr_n),
- .d_addr (mod_sub_addr_d),
- .d_wren (mod_sub_wren_d),
-
- .a_din (mod_sub_din_a),
- .b_din (mod_sub_din_b),
- .n_din (mod_sub_din_n),
- .d_dout (mod_sub_dout_d)
- );
-
-
- //
- // Modular Multiplier
- //
- wire mod_mul_ena;
- wire mod_mul_rdy;
-
- wire [WORD_COUNTER_WIDTH-1:0] mod_mul_addr_a;
- wire [WORD_COUNTER_WIDTH-1:0] mod_mul_addr_b;
- wire [WORD_COUNTER_WIDTH-1:0] mod_mul_addr_n;
- wire [WORD_COUNTER_WIDTH-1:0] mod_mul_addr_p;
- wire mod_mul_wren_p;
-
- wire [ 32-1:0] mod_mul_din_a;
- wire [ 32-1:0] mod_mul_din_b;
- wire [ 32-1:0] mod_mul_din_n;
- wire [ 32-1:0] mod_mul_dout_p;
-
- assign mod_mul_din_n = q_din;
-
- modular_multiplier_256 modular_multiplier_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (mod_mul_ena),
- .rdy (mod_mul_rdy),
-
- .a_addr (mod_mul_addr_a),
- .b_addr (mod_mul_addr_b),
- .n_addr (mod_mul_addr_n),
- .p_addr (mod_mul_addr_p),
- .p_wren (mod_mul_wren_p),
-
- .a_din (mod_mul_din_a),
- .b_din (mod_mul_din_b),
- .n_din (mod_mul_din_n),
- .p_dout (mod_mul_dout_p)
- );
-
-
- //
- // Multi-Word Data Mover
- //
- wire mw_mov_ena;
- wire mw_mov_rdy;
-
- wire [WORD_COUNTER_WIDTH-1:0] mw_mov_addr_x;
- wire [WORD_COUNTER_WIDTH-1:0] mw_mov_addr_y;
- wire mw_mov_wren_y;
-
- wire [ 32-1:0] mw_mov_din_x;
- wire [ 32-1:0] mw_mov_dout_y;
-
- mw_mover #
- (
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH),
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS)
-
- )
- mw_mover_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (mw_mov_ena),
- .rdy (mw_mov_rdy),
-
- .x_addr (mw_mov_addr_x),
- .y_addr (mw_mov_addr_y),
- .y_wren (mw_mov_wren_y),
-
- .x_din (mw_mov_din_x),
- .y_dout (mw_mov_dout_y)
- );
-
-
- //
- // ROMs
- //
- reg [WORD_COUNTER_WIDTH-1:0] brom_one_addr;
- //reg [WORD_COUNTER_WIDTH-1:0] brom_zero_addr;
- reg [WORD_COUNTER_WIDTH-1:0] brom_delta_addr;
- reg [WORD_COUNTER_WIDTH-1:0] brom_g_x_addr;
- reg [WORD_COUNTER_WIDTH-1:0] brom_g_y_addr;
- reg [WORD_COUNTER_WIDTH-1:0] brom_h_x_addr;
- reg [WORD_COUNTER_WIDTH-1:0] brom_h_y_addr;
-
- wire [ 32-1:0] brom_one_dout;
- wire [ 32-1:0] brom_zero_dout;
- wire [ 32-1:0] brom_delta_dout;
- wire [ 32-1:0] brom_g_x_dout;
- wire [ 32-1:0] brom_g_y_dout;
- wire [ 32-1:0] brom_h_x_dout;
- wire [ 32-1:0] brom_h_y_dout;
-
- (* ROM_STYLE="BLOCK" *) brom_p256_one brom_one_inst
- (.clk(clk), .b_addr(brom_one_addr), .b_out(brom_one_dout));
-
- brom_p256_zero brom_zero_inst
- (.b_out(brom_zero_dout));
-
- (* ROM_STYLE="BLOCK" *) brom_p256_delta brom_delta_inst
- (.clk(clk), .b_addr(brom_delta_addr), .b_out(brom_delta_dout));
-
- (* ROM_STYLE="BLOCK" *) brom_p256_g_x brom_g_x_inst
- (.clk(clk), .b_addr(brom_g_x_addr), .b_out(brom_g_x_dout));
-
- (* ROM_STYLE="BLOCK" *) brom_p256_g_y brom_g_y_inst
- (.clk(clk), .b_addr(brom_g_y_addr), .b_out(brom_g_y_dout));
-
- (* ROM_STYLE="BLOCK" *) brom_p256_h_x brom_h_x_inst
- (.clk(clk), .b_addr(brom_h_x_addr), .b_out(brom_h_x_dout));
-
- (* ROM_STYLE="BLOCK" *) brom_p256_h_y brom_h_y_inst
- (.clk(clk), .b_addr(brom_h_y_addr), .b_out(brom_h_y_dout));
-
-
- //
- // Temporary Variables
- //
- reg [WORD_COUNTER_WIDTH-1:0] bram_t1_wr_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t2_wr_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t3_wr_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t4_wr_addr;
-
- reg [WORD_COUNTER_WIDTH-1:0] bram_t1_rd_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t2_rd_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t3_rd_addr;
- reg [WORD_COUNTER_WIDTH-1:0] bram_t4_rd_addr;
-
- wire bram_t1_wr_en;
- wire bram_t2_wr_en;
- wire bram_t3_wr_en;
- wire bram_t4_wr_en;
-
- wire [ 32-1:0] bram_t1_wr_data;
- wire [ 32-1:0] bram_t2_wr_data;
- wire [ 32-1:0] bram_t3_wr_data;
- wire [ 32-1:0] bram_t4_wr_data;
-
- wire [ 32-1:0] bram_t1_rd_data;
- wire [ 32-1:0] bram_t2_rd_data;
- wire [ 32-1:0] bram_t3_rd_data;
- wire [ 32-1:0] bram_t4_rd_data;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH)
- )
- bram_t1
- ( .clk (clk),
- .a_addr(bram_t1_wr_addr), .a_wr(bram_t1_wr_en), .a_in(bram_t1_wr_data), .a_out(),
- .b_addr(bram_t1_rd_addr), .b_out(bram_t1_rd_data)
- );
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH)
- )
- bram_t2
- ( .clk (clk),
- .a_addr(bram_t2_wr_addr), .a_wr(bram_t2_wr_en), .a_in(bram_t2_wr_data), .a_out(),
- .b_addr(bram_t2_rd_addr), .b_out(bram_t2_rd_data)
- );
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH)
- )
- bram_t3
- ( .clk (clk),
- .a_addr(bram_t3_wr_addr), .a_wr(bram_t3_wr_en), .a_in(bram_t3_wr_data), .a_out(),
- .b_addr(bram_t3_rd_addr), .b_out(bram_t3_rd_data)
- );
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH)
- )
- bram_t4
- ( .clk (clk),
- .a_addr(bram_t4_wr_addr), .a_wr(bram_t4_wr_en), .a_in(bram_t4_wr_data), .a_out(),
- .b_addr(bram_t4_rd_addr), .b_out(bram_t4_rd_data)
- );
-
-
- //
- // uOP Trigger Logic
- //
- reg uop_trig;
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) uop_trig <= 1'b0;
- else uop_trig <= (fsm_state == FSM_STATE_FETCH) ? 1'b1 : 1'b0;
-
-
- //
- // FSM
- //
- localparam [ 1: 0] FSM_STATE_STALL = 2'b00;
- localparam [ 1: 0] FSM_STATE_FETCH = 2'b01;
- localparam [ 1: 0] FSM_STATE_EXECUTE = 2'b10;
-
- reg [ 1: 0] fsm_state = FSM_STATE_STALL;
- wire [ 1: 0] fsm_state_next = (uop_opcode == OPCODE_RDY) ? FSM_STATE_STALL : FSM_STATE_FETCH;
-
-
- //
- // FSM Transition Logic
- //
- reg uop_done;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) fsm_state <= FSM_STATE_STALL;
- else case (fsm_state)
- FSM_STATE_STALL: fsm_state <= ena ? FSM_STATE_FETCH : FSM_STATE_STALL;
- FSM_STATE_FETCH: fsm_state <= FSM_STATE_EXECUTE;
- FSM_STATE_EXECUTE: fsm_state <= (!uop_trig && uop_done) ? fsm_state_next : FSM_STATE_EXECUTE;
- default: fsm_state <= FSM_STATE_STALL;
- endcase
-
-
- //
- // uOP Address Increment Logic
- //
- always @(posedge clk)
- //
- if (fsm_state == FSM_STATE_STALL)
- uop_addr <= 5'd0;
- else if (fsm_state == FSM_STATE_EXECUTE)
- if (!uop_trig && uop_done)
- uop_addr <= (uop_opcode == OPCODE_RDY) ? 5'd0 : uop_addr + 1'b1;
-
-
- //
- // uOP Completion Logic
- //
- always @(*)
- //
- case (uop_opcode)
- OPCODE_CMP: uop_done = mw_cmp_rdy;
- OPCODE_MOV: uop_done = mw_mov_rdy;
- OPCODE_ADD: uop_done = mod_add_rdy;
- OPCODE_SUB: uop_done = mod_sub_rdy;
- OPCODE_MUL: uop_done = mod_mul_rdy;
- OPCODE_RDY: uop_done = 1'b1;
- default: uop_done = 1'b0;
- endcase
-
-
- //
- // Helper Modules Enable Logic
- //
- assign mw_cmp_ena = uop_opcode[0] & uop_trig;
- assign mw_mov_ena = uop_opcode[1] & uop_trig;
- assign mod_add_ena = uop_opcode[2] & uop_trig;
- assign mod_sub_ena = uop_opcode[3] & uop_trig;
- assign mod_mul_ena = uop_opcode[4] & uop_trig;
-
-
- //
- // uOP Source Value Decoding Logic
- //
- reg [31: 0] uop_src_a_value;
-
- always @(*)
- //
- case (uop_src_a)
- UOP_SRC_PX: uop_src_a_value = px_din;
- UOP_SRC_PY: uop_src_a_value = py_din;
- UOP_SRC_PZ: uop_src_a_value = pz_din;
-
- UOP_SRC_RX: uop_src_a_value = rx_din;
- UOP_SRC_RY: uop_src_a_value = ry_din;
- UOP_SRC_RZ: uop_src_a_value = rz_din;
-
- UOP_SRC_T1: uop_src_a_value = bram_t1_rd_data;
- UOP_SRC_T2: uop_src_a_value = bram_t2_rd_data;
- UOP_SRC_T3: uop_src_a_value = bram_t3_rd_data;
- UOP_SRC_T4: uop_src_a_value = bram_t4_rd_data;
-
- UOP_SRC_ONE: uop_src_a_value = brom_one_dout;
- UOP_SRC_ZERO: uop_src_a_value = brom_zero_dout;
- UOP_SRC_DELTA: uop_src_a_value = brom_delta_dout;
-
- UOP_SRC_G_X: uop_src_a_value = brom_g_x_dout;
- UOP_SRC_G_Y: uop_src_a_value = brom_g_y_dout;
-
- UOP_SRC_H_X: uop_src_a_value = brom_h_x_dout;
- UOP_SRC_H_Y: uop_src_a_value = brom_h_y_dout;
-
- UOP_SRC_V: uop_src_a_value = v_din;
-
- default: uop_src_a_value = {32{1'bX}};
- endcase
-
-
- assign mw_cmp_din_x = uop_src_a_value;
- assign mw_mov_din_x = uop_src_a_value;
- assign mod_add_din_a = uop_src_a_value;
- assign mod_sub_din_a = uop_src_a_value;
- assign mod_mul_din_a = uop_src_a_value;
-
- reg [31: 0] uop_src_b_value;
-
- always @(*)
- //
- case (uop_src_b)
- UOP_SRC_PX: uop_src_b_value = px_din;
- UOP_SRC_PY: uop_src_b_value = py_din;
- UOP_SRC_PZ: uop_src_b_value = pz_din;
-
- UOP_SRC_RX: uop_src_b_value = rx_din;
- UOP_SRC_RY: uop_src_b_value = ry_din;
- UOP_SRC_RZ: uop_src_b_value = rz_din;
-
- UOP_SRC_T1: uop_src_b_value = bram_t1_rd_data;
- UOP_SRC_T2: uop_src_b_value = bram_t2_rd_data;
- UOP_SRC_T3: uop_src_b_value = bram_t3_rd_data;
- UOP_SRC_T4: uop_src_b_value = bram_t4_rd_data;
-
- UOP_SRC_ONE: uop_src_b_value = brom_one_dout;
- UOP_SRC_ZERO: uop_src_b_value = brom_zero_dout;
- UOP_SRC_DELTA: uop_src_b_value = brom_delta_dout;
-
- UOP_SRC_G_X: uop_src_b_value = brom_g_x_dout;
- UOP_SRC_G_Y: uop_src_b_value = brom_g_y_dout;
-
- UOP_SRC_H_X: uop_src_b_value = brom_h_x_dout;
- UOP_SRC_H_Y: uop_src_b_value = brom_h_y_dout;
-
- UOP_SRC_V: uop_src_b_value = v_din;
-
- default: uop_src_b_value = {32{1'bX}};
- endcase
-
- assign mw_cmp_din_y = uop_src_b_value;
- assign mod_add_din_b = uop_src_b_value;
- assign mod_sub_din_b = uop_src_b_value;
- assign mod_mul_din_b = uop_src_b_value;
-
-
- //
- // uOP Source & Destination Address Decoding Logic
- //
- reg [WORD_COUNTER_WIDTH-1:0] uop_src_a_addr;
- reg [WORD_COUNTER_WIDTH-1:0] uop_src_b_addr;
- reg [WORD_COUNTER_WIDTH-1:0] uop_dst_addr;
- reg [WORD_COUNTER_WIDTH-1:0] uop_q_addr;
-
- assign q_addr = uop_q_addr;
-
- always @(*)
- //
- case (uop_opcode)
- //
- OPCODE_CMP: begin
- uop_src_a_addr = mw_cmp_addr_xy;
- uop_src_b_addr = mw_cmp_addr_xy;
- uop_dst_addr = {WORD_COUNTER_WIDTH{1'bX}};
- uop_q_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- OPCODE_MOV: begin
- uop_src_a_addr = mw_mov_addr_x;
- uop_src_b_addr = {WORD_COUNTER_WIDTH{1'bX}};
- uop_dst_addr = mw_mov_addr_y;
- uop_q_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- OPCODE_ADD: begin
- uop_src_a_addr = mod_add_addr_ab;
- uop_src_b_addr = mod_add_addr_ab;
- uop_dst_addr = mod_add_addr_s;
- uop_q_addr = mod_add_addr_n;
- end
- //
- OPCODE_SUB: begin
- uop_src_a_addr = mod_sub_addr_ab;
- uop_src_b_addr = mod_sub_addr_ab;
- uop_dst_addr = mod_sub_addr_d;
- uop_q_addr = mod_sub_addr_n;
- end
- //
- OPCODE_MUL: begin
- uop_src_a_addr = mod_mul_addr_a;
- uop_src_b_addr = mod_mul_addr_b;
- uop_dst_addr = mod_mul_addr_p;
- uop_q_addr = mod_mul_addr_n;
- end
- //
- default: begin
- uop_src_a_addr = {WORD_COUNTER_WIDTH{1'bX}};
- uop_src_b_addr = {WORD_COUNTER_WIDTH{1'bX}};
- uop_dst_addr = {WORD_COUNTER_WIDTH{1'bX}};
- uop_q_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- endcase
-
-
- //
- // uOP Conditional Execution Logic
- //
- reg uop_exec_effective;
-
- always @(*)
- //
- case (uop_exec)
- UOP_EXEC_ALWAYS: uop_exec_effective = 1'b1;
- UOP_EXEC_PZT1T2_0XX: uop_exec_effective = flag_pz_is_zero;
- UOP_EXEC_PZT1T2_100: uop_exec_effective = !flag_pz_is_zero && flag_t1_is_zero && flag_t2_is_zero;
- UOP_EXEC_PZT1T2_101: uop_exec_effective = !flag_pz_is_zero && flag_t1_is_zero && !flag_t2_is_zero;
- endcase
-
-
- //
- // uOP Destination Store Logic
- //
- reg uop_dst_wren;
-
- always @(*)
- //
- case (uop_opcode)
- //
- OPCODE_MOV: uop_dst_wren = mw_mov_wren_y & uop_exec_effective;
- OPCODE_ADD: uop_dst_wren = mod_add_wren_s;
- OPCODE_SUB: uop_dst_wren = mod_sub_wren_d;
- OPCODE_MUL: uop_dst_wren = mod_mul_wren_p;
- default: uop_dst_wren = 1'b0;
- //
- endcase
-
-
- always @(*) begin
- //
- //
- //
- if (uop_src_a == UOP_SRC_PX) px_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_PX) px_addr = uop_src_b_addr;
- else px_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_PY) py_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_PY) py_addr = uop_src_b_addr;
- else py_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_PZ) pz_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_PZ) pz_addr = uop_src_b_addr;
- else pz_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_src_a == UOP_SRC_ONE) brom_one_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_ONE) brom_one_addr = uop_src_b_addr;
- else brom_one_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //if (uop_src_a == UOP_SRC_ZERO) brom_zero_addr = uop_src_a_addr;
- //else if (uop_src_b == UOP_SRC_ZERO) brom_zero_addr = uop_src_b_addr;
- //else brom_zero_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_DELTA) brom_delta_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_DELTA) brom_delta_addr = uop_src_b_addr;
- else brom_delta_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_src_a == UOP_SRC_G_X) brom_g_x_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_G_X) brom_g_x_addr = uop_src_b_addr;
- else brom_g_x_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_G_Y) brom_g_y_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_G_Y) brom_g_y_addr = uop_src_b_addr;
- else brom_g_y_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_src_a == UOP_SRC_H_X) brom_h_x_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_H_X) brom_h_x_addr = uop_src_b_addr;
- else brom_h_x_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_H_Y) brom_h_y_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_H_Y) brom_h_y_addr = uop_src_b_addr;
- else brom_h_y_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_src_a == UOP_SRC_V) v_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_V) v_addr = uop_src_b_addr;
- else v_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_src_a == UOP_SRC_T1) bram_t1_rd_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_T1) bram_t1_rd_addr = uop_src_b_addr;
- else bram_t1_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_T2) bram_t2_rd_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_T2) bram_t2_rd_addr = uop_src_b_addr;
- else bram_t2_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_T3) bram_t3_rd_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_T3) bram_t3_rd_addr = uop_src_b_addr;
- else bram_t3_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_src_a == UOP_SRC_T4) bram_t4_rd_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_T4) bram_t4_rd_addr = uop_src_b_addr;
- else bram_t4_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if (uop_dst == UOP_DST_T1) bram_t1_wr_addr = uop_dst_addr;
- else bram_t1_wr_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_dst == UOP_DST_T2) bram_t2_wr_addr = uop_dst_addr;
- else bram_t2_wr_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_dst == UOP_DST_T3) bram_t3_wr_addr = uop_dst_addr;
- else bram_t3_wr_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- if (uop_dst == UOP_DST_T4) bram_t4_wr_addr = uop_dst_addr;
- else bram_t4_wr_addr = {WORD_COUNTER_WIDTH{1'bX}};
- //
- //
- //
- if ((uop_dst == UOP_DST_RX) && (uop_dst_wren)) rx_addr = uop_dst_addr;
- else begin
- if (uop_src_a == UOP_SRC_RX) rx_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_RX) rx_addr = uop_src_b_addr;
- else rx_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- if ((uop_dst == UOP_DST_RY) && (uop_dst_wren)) ry_addr = uop_dst_addr;
- else begin
- if (uop_src_a == UOP_SRC_RY) ry_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_RY) ry_addr = uop_src_b_addr;
- else ry_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- if ((uop_dst == UOP_DST_RZ) && (uop_dst_wren)) rz_addr = uop_dst_addr;
- else begin
- if (uop_src_a == UOP_SRC_RZ) rz_addr = uop_src_a_addr;
- else if (uop_src_b == UOP_SRC_RZ) rz_addr = uop_src_b_addr;
- else rz_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- end
-
-
- assign rx_wren = uop_dst_wren && (uop_dst == UOP_DST_RX);
- assign ry_wren = uop_dst_wren && (uop_dst == UOP_DST_RY);
- assign rz_wren = uop_dst_wren && (uop_dst == UOP_DST_RZ);
-
- assign bram_t1_wr_en = uop_dst_wren && (uop_dst == UOP_DST_T1);
- assign bram_t2_wr_en = uop_dst_wren && (uop_dst == UOP_DST_T2);
- assign bram_t3_wr_en = uop_dst_wren && (uop_dst == UOP_DST_T3);
- assign bram_t4_wr_en = uop_dst_wren && (uop_dst == UOP_DST_T4);
-
-
-
- //
- // Destination Value Selector
- //
- reg [31: 0] uop_dst_value;
-
- always @(*)
- //
- case (uop_opcode)
-
- OPCODE_MOV: uop_dst_value = mw_mov_dout_y;
- OPCODE_ADD: uop_dst_value = mod_add_dout_s;
- OPCODE_SUB: uop_dst_value = mod_sub_dout_d;
- OPCODE_MUL: uop_dst_value = mod_mul_dout_p;
-
- default: uop_dst_value = {32{1'bX}};
-
- endcase
-
- assign rx_dout = uop_dst_value;
- assign ry_dout = uop_dst_value;
- assign rz_dout = uop_dst_value;
-
- assign bram_t1_wr_data = uop_dst_value;
- assign bram_t2_wr_data = uop_dst_value;
- assign bram_t3_wr_data = uop_dst_value;
- assign bram_t4_wr_data = uop_dst_value;
-
-
- //
- // Latch Comparison Flags
- //
- always @(posedge clk)
- //
- if ( (fsm_state == FSM_STATE_EXECUTE) &&
- (uop_opcode == OPCODE_CMP) &&
- (uop_done && !uop_trig) ) begin
-
- if ( (uop_src_a == UOP_SRC_PZ) && (uop_src_b == UOP_SRC_ZERO) )
- flag_pz_is_zero <= !mw_cmp_out_l && mw_cmp_out_e && !mw_cmp_out_g;
-
- if ( (uop_src_a == UOP_SRC_T1) && (uop_src_b == UOP_SRC_ZERO) )
- flag_t1_is_zero <= !mw_cmp_out_l && mw_cmp_out_e && !mw_cmp_out_g;
-
- if ( (uop_src_a == UOP_SRC_T2) && (uop_src_b == UOP_SRC_ZERO) )
- flag_t2_is_zero <= !mw_cmp_out_l && mw_cmp_out_e && !mw_cmp_out_g;
-
- end
-
-
- //
- // Ready Flag Logic
- //
- reg rdy_reg = 1'b1;
- assign rdy = rdy_reg;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) rdy_reg <= 1'b1;
- else begin
-
- /* clear flag */
- if (fsm_state == FSM_STATE_STALL)
- if (ena) rdy_reg <= 1'b0;
-
- /* set flag */
- if ((fsm_state == FSM_STATE_EXECUTE) && !uop_trig && uop_done)
- if (uop_opcode == OPCODE_RDY) rdy_reg <= 1'b1;
-
- end
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
diff --git a/rtl/curve/curve_mul_256.v b/rtl/curve/curve_mul_256.v
deleted file mode 100644
index 0ac2be0..0000000
--- a/rtl/curve/curve_mul_256.v
+++ /dev/null
@@ -1,720 +0,0 @@
-//------------------------------------------------------------------------------
-//
-// curve_mul_256.v
-// -----------------------------------------------------------------------------
-// Elliptic curve point scalar multiplier.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module curve_mul_256
- (
- clk, rst_n,
- ena, rdy,
- k_addr, rx_addr, ry_addr,
- rx_wren, ry_wren,
- k_din,
- rx_dout, ry_dout
- );
-
-
- //
- // Constants
- //
- localparam WORD_COUNTER_WIDTH = 3; // 0 .. 7
- localparam OPERAND_NUM_WORDS = 8; // 8 * 32 = 256
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [ 2: 0] k_addr;
- output wire [ 2: 0] rx_addr;
- output wire [ 2: 0] ry_addr;
-
- output wire rx_wren;
- output wire ry_wren;
-
- input wire [31: 0] k_din;
-
- output wire [31: 0] rx_dout;
- output wire [31: 0] ry_dout;
-
-
- //
- // Temporary Variables
- //
- reg [ 2: 0] bram_tx_wr_addr;
- reg [ 2: 0] bram_ty_wr_addr;
- reg [ 2: 0] bram_tz_wr_addr;
-
- reg [ 2: 0] bram_rx_wr_addr;
- reg [ 2: 0] bram_ry_wr_addr;
- reg [ 2: 0] bram_rz_wr_addr;
- wire [ 2: 0] bram_rz1_wr_addr;
-
- reg [ 2: 0] bram_tx_rd_addr;
- reg [ 2: 0] bram_ty_rd_addr;
- reg [ 2: 0] bram_tz_rd_addr;
-
- reg [ 2: 0] bram_rx_rd_addr;
- reg [ 2: 0] bram_ry_rd_addr;
- reg [ 2: 0] bram_rz_rd_addr;
- wire [ 2: 0] bram_rz1_rd_addr;
-
- reg bram_tx_wr_en;
- reg bram_ty_wr_en;
- reg bram_tz_wr_en;
-
- reg bram_rx_wr_en;
- reg bram_ry_wr_en;
- reg bram_rz_wr_en;
- wire bram_rz1_wr_en;
-
- wire [31: 0] bram_tx_rd_data;
- wire [31: 0] bram_ty_rd_data;
- wire [31: 0] bram_tz_rd_data;
-
- wire [31: 0] bram_rx_rd_data;
- wire [31: 0] bram_ry_rd_data;
- wire [31: 0] bram_rz_rd_data;
- wire [31: 0] bram_rz1_rd_data;
-
- reg [31: 0] bram_tx_wr_data_in;
- reg [31: 0] bram_ty_wr_data_in;
- reg [31: 0] bram_tz_wr_data_in;
-
- reg [31: 0] bram_rx_wr_data_in;
- reg [31: 0] bram_ry_wr_data_in;
- reg [31: 0] bram_rz_wr_data_in;
- wire [31: 0] bram_rz1_wr_data_in;
-
- wire [31: 0] bram_tx_wr_data_out;
- wire [31: 0] bram_ty_wr_data_out;
- wire [31: 0] bram_tz_wr_data_out;
-
- wire [31: 0] bram_rx_wr_data_out;
- wire [31: 0] bram_ry_wr_data_out;
- wire [31: 0] bram_rz_wr_data_out;
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_tx (.clk(clk),
- .a_addr(bram_tx_wr_addr), .a_wr(bram_tx_wr_en), .a_in(bram_tx_wr_data_in), .a_out(bram_tx_wr_data_out),
- .b_addr(bram_tx_rd_addr), .b_out(bram_tx_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_ty (.clk(clk),
- .a_addr(bram_ty_wr_addr), .a_wr(bram_ty_wr_en), .a_in(bram_ty_wr_data_in), .a_out(bram_ty_wr_data_out),
- .b_addr(bram_ty_rd_addr), .b_out(bram_ty_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_tz (.clk(clk),
- .a_addr(bram_tz_wr_addr), .a_wr(bram_tz_wr_en), .a_in(bram_tz_wr_data_in), .a_out(bram_tz_wr_data_out),
- .b_addr(bram_tz_rd_addr), .b_out(bram_tz_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_rx (.clk(clk),
- .a_addr(bram_rx_wr_addr), .a_wr(bram_rx_wr_en), .a_in(bram_rx_wr_data_in), .a_out(bram_rx_wr_data_out),
- .b_addr(bram_rx_rd_addr), .b_out(bram_rx_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_ry (.clk(clk),
- .a_addr(bram_ry_wr_addr), .a_wr(bram_ry_wr_en), .a_in(bram_ry_wr_data_in), .a_out(bram_ry_wr_data_out),
- .b_addr(bram_ry_rd_addr), .b_out(bram_ry_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_rz (.clk(clk),
- .a_addr(bram_rz_wr_addr), .a_wr(bram_rz_wr_en), .a_in(bram_rz_wr_data_in), .a_out(bram_rz_wr_data_out),
- .b_addr(bram_rz_rd_addr), .b_out(bram_rz_rd_data));
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(3))
- bram_rz1 (.clk(clk),
- .a_addr(bram_rz1_wr_addr), .a_wr(bram_rz1_wr_en), .a_in(bram_rz1_wr_data_in), .a_out(),
- .b_addr(bram_rz1_rd_addr), .b_out(bram_rz1_rd_data));
-
-
- //
- // FSM
- //
- localparam [ 3: 0] FSM_STATE_IDLE = 4'd00;
- localparam [ 3: 0] FSM_STATE_PREPARE_TRIG = 4'd01;
- localparam [ 3: 0] FSM_STATE_PREPARE_WAIT = 4'd02;
- localparam [ 3: 0] FSM_STATE_DOUBLE_TRIG = 4'd03;
- localparam [ 3: 0] FSM_STATE_DOUBLE_WAIT = 4'd04;
- localparam [ 3: 0] FSM_STATE_ADD_TRIG = 4'd05;
- localparam [ 3: 0] FSM_STATE_ADD_WAIT = 4'd06;
- localparam [ 3: 0] FSM_STATE_COPY_TRIG = 4'd07;
- localparam [ 3: 0] FSM_STATE_COPY_WAIT = 4'd08;
- localparam [ 3: 0] FSM_STATE_INVERT_TRIG = 4'd09;
- localparam [ 3: 0] FSM_STATE_INVERT_WAIT = 4'd10;
- localparam [ 3: 0] FSM_STATE_CONVERT_TRIG = 4'd11;
- localparam [ 3: 0] FSM_STATE_CONVERT_WAIT = 4'd12;
- localparam [ 3: 0] FSM_STATE_DONE = 4'd13;
-
- reg [3:0] fsm_state = FSM_STATE_IDLE;
-
-
- //
- // Round Counter
- //
- reg [ 7: 0] bit_counter;
- wire [ 7: 0] bit_counter_max = 8'd255;
- wire [ 7: 0] bit_counter_zero = 8'd0;
- wire [ 7: 0] bit_counter_next =
- (bit_counter < bit_counter_max) ? bit_counter + 1'b1 : bit_counter_zero;
-
-
- //
- // Round Completion
- //
- wire [ 3: 0] fsm_state_round_next = (bit_counter < bit_counter_max) ?
- FSM_STATE_DOUBLE_TRIG : FSM_STATE_INVERT_TRIG;
-
-
- //
- // OP Trigger Logic
- //
- reg op_trig;
- wire op_done;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) op_trig <= 1'b0;
- else op_trig <= (fsm_state == FSM_STATE_PREPARE_TRIG) ||
- (fsm_state == FSM_STATE_DOUBLE_TRIG) ||
- (fsm_state == FSM_STATE_ADD_TRIG) ||
- (fsm_state == FSM_STATE_CONVERT_TRIG);
-
- //
- // Microprograms
- //
- wire [ 5: 0] op_rom_addr;
- wire [19: 0] op_rom_init_data;
- wire [19: 0] op_rom_dbl_data;
- wire [19: 0] op_rom_add_data;
- wire [19: 0] op_rom_conv_data;
- reg [19: 0] op_rom_mux_data;
-
- (* RAM_STYLE="BLOCK" *)
- uop_init_rom op_rom_init
- (
- .clk (clk),
- .addr (op_rom_addr),
- .data (op_rom_init_data)
- );
-
- (* RAM_STYLE="BLOCK" *)
- uop_dbl_rom op_rom_dbl
- (
- .clk (clk),
- .addr (op_rom_addr),
- .data (op_rom_dbl_data)
- );
-
- (* RAM_STYLE="BLOCK" *)
- uop_add_rom op_rom_add
- (
- .clk (clk),
- .addr (op_rom_addr),
- .data (op_rom_add_data)
- );
-
- (* RAM_STYLE="BLOCK" *)
- uop_conv_rom op_rom_conv
- (
- .clk (clk),
- .addr (op_rom_addr),
- .data (op_rom_conv_data)
- );
-
- always @(*)
- //
- case (fsm_state)
- FSM_STATE_PREPARE_WAIT: op_rom_mux_data = op_rom_init_data;
- FSM_STATE_DOUBLE_WAIT: op_rom_mux_data = op_rom_dbl_data;
- FSM_STATE_ADD_WAIT: op_rom_mux_data = op_rom_add_data;
- FSM_STATE_CONVERT_WAIT: op_rom_mux_data = op_rom_conv_data;
- default: op_rom_mux_data = {20{1'bX}};
- endcase
-
-
-
- //
- // Modulus
- //
- reg [ 2: 0] rom_q_addr;
- wire [31: 0] rom_q_data;
-
- brom_p256_q rom_q
- (
- .clk (clk),
- .b_addr (rom_q_addr),
- .b_out (rom_q_data)
- );
-
-
- //
- // Worker
- //
- wire [ 2: 0] worker_addr_px;
- wire [ 2: 0] worker_addr_py;
- wire [ 2: 0] worker_addr_pz;
-
- wire [ 2: 0] worker_addr_rx;
- wire [ 2: 0] worker_addr_ry;
- wire [ 2: 0] worker_addr_rz;
-
- wire [ 2: 0] worker_addr_q;
-
- wire worker_wren_rx;
- wire worker_wren_ry;
- wire worker_wren_rz;
-
- reg [31: 0] worker_din_px;
- reg [31: 0] worker_din_py;
- reg [31: 0] worker_din_pz;
-
- reg [31: 0] worker_din_rx;
- reg [31: 0] worker_din_ry;
- reg [31: 0] worker_din_rz;
-
- wire [31: 0] worker_dout_rx;
- wire [31: 0] worker_dout_ry;
- wire [31: 0] worker_dout_rz;
-
- curve_dbl_add_256 worker
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (op_trig),
- .rdy (op_done),
-
- .uop_addr (op_rom_addr),
- .uop (op_rom_mux_data),
-
- .px_addr (worker_addr_px),
- .py_addr (worker_addr_py),
- .pz_addr (worker_addr_pz),
-
- .rx_addr (worker_addr_rx),
- .ry_addr (worker_addr_ry),
- .rz_addr (worker_addr_rz),
-
- .q_addr (worker_addr_q),
-
- .v_addr (bram_rz1_rd_addr),
-
- .rx_wren (worker_wren_rx),
- .ry_wren (worker_wren_ry),
- .rz_wren (worker_wren_rz),
-
- .px_din (worker_din_px),
- .py_din (worker_din_py),
- .pz_din (worker_din_pz),
-
- .rx_din (worker_din_rx),
- .ry_din (worker_din_ry),
- .rz_din (worker_din_rz),
-
- .rx_dout (worker_dout_rx),
- .ry_dout (worker_dout_ry),
- .rz_dout (worker_dout_rz),
-
- .q_din (rom_q_data),
-
- .v_din (bram_rz1_rd_data)
- );
-
-
- //
- // Mover
- //
- reg move_trig;
- wire move_done;
-
- wire [ 2: 0] mover_addr_x;
- wire [ 2: 0] mover_addr_y;
-
- wire mover_wren_y;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) move_trig <= 1'b0;
- else move_trig <= (fsm_state == FSM_STATE_COPY_TRIG);
-
- mw_mover #
- (
- .WORD_COUNTER_WIDTH (3),
- .OPERAND_NUM_WORDS (8)
- )
- mover
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (move_trig),
- .rdy (move_done),
-
- .x_addr (mover_addr_x),
- .y_addr (mover_addr_y),
- .y_wren (mover_wren_y),
-
- .x_din ({32{1'bX}}),
- .y_dout ()
- );
-
-
- //
- // Invertor
- //
- reg invert_trig;
- wire invert_done;
-
- wire [ 2: 0] invertor_addr_a;
- wire [ 2: 0] invertor_addr_q;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) invert_trig <= 1'b0;
- else invert_trig <= (fsm_state == FSM_STATE_INVERT_TRIG);
-
- modular_invertor #
- (
- .MAX_OPERAND_WIDTH(256)
- )
- invertor
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (invert_trig),
- .rdy (invert_done),
-
- .a_addr (invertor_addr_a),
- .q_addr (invertor_addr_q),
- .a1_addr (bram_rz1_wr_addr),
- .a1_wren (bram_rz1_wr_en),
-
- .a_din (bram_rz_rd_data),
- .q_din (rom_q_data),
- .a1_dout (bram_rz1_wr_data_in)
- );
-
-
- //
- // FSM Transition Logic
- //
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) fsm_state <= FSM_STATE_IDLE;
- else case (fsm_state)
-
- FSM_STATE_IDLE: fsm_state <= ena ? FSM_STATE_PREPARE_TRIG : FSM_STATE_IDLE;
-
- FSM_STATE_PREPARE_TRIG: fsm_state <= FSM_STATE_PREPARE_WAIT;
- FSM_STATE_PREPARE_WAIT: fsm_state <= (!op_trig && op_done) ? FSM_STATE_DOUBLE_TRIG : FSM_STATE_PREPARE_WAIT;
-
- FSM_STATE_DOUBLE_TRIG: fsm_state <= FSM_STATE_DOUBLE_WAIT;
- FSM_STATE_DOUBLE_WAIT: fsm_state <= (!op_trig && op_done) ? FSM_STATE_ADD_TRIG : FSM_STATE_DOUBLE_WAIT;
-
- FSM_STATE_ADD_TRIG: fsm_state <= FSM_STATE_ADD_WAIT;
- FSM_STATE_ADD_WAIT: fsm_state <= (!op_trig && op_done) ? FSM_STATE_COPY_TRIG : FSM_STATE_ADD_WAIT;
-
- FSM_STATE_COPY_TRIG: fsm_state <= FSM_STATE_COPY_WAIT;
- FSM_STATE_COPY_WAIT: fsm_state <= (!move_trig && move_done) ? fsm_state_round_next : FSM_STATE_COPY_WAIT;
-
- FSM_STATE_INVERT_TRIG: fsm_state <= FSM_STATE_INVERT_WAIT;
- FSM_STATE_INVERT_WAIT: fsm_state <= (!invert_trig && invert_done) ? FSM_STATE_CONVERT_TRIG : FSM_STATE_INVERT_WAIT;
-
- FSM_STATE_CONVERT_TRIG: fsm_state <= FSM_STATE_CONVERT_WAIT;
- FSM_STATE_CONVERT_WAIT: fsm_state <= (!op_trig && op_done) ? FSM_STATE_DONE : FSM_STATE_CONVERT_WAIT;
-
- FSM_STATE_DONE: fsm_state <= FSM_STATE_IDLE;
-
- default: fsm_state <= FSM_STATE_IDLE;
-
- endcase
-
-
- //
- // Bit Counter Increment
- //
- always @(posedge clk) begin
- //
- if ((fsm_state == FSM_STATE_PREPARE_WAIT) && !op_trig && op_done)
- bit_counter <= bit_counter_zero;
- //
- if ((fsm_state == FSM_STATE_COPY_WAIT) && !move_trig && move_done)
- bit_counter <= bit_counter_next;
- //
- end
-
-
- //
- // K Latch Logic
- //
- reg [ 2: 0] k_addr_reg;
- reg [31: 0] k_din_reg;
-
- assign k_addr = k_addr_reg;
-
- always @(posedge clk) begin
- //
- if (fsm_state == FSM_STATE_DOUBLE_TRIG)
- k_addr_reg <= 3'd7 - bit_counter[7:5];
- //
- if (fsm_state == FSM_STATE_ADD_TRIG)
- k_din_reg <= (bit_counter[4:0] == 5'd0) ? k_din : {k_din_reg[30:0], 1'bX};
- //
- end
-
-
-
- //
- // Copy Inhibit Logic
- //
- wire move_inhibit = k_din_reg[31];
-
- wire copy_t2r_int = mover_wren_y & ~move_inhibit;
-
-
- always @(*) begin
- //
- // Q
- //
- case (fsm_state)
- FSM_STATE_DOUBLE_WAIT: rom_q_addr = worker_addr_q;
- FSM_STATE_ADD_WAIT: rom_q_addr = worker_addr_q;
- FSM_STATE_INVERT_WAIT: rom_q_addr = invertor_addr_q;
- FSM_STATE_CONVERT_WAIT: rom_q_addr = worker_addr_q;
- default: rom_q_addr = worker_addr_q;
- endcase
-
- //
- // R(X,Y,Z)
- //
- case (fsm_state)
- //
- FSM_STATE_PREPARE_WAIT: begin
- //
- bram_rx_rd_addr <= {3{1'bX}}; bram_ry_rd_addr <= {3{1'bX}}; bram_rz_rd_addr <= {3{1'bX}};
- bram_rx_wr_addr <= worker_addr_rx; bram_ry_wr_addr <= worker_addr_ry; bram_rz_wr_addr <= worker_addr_rz;
- bram_rx_wr_en <= worker_wren_rx; bram_ry_wr_en <= worker_wren_ry; bram_rz_wr_en <= worker_wren_rz;
- bram_rx_wr_data_in <= worker_dout_rx; bram_ry_wr_data_in <= worker_dout_ry; bram_rz_wr_data_in <= worker_dout_rz;
- //
- end
- //
- FSM_STATE_DOUBLE_WAIT: begin
- //
- bram_rx_rd_addr <= worker_addr_px; bram_ry_rd_addr <= worker_addr_py; bram_rz_rd_addr <= worker_addr_pz;
- bram_rx_wr_addr <= {3{1'bX}}; bram_ry_wr_addr <= {3{1'bX}}; bram_rz_wr_addr <= {3{1'bX}};
- bram_rx_wr_en <= 1'b0; bram_ry_wr_en <= 1'b0; bram_rz_wr_en <= 1'b0;
- bram_rx_wr_data_in <= {32{1'bX}}; bram_ry_wr_data_in <= {32{1'bX}}; bram_rz_wr_data_in <= {32{1'bX}};
- //
- end
- //
- FSM_STATE_ADD_WAIT: begin
- //
- bram_rx_rd_addr <= {3{1'bX}}; bram_ry_rd_addr <= {3{1'bX}}; bram_rz_rd_addr <= {3{1'bX}};
- bram_rx_wr_addr <= worker_addr_rx; bram_ry_wr_addr <= worker_addr_ry; bram_rz_wr_addr <= worker_addr_rz;
- bram_rx_wr_en <= worker_wren_rx; bram_ry_wr_en <= worker_wren_ry; bram_rz_wr_en <= worker_wren_rz;
- bram_rx_wr_data_in <= worker_dout_rx; bram_ry_wr_data_in <= worker_dout_ry; bram_rz_wr_data_in <= worker_dout_rz;
- //
- end
- //
- FSM_STATE_COPY_WAIT: begin
- //
- bram_rx_rd_addr <= {3{1'bX}}; bram_ry_rd_addr <= {3{1'bX}}; bram_rz_rd_addr <= {3{1'bX}};
- bram_rx_wr_addr <= mover_addr_y; bram_ry_wr_addr <= mover_addr_y; bram_rz_wr_addr <= mover_addr_y;
- bram_rx_wr_en <= copy_t2r_int; bram_ry_wr_en <= copy_t2r_int; bram_rz_wr_en <= copy_t2r_int;
- bram_rx_wr_data_in <= bram_tx_rd_data; bram_ry_wr_data_in <= bram_ty_rd_data; bram_rz_wr_data_in <= bram_tz_rd_data;
- //
- end
- //
- FSM_STATE_INVERT_WAIT: begin
- //
- bram_rx_rd_addr <= {3{1'bX}}; bram_ry_rd_addr <= {3{1'bX}}; bram_rz_rd_addr <= invertor_addr_a;
- bram_rx_wr_addr <= {3{1'bX}}; bram_ry_wr_addr <= {3{1'bX}}; bram_rz_wr_addr <= {3{1'bX}};
- bram_rx_wr_en <= 1'b0; bram_ry_wr_en <= 1'b0; bram_rz_wr_en <= 1'b0;
- bram_rx_wr_data_in <= {32{1'bX}}; bram_ry_wr_data_in <= {32{1'bX}}; bram_rz_wr_data_in <= {32{1'bX}};
- //
- end
- //
- FSM_STATE_CONVERT_WAIT: begin
- //
- bram_rx_rd_addr <= worker_addr_px; bram_ry_rd_addr <= worker_addr_py; bram_rz_rd_addr <= worker_addr_pz;
- bram_rx_wr_addr <= {3{1'bX}}; bram_ry_wr_addr <= {3{1'bX}}; bram_rz_wr_addr <= {3{1'bX}};
- bram_rx_wr_en <= 1'b0; bram_ry_wr_en <= 1'b0; bram_rz_wr_en <= 1'b0;
- bram_rx_wr_data_in <= {32{1'bX}}; bram_ry_wr_data_in <= {32{1'bX}}; bram_rz_wr_data_in <= {32{1'bX}};
- //
- end
-
- //
- default: begin
- //
- bram_rx_rd_addr <= {3{1'bX}}; bram_ry_rd_addr <= {3{1'bX}}; bram_rz_rd_addr <= {3{1'bX}};
- bram_rx_wr_addr <= {3{1'bX}}; bram_ry_wr_addr <= {3{1'bX}}; bram_rz_wr_addr <= {3{1'bX}};
- bram_rx_wr_en <= 1'b0; bram_ry_wr_en <= 1'b0; bram_rz_wr_en <= 1'b0;
- bram_rx_wr_data_in <= {32{1'bX}}; bram_ry_wr_data_in <= {32{1'bX}}; bram_rz_wr_data_in <= {32{1'bX}};
- //
- end
- //
- endcase
- //
- // T(X,Y,Z)
- //
- case (fsm_state)
- //
- FSM_STATE_DOUBLE_WAIT: begin
- //
- bram_tx_rd_addr <= {3{1'bX}}; bram_ty_rd_addr <= {3{1'bX}}; bram_tz_rd_addr <= {3{1'bX}};
- bram_tx_wr_addr <= worker_addr_rx; bram_ty_wr_addr <= worker_addr_ry; bram_tz_wr_addr <= worker_addr_rz;
- bram_tx_wr_en <= worker_wren_rx; bram_ty_wr_en <= worker_wren_ry; bram_tz_wr_en <= worker_wren_rz;
- bram_tx_wr_data_in <= worker_dout_rx; bram_ty_wr_data_in <= worker_dout_ry; bram_tz_wr_data_in <= worker_dout_rz;
- //
- end
- //
- FSM_STATE_ADD_WAIT: begin
- //
- bram_tx_rd_addr <= worker_addr_px; bram_ty_rd_addr <= worker_addr_py; bram_tz_rd_addr <= worker_addr_pz;
- bram_tx_wr_addr <= {3{1'bX}}; bram_ty_wr_addr <= {3{1'bX}}; bram_tz_wr_addr <= {3{1'bX}};
- bram_tx_wr_en <= 1'b0; bram_ty_wr_en <= 1'b0; bram_tz_wr_en <= 1'b0;
- bram_tx_wr_data_in <= {32{1'bX}}; bram_ty_wr_data_in <= {32{1'bX}}; bram_tz_wr_data_in <= {32{1'bX}};
- //
- end
- //
- FSM_STATE_COPY_WAIT: begin
- //
- bram_tx_rd_addr <= mover_addr_x; bram_ty_rd_addr <= mover_addr_x; bram_tz_rd_addr <= mover_addr_x;
- bram_tx_wr_addr <= {3{1'bX}}; bram_ty_wr_addr <= {3{1'bX}}; bram_tz_wr_addr <= {3{1'bX}};
- bram_tx_wr_en <= 1'b0; bram_ty_wr_en <= 1'b0; bram_tz_wr_en <= 1'b0;
- bram_tx_wr_data_in <= {32{1'bX}}; bram_ty_wr_data_in <= {32{1'bX}}; bram_tz_wr_data_in <= {32{1'bX}};
- //
- end
-
- //
- default: begin
- //
- bram_tx_rd_addr <= {3{1'bX}}; bram_ty_rd_addr <= {3{1'bX}}; bram_tz_rd_addr <= {3{1'bX}};
- bram_tx_wr_addr <= {3{1'bX}}; bram_ty_wr_addr <= {3{1'bX}}; bram_tz_wr_addr <= {3{1'bX}};
- bram_tx_wr_en <= 1'b0; bram_ty_wr_en <= 1'b0; bram_tz_wr_en <= 1'b0;
- bram_tx_wr_data_in <= {32{1'bX}}; bram_ty_wr_data_in <= {32{1'bX}}; bram_tz_wr_data_in <= {32{1'bX}};
- //
- end
- //
- endcase
- //
- // Worker
- //
- case (fsm_state)
- //
- FSM_STATE_DOUBLE_WAIT: begin
- //
- worker_din_px <= bram_rx_rd_data; worker_din_py <= bram_ry_rd_data; worker_din_pz <= bram_rz_rd_data;
- worker_din_rx <= bram_tx_wr_data_out; worker_din_ry <= bram_ty_wr_data_out; worker_din_rz <= bram_tz_wr_data_out;
- //
- end
- //
- FSM_STATE_ADD_WAIT: begin
- //
- worker_din_px <= bram_tx_rd_data; worker_din_py <= bram_ty_rd_data; worker_din_pz <= bram_tz_rd_data;
- worker_din_rx <= bram_rx_wr_data_out; worker_din_ry <= bram_ry_wr_data_out; worker_din_rz <= bram_rz_wr_data_out;
- //
- end
- //
- FSM_STATE_CONVERT_WAIT: begin
- //
- worker_din_px <= bram_rx_rd_data; worker_din_py <= bram_ry_rd_data; worker_din_pz <= bram_rz_rd_data;
- worker_din_rx <= {32{1'bX}}; worker_din_ry <= {32{1'bX}}; worker_din_rz <= {32{1'bX}};
- //
- end
- //
- default: begin
- //
- worker_din_px <= {32{1'bX}}; worker_din_py <= {32{1'bX}}; worker_din_pz <= {32{1'bX}};
- worker_din_rx <= {32{1'bX}}; worker_din_ry <= {32{1'bX}}; worker_din_rz <= {32{1'bX}};
- //
- end
- //
- endcase
- //
- end
-
-
- //
- // Output Mapping
- //
- assign rx_wren = worker_wren_rx && (fsm_state == FSM_STATE_CONVERT_WAIT);
- assign ry_wren = worker_wren_ry && (fsm_state == FSM_STATE_CONVERT_WAIT);
-
- assign rx_dout = worker_dout_rx;
- assign ry_dout = worker_dout_ry;
-
- assign rx_addr = worker_addr_rx;
- assign ry_addr = worker_addr_ry;
-
-
- //
- // Ready Flag Logic
- //
- reg rdy_reg = 1'b1;
- assign rdy = rdy_reg;
-
- always @(posedge clk or negedge rst_n)
-
- if (rst_n == 1'b0) rdy_reg <= 1'b1;
- else begin
-
- /* clear flag */
- if ((fsm_state == FSM_STATE_IDLE) && ena)
- rdy_reg <= 1'b0;
-
- /* set flag */
- if (fsm_state == FSM_STATE_DONE)
- rdy_reg <= 1'b1;
-
- end
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
diff --git a/rtl/curve/rom/brom_p256_delta.v b/rtl/curve/rom/brom_p256_delta.v
deleted file mode 100644
index b9a345a..0000000
--- a/rtl/curve/rom/brom_p256_delta.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_delta
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'h00000000;
- 3'b001: bram_reg_b <= 32'h00000000;
- 3'b010: bram_reg_b <= 32'h80000000;
- 3'b011: bram_reg_b <= 32'h00000000;
- 3'b100: bram_reg_b <= 32'h00000000;
- 3'b101: bram_reg_b <= 32'h80000000;
- 3'b110: bram_reg_b <= 32'h80000000;
- 3'b111: bram_reg_b <= 32'h7fffffff;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_g_x.v b/rtl/curve/rom/brom_p256_g_x.v
deleted file mode 100644
index 0816ef6..0000000
--- a/rtl/curve/rom/brom_p256_g_x.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_g_x
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'hd898c296;
- 3'b001: bram_reg_b <= 32'hf4a13945;
- 3'b010: bram_reg_b <= 32'h2deb33a0;
- 3'b011: bram_reg_b <= 32'h77037d81;
- 3'b100: bram_reg_b <= 32'h63a440f2;
- 3'b101: bram_reg_b <= 32'hf8bce6e5;
- 3'b110: bram_reg_b <= 32'he12c4247;
- 3'b111: bram_reg_b <= 32'h6b17d1f2;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_g_y.v b/rtl/curve/rom/brom_p256_g_y.v
deleted file mode 100644
index 4d9c61e..0000000
--- a/rtl/curve/rom/brom_p256_g_y.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_g_y
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'h37bf51f5;
- 3'b001: bram_reg_b <= 32'hcbb64068;
- 3'b010: bram_reg_b <= 32'h6b315ece;
- 3'b011: bram_reg_b <= 32'h2bce3357;
- 3'b100: bram_reg_b <= 32'h7c0f9e16;
- 3'b101: bram_reg_b <= 32'h8ee7eb4a;
- 3'b110: bram_reg_b <= 32'hfe1a7f9b;
- 3'b111: bram_reg_b <= 32'h4fe342e2;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_h_x.v b/rtl/curve/rom/brom_p256_h_x.v
deleted file mode 100644
index 0b69f77..0000000
--- a/rtl/curve/rom/brom_p256_h_x.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_h_x
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'h4ece7ad0;
- 3'b001: bram_reg_b <= 32'h16bd8d74;
- 3'b010: bram_reg_b <= 32'ha42998be;
- 3'b011: bram_reg_b <= 32'h11f904fe;
- 3'b100: bram_reg_b <= 32'h38b77e1b;
- 3'b101: bram_reg_b <= 32'h0e863235;
- 3'b110: bram_reg_b <= 32'h3da77b71;
- 3'b111: bram_reg_b <= 32'h29d05c19;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_h_y.v b/rtl/curve/rom/brom_p256_h_y.v
deleted file mode 100644
index 362fce6..0000000
--- a/rtl/curve/rom/brom_p256_h_y.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_h_y
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'hc840ae07;
- 3'b001: bram_reg_b <= 32'h3449bf97;
- 3'b010: bram_reg_b <= 32'h94cea131;
- 3'b011: bram_reg_b <= 32'hd431cca9;
- 3'b100: bram_reg_b <= 32'h83f061e9;
- 3'b101: bram_reg_b <= 32'h711814b5;
- 3'b110: bram_reg_b <= 32'h01e58065;
- 3'b111: bram_reg_b <= 32'hb01cbd1c;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_one.v b/rtl/curve/rom/brom_p256_one.v
deleted file mode 100644
index 4097874..0000000
--- a/rtl/curve/rom/brom_p256_one.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_one
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'h00000001;
- 3'b001: bram_reg_b <= 32'h00000000;
- 3'b010: bram_reg_b <= 32'h00000000;
- 3'b011: bram_reg_b <= 32'h00000000;
- 3'b100: bram_reg_b <= 32'h00000000;
- 3'b101: bram_reg_b <= 32'h00000000;
- 3'b110: bram_reg_b <= 32'h00000000;
- 3'b111: bram_reg_b <= 32'h00000000;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_q.v b/rtl/curve/rom/brom_p256_q.v
deleted file mode 100644
index fe94593..0000000
--- a/rtl/curve/rom/brom_p256_q.v
+++ /dev/null
@@ -1,68 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_q
- (
- input wire clk,
- input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- //
- // Output Registers
- //
- reg [31:0] bram_reg_b;
-
- assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- always @(posedge clk)
- //
- case (b_addr)
- 3'b000: bram_reg_b <= 32'hffffffff;
- 3'b001: bram_reg_b <= 32'hffffffff;
- 3'b010: bram_reg_b <= 32'hffffffff;
- 3'b011: bram_reg_b <= 32'h00000000;
- 3'b100: bram_reg_b <= 32'h00000000;
- 3'b101: bram_reg_b <= 32'h00000000;
- 3'b110: bram_reg_b <= 32'h00000001;
- 3'b111: bram_reg_b <= 32'hffffffff;
- endcase
-
-
-endmodule
diff --git a/rtl/curve/rom/brom_p256_zero.v b/rtl/curve/rom/brom_p256_zero.v
deleted file mode 100644
index f6d19a1..0000000
--- a/rtl/curve/rom/brom_p256_zero.v
+++ /dev/null
@@ -1,70 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module brom_p256_zero
- (
- //input wire clk,
- //input wire [ 3-1:0] b_addr,
- output wire [32-1:0] b_out
- );
-
-
- assign b_out = {32{1'b0}};
-
- //
- // Output Registers
- //
- //reg [31:0] bram_reg_b;
-
- //assign b_out = bram_reg_b;
-
-
- //
- // Read-Only Port B
- //
- //always @(posedge clk)
- //
- //case (b_addr)
- //3'b000: bram_reg_b <= 32'h00000000;
- //3'b001: bram_reg_b <= 32'h00000000;
- //3'b010: bram_reg_b <= 32'h00000000;
- //3'b011: bram_reg_b <= 32'h00000000;
- //3'b100: bram_reg_b <= 32'h00000000;
- //3'b101: bram_reg_b <= 32'h00000000;
- //3'b110: bram_reg_b <= 32'h00000000;
- //3'b111: bram_reg_b <= 32'h00000000;
- //endcase
-
-
-endmodule
diff --git a/rtl/curve/uop/uop_add_rom.v b/rtl/curve/uop/uop_add_rom.v
index c807736..c94aaf8 100644
--- a/rtl/curve/uop/uop_add_rom.v
+++ b/rtl/curve/uop/uop_add_rom.v
@@ -1,44 +1,44 @@
-`timescale 1ns / 1ps
-
-module uop_add_rom
- (
- input wire clk,
- input wire [ 5: 0] addr,
- output reg [19: 0] data
- );
-
+`timescale 1ns / 1ps
- //
- // Microcode
- //
-`include "..\uop_ecdsa.v"
-
+module uop_add_rom
+ (
+ input wire clk,
+ input wire [ 5: 0] addr,
+ output reg [19: 0] data
+ );
- //
- // Addition Microprogram
- //
+
+ //
+ // Microcode
+ //
+`include "../uop_ecdsa.v"
+
+
+ //
+ // Addition Microprogram
+ //
always @(posedge clk)
- case (addr)
-
+ case (addr)
+
/* 2. */6'd00: data <= {OPCODE_CMP, UOP_SRC_PZ, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
/* 3. */6'd01: data <= {OPCODE_MOV, UOP_SRC_PZ, UOP_SRC_DUMMY, UOP_DST_T1, UOP_EXEC_ALWAYS};
- 6'd02: data <= {OPCODE_MUL, UOP_SRC_PZ, UOP_SRC_T1, UOP_DST_T1, UOP_EXEC_ALWAYS};
+ 6'd02: data <= {OPCODE_MUL, UOP_SRC_PZ, UOP_SRC_T1, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 4. */6'd03: data <= {OPCODE_MUL, UOP_SRC_PZ, UOP_SRC_T1, UOP_DST_T2, UOP_EXEC_ALWAYS};
/* 5. */6'd04: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_G_X, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 6. */6'd05: data <= {OPCODE_MUL, UOP_SRC_T2, UOP_SRC_G_Y, UOP_DST_T2, UOP_EXEC_ALWAYS};
/* 7. */6'd06: data <= {OPCODE_SUB, UOP_SRC_T1, UOP_SRC_PX, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 8. */6'd07: data <= {OPCODE_SUB, UOP_SRC_T2, UOP_SRC_PY, UOP_DST_T2, UOP_EXEC_ALWAYS};
/* 9. */6'd08: data <= {OPCODE_CMP, UOP_SRC_T1, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
- 6'd09: data <= {OPCODE_CMP, UOP_SRC_T2, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
+ 6'd09: data <= {OPCODE_CMP, UOP_SRC_T2, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
/* 10. */6'd10: data <= {OPCODE_MUL, UOP_SRC_PZ, UOP_SRC_T1, UOP_DST_RZ, UOP_EXEC_ALWAYS};
/* 11. */6'd11: data <= {OPCODE_MOV, UOP_SRC_T1, UOP_SRC_DUMMY, UOP_DST_T3, UOP_EXEC_ALWAYS};
- 6'd12: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_T3, UOP_DST_T3, UOP_EXEC_ALWAYS};
+ 6'd12: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_T3, UOP_DST_T3, UOP_EXEC_ALWAYS};
/* 12. */6'd13: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_T3, UOP_DST_T4, UOP_EXEC_ALWAYS};
/* 13. */6'd14: data <= {OPCODE_MUL, UOP_SRC_PX, UOP_SRC_T3, UOP_DST_T3, UOP_EXEC_ALWAYS};
/* 14. */6'd15: data <= {OPCODE_ADD, UOP_SRC_T3, UOP_SRC_T3, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 15. */6'd16: data <= {OPCODE_MOV, UOP_SRC_T2, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_ALWAYS};
- 6'd17: data <= {OPCODE_MUL, UOP_SRC_RX, UOP_SRC_T2, UOP_DST_RX, UOP_EXEC_ALWAYS};
+ 6'd17: data <= {OPCODE_MUL, UOP_SRC_RX, UOP_SRC_T2, UOP_DST_RX, UOP_EXEC_ALWAYS};
/* 16. */6'd18: data <= {OPCODE_SUB, UOP_SRC_RX, UOP_SRC_T1, UOP_DST_RX, UOP_EXEC_ALWAYS};
/* 17. */6'd19: data <= {OPCODE_SUB, UOP_SRC_RX, UOP_SRC_T4, UOP_DST_RX, UOP_EXEC_ALWAYS};
/* 18. */6'd20: data <= {OPCODE_SUB, UOP_SRC_T3, UOP_SRC_RX, UOP_DST_T3, UOP_EXEC_ALWAYS};
@@ -46,21 +46,21 @@ module uop_add_rom
/* 20. */6'd22: data <= {OPCODE_MUL, UOP_SRC_PY, UOP_SRC_T4, UOP_DST_T4, UOP_EXEC_ALWAYS};
/* 21. */6'd23: data <= {OPCODE_SUB, UOP_SRC_T3, UOP_SRC_T4, UOP_DST_RY, UOP_EXEC_ALWAYS};
- 6'd24: data <= {OPCODE_MOV, UOP_SRC_G_X, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
- 6'd25: data <= {OPCODE_MOV, UOP_SRC_G_Y, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
- 6'd26: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_0XX};
-
- 6'd27: data <= {OPCODE_MOV, UOP_SRC_H_X, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_100};
- 6'd28: data <= {OPCODE_MOV, UOP_SRC_H_Y, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_100};
- 6'd29: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_100};
-
- 6'd30: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_101};
- 6'd31: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_101};
- 6'd32: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_101};
-
- default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
-
- endcase
-
-
-endmodule
+ 6'd24: data <= {OPCODE_MOV, UOP_SRC_G_X, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
+ 6'd25: data <= {OPCODE_MOV, UOP_SRC_G_Y, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
+ 6'd26: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_0XX};
+
+ 6'd27: data <= {OPCODE_MOV, UOP_SRC_H_X, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_100};
+ 6'd28: data <= {OPCODE_MOV, UOP_SRC_H_Y, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_100};
+ 6'd29: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_100};
+
+ 6'd30: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_101};
+ 6'd31: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_101};
+ 6'd32: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_101};
+
+ default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
+
+ endcase
+
+
+endmodule
diff --git a/rtl/curve/uop/uop_conv_rom.v b/rtl/curve/uop/uop_conv_rom.v
index 3097736..dd6a7cb 100644
--- a/rtl/curve/uop/uop_conv_rom.v
+++ b/rtl/curve/uop/uop_conv_rom.v
@@ -1,38 +1,38 @@
-`timescale 1ns / 1ps
-
-module uop_conv_rom
- (
- input wire clk,
- input wire [ 5: 0] addr,
- output reg [19: 0] data
- );
-
-
- //
- // Microcode
- //
-`include "..\uop_ecdsa.v"
-
-
- //
- // Doubling Microprogram
- //
+`timescale 1ns / 1ps
+
+module uop_conv_rom
+ (
+ input wire clk,
+ input wire [ 5: 0] addr,
+ output reg [19: 0] data
+ );
+
+
+ //
+ // Microcode
+ //
+`include "../uop_ecdsa.v"
+
+
+ //
+ // Doubling Microprogram
+ //
always @(posedge clk)
- case (addr)
-
- 6'd00: data <= {OPCODE_CMP, UOP_SRC_PZ, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
- 6'd01: data <= {OPCODE_MOV, UOP_SRC_V, UOP_SRC_DUMMY, UOP_DST_T1, UOP_EXEC_ALWAYS};
- 6'd02: data <= {OPCODE_MUL, UOP_SRC_V, UOP_SRC_T1, UOP_DST_T2, UOP_EXEC_ALWAYS};
- 6'd03: data <= {OPCODE_MUL, UOP_SRC_V, UOP_SRC_T2, UOP_DST_T3, UOP_EXEC_ALWAYS};
- 6'd04: data <= {OPCODE_MUL, UOP_SRC_PX, UOP_SRC_T2, UOP_DST_RX, UOP_EXEC_ALWAYS};
- 6'd05: data <= {OPCODE_MUL, UOP_SRC_PY, UOP_SRC_T3, UOP_DST_RY, UOP_EXEC_ALWAYS};
- 6'd06: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
- 6'd07: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
-
- default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
-
- endcase
-
-
-endmodule
+ case (addr)
+
+ 6'd00: data <= {OPCODE_CMP, UOP_SRC_PZ, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
+ 6'd01: data <= {OPCODE_MOV, UOP_SRC_V, UOP_SRC_DUMMY, UOP_DST_T1, UOP_EXEC_ALWAYS};
+ 6'd02: data <= {OPCODE_MUL, UOP_SRC_V, UOP_SRC_T1, UOP_DST_T2, UOP_EXEC_ALWAYS};
+ 6'd03: data <= {OPCODE_MUL, UOP_SRC_V, UOP_SRC_T2, UOP_DST_T3, UOP_EXEC_ALWAYS};
+ 6'd04: data <= {OPCODE_MUL, UOP_SRC_PX, UOP_SRC_T2, UOP_DST_RX, UOP_EXEC_ALWAYS};
+ 6'd05: data <= {OPCODE_MUL, UOP_SRC_PY, UOP_SRC_T3, UOP_DST_RY, UOP_EXEC_ALWAYS};
+ 6'd06: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
+ 6'd07: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
+
+ default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
+
+ endcase
+
+
+endmodule
diff --git a/rtl/curve/uop/uop_dbl_rom.v b/rtl/curve/uop/uop_dbl_rom.v
index 1939ca9..9ded543 100644
--- a/rtl/curve/uop/uop_dbl_rom.v
+++ b/rtl/curve/uop/uop_dbl_rom.v
@@ -1,26 +1,26 @@
-`timescale 1ns / 1ps
-
-module uop_dbl_rom
- (
- input wire clk,
- input wire [ 5: 0] addr,
- output reg [19: 0] data
- );
-
-
- //
- // Microcode
- //
-`include "..\uop_ecdsa.v"
-
-
- //
- // Doubling Microprogram
- //
+`timescale 1ns / 1ps
+
+module uop_dbl_rom
+ (
+ input wire clk,
+ input wire [ 5: 0] addr,
+ output reg [19: 0] data
+ );
+
+
+ //
+ // Microcode
+ //
+`include "../uop_ecdsa.v"
+
+
+ //
+ // Doubling Microprogram
+ //
always @(posedge clk)
- case (addr)
-
+ case (addr)
+
/* 1. */6'd00: data <= {OPCODE_CMP, UOP_SRC_PZ, UOP_SRC_ZERO, UOP_DST_DUMMY, UOP_EXEC_ALWAYS};
/* 2. */6'd01: data <= {OPCODE_MOV, UOP_SRC_PZ, UOP_SRC_DUMMY, UOP_DST_T1, UOP_EXEC_ALWAYS};
5'd02: data <= {OPCODE_MUL, UOP_SRC_PZ, UOP_SRC_T1, UOP_DST_T1, UOP_EXEC_ALWAYS};
@@ -42,17 +42,17 @@ module uop_dbl_rom
6'd18: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_T2, UOP_DST_RX, UOP_EXEC_ALWAYS};
/* 14. */6'd19: data <= {OPCODE_ADD, UOP_SRC_T3, UOP_SRC_T3, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 15. */6'd20: data <= {OPCODE_SUB, UOP_SRC_RX, UOP_SRC_T1, UOP_DST_RX, UOP_EXEC_ALWAYS};
-/* 16. */6'd21: data <= {OPCODE_SUB, UOP_SRC_T3, UOP_SRC_RX, UOP_DST_T1, UOP_EXEC_ALWAYS};
+/* 16. */6'd21: data <= {OPCODE_SUB, UOP_SRC_T3, UOP_SRC_RX, UOP_DST_T1, UOP_EXEC_ALWAYS};
/* 17. */6'd22: data <= {OPCODE_MUL, UOP_SRC_T1, UOP_SRC_T2, UOP_DST_T1, UOP_EXEC_ALWAYS};
-/* 18. */6'd23: data <= {OPCODE_SUB, UOP_SRC_T1, UOP_SRC_RY, UOP_DST_RY, UOP_EXEC_ALWAYS};
-
- 6'd24: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
- 6'd25: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
- 6'd26: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_0XX};
-
- default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
-
- endcase
-
-
-endmodule
+/* 18. */6'd23: data <= {OPCODE_SUB, UOP_SRC_T1, UOP_SRC_RY, UOP_DST_RY, UOP_EXEC_ALWAYS};
+
+ 6'd24: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_PZT1T2_0XX};
+ 6'd25: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_PZT1T2_0XX};
+ 6'd26: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_PZT1T2_0XX};
+
+ default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
+
+ endcase
+
+
+endmodule
diff --git a/rtl/curve/uop/uop_init_rom.v b/rtl/curve/uop/uop_init_rom.v
index ac44b55..3863dbf 100644
--- a/rtl/curve/uop/uop_init_rom.v
+++ b/rtl/curve/uop/uop_init_rom.v
@@ -1,33 +1,33 @@
-`timescale 1ns / 1ps
-
-module uop_init_rom
- (
- input wire clk,
- input wire [ 5: 0] addr,
- output reg [19: 0] data
- );
-
-
- //
- // Microcode
- //
-`include "..\uop_ecdsa.v"
-
-
- //
- // Doubling Microprogram
- //
+`timescale 1ns / 1ps
+
+module uop_init_rom
+ (
+ input wire clk,
+ input wire [ 5: 0] addr,
+ output reg [19: 0] data
+ );
+
+
+ //
+ // Microcode
+ //
+`include "../uop_ecdsa.v"
+
+
+ //
+ // Doubling Microprogram
+ //
always @(posedge clk)
- case (addr)
-
- 6'd00: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_ALWAYS};
- 6'd01: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_ALWAYS};
- 6'd02: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_ALWAYS};
-
- default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
-
- endcase
-
-
-endmodule
+ case (addr)
+
+ 6'd00: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RX, UOP_EXEC_ALWAYS};
+ 6'd01: data <= {OPCODE_MOV, UOP_SRC_ONE, UOP_SRC_DUMMY, UOP_DST_RY, UOP_EXEC_ALWAYS};
+ 6'd02: data <= {OPCODE_MOV, UOP_SRC_ZERO, UOP_SRC_DUMMY, UOP_DST_RZ, UOP_EXEC_ALWAYS};
+
+ default: data <= {OPCODE_RDY, UOP_SRC_DUMMY, UOP_SRC_DUMMY, UOP_DST_DUMMY};
+
+ endcase
+
+
+endmodule
diff --git a/rtl/curve/uop_ecdsa.v b/rtl/curve/uop_ecdsa.v
index e64119d..ce757be 100644
--- a/rtl/curve/uop_ecdsa.v
+++ b/rtl/curve/uop_ecdsa.v
@@ -20,8 +20,8 @@ localparam [ 4: 0] UOP_SRC_T4 = 5'h0_9;
localparam [ 4: 0] UOP_SRC_ONE = 5'h0_A;
localparam [ 4: 0] UOP_SRC_ZERO = 5'h0_B;
-localparam [ 4: 0] UOP_SRC_DELTA = 5'h0_C;
-
+localparam [ 4: 0] UOP_SRC_DELTA = 5'h0_C;
+
localparam [ 4: 0] UOP_SRC_V = 5'h0_F;
localparam [ 4: 0] UOP_SRC_G_X = 5'h1_0;
diff --git a/rtl/ecdsa256.v b/rtl/ecdsa256.v
deleted file mode 100644
index 1e712bf..0000000
--- a/rtl/ecdsa256.v
+++ /dev/null
@@ -1,160 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-`timescale 1ns / 1ps
-
-module ecdsa256
- (
- input wire clk,
- input wire rst_n,
-
- input wire next,
- output wire valid,
-
- input wire bus_cs,
- input wire bus_we,
- input wire [ 4:0] bus_addr,
- input wire [31:0] bus_data_wr,
- output wire [31:0] bus_data_rd
- );
-
-
- //
- // Memory Banks
- //
- localparam [1:0] BUS_ADDR_BANK_K = 2'b00;
- localparam [1:0] BUS_ADDR_BANK_X = 2'b01;
- localparam [1:0] BUS_ADDR_BANK_Y = 2'b10;
-
- wire [1:0] bus_addr_upper = bus_addr[4:3];
- wire [2:0] bus_addr_lower = bus_addr[2:0];
-
-
- //
- // Memories
- //
-
- wire [31:0] user_rw_k_bram_out;
- wire [31:0] user_ro_x_bram_out;
- wire [31:0] user_ro_y_bram_out;
-
- wire [ 2:0] core_ro_k_bram_addr;
- wire [ 2:0] core_rw_x_bram_addr;
- wire [ 2:0] core_rw_y_bram_addr;
-
- wire core_rw_x_bram_wren;
- wire core_rw_y_bram_wren;
-
- wire [31:0] core_ro_k_bram_dout;
- wire [31:0] core_rw_x_bram_din;
- wire [31:0] core_rw_y_bram_din;
-
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(3)
- )
- bram_k
- ( .clk(clk),
- .a_addr(bus_addr_lower), .a_out(user_rw_k_bram_out), .a_wr(bus_cs && bus_we && (bus_addr_upper == BUS_ADDR_BANK_K)), .a_in(bus_data_wr),
- .b_addr(core_ro_k_bram_addr), .b_out(core_ro_k_bram_dout)
- );
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(3)
- )
- bram_x
- ( .clk(clk),
- .a_addr(core_rw_x_bram_addr), .a_out(), .a_wr(core_rw_x_bram_wren), .a_in(core_rw_x_bram_din),
- .b_addr(bus_addr_lower), .b_out(user_ro_x_bram_out)
- );
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(3)
- )
- bram_y
- ( .clk(clk),
- .a_addr(core_rw_y_bram_addr), .a_out(), .a_wr(core_rw_y_bram_wren), .a_in(core_rw_y_bram_din),
- .b_addr(bus_addr_lower), .b_out(user_ro_y_bram_out)
- );
-
-
- //
- // Curve Base Point Multiplier
- //
- reg next_dly;
-
- always @(posedge clk) next_dly <= next;
-
- wire next_trig = next && !next_dly;
-
- curve_mul_256 base_point_multiplier_p256
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (next_trig),
- .rdy (valid),
-
- .k_addr (core_ro_k_bram_addr),
- .rx_addr (core_rw_x_bram_addr),
- .ry_addr (core_rw_y_bram_addr),
-
- .rx_wren (core_rw_x_bram_wren),
- .ry_wren (core_rw_y_bram_wren),
-
- .k_din (core_ro_k_bram_dout),
- .rx_dout (core_rw_x_bram_din),
- .ry_dout (core_rw_y_bram_din)
- );
-
- //
- // Output Selector
- //
- reg [1:0] bus_addr_upper_prev;
- always @(posedge clk) bus_addr_upper_prev = bus_addr_upper;
-
- reg [31: 0] bus_data_rd_mux;
- assign bus_data_rd = bus_data_rd_mux;
-
- always @(*)
- //
- case (bus_addr_upper_prev)
- //
- BUS_ADDR_BANK_K: bus_data_rd_mux = user_rw_k_bram_out;
- BUS_ADDR_BANK_X: bus_data_rd_mux = user_ro_x_bram_out;
- BUS_ADDR_BANK_Y: bus_data_rd_mux = user_ro_y_bram_out;
- //
- default: bus_data_rd_mux = {32{1'b0}};
- //
- endcase
-
-endmodule
diff --git a/rtl/ecdsa256_wrapper.v b/rtl/ecdsa256_wrapper.v
deleted file mode 100644
index c6e93ea..0000000
--- a/rtl/ecdsa256_wrapper.v
+++ /dev/null
@@ -1,177 +0,0 @@
-//======================================================================
-//
-// Copyright (c) 2016, NORDUnet A/S All rights reserved.
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions
-// are met:
-// - Redistributions of source code must retain the above copyright
-// notice, this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright
-// notice, this list of conditions and the following disclaimer in the
-// documentation and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may
-// be used to endorse or promote products derived from this software
-// without specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
-// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
-// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
-// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
-// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
-// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
-// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
-// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
-// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
-// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-//
-//======================================================================
-
-module ecdsa256_wrapper
- (
- input wire clk,
- input wire rst_n,
-
- input wire cs,
- input wire we,
-
- input wire [5: 0] address,
- input wire [31: 0] write_data,
- output wire [31: 0] read_data
- );
-
-
- //
- // Address Decoder
- //
- localparam ADDR_MSB_REGS = 1'b0;
- localparam ADDR_MSB_CORE = 1'b1;
-
- wire [0:0] addr_msb = address[5];
- wire [4:0] addr_lsb = address[4:0];
-
-
- //
- // Output Mux
- //
- wire [31: 0] read_data_regs;
- wire [31: 0] read_data_core;
-
-
- //
- // Registers
- //
- localparam ADDR_NAME0 = 5'h00;
- localparam ADDR_NAME1 = 5'h01;
- localparam ADDR_VERSION = 5'h02;
-
- localparam ADDR_CONTROL = 5'h08; // {next, init}
- localparam ADDR_STATUS = 5'h09; // {valid, ready}
- localparam ADDR_DUMMY = 5'h0F; // don't care
-
-// localparam CONTROL_INIT_BIT = 0; -- not used
- localparam CONTROL_NEXT_BIT = 1;
-
-// localparam STATUS_READY_BIT = 0; -- hardcoded to always read 1
- localparam STATUS_VALID_BIT = 1;
-
- localparam CORE_NAME0 = 32'h65636473; // "ecds"
- localparam CORE_NAME1 = 32'h61323536; // "a256"
- localparam CORE_VERSION = 32'h302E3131; // "0.11"
-
-
- //
- // Registers
- //
- reg reg_control;
- reg [31:0] reg_dummy;
-
-
- //
- // Wires
- //
- wire reg_status;
-
-
- //
- // ECDSA256
- //
- ecdsa256 ecdsa256_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .next (reg_control),
- .valid (reg_status),
-
- .bus_cs (cs && (addr_msb == ADDR_MSB_CORE)),
- .bus_we (we),
- .bus_addr (addr_lsb),
- .bus_data_wr (write_data),
- .bus_data_rd (read_data_core)
- );
-
-
- //
- // Read Latch
- //
- reg [31: 0] tmp_read_data;
-
-
- //
- // Read/Write Interface
- //
- always @(posedge clk)
- //
- if (!rst_n) begin
- //
- reg_control <= 1'b0;
- //
- end else if (cs && (addr_msb == ADDR_MSB_REGS)) begin
- //
- if (we) begin
- //
- // Write Handler
- //
- case (addr_lsb)
- //
- ADDR_CONTROL: reg_control <= write_data[1];
- ADDR_DUMMY: reg_dummy <= write_data[31:0];
- //
- endcase
- //
- end else begin
- //
- // Read Handler
- //
- case (address)
- //
- ADDR_NAME0: tmp_read_data <= CORE_NAME0;
- ADDR_NAME1: tmp_read_data <= CORE_NAME1;
- ADDR_VERSION: tmp_read_data <= CORE_VERSION;
- ADDR_CONTROL: tmp_read_data <= {{30{1'b0}}, reg_control, 1'b0};
- ADDR_STATUS: tmp_read_data <= {{30{1'b0}}, reg_status, 1'b1};
- ADDR_DUMMY: tmp_read_data <= reg_dummy;
- //
- default: tmp_read_data <= 32'h00000000;
- //
- endcase
- //
- end
- //
- end
-
-
- //
- // Register / Core Memory Selector
- //
- reg addr_msb_last;
- always @(posedge clk) addr_msb_last = addr_msb;
-
- assign read_data = (addr_msb_last == ADDR_MSB_REGS) ? tmp_read_data : read_data_core;
-
-
-endmodule
diff --git a/rtl/lowlevel/adder32_wrapper.v b/rtl/lowlevel/adder32_wrapper.v
index ebfd8ce..57778df 100644
--- a/rtl/lowlevel/adder32_wrapper.v
+++ b/rtl/lowlevel/adder32_wrapper.v
@@ -2,7 +2,7 @@
//
// adder32_wrapper.v
// -----------------------------------------------------------------------------
-// Wrapper for 32-bit adder.
+// Wrapper for 32-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,40 +34,40 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder32_wrapper
- (
- input clk, // clock
- input [31: 0] a, // operand input
- input [31: 0] b, // operand input
- output [31: 0] s, // sum output
- input c_in, // carry input
- output c_out // carry output
- );
-
- //
- // Include Primitive Selector
- //
-`include "ecdsa_lowlevel_settings.v"
-
-
- //
- // Instantiate Vendor/Generic Primitive
- //
- `ADDER32_PRIMITIVE adder32_inst
- (
- .clk(clk),
- .a(a),
- .b(b),
- .s(s),
- .c_in(c_in),
- .c_out(c_out)
- );
-
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder32_wrapper
+ (
+ input clk, // clock
+ input [31: 0] a, // operand input
+ input [31: 0] b, // operand input
+ output [31: 0] s, // sum output
+ input c_in, // carry input
+ output c_out // carry output
+ );
+
+ //
+ // Include Primitive Selector
+ //
+`include "ecdsa_lowlevel_settings.v"
+
+
+ //
+ // Instantiate Vendor/Generic Primitive
+ //
+ `ADDER32_PRIMITIVE adder32_inst
+ (
+ .clk(clk),
+ .a(a),
+ .b(b),
+ .s(s),
+ .c_in(c_in),
+ .c_out(c_out)
+ );
+
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/adder47_wrapper.v b/rtl/lowlevel/adder47_wrapper.v
index 1a0a18e..be5b1ee 100644
--- a/rtl/lowlevel/adder47_wrapper.v
+++ b/rtl/lowlevel/adder47_wrapper.v
@@ -2,7 +2,7 @@
//
// adder47_wrapper.v
// -----------------------------------------------------------------------------
-// Wrapper for 47-bit adder.
+// Wrapper for 47-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,36 +34,36 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder47_wrapper
- (
- input clk, // clock
- input [46: 0] a, // operand input
- input [46: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
- //
- // Include Primitive Selector
- //
-`include "ecdsa_lowlevel_settings.v"
-
-
- //
- // Instantiate Vendor/Generic Primitive
- //
- `ADDER47_PRIMITIVE adder47_inst
- (
- .clk(clk),
- .a(a),
- .b(b),
- .s(s)
- );
-
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder47_wrapper
+ (
+ input clk, // clock
+ input [46: 0] a, // operand input
+ input [46: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+ //
+ // Include Primitive Selector
+ //
+`include "ecdsa_lowlevel_settings.v"
+
+
+ //
+ // Instantiate Vendor/Generic Primitive
+ //
+ `ADDER47_PRIMITIVE adder47_inst
+ (
+ .clk(clk),
+ .a(a),
+ .b(b),
+ .s(s)
+ );
+
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/artix7/adder32_artix7.v b/rtl/lowlevel/artix7/adder32_artix7.v
index 5f9ba79..dad2340 100644
--- a/rtl/lowlevel/artix7/adder32_artix7.v
+++ b/rtl/lowlevel/artix7/adder32_artix7.v
@@ -2,7 +2,7 @@
//
// adder32_artix7.v
// -----------------------------------------------------------------------------
-// Hardware (Artix-7 DSP48E1) 32-bit adder.
+// Hardware (Artix-7 DSP48E1) 32-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,63 +34,63 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder32_artix7
- (
- input clk, // clock
- input [31: 0] a, // operand input
- input [31: 0] b, // operand input
- output [31: 0] s, // sum output
- input c_in, // carry input
- output c_out // carry output
- );
-
- //
- // Lower and higher parts of operand
- //
- wire [17: 0] bl = b[17: 0];
- wire [13: 0] bh = b[31:18];
-
-
- //
- // DSP48E1 Slice
- //
-
- /* Operation Mode */
- wire [ 3: 0] dsp48e1_alumode = 4'b0000;
- wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
-
- /* Internal Product */
- wire [47: 0] p_int;
-
- dsp48e1_wrapper dsp_adder
- (
- .clk (clk),
-
- .ce (1'b1),
-
- .carry (c_in),
-
- .alumode (dsp48e1_alumode),
- .opmode (dsp48e1_opmode),
-
- .a ({{16{1'b0}}, bh}),
- .b (bl),
- .c ({{16{1'b0}}, a}),
-
- .p (p_int)
- );
-
- //
- // Output Mapping
- //
- assign s = p_int[31: 0];
- assign c_out = p_int[32];
-
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder32_artix7
+ (
+ input clk, // clock
+ input [31: 0] a, // operand input
+ input [31: 0] b, // operand input
+ output [31: 0] s, // sum output
+ input c_in, // carry input
+ output c_out // carry output
+ );
+
+ //
+ // Lower and higher parts of operand
+ //
+ wire [17: 0] bl = b[17: 0];
+ wire [13: 0] bh = b[31:18];
+
+
+ //
+ // DSP48E1 Slice
+ //
+
+ /* Operation Mode */
+ wire [ 3: 0] dsp48e1_alumode = 4'b0000;
+ wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
+
+ /* Internal Product */
+ wire [47: 0] p_int;
+
+ dsp48e1_wrapper dsp_adder
+ (
+ .clk (clk),
+
+ .ce (1'b1),
+
+ .carry (c_in),
+
+ .alumode (dsp48e1_alumode),
+ .opmode (dsp48e1_opmode),
+
+ .a ({{16{1'b0}}, bh}),
+ .b (bl),
+ .c ({{16{1'b0}}, a}),
+
+ .p (p_int)
+ );
+
+ //
+ // Output Mapping
+ //
+ assign s = p_int[31: 0];
+ assign c_out = p_int[32];
+
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/artix7/adder47_artix7.v b/rtl/lowlevel/artix7/adder47_artix7.v
index 00566e4..caafc85 100644
--- a/rtl/lowlevel/artix7/adder47_artix7.v
+++ b/rtl/lowlevel/artix7/adder47_artix7.v
@@ -2,7 +2,7 @@
//
// adder47_artix7.v
// -----------------------------------------------------------------------------
-// Hardware (Artix-7 DSP48E1) 47-bit adder.
+// Hardware (Artix-7 DSP48E1) 47-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,58 +34,58 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder47_artix7
- (
- input clk, // clock
- input [46: 0] a, // operand input
- input [46: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
- //
- // Lower and higher parts of operand
- //
- wire [17: 0] bl = b[17: 0];
- wire [28: 0] bh = b[46:18];
-
- //
- // DSP48E1 Slice
- //
-
- /* Operation Mode */
- wire [ 3: 0] dsp48e1_alumode = 4'b0000;
- wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
-
- /* Internal Product */
- wire [47: 0] p_int;
-
- dsp48e1_wrapper dsp_adder
- (
- .clk (clk),
-
- .ce (1'b1),
-
- .carry (1'b0),
-
- .alumode (dsp48e1_alumode),
- .opmode (dsp48e1_opmode),
-
- .a ({1'b0, bh}),
- .b (bl),
- .c ({1'b0, a}),
-
- .p (p_int)
- );
-
- //
- // Output Mapping
- //
- assign s = p_int[46: 0];
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder47_artix7
+ (
+ input clk, // clock
+ input [46: 0] a, // operand input
+ input [46: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+ //
+ // Lower and higher parts of operand
+ //
+ wire [17: 0] bl = b[17: 0];
+ wire [28: 0] bh = b[46:18];
+
+ //
+ // DSP48E1 Slice
+ //
+
+ /* Operation Mode */
+ wire [ 3: 0] dsp48e1_alumode = 4'b0000;
+ wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
+
+ /* Internal Product */
+ wire [47: 0] p_int;
+
+ dsp48e1_wrapper dsp_adder
+ (
+ .clk (clk),
+
+ .ce (1'b1),
+
+ .carry (1'b0),
+
+ .alumode (dsp48e1_alumode),
+ .opmode (dsp48e1_opmode),
+
+ .a ({1'b0, bh}),
+ .b (bl),
+ .c ({1'b0, a}),
+
+ .p (p_int)
+ );
+
+ //
+ // Output Mapping
+ //
+ assign s = p_int[46: 0];
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/artix7/dsp48e1_wrapper.v b/rtl/lowlevel/artix7/dsp48e1_wrapper.v
index 11a21bc..4c272f0 100644
--- a/rtl/lowlevel/artix7/dsp48e1_wrapper.v
+++ b/rtl/lowlevel/artix7/dsp48e1_wrapper.v
@@ -2,7 +2,7 @@
//
// dsp48e1_wrapper.v
// -----------------------------------------------------------------------------
-// Hardware (Artix-7 DSP48E1) tile wrapper.
+// Hardware (Artix-7 DSP48E1) tile wrapper.
//
// Authors: Pavel Shatov
//
@@ -34,126 +34,126 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module dsp48e1_wrapper
- (
- input clk,
-
- input ce,
-
- input [ 6: 0] opmode,
- input [ 3: 0] alumode,
-
- input carry,
-
- input [29: 0] a,
- input [17: 0] b,
- input [47: 0] c,
-
- output [47: 0] p
- );
-
-
- //
- // Tile instantiation
- //
- DSP48E1 #
- (
- .AREG (0),
- .BREG (0),
- .CREG (0),
- .DREG (0),
- .MREG (0),
- .PREG (1),
- .ADREG (0),
-
- .ACASCREG (0),
- .BCASCREG (0),
- .ALUMODEREG (0),
- .INMODEREG (0),
- .OPMODEREG (0),
- .CARRYINREG (0),
- .CARRYINSELREG (0),
-
- .A_INPUT ("DIRECT"),
- .B_INPUT ("DIRECT"),
-
- .USE_DPORT ("FALSE"),
- .USE_MULT ("DYNAMIC"),
- .USE_SIMD ("ONE48"),
-
- .USE_PATTERN_DETECT ("NO_PATDET"),
- .SEL_PATTERN ("PATTERN"),
- .SEL_MASK ("MASK"),
- .PATTERN (48'h000000000000),
- .MASK (48'h3fffffffffff),
- .AUTORESET_PATDET ("NO_RESET")
- )
- DSP48E1_inst
- (
- .CLK (clk),
-
- .RSTA (1'b0),
- .RSTB (1'b0),
- .RSTC (1'b0),
- .RSTD (1'b0),
- .RSTM (1'b0),
- .RSTP (1'b0),
-
- .RSTCTRL (1'b0),
- .RSTINMODE (1'b0),
- .RSTALUMODE (1'b0),
- .RSTALLCARRYIN (1'b0),
-
- .CEA1 (1'b0),
- .CEA2 (1'b0),
- .CEB1 (1'b0),
- .CEB2 (1'b0),
- .CEC (1'b0),
- .CED (1'b0),
- .CEM (1'b0),
- .CEP (ce),
- .CEAD (1'b0),
- .CEALUMODE (1'b0),
- .CEINMODE (1'b0),
-
- .CECTRL (1'b0),
- .CECARRYIN (1'b0),
-
- .A (a),
- .B (b),
- .C (c),
- .D ({25{1'b1}}),
- .P (p),
-
- .CARRYIN (carry),
- .CARRYOUT (),
- .CARRYINSEL (3'b000),
-
- .CARRYCASCIN (1'b0),
- .CARRYCASCOUT (),
-
- .PATTERNDETECT (),
- .PATTERNBDETECT (),
-
- .OPMODE (opmode),
- .ALUMODE (alumode),
- .INMODE (5'b00000),
-
- .MULTSIGNIN (1'b0),
- .MULTSIGNOUT (),
-
- .UNDERFLOW (),
- .OVERFLOW (),
-
- .ACIN (30'd0),
- .BCIN (18'd0),
- .PCIN (48'd0),
-
- .ACOUT (),
- .BCOUT (),
- .PCOUT ()
- );
-
-endmodule
+//------------------------------------------------------------------------------
+
+module dsp48e1_wrapper
+ (
+ input clk,
+
+ input ce,
+
+ input [ 6: 0] opmode,
+ input [ 3: 0] alumode,
+
+ input carry,
+
+ input [29: 0] a,
+ input [17: 0] b,
+ input [47: 0] c,
+
+ output [47: 0] p
+ );
+
+
+ //
+ // Tile instantiation
+ //
+ DSP48E1 #
+ (
+ .AREG (0),
+ .BREG (0),
+ .CREG (0),
+ .DREG (0),
+ .MREG (0),
+ .PREG (1),
+ .ADREG (0),
+
+ .ACASCREG (0),
+ .BCASCREG (0),
+ .ALUMODEREG (0),
+ .INMODEREG (0),
+ .OPMODEREG (0),
+ .CARRYINREG (0),
+ .CARRYINSELREG (0),
+
+ .A_INPUT ("DIRECT"),
+ .B_INPUT ("DIRECT"),
+
+ .USE_DPORT ("FALSE"),
+ .USE_MULT ("DYNAMIC"),
+ .USE_SIMD ("ONE48"),
+
+ .USE_PATTERN_DETECT ("NO_PATDET"),
+ .SEL_PATTERN ("PATTERN"),
+ .SEL_MASK ("MASK"),
+ .PATTERN (48'h000000000000),
+ .MASK (48'h3fffffffffff),
+ .AUTORESET_PATDET ("NO_RESET")
+ )
+ DSP48E1_inst
+ (
+ .CLK (clk),
+
+ .RSTA (1'b0),
+ .RSTB (1'b0),
+ .RSTC (1'b0),
+ .RSTD (1'b0),
+ .RSTM (1'b0),
+ .RSTP (1'b0),
+
+ .RSTCTRL (1'b0),
+ .RSTINMODE (1'b0),
+ .RSTALUMODE (1'b0),
+ .RSTALLCARRYIN (1'b0),
+
+ .CEA1 (1'b0),
+ .CEA2 (1'b0),
+ .CEB1 (1'b0),
+ .CEB2 (1'b0),
+ .CEC (1'b0),
+ .CED (1'b0),
+ .CEM (1'b0),
+ .CEP (ce),
+ .CEAD (1'b0),
+ .CEALUMODE (1'b0),
+ .CEINMODE (1'b0),
+
+ .CECTRL (1'b0),
+ .CECARRYIN (1'b0),
+
+ .A (a),
+ .B (b),
+ .C (c),
+ .D ({25{1'b1}}),
+ .P (p),
+
+ .CARRYIN (carry),
+ .CARRYOUT (),
+ .CARRYINSEL (3'b000),
+
+ .CARRYCASCIN (1'b0),
+ .CARRYCASCOUT (),
+
+ .PATTERNDETECT (),
+ .PATTERNBDETECT (),
+
+ .OPMODE (opmode),
+ .ALUMODE (alumode),
+ .INMODE (5'b00000),
+
+ .MULTSIGNIN (1'b0),
+ .MULTSIGNOUT (),
+
+ .UNDERFLOW (),
+ .OVERFLOW (),
+
+ .ACIN (30'd0),
+ .BCIN (18'd0),
+ .PCIN (48'd0),
+
+ .ACOUT (),
+ .BCOUT (),
+ .PCOUT ()
+ );
+
+endmodule
diff --git a/rtl/lowlevel/artix7/mac16_artix7.v b/rtl/lowlevel/artix7/mac16_artix7.v
index 63b74ab..421e7ba 100644
--- a/rtl/lowlevel/artix7/mac16_artix7.v
+++ b/rtl/lowlevel/artix7/mac16_artix7.v
@@ -2,7 +2,7 @@
//
// mac16_artix7.v
// -----------------------------------------------------------------------------
-// Hardware (Artix-7 DSP48E1) 16-bit multiplier and 47-bit accumulator.
+// Hardware (Artix-7 DSP48E1) 16-bit multiplier and 47-bit accumulator.
//
// Authors: Pavel Shatov
//
@@ -34,57 +34,57 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module mac16_artix7
- (
- input clk, // clock
- input clr, // clear accumulator (active-high)
- input ce, // enable clock (active-high)
- input [15: 0] a, // operand input
- input [15: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
-
- //
- // DSP48E1 Slice
- //
-
- /* Operation Mode */
- wire [ 3: 0] dsp48e1_alumode = 4'b0000;
- wire [ 6: 0] dsp48e1_opmode = {2'b01, clr, 4'b0101};
-
- /* Internal Product */
- wire [47: 0] p_int;
-
- dsp48e1_wrapper dsp_adder
- (
- .clk (clk),
-
- .ce (ce),
-
- .carry (1'b0),
-
- .alumode (dsp48e1_alumode),
- .opmode (dsp48e1_opmode),
-
- .a ({{14{1'b0}}, a}),
- .b ({{ 2{1'b0}}, b}),
- .c ({48{1'b0}}),
-
- .p (p_int)
- );
-
- //
- // Output Mapping
- //
- assign s = p_int[46:0];
-
-
-endmodule
-
-
+//------------------------------------------------------------------------------
+
+module mac16_artix7
+ (
+ input clk, // clock
+ input clr, // clear accumulator (active-high)
+ input ce, // enable clock (active-high)
+ input [15: 0] a, // operand input
+ input [15: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+
+ //
+ // DSP48E1 Slice
+ //
+
+ /* Operation Mode */
+ wire [ 3: 0] dsp48e1_alumode = 4'b0000;
+ wire [ 6: 0] dsp48e1_opmode = {2'b01, clr, 4'b0101};
+
+ /* Internal Product */
+ wire [47: 0] p_int;
+
+ dsp48e1_wrapper dsp_adder
+ (
+ .clk (clk),
+
+ .ce (ce),
+
+ .carry (1'b0),
+
+ .alumode (dsp48e1_alumode),
+ .opmode (dsp48e1_opmode),
+
+ .a ({{14{1'b0}}, a}),
+ .b ({{ 2{1'b0}}, b}),
+ .c ({48{1'b0}}),
+
+ .p (p_int)
+ );
+
+ //
+ // Output Mapping
+ //
+ assign s = p_int[46:0];
+
+
+endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/artix7/subtractor32_artix7.v b/rtl/lowlevel/artix7/subtractor32_artix7.v
index b46ac5c..7377781 100644
--- a/rtl/lowlevel/artix7/subtractor32_artix7.v
+++ b/rtl/lowlevel/artix7/subtractor32_artix7.v
@@ -1,94 +1,94 @@
-//------------------------------------------------------------------------------
-//
-// subtractor32_artix7.v
-// -----------------------------------------------------------------------------
-// Hardware (Artix-7 DSP48E1) 32-bit subtractor.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module subtractor32_artix7
- (
- input clk,
- input [31: 0] a,
- input [31: 0] b,
- output [31: 0] d,
- input b_in,
- output b_out
- );
-
- //
- // Lower and higher parts of operand
- //
- wire [17: 0] bl = b[17: 0];
- wire [13: 0] bh = b[31:18];
-
- //
- // DSP48E1 Slice
- //
-
- /* Operation Mode */
- wire [ 3: 0] dsp48e1_alumode = 4'b0011;
- wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
-
- /* Internal Product */
- wire [47: 0] p_int;
-
- dsp48e1_wrapper dsp_subtractor
- (
- .clk (clk),
-
- .ce (1'b1),
-
- .carry (b_in),
-
- .alumode (dsp48e1_alumode),
- .opmode (dsp48e1_opmode),
-
- .a ({{16{1'b0}}, bh}),
- .b (bl),
- .c ({{16{1'b0}}, a}),
-
- .p (p_int)
- );
-
- //
- // Output Mapping
- //
- assign d = p_int[31: 0];
- assign b_out = p_int[32];
-
-endmodule
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
+//
+// subtractor32_artix7.v
+// -----------------------------------------------------------------------------
+// Hardware (Artix-7 DSP48E1) 32-bit subtractor.
+//
+// Authors: Pavel Shatov
+//
+// Copyright (c) 2016, NORDUnet A/S
+//
+// Redistribution and use in source and binary forms, with or without
+// modification, are permitted provided that the following conditions are met:
+//
+// - Redistributions of source code must retain the above copyright notice,
+// this list of conditions and the following disclaimer.
+//
+// - Redistributions in binary form must reproduce the above copyright notice,
+// this list of conditions and the following disclaimer in the documentation
+// and/or other materials provided with the distribution.
+//
+// - Neither the name of the NORDUnet nor the names of its contributors may be
+// used to endorse or promote products derived from this software without
+// specific prior written permission.
+//
+// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
+// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+// POSSIBILITY OF SUCH DAMAGE.
+//
+//------------------------------------------------------------------------------
+
+module subtractor32_artix7
+ (
+ input clk,
+ input [31: 0] a,
+ input [31: 0] b,
+ output [31: 0] d,
+ input b_in,
+ output b_out
+ );
+
+ //
+ // Lower and higher parts of operand
+ //
+ wire [17: 0] bl = b[17: 0];
+ wire [13: 0] bh = b[31:18];
+
+ //
+ // DSP48E1 Slice
+ //
+
+ /* Operation Mode */
+ wire [ 3: 0] dsp48e1_alumode = 4'b0011;
+ wire [ 6: 0] dsp48e1_opmode = 7'b0110011;
+
+ /* Internal Product */
+ wire [47: 0] p_int;
+
+ dsp48e1_wrapper dsp_subtractor
+ (
+ .clk (clk),
+
+ .ce (1'b1),
+
+ .carry (b_in),
+
+ .alumode (dsp48e1_alumode),
+ .opmode (dsp48e1_opmode),
+
+ .a ({{16{1'b0}}, bh}),
+ .b (bl),
+ .c ({{16{1'b0}}, a}),
+
+ .p (p_int)
+ );
+
+ //
+ // Output Mapping
+ //
+ assign d = p_int[31: 0];
+ assign b_out = p_int[32];
+
+endmodule
+
+//------------------------------------------------------------------------------
+// End-of-File
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/ecdsa_lowlevel_settings.v b/rtl/lowlevel/ecdsa_lowlevel_settings.v
index 8f95e2f..c04a14f 100644
--- a/rtl/lowlevel/ecdsa_lowlevel_settings.v
+++ b/rtl/lowlevel/ecdsa_lowlevel_settings.v
@@ -1,17 +1,17 @@
-`define USE_VENDOR_PRIMITIVES
-
-`ifdef USE_VENDOR_PRIMITIVES
-
-`define MAC16_PRIMITIVE mac16_artix7
-`define ADDER32_PRIMITIVE adder32_artix7
-`define ADDER47_PRIMITIVE adder47_artix7
-`define SUBTRACTOR32_PRIMITIVE subtractor32_artix7
-
-`else
-
-`define MAC16_PRIMITIVE mac16_generic
-`define ADDER32_PRIMITIVE adder32_generic
-`define ADDER47_PRIMITIVE adder47_generic
-`define SUBTRACTOR32_PRIMITIVE subtractor32_generic
-
-`endif
+`define USE_VENDOR_PRIMITIVES
+
+`ifdef USE_VENDOR_PRIMITIVES
+
+`define MAC16_PRIMITIVE mac16_artix7
+`define ADDER32_PRIMITIVE adder32_artix7
+`define ADDER47_PRIMITIVE adder47_artix7
+`define SUBTRACTOR32_PRIMITIVE subtractor32_artix7
+
+`else
+
+`define MAC16_PRIMITIVE mac16_generic
+`define ADDER32_PRIMITIVE adder32_generic
+`define ADDER47_PRIMITIVE adder47_generic
+`define SUBTRACTOR32_PRIMITIVE subtractor32_generic
+
+`endif
diff --git a/rtl/lowlevel/generic/adder32_generic.v b/rtl/lowlevel/generic/adder32_generic.v
index b9c94aa..eadfb6f 100644
--- a/rtl/lowlevel/generic/adder32_generic.v
+++ b/rtl/lowlevel/generic/adder32_generic.v
@@ -2,7 +2,7 @@
//
// adder32_generic.v
// -----------------------------------------------------------------------------
-// Generic 32-bit adder.
+// Generic 32-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,34 +34,34 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder32_generic
- (
- input clk, // clock
- input [31: 0] a, // operand input
- input [31: 0] b, // operand input
- output [31: 0] s, // sum output
- input c_in, // carry input
- output c_out // carry output
- );
-
- //
- // Sum
- //
- reg [32: 0] s_int;
-
- always @(posedge clk)
- s_int <= {1'b0, a} + {1'b0, b} + {{32{1'b0}}, c_in};
-
- //
- // Output
- //
- assign s = s_int[31:0];
- assign c_out = s_int[32];
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder32_generic
+ (
+ input clk, // clock
+ input [31: 0] a, // operand input
+ input [31: 0] b, // operand input
+ output [31: 0] s, // sum output
+ input c_in, // carry input
+ output c_out // carry output
+ );
+
+ //
+ // Sum
+ //
+ reg [32: 0] s_int;
+
+ always @(posedge clk)
+ s_int <= {1'b0, a} + {1'b0, b} + {{32{1'b0}}, c_in};
+
+ //
+ // Output
+ //
+ assign s = s_int[31:0];
+ assign c_out = s_int[32];
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/generic/adder47_generic.v b/rtl/lowlevel/generic/adder47_generic.v
index f472061..406c175 100644
--- a/rtl/lowlevel/generic/adder47_generic.v
+++ b/rtl/lowlevel/generic/adder47_generic.v
@@ -2,7 +2,7 @@
//
// adder47_generic.v
// -----------------------------------------------------------------------------
-// Generic 47-bit adder.
+// Generic 47-bit adder.
//
// Authors: Pavel Shatov
//
@@ -34,31 +34,31 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module adder47_generic
- (
- input clk, // clock
- input [46: 0] a, // operand input
- input [46: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
- //
- // Sum
- //
- reg [46: 0] s_int;
-
- always @(posedge clk)
- s_int <= a + b;
-
- //
- // Output
- //
- assign s = s_int;
-
-endmodule
-
+//------------------------------------------------------------------------------
+
+module adder47_generic
+ (
+ input clk, // clock
+ input [46: 0] a, // operand input
+ input [46: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+ //
+ // Sum
+ //
+ reg [46: 0] s_int;
+
+ always @(posedge clk)
+ s_int <= a + b;
+
+ //
+ // Output
+ //
+ assign s = s_int;
+
+endmodule
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/generic/mac16_generic.v b/rtl/lowlevel/generic/mac16_generic.v
index dc95645..6d120a3 100644
--- a/rtl/lowlevel/generic/mac16_generic.v
+++ b/rtl/lowlevel/generic/mac16_generic.v
@@ -2,7 +2,7 @@
//
// mac16_generic.v
// -----------------------------------------------------------------------------
-// Generic 16-bit multiplier and 47-bit accumulator.
+// Generic 16-bit multiplier and 47-bit accumulator.
//
// Authors: Pavel Shatov
//
@@ -34,41 +34,41 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module mac16_generic
- (
- input clk, // clock
- input clr, // clear accumulator (active-high)
- input ce, // enable clock (active-high)
- input [15: 0] a, // operand input
- input [15: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
- //
- // Multiplier
- //
- wire [31: 0] p = {{16{1'b0}}, a} * {{16{1'b0}}, b};
- wire [46: 0] p_ext = {{15{1'b0}}, p};
-
- //
- // Accumulator
- //
- reg [46: 0] s_int;
-
- always @(posedge clk)
- //
- if (ce) s_int <= clr ? p_ext : p_ext + s_int;
-
- //
- // Output
- //
- assign s = s_int;
-
-endmodule
-
-
+//------------------------------------------------------------------------------
+
+module mac16_generic
+ (
+ input clk, // clock
+ input clr, // clear accumulator (active-high)
+ input ce, // enable clock (active-high)
+ input [15: 0] a, // operand input
+ input [15: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+ //
+ // Multiplier
+ //
+ wire [31: 0] p = {{16{1'b0}}, a} * {{16{1'b0}}, b};
+ wire [46: 0] p_ext = {{15{1'b0}}, p};
+
+ //
+ // Accumulator
+ //
+ reg [46: 0] s_int;
+
+ always @(posedge clk)
+ //
+ if (ce) s_int <= clr ? p_ext : p_ext + s_int;
+
+ //
+ // Output
+ //
+ assign s = s_int;
+
+endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/generic/subtractor32_generic.v b/rtl/lowlevel/generic/subtractor32_generic.v
index 46aefe8..5137ace 100644
--- a/rtl/lowlevel/generic/subtractor32_generic.v
+++ b/rtl/lowlevel/generic/subtractor32_generic.v
@@ -1,67 +1,67 @@
-//------------------------------------------------------------------------------
-//
-// subtractor32_generic.v
-// -----------------------------------------------------------------------------
-// Generic 32-bit subtractor.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module subtractor32_generic
- (
- input clk,
- input [31: 0] a,
- input [31: 0] b,
- output [31: 0] d,
- input b_in,
- output b_out
- );
-
- //
- // Difference
- //
- reg [32: 0] d_int;
-
- always @(posedge clk)
- d_int <= {1'b0, a} - {1'b0, b} - {{32{1'b0}}, b_in};
-
- //
- // Output
- //
- assign d = d_int[31:0];
- assign b_out = d_int[32];
-
-endmodule
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
+//
+// subtractor32_generic.v
+// -----------------------------------------------------------------------------
+// Generic 32-bit subtractor.
+//
+// Authors: Pavel Shatov
+//
+// Copyright (c) 2016, NORDUnet A/S
+//
+// Redistribution and use in source and binary forms, with or without
+// modification, are permitted provided that the following conditions are met:
+//
+// - Redistributions of source code must retain the above copyright notice,
+// this list of conditions and the following disclaimer.
+//
+// - Redistributions in binary form must reproduce the above copyright notice,
+// this list of conditions and the following disclaimer in the documentation
+// and/or other materials provided with the distribution.
+//
+// - Neither the name of the NORDUnet nor the names of its contributors may be
+// used to endorse or promote products derived from this software without
+// specific prior written permission.
+//
+// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
+// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+// POSSIBILITY OF SUCH DAMAGE.
+//
+//------------------------------------------------------------------------------
+
+module subtractor32_generic
+ (
+ input clk,
+ input [31: 0] a,
+ input [31: 0] b,
+ output [31: 0] d,
+ input b_in,
+ output b_out
+ );
+
+ //
+ // Difference
+ //
+ reg [32: 0] d_int;
+
+ always @(posedge clk)
+ d_int <= {1'b0, a} - {1'b0, b} - {{32{1'b0}}, b_in};
+
+ //
+ // Output
+ //
+ assign d = d_int[31:0];
+ assign b_out = d_int[32];
+
+endmodule
+
+//------------------------------------------------------------------------------
+// End-of-File
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/mac16_wrapper.v b/rtl/lowlevel/mac16_wrapper.v
index b91e518..89dbba1 100644
--- a/rtl/lowlevel/mac16_wrapper.v
+++ b/rtl/lowlevel/mac16_wrapper.v
@@ -2,7 +2,7 @@
//
// mac16_wrapper.v
// -----------------------------------------------------------------------------
-// Wrapper for 16-bit multiplier and 48-bit accumulator.
+// Wrapper for 16-bit multiplier and 48-bit accumulator.
//
// Authors: Pavel Shatov
//
@@ -34,42 +34,42 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module mac16_wrapper
- (
- input clk, // clock
- input clr, // clear accumulator (active-high)
- input ce, // enable clock (active-high)
- input [15: 0] a, // operand input
- input [15: 0] b, // operand input
- output [46: 0] s // sum output
- );
-
-
- //
- // Include Primitive Selector
- //
+//------------------------------------------------------------------------------
+
+module mac16_wrapper
+ (
+ input clk, // clock
+ input clr, // clear accumulator (active-high)
+ input ce, // enable clock (active-high)
+ input [15: 0] a, // operand input
+ input [15: 0] b, // operand input
+ output [46: 0] s // sum output
+ );
+
+
+ //
+ // Include Primitive Selector
+ //
`include "ecdsa_lowlevel_settings.v"
- //
- // Instantiate Vendor/Generic Primitive
- //
- `MAC16_PRIMITIVE mac16_inst
- (
- .clk(clk),
- .clr(clr),
- .ce(ce),
- .a(a),
- .b(b),
- .s(s)
- );
-
-
-endmodule
-
-
+ //
+ // Instantiate Vendor/Generic Primitive
+ //
+ `MAC16_PRIMITIVE mac16_inst
+ (
+ .clk(clk),
+ .clr(clr),
+ .ce(ce),
+ .a(a),
+ .b(b),
+ .s(s)
+ );
+
+
+endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/lowlevel/subtractor32_wrapper.v b/rtl/lowlevel/subtractor32_wrapper.v
index 3c7e5e9..063e753 100644
--- a/rtl/lowlevel/subtractor32_wrapper.v
+++ b/rtl/lowlevel/subtractor32_wrapper.v
@@ -1,72 +1,72 @@
-//------------------------------------------------------------------------------
-//
-// subtractor32_wrapper.v
-// -----------------------------------------------------------------------------
-// Wrapper for 32-bit subtractor.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module subtractor32_wrapper
- (
- input clk,
- input [31: 0] a,
- input [31: 0] b,
- output [31: 0] d,
- input b_in,
- output b_out
- );
-
- //
- // Include Primitive Selector
- //
+//------------------------------------------------------------------------------
+//
+// subtractor32_wrapper.v
+// -----------------------------------------------------------------------------
+// Wrapper for 32-bit subtractor.
+//
+// Authors: Pavel Shatov
+//
+// Copyright (c) 2016, NORDUnet A/S
+//
+// Redistribution and use in source and binary forms, with or without
+// modification, are permitted provided that the following conditions are met:
+//
+// - Redistributions of source code must retain the above copyright notice,
+// this list of conditions and the following disclaimer.
+//
+// - Redistributions in binary form must reproduce the above copyright notice,
+// this list of conditions and the following disclaimer in the documentation
+// and/or other materials provided with the distribution.
+//
+// - Neither the name of the NORDUnet nor the names of its contributors may be
+// used to endorse or promote products derived from this software without
+// specific prior written permission.
+//
+// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
+// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+// POSSIBILITY OF SUCH DAMAGE.
+//
+//------------------------------------------------------------------------------
+
+module subtractor32_wrapper
+ (
+ input clk,
+ input [31: 0] a,
+ input [31: 0] b,
+ output [31: 0] d,
+ input b_in,
+ output b_out
+ );
+
+ //
+ // Include Primitive Selector
+ //
`include "ecdsa_lowlevel_settings.v"
- //
- // Instantiate Vendor/Generic Primitive
- //
- `SUBTRACTOR32_PRIMITIVE subtractor32_inst
- (
- .clk(clk),
- .a(a),
- .b(b),
- .d(d),
- .b_in(b_in),
- .b_out(b_out)
- );
-
-endmodule
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
+ //
+ // Instantiate Vendor/Generic Primitive
+ //
+ `SUBTRACTOR32_PRIMITIVE subtractor32_inst
+ (
+ .clk(clk),
+ .a(a),
+ .b(b),
+ .d(d),
+ .b_in(b_in),
+ .b_out(b_out)
+ );
+
+endmodule
+
+//------------------------------------------------------------------------------
+// End-of-File
+//------------------------------------------------------------------------------
diff --git a/rtl/modular/modular_adder.v b/rtl/modular/modular_adder.v
index 5641feb..189059d 100644
--- a/rtl/modular/modular_adder.v
+++ b/rtl/modular/modular_adder.v
@@ -2,7 +2,7 @@
//
// modular_adder.v
// -----------------------------------------------------------------------------
-// Modular adder.
+// Modular adder.
//
// Authors: Pavel Shatov
//
@@ -34,265 +34,265 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module modular_adder
- (
- clk, rst_n,
- ena, rdy,
- ab_addr, n_addr, s_addr, s_wren,
- a_din, b_din, n_din, s_dout
- );
-
-
- //
- // Parameters
- //
- parameter OPERAND_NUM_WORDS = 8;
- parameter WORD_COUNTER_WIDTH = 3;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
- WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-1:0] ab_addr; // index of current A and B words
- output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
- output wire [WORD_COUNTER_WIDTH-1:0] s_addr; // index of current S word
- output wire s_wren; // store current S word now
-
- input wire [ 31:0] a_din; // A
- input wire [ 31:0] b_din; // B
- input wire [ 31:0] n_din; // N
- output wire [ 31:0] s_dout; // S = (A + B) mod N
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH-1:0] index_ab;
- reg [WORD_COUNTER_WIDTH-1:0] index_n;
- reg [WORD_COUNTER_WIDTH-1:0] index_s;
-
- /* map registers to output ports */
- assign ab_addr = index_ab;
- assign n_addr = index_n;
- assign s_addr = index_s;
-
-
- //
- // Adder
- //
- wire [31: 0] add32_s;
- wire add32_c_in;
- wire add32_c_out;
-
- adder32_wrapper adder32
- (
- .clk (clk),
- .a (a_din),
- .b (b_din),
- .s (add32_s),
- .c_in (add32_c_in),
- .c_out (add32_c_out)
- );
-
-
- //
- // Subtractor
- //
- wire [31: 0] sub32_d;
- wire sub32_b_in;
- wire sub32_b_out;
-
- subtractor32_wrapper subtractor32
- (
- .clk (clk),
- .a (add32_s),
- .b (n_din),
- .d (sub32_d),
- .b_in (sub32_b_in),
- .b_out (sub32_b_out)
- );
-
-
- //
- // FSM
- //
-
- localparam FSM_SHREG_WIDTH = 2*OPERAND_NUM_WORDS + 5;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_sum_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_sum_ab_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_data_s = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 3)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_s = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 4)];
-
- wire fsm_latch_msb_carry = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
- wire fsm_latch_msb_borrow = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
-
- wire inc_index_ab = |fsm_shreg_inc_index_ab;
- wire inc_index_n = |fsm_shreg_inc_index_n;
- wire store_sum_ab = |fsm_shreg_store_sum_ab;
- wire store_sum_ab_n = |fsm_shreg_store_sum_ab_n;
- wire store_data_s = |fsm_shreg_store_data_s;
- wire inc_index_s = |fsm_shreg_inc_index_s;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
-
-
-
-
-
- //
- // Carry & Borrow Masking Logic
- //
- reg add32_c_mask;
- reg sub32_b_mask;
-
- always @(posedge clk) begin
- //
- add32_c_mask <= (index_ab == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
- sub32_b_mask <= (index_n == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
- //
- end
-
- assign add32_c_in = add32_c_out & ~add32_c_mask;
- assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
-
-
- //
- // Carry & Borrow Latch Logic
- //
- reg add32_carry_latch;
- reg sub32_borrow_latch;
-
- always @(posedge clk) begin
- //
- if (fsm_latch_msb_carry) add32_carry_latch <= add32_c_out;
- if (fsm_latch_msb_borrow) sub32_borrow_latch <= sub32_b_out;
- //
- end
-
-
- //
- // Intermediate Results
- //
- reg [32*OPERAND_NUM_WORDS-1:0] s_ab;
- reg [32*OPERAND_NUM_WORDS-1:0] s_ab_n;
-
- always @(posedge clk)
- //
- if (store_data_s) begin
- //
- s_ab <= {{32{1'bX}}, s_ab[32*OPERAND_NUM_WORDS-1:32]};
- s_ab_n <= {{32{1'bX}}, s_ab_n[32*OPERAND_NUM_WORDS-1:32]};
- //
- end else begin
- //
- if (store_sum_ab) s_ab <= {add32_s, s_ab[32*OPERAND_NUM_WORDS-1:32]};
- if (store_sum_ab_n) s_ab_n <= {sub32_d, s_ab_n[32*OPERAND_NUM_WORDS-1:32]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- always @(posedge clk)
- //
- if (rdy) begin
- //
- index_ab <= WORD_INDEX_ZERO;
- index_n <= WORD_INDEX_ZERO;
- index_s <= WORD_INDEX_ZERO;
- //
- end else begin
- //
- if (inc_index_ab) index_ab <= WORD_INDEX_NEXT_OR_ZERO(index_ab);
- if (inc_index_n) index_n <= WORD_INDEX_NEXT_OR_ZERO(index_n);
- if (inc_index_s) index_s <= WORD_INDEX_NEXT_OR_ZERO(index_s);
- //
- end
-
-
- //
- // Output Sum Selector
- //
- wire mux_select_ab = sub32_borrow_latch && !add32_carry_latch;
-
-
- //
- // Output Data and Write Enable Logic
- //
- reg s_wren_reg;
- reg [31: 0] s_dout_reg;
- wire [31: 0] s_dout_mux = mux_select_ab ? s_ab[31:0] : s_ab_n[31:0];
-
- assign s_wren = s_wren_reg;
- assign s_dout = s_dout_reg;
-
- always @(posedge clk)
- //
- if (rdy) begin
- //
- s_wren_reg <= 1'b0;
- s_dout_reg <= {32{1'bX}};
- //
- end else begin
- //
- s_wren_reg <= store_data_s;
- s_dout_reg <= store_data_s ? s_dout_mux : {32{1'bX}};
- //
- end
-
-
-endmodule
-
-
+//------------------------------------------------------------------------------
+
+module modular_adder
+ (
+ clk, rst_n,
+ ena, rdy,
+ ab_addr, n_addr, s_addr, s_wren,
+ a_din, b_din, n_din, s_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter OPERAND_NUM_WORDS = 8;
+ parameter WORD_COUNTER_WIDTH = 3;
+
+
+ //
+ // Handy Numbers
+ //
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
+
+
+ //
+ // Handy Functions
+ //
+ function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
+ input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
+ begin
+ WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
+ WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
+ end
+ endfunction
+
+
+ //
+ // Ports
+ //
+ input wire clk; // system clock
+ input wire rst_n; // active-low async reset
+
+ input wire ena; // enable input
+ output wire rdy; // ready output
+
+ output wire [WORD_COUNTER_WIDTH-1:0] ab_addr; // index of current A and B words
+ output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
+ output wire [WORD_COUNTER_WIDTH-1:0] s_addr; // index of current S word
+ output wire s_wren; // store current S word now
+
+ input wire [ 31:0] a_din; // A
+ input wire [ 31:0] b_din; // B
+ input wire [ 31:0] n_din; // N
+ output wire [ 31:0] s_dout; // S = (A + B) mod N
+
+
+ //
+ // Word Indices
+ //
+ reg [WORD_COUNTER_WIDTH-1:0] index_ab;
+ reg [WORD_COUNTER_WIDTH-1:0] index_n;
+ reg [WORD_COUNTER_WIDTH-1:0] index_s;
+
+ /* map registers to output ports */
+ assign ab_addr = index_ab;
+ assign n_addr = index_n;
+ assign s_addr = index_s;
+
+
+ //
+ // Adder
+ //
+ wire [31: 0] add32_s;
+ wire add32_c_in;
+ wire add32_c_out;
+
+ adder32_wrapper adder32
+ (
+ .clk (clk),
+ .a (a_din),
+ .b (b_din),
+ .s (add32_s),
+ .c_in (add32_c_in),
+ .c_out (add32_c_out)
+ );
+
+
+ //
+ // Subtractor
+ //
+ wire [31: 0] sub32_d;
+ wire sub32_b_in;
+ wire sub32_b_out;
+
+ subtractor32_wrapper subtractor32
+ (
+ .clk (clk),
+ .a (add32_s),
+ .b (n_din),
+ .d (sub32_d),
+ .b_in (sub32_b_in),
+ .b_out (sub32_b_out)
+ );
+
+
+ //
+ // FSM
+ //
+
+ localparam FSM_SHREG_WIDTH = 2*OPERAND_NUM_WORDS + 5;
+
+ reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
+
+ assign rdy = fsm_shreg[0];
+
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_sum_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_sum_ab_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_data_s = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 3)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_s = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 4)];
+
+ wire fsm_latch_msb_carry = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+ wire fsm_latch_msb_borrow = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
+
+ wire inc_index_ab = |fsm_shreg_inc_index_ab;
+ wire inc_index_n = |fsm_shreg_inc_index_n;
+ wire store_sum_ab = |fsm_shreg_store_sum_ab;
+ wire store_sum_ab_n = |fsm_shreg_store_sum_ab_n;
+ wire store_data_s = |fsm_shreg_store_data_s;
+ wire inc_index_s = |fsm_shreg_inc_index_s;
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0)
+ //
+ fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
+ //
+ else begin
+ //
+ if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
+ //
+ else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
+ //
+ end
+
+
+
+
+
+
+
+ //
+ // Carry & Borrow Masking Logic
+ //
+ reg add32_c_mask;
+ reg sub32_b_mask;
+
+ always @(posedge clk) begin
+ //
+ add32_c_mask <= (index_ab == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
+ sub32_b_mask <= (index_n == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
+ //
+ end
+
+ assign add32_c_in = add32_c_out & ~add32_c_mask;
+ assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
+
+
+ //
+ // Carry & Borrow Latch Logic
+ //
+ reg add32_carry_latch;
+ reg sub32_borrow_latch;
+
+ always @(posedge clk) begin
+ //
+ if (fsm_latch_msb_carry) add32_carry_latch <= add32_c_out;
+ if (fsm_latch_msb_borrow) sub32_borrow_latch <= sub32_b_out;
+ //
+ end
+
+
+ //
+ // Intermediate Results
+ //
+ reg [32*OPERAND_NUM_WORDS-1:0] s_ab;
+ reg [32*OPERAND_NUM_WORDS-1:0] s_ab_n;
+
+ always @(posedge clk)
+ //
+ if (store_data_s) begin
+ //
+ s_ab <= {{32{1'bX}}, s_ab[32*OPERAND_NUM_WORDS-1:32]};
+ s_ab_n <= {{32{1'bX}}, s_ab_n[32*OPERAND_NUM_WORDS-1:32]};
+ //
+ end else begin
+ //
+ if (store_sum_ab) s_ab <= {add32_s, s_ab[32*OPERAND_NUM_WORDS-1:32]};
+ if (store_sum_ab_n) s_ab_n <= {sub32_d, s_ab_n[32*OPERAND_NUM_WORDS-1:32]};
+ //
+ end
+
+
+ //
+ // Word Index Increment Logic
+ //
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ index_ab <= WORD_INDEX_ZERO;
+ index_n <= WORD_INDEX_ZERO;
+ index_s <= WORD_INDEX_ZERO;
+ //
+ end else begin
+ //
+ if (inc_index_ab) index_ab <= WORD_INDEX_NEXT_OR_ZERO(index_ab);
+ if (inc_index_n) index_n <= WORD_INDEX_NEXT_OR_ZERO(index_n);
+ if (inc_index_s) index_s <= WORD_INDEX_NEXT_OR_ZERO(index_s);
+ //
+ end
+
+
+ //
+ // Output Sum Selector
+ //
+ wire mux_select_ab = sub32_borrow_latch && !add32_carry_latch;
+
+
+ //
+ // Output Data and Write Enable Logic
+ //
+ reg s_wren_reg;
+ reg [31: 0] s_dout_reg;
+ wire [31: 0] s_dout_mux = mux_select_ab ? s_ab[31:0] : s_ab_n[31:0];
+
+ assign s_wren = s_wren_reg;
+ assign s_dout = s_dout_reg;
+
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ s_wren_reg <= 1'b0;
+ s_dout_reg <= {32{1'bX}};
+ //
+ end else begin
+ //
+ s_wren_reg <= store_data_s;
+ s_dout_reg <= store_data_s ? s_dout_mux : {32{1'bX}};
+ //
+ end
+
+
+endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_copy.v b/rtl/modular/modular_invertor/helper/modinv_helper_copy.v
index 07c1b4f..f097362 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_copy.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_copy.v
@@ -1,148 +1,148 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_copy
- (
- clk, rst_n,
- ena, rdy,
- s_addr, s_din,
- a1_addr, a1_wren, a1_dout
- );
-
-
- //
- // Parameters
- //
- parameter OPERAND_NUM_WORDS = 8;
- parameter OPERAND_ADDR_BITS = 3;
-
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = OPERAND_NUM_WORDS + 2;
- localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
-
- input wire ena;
- output wire rdy;
-
- output wire [ BUFFER_ADDR_BITS-1:0] s_addr;
- output wire [OPERAND_ADDR_BITS-1:0] a1_addr;
-
- output wire a1_wren;
-
- input wire [ 31:0] s_din;
-
- output wire [ 31:0] a1_dout;
-
-
- //
- // 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 [OPERAND_ADDR_BITS-1:0] addr_s;
-
- wire [OPERAND_ADDR_BITS-1:0] addr_s_max = OPERAND_NUM_WORDS - 1;
- wire [OPERAND_ADDR_BITS-1:0] addr_s_zero = {OPERAND_ADDR_BITS{1'b0}};
- wire [OPERAND_ADDR_BITS-1:0] addr_s_next = (addr_s < addr_s_max) ?
- addr_s + 1'b1 : addr_s_zero;
-
- reg [OPERAND_ADDR_BITS-1:0] addr_a1;
-
- wire [OPERAND_ADDR_BITS-1:0] addr_a1_max = OPERAND_NUM_WORDS - 1;
- wire [OPERAND_ADDR_BITS-1:0] addr_a1_zero = {OPERAND_ADDR_BITS{1'b0}};
- wire [OPERAND_ADDR_BITS-1:0] addr_a1_next = (addr_a1 < addr_a1_max) ?
- addr_a1 + 1'b1 : addr_a1_zero;
-
- assign s_addr = {{(BUFFER_ADDR_BITS - OPERAND_ADDR_BITS){1'b0}}, addr_s};
- assign a1_addr = addr_a1;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Increment Logic
- //
- wire inc_addr_s;
- wire inc_addr_a1;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_s_start = 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_s_stop = OPERAND_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_a1_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_a1_stop = OPERAND_NUM_WORDS + 1;
-
- assign inc_addr_s = (proc_cnt >= cnt_inc_addr_s_start) && (proc_cnt <= cnt_inc_addr_s_stop);
- assign inc_addr_a1 = (proc_cnt >= cnt_inc_addr_a1_start) && (proc_cnt <= cnt_inc_addr_a1_stop);
-
- always @(posedge clk) begin
- //
- if (inc_addr_s) addr_s <= addr_s_next;
- else addr_s <= addr_s_zero;
- //
- if (inc_addr_a1) addr_a1 <= addr_a1_next;
- else addr_a1 <= addr_a1_zero;
- //
- end
-
-
- //
- // Write Enable Logic
- //
- wire wren_a1;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_a1_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_wren_a1_stop = OPERAND_NUM_WORDS + 1;
-
- assign wren_a1 = (proc_cnt >= cnt_wren_a1_start) && (proc_cnt <= cnt_wren_a1_stop);
-
- assign a1_wren = wren_a1;
-
-
- //
- // Data Logic
- //
- assign a1_dout = s_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_copy
+ (
+ clk, rst_n,
+ ena, rdy,
+ s_addr, s_din,
+ a1_addr, a1_wren, a1_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter OPERAND_NUM_WORDS = 8;
+ parameter OPERAND_ADDR_BITS = 3;
+
+ parameter BUFFER_NUM_WORDS = 9;
+ parameter BUFFER_ADDR_BITS = 4;
+
+
+ //
+ // clog2
+ //
+`include "../modinv_clog2.v"
+
+
+ //
+ // Constants
+ //
+ localparam PROC_NUM_CYCLES = OPERAND_NUM_WORDS + 2;
+ localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
+
+
+ //
+ // Ports
+ //
+ input wire clk;
+ input wire rst_n;
+
+ input wire ena;
+ output wire rdy;
+
+ output wire [ BUFFER_ADDR_BITS-1:0] s_addr;
+ output wire [OPERAND_ADDR_BITS-1:0] a1_addr;
+
+ output wire a1_wren;
+
+ input wire [ 31:0] s_din;
+
+ output wire [ 31:0] a1_dout;
+
+
+ //
+ // 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 [OPERAND_ADDR_BITS-1:0] addr_s;
+
+ wire [OPERAND_ADDR_BITS-1:0] addr_s_max = OPERAND_NUM_WORDS - 1;
+ wire [OPERAND_ADDR_BITS-1:0] addr_s_zero = {OPERAND_ADDR_BITS{1'b0}};
+ wire [OPERAND_ADDR_BITS-1:0] addr_s_next = (addr_s < addr_s_max) ?
+ addr_s + 1'b1 : addr_s_zero;
+
+ reg [OPERAND_ADDR_BITS-1:0] addr_a1;
+
+ wire [OPERAND_ADDR_BITS-1:0] addr_a1_max = OPERAND_NUM_WORDS - 1;
+ wire [OPERAND_ADDR_BITS-1:0] addr_a1_zero = {OPERAND_ADDR_BITS{1'b0}};
+ wire [OPERAND_ADDR_BITS-1:0] addr_a1_next = (addr_a1 < addr_a1_max) ?
+ addr_a1 + 1'b1 : addr_a1_zero;
+
+ assign s_addr = {{(BUFFER_ADDR_BITS - OPERAND_ADDR_BITS){1'b0}}, addr_s};
+ assign a1_addr = addr_a1;
+
+
+ //
+ // Ready Flag
+ //
+ assign rdy = (proc_cnt == proc_cnt_zero);
+
+
+ //
+ // Address Increment Logic
+ //
+ wire inc_addr_s;
+ wire inc_addr_a1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_s_start = 1;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_s_stop = OPERAND_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_a1_start = 2;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_a1_stop = OPERAND_NUM_WORDS + 1;
+
+ assign inc_addr_s = (proc_cnt >= cnt_inc_addr_s_start) && (proc_cnt <= cnt_inc_addr_s_stop);
+ assign inc_addr_a1 = (proc_cnt >= cnt_inc_addr_a1_start) && (proc_cnt <= cnt_inc_addr_a1_stop);
+
+ always @(posedge clk) begin
+ //
+ if (inc_addr_s) addr_s <= addr_s_next;
+ else addr_s <= addr_s_zero;
+ //
+ if (inc_addr_a1) addr_a1 <= addr_a1_next;
+ else addr_a1 <= addr_a1_zero;
+ //
+ end
+
+
+ //
+ // Write Enable Logic
+ //
+ wire wren_a1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_a1_start = 2;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_a1_stop = OPERAND_NUM_WORDS + 1;
+
+ assign wren_a1 = (proc_cnt >= cnt_wren_a1_start) && (proc_cnt <= cnt_wren_a1_stop);
+
+ assign a1_wren = wren_a1;
+
+
+ //
+ // Data Logic
+ //
+ assign a1_dout = s_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
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_init.v b/rtl/modular/modular_invertor/helper/modinv_helper_init.v
index 0468134..5a909c0 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_init.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_init.v
@@ -1,172 +1,172 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_init
- (
- clk, rst_n,
- ena, rdy,
- a_addr, a_din,
- q_addr, q_din,
- r_addr, r_wren, r_dout,
- s_addr, s_wren, s_dout,
- u_addr, u_wren, u_dout,
- v_addr, v_wren, v_dout
- );
-
-
- //
- // Parameters
- //
- parameter OPERAND_NUM_WORDS = 8;
- parameter OPERAND_ADDR_BITS = 3;
-
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = OPERAND_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;
-
- output wire [OPERAND_ADDR_BITS-1:0] a_addr;
- output wire [OPERAND_ADDR_BITS-1:0] q_addr;
- output wire [ BUFFER_ADDR_BITS-1:0] r_addr;
- 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 r_wren;
- output wire s_wren;
- output wire u_wren;
- output wire v_wren;
-
- input wire [ 31:0] a_din;
- input wire [ 31:0] q_din;
- output wire [ 31:0] r_dout;
- output wire [ 31:0] s_dout;
- output wire [ 31:0] u_dout;
- output wire [ 31:0] v_dout;
-
-
- //
- // 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 [OPERAND_ADDR_BITS-1:0] addr_aq;
-
- wire [OPERAND_ADDR_BITS-1:0] addr_aq_max = OPERAND_NUM_WORDS - 1;
- wire [OPERAND_ADDR_BITS-1:0] addr_aq_zero = {OPERAND_ADDR_BITS{1'b0}};
- wire [OPERAND_ADDR_BITS-1:0] addr_aq_next = (addr_aq < addr_aq_max) ?
- addr_aq + 1'b1 : addr_aq_zero;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_rsuv;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_max = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_next = (addr_rsuv < addr_rsuv_max) ?
- addr_rsuv + 1'b1 : addr_rsuv_zero;
-
- assign a_addr = addr_aq;
- assign q_addr = addr_aq;
-
- assign r_addr = addr_rsuv;
- assign s_addr = addr_rsuv;
- assign u_addr = addr_rsuv;
- assign v_addr = addr_rsuv;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Increment Logic
- //
- wire inc_addr_aq;
- wire inc_addr_rsuv;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_aq_start = 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_aq_stop = OPERAND_NUM_WORDS;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_rsuv_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_rsuv_stop = BUFFER_NUM_WORDS + 1;
-
- assign inc_addr_aq = (proc_cnt >= cnt_inc_addr_aq_start) && (proc_cnt <= cnt_inc_addr_aq_stop);
- assign inc_addr_rsuv = (proc_cnt >= cnt_inc_addr_rsuv_start) && (proc_cnt <= cnt_inc_addr_rsuv_stop);
-
- always @(posedge clk) begin
- //
- if (inc_addr_aq) addr_aq <= addr_aq_next;
- else addr_aq <= addr_aq_zero;
- //
- if (inc_addr_rsuv) addr_rsuv <= addr_rsuv_next;
- else addr_rsuv <= addr_rsuv_zero;
- //
- end
-
-
- //
- // Write Enable Logic
- //
- wire wren_rsuv;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_rsuv_start = 2;
- wire [PROC_CNT_BITS-1:0] cnt_wren_rsuv_stop = BUFFER_NUM_WORDS + 1;
-
- assign wren_rsuv = (proc_cnt >= cnt_wren_rsuv_start) && (proc_cnt <= cnt_wren_rsuv_stop);
-
- assign r_wren = wren_rsuv;
- assign s_wren = wren_rsuv;
- assign u_wren = wren_rsuv;
- assign v_wren = wren_rsuv;
-
-
- //
- // Data Logic
- //
- assign r_dout = 32'd0;
- assign s_dout = (proc_cnt == cnt_wren_rsuv_start) ? 32'd1 : 32'd0;
- assign u_dout = (proc_cnt != cnt_wren_rsuv_stop) ? q_din : 32'd0;
- assign v_dout = (proc_cnt != cnt_wren_rsuv_stop) ? a_din : 32'd0;
-
-
- //
- // 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_init
+ (
+ clk, rst_n,
+ ena, rdy,
+ a_addr, a_din,
+ q_addr, q_din,
+ r_addr, r_wren, r_dout,
+ s_addr, s_wren, s_dout,
+ u_addr, u_wren, u_dout,
+ v_addr, v_wren, v_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter OPERAND_NUM_WORDS = 8;
+ parameter OPERAND_ADDR_BITS = 3;
+
+ parameter BUFFER_NUM_WORDS = 9;
+ parameter BUFFER_ADDR_BITS = 4;
+
+
+ //
+ // clog2
+ //
+`include "../modinv_clog2.v"
+
+
+ //
+ // Constants
+ //
+ localparam PROC_NUM_CYCLES = OPERAND_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;
+
+ output wire [OPERAND_ADDR_BITS-1:0] a_addr;
+ output wire [OPERAND_ADDR_BITS-1:0] q_addr;
+ output wire [ BUFFER_ADDR_BITS-1:0] r_addr;
+ 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 r_wren;
+ output wire s_wren;
+ output wire u_wren;
+ output wire v_wren;
+
+ input wire [ 31:0] a_din;
+ input wire [ 31:0] q_din;
+ output wire [ 31:0] r_dout;
+ output wire [ 31:0] s_dout;
+ output wire [ 31:0] u_dout;
+ output wire [ 31:0] v_dout;
+
+
+ //
+ // 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 [OPERAND_ADDR_BITS-1:0] addr_aq;
+
+ wire [OPERAND_ADDR_BITS-1:0] addr_aq_max = OPERAND_NUM_WORDS - 1;
+ wire [OPERAND_ADDR_BITS-1:0] addr_aq_zero = {OPERAND_ADDR_BITS{1'b0}};
+ wire [OPERAND_ADDR_BITS-1:0] addr_aq_next = (addr_aq < addr_aq_max) ?
+ addr_aq + 1'b1 : addr_aq_zero;
+
+ reg [BUFFER_ADDR_BITS-1:0] addr_rsuv;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_max = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_rsuv_next = (addr_rsuv < addr_rsuv_max) ?
+ addr_rsuv + 1'b1 : addr_rsuv_zero;
+
+ assign a_addr = addr_aq;
+ assign q_addr = addr_aq;
+
+ assign r_addr = addr_rsuv;
+ assign s_addr = addr_rsuv;
+ assign u_addr = addr_rsuv;
+ assign v_addr = addr_rsuv;
+
+
+ //
+ // Ready Flag
+ //
+ assign rdy = (proc_cnt == proc_cnt_zero);
+
+
+ //
+ // Address Increment Logic
+ //
+ wire inc_addr_aq;
+ wire inc_addr_rsuv;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_aq_start = 1;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_aq_stop = OPERAND_NUM_WORDS;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_rsuv_start = 2;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_rsuv_stop = BUFFER_NUM_WORDS + 1;
+
+ assign inc_addr_aq = (proc_cnt >= cnt_inc_addr_aq_start) && (proc_cnt <= cnt_inc_addr_aq_stop);
+ assign inc_addr_rsuv = (proc_cnt >= cnt_inc_addr_rsuv_start) && (proc_cnt <= cnt_inc_addr_rsuv_stop);
+
+ always @(posedge clk) begin
+ //
+ if (inc_addr_aq) addr_aq <= addr_aq_next;
+ else addr_aq <= addr_aq_zero;
+ //
+ if (inc_addr_rsuv) addr_rsuv <= addr_rsuv_next;
+ else addr_rsuv <= addr_rsuv_zero;
+ //
+ end
+
+
+ //
+ // Write Enable Logic
+ //
+ wire wren_rsuv;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_rsuv_start = 2;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_rsuv_stop = BUFFER_NUM_WORDS + 1;
+
+ assign wren_rsuv = (proc_cnt >= cnt_wren_rsuv_start) && (proc_cnt <= cnt_wren_rsuv_stop);
+
+ assign r_wren = wren_rsuv;
+ assign s_wren = wren_rsuv;
+ assign u_wren = wren_rsuv;
+ assign v_wren = wren_rsuv;
+
+
+ //
+ // Data Logic
+ //
+ assign r_dout = 32'd0;
+ assign s_dout = (proc_cnt == cnt_wren_rsuv_start) ? 32'd1 : 32'd0;
+ assign u_dout = (proc_cnt != cnt_wren_rsuv_stop) ? q_din : 32'd0;
+ assign v_dout = (proc_cnt != cnt_wren_rsuv_stop) ? a_din : 32'd0;
+
+
+ //
+ // 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
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_invert_compare.v b/rtl/modular/modular_invertor/helper/modinv_helper_invert_compare.v
index 6b65eb1..724b9f8 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_invert_compare.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_invert_compare.v
@@ -1,286 +1,286 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_invert_compare
- (
- clk, rst_n,
- ena, rdy,
-
- u_addr, u_din,
- v_addr, v_din,
-
- u_gt_v, v_eq_1,
- u_is_even, v_is_even
- );
-
-
- //
- // Parameters
- //
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = 1 * BUFFER_NUM_WORDS + 10;
- localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
- input wire ena;
- output wire rdy;
-
- output wire [BUFFER_ADDR_BITS-1:0] u_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_addr;
-
- input wire [ 32-1:0] u_din;
- input wire [ 32-1:0] v_din;
-
- output wire u_gt_v;
- output wire v_eq_1;
- output wire u_is_even;
- output wire v_is_even;
-
-
- //
- // 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_last = 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_prev = (addr_in > addr_in_zero) ?
- addr_in - 1'b1 : addr_in_last;
-
- assign u_addr = addr_in;
- assign v_addr = addr_in;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Decrement Logic
- //
- wire dec_addr_in;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_start = 0 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_stop = 1 * BUFFER_NUM_WORDS + 0;
-
- assign dec_addr_in = (proc_cnt >= cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop);
-
- always @(posedge clk)
- //
- if (rdy) addr_in <= addr_in_last;
- else if (dec_addr_in) addr_in <= addr_in_prev;
-
-
- //
- // Comparison Stage Flags
- //
- wire calc_leg;
- wire calc_leg_final;
- wire calc_parity;
-
- wire [PROC_CNT_BITS-1:0] cnt_calc_leg_start = 0 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_calc_leg_stop = 1 * BUFFER_NUM_WORDS + 2;
- wire [PROC_CNT_BITS-1:0] cnt_calc_parity = 1 * BUFFER_NUM_WORDS + 1;
-
- assign calc_leg = (proc_cnt >= cnt_calc_leg_start) && (proc_cnt <= cnt_calc_leg_stop);
- assign calc_leg_final = (proc_cnt == cnt_calc_leg_stop);
- assign calc_parity = (proc_cnt == cnt_calc_parity);
-
-
- //
- // Dummy Input
- //
- reg sub32_din_1_lsb;
- wire [31: 0] sub32_din_1 = {{31{1'b0}}, sub32_din_1_lsb};
-
- always @(posedge clk)
- //
- sub32_din_1_lsb <= (addr_in == addr_in_zero) ? 1'b1 : 1'b0;
-
-
- //
- // Subtractor (u - v)
- //
- wire [31: 0] sub32_u_minus_v_difference_out;
- wire sub32_u_minus_v_borrow_in;
- wire sub32_u_minus_v_borrow_out;
-
- subtractor32_wrapper sub32_u_minus_v
- (
- .clk (clk),
- .a (u_din),
- .b (v_din),
- .d (sub32_u_minus_v_difference_out),
- .b_in (sub32_u_minus_v_borrow_in),
- .b_out (sub32_u_minus_v_borrow_out)
- );
-
-
- //
- // Subtractor (v - 1)
- //
- wire [31: 0] sub32_v_minus_1_difference_out;
- wire sub32_v_minus_1_borrow_in;
- wire sub32_v_minus_1_borrow_out;
-
- subtractor32_wrapper sub32_v_minus_1
- (
- .clk (clk),
- .a (v_din),
- .b (sub32_din_1),
- .d (sub32_v_minus_1_difference_out),
- .b_in (sub32_v_minus_1_borrow_in),
- .b_out (sub32_v_minus_1_borrow_out)
- );
-
-
-
- //
- // Borrow Masking Logic
- //
- reg mask_borrow;
-
- always @(posedge clk)
- //
- mask_borrow <= ((proc_cnt > cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop)) ?
- 1'b0 : 1'b1;
-
- assign sub32_u_minus_v_borrow_in = sub32_u_minus_v_borrow_out & ~mask_borrow;
- assign sub32_v_minus_1_borrow_in = sub32_v_minus_1_borrow_out & ~mask_borrow;
-
-
- //
- // Comparison Logic
- //
- reg cmp_u_v_l;
- reg cmp_u_v_e;
- reg cmp_u_v_g;
-
- reg cmp_v_1_l;
- reg cmp_v_1_e;
- reg cmp_v_1_g;
-
- wire cmp_unresolved_u_v = !(cmp_u_v_l || cmp_u_v_g);
- wire cmp_unresolved_v_1 = !(cmp_v_1_l || cmp_v_1_g);
-
- wire cmp_u_v_borrow_is_set = (sub32_u_minus_v_borrow_out == 1'b1) ? 1'b1 : 1'b0;
- wire cmp_u_v_difference_is_nonzero = (sub32_u_minus_v_difference_out != 32'd0) ? 1'b1 : 1'b0;
-
- wire cmp_v_1_borrow_is_set = (sub32_v_minus_1_borrow_out == 1'b1) ? 1'b1 : 1'b0;
- wire cmp_v_1_difference_is_nonzero = (sub32_v_minus_1_difference_out != 32'd0) ? 1'b1 : 1'b0;
-
- reg u_is_even_reg;
- reg v_is_even_reg;
-
- always @(posedge clk)
- //
- if (rdy) begin
- //
- if (ena) begin
- //
- cmp_u_v_l <= 1'b0;
- cmp_u_v_e <= 1'b0;
- cmp_u_v_g <= 1'b0;
- //
- cmp_v_1_l <= 1'b0;
- cmp_v_1_e <= 1'b0;
- cmp_v_1_g <= 1'b0;
- //
- u_is_even_reg <= 1'bX;
- v_is_even_reg <= 1'bX;
- //
- end
- //
- end else begin
- //
- // parity
- //
- if (calc_parity) begin
- u_is_even_reg <= ~u_din[0];
- v_is_even_reg <= ~v_din[0];
- end
- //
- // u <> v
- //
- if (cmp_unresolved_u_v && calc_leg) begin
- //
- if (cmp_u_v_borrow_is_set)
- cmp_u_v_l <= 1'b1;
- //
- if (!cmp_u_v_borrow_is_set && cmp_u_v_difference_is_nonzero)
- cmp_u_v_g <= 1'b1;
- //
- if (!cmp_u_v_borrow_is_set && !cmp_u_v_difference_is_nonzero && calc_leg_final)
- cmp_u_v_e <= 1'b1;
- //
- end
- //
- // v <> 1
- //
- if (cmp_unresolved_v_1 && calc_leg) begin
- //
- if (cmp_v_1_borrow_is_set)
- cmp_v_1_l <= 1'b1;
- //
- if (!cmp_v_1_borrow_is_set && cmp_v_1_difference_is_nonzero)
- cmp_v_1_g <= 1'b1;
- //
- if (!cmp_v_1_borrow_is_set && !cmp_v_1_difference_is_nonzero && calc_leg_final)
- cmp_v_1_e <= 1'b1;
- //
- end
- //
- end
-
-
- //
- // Output Flags
- //
- assign u_gt_v = !cmp_u_v_l && !cmp_u_v_e && cmp_u_v_g;
- assign v_eq_1 = !cmp_v_1_l && cmp_v_1_e && !cmp_v_1_g;
-
- assign u_is_even = u_is_even_reg;
- assign v_is_even = v_is_even_reg;
-
-
- //
- // 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_invert_compare
+ (
+ clk, rst_n,
+ ena, rdy,
+
+ u_addr, u_din,
+ v_addr, v_din,
+
+ u_gt_v, v_eq_1,
+ u_is_even, v_is_even
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter BUFFER_NUM_WORDS = 9;
+ parameter BUFFER_ADDR_BITS = 4;
+
+
+ //
+ // clog2
+ //
+`include "../modinv_clog2.v"
+
+
+ //
+ // Constants
+ //
+ localparam PROC_NUM_CYCLES = 1 * BUFFER_NUM_WORDS + 10;
+ localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
+
+
+ //
+ // Ports
+ //
+ input wire clk;
+ input wire rst_n;
+ input wire ena;
+ output wire rdy;
+
+ output wire [BUFFER_ADDR_BITS-1:0] u_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_addr;
+
+ input wire [ 32-1:0] u_din;
+ input wire [ 32-1:0] v_din;
+
+ output wire u_gt_v;
+ output wire v_eq_1;
+ output wire u_is_even;
+ output wire v_is_even;
+
+
+ //
+ // 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_last = 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_prev = (addr_in > addr_in_zero) ?
+ addr_in - 1'b1 : addr_in_last;
+
+ assign u_addr = addr_in;
+ assign v_addr = addr_in;
+
+
+ //
+ // Ready Flag
+ //
+ assign rdy = (proc_cnt == proc_cnt_zero);
+
+
+ //
+ // Address Decrement Logic
+ //
+ wire dec_addr_in;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_start = 0 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_stop = 1 * BUFFER_NUM_WORDS + 0;
+
+ assign dec_addr_in = (proc_cnt >= cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop);
+
+ always @(posedge clk)
+ //
+ if (rdy) addr_in <= addr_in_last;
+ else if (dec_addr_in) addr_in <= addr_in_prev;
+
+
+ //
+ // Comparison Stage Flags
+ //
+ wire calc_leg;
+ wire calc_leg_final;
+ wire calc_parity;
+
+ wire [PROC_CNT_BITS-1:0] cnt_calc_leg_start = 0 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_calc_leg_stop = 1 * BUFFER_NUM_WORDS + 2;
+ wire [PROC_CNT_BITS-1:0] cnt_calc_parity = 1 * BUFFER_NUM_WORDS + 1;
+
+ assign calc_leg = (proc_cnt >= cnt_calc_leg_start) && (proc_cnt <= cnt_calc_leg_stop);
+ assign calc_leg_final = (proc_cnt == cnt_calc_leg_stop);
+ assign calc_parity = (proc_cnt == cnt_calc_parity);
+
+
+ //
+ // Dummy Input
+ //
+ reg sub32_din_1_lsb;
+ wire [31: 0] sub32_din_1 = {{31{1'b0}}, sub32_din_1_lsb};
+
+ always @(posedge clk)
+ //
+ sub32_din_1_lsb <= (addr_in == addr_in_zero) ? 1'b1 : 1'b0;
+
+
+ //
+ // Subtractor (u - v)
+ //
+ wire [31: 0] sub32_u_minus_v_difference_out;
+ wire sub32_u_minus_v_borrow_in;
+ wire sub32_u_minus_v_borrow_out;
+
+ subtractor32_wrapper sub32_u_minus_v
+ (
+ .clk (clk),
+ .a (u_din),
+ .b (v_din),
+ .d (sub32_u_minus_v_difference_out),
+ .b_in (sub32_u_minus_v_borrow_in),
+ .b_out (sub32_u_minus_v_borrow_out)
+ );
+
+
+ //
+ // Subtractor (v - 1)
+ //
+ wire [31: 0] sub32_v_minus_1_difference_out;
+ wire sub32_v_minus_1_borrow_in;
+ wire sub32_v_minus_1_borrow_out;
+
+ subtractor32_wrapper sub32_v_minus_1
+ (
+ .clk (clk),
+ .a (v_din),
+ .b (sub32_din_1),
+ .d (sub32_v_minus_1_difference_out),
+ .b_in (sub32_v_minus_1_borrow_in),
+ .b_out (sub32_v_minus_1_borrow_out)
+ );
+
+
+
+ //
+ // Borrow Masking Logic
+ //
+ reg mask_borrow;
+
+ always @(posedge clk)
+ //
+ mask_borrow <= ((proc_cnt > cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop)) ?
+ 1'b0 : 1'b1;
+
+ assign sub32_u_minus_v_borrow_in = sub32_u_minus_v_borrow_out & ~mask_borrow;
+ assign sub32_v_minus_1_borrow_in = sub32_v_minus_1_borrow_out & ~mask_borrow;
+
+
+ //
+ // Comparison Logic
+ //
+ reg cmp_u_v_l;
+ reg cmp_u_v_e;
+ reg cmp_u_v_g;
+
+ reg cmp_v_1_l;
+ reg cmp_v_1_e;
+ reg cmp_v_1_g;
+
+ wire cmp_unresolved_u_v = !(cmp_u_v_l || cmp_u_v_g);
+ wire cmp_unresolved_v_1 = !(cmp_v_1_l || cmp_v_1_g);
+
+ wire cmp_u_v_borrow_is_set = (sub32_u_minus_v_borrow_out == 1'b1) ? 1'b1 : 1'b0;
+ wire cmp_u_v_difference_is_nonzero = (sub32_u_minus_v_difference_out != 32'd0) ? 1'b1 : 1'b0;
+
+ wire cmp_v_1_borrow_is_set = (sub32_v_minus_1_borrow_out == 1'b1) ? 1'b1 : 1'b0;
+ wire cmp_v_1_difference_is_nonzero = (sub32_v_minus_1_difference_out != 32'd0) ? 1'b1 : 1'b0;
+
+ reg u_is_even_reg;
+ reg v_is_even_reg;
+
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ if (ena) begin
+ //
+ cmp_u_v_l <= 1'b0;
+ cmp_u_v_e <= 1'b0;
+ cmp_u_v_g <= 1'b0;
+ //
+ cmp_v_1_l <= 1'b0;
+ cmp_v_1_e <= 1'b0;
+ cmp_v_1_g <= 1'b0;
+ //
+ u_is_even_reg <= 1'bX;
+ v_is_even_reg <= 1'bX;
+ //
+ end
+ //
+ end else begin
+ //
+ // parity
+ //
+ if (calc_parity) begin
+ u_is_even_reg <= ~u_din[0];
+ v_is_even_reg <= ~v_din[0];
+ end
+ //
+ // u <> v
+ //
+ if (cmp_unresolved_u_v && calc_leg) begin
+ //
+ if (cmp_u_v_borrow_is_set)
+ cmp_u_v_l <= 1'b1;
+ //
+ if (!cmp_u_v_borrow_is_set && cmp_u_v_difference_is_nonzero)
+ cmp_u_v_g <= 1'b1;
+ //
+ if (!cmp_u_v_borrow_is_set && !cmp_u_v_difference_is_nonzero && calc_leg_final)
+ cmp_u_v_e <= 1'b1;
+ //
+ end
+ //
+ // v <> 1
+ //
+ if (cmp_unresolved_v_1 && calc_leg) begin
+ //
+ if (cmp_v_1_borrow_is_set)
+ cmp_v_1_l <= 1'b1;
+ //
+ if (!cmp_v_1_borrow_is_set && cmp_v_1_difference_is_nonzero)
+ cmp_v_1_g <= 1'b1;
+ //
+ if (!cmp_v_1_borrow_is_set && !cmp_v_1_difference_is_nonzero && calc_leg_final)
+ cmp_v_1_e <= 1'b1;
+ //
+ end
+ //
+ end
+
+
+ //
+ // Output Flags
+ //
+ assign u_gt_v = !cmp_u_v_l && !cmp_u_v_e && cmp_u_v_g;
+ assign v_eq_1 = !cmp_v_1_l && cmp_v_1_e && !cmp_v_1_g;
+
+ assign u_is_even = u_is_even_reg;
+ assign v_is_even = v_is_even_reg;
+
+
+ //
+ // 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
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_invert_precalc.v b/rtl/modular/modular_invertor/helper/modinv_helper_invert_precalc.v
index ab15563..3ebea00 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_invert_precalc.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_invert_precalc.v
@@ -1,408 +1,408 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_invert_precalc
- (
- clk, rst_n,
- ena, rdy,
-
- r_addr, r_din,
- s_addr, s_din,
- u_addr, u_din,
- v_addr, v_din,
-
- r_dbl_addr, r_dbl_wren, r_dbl_dout,
- s_dbl_addr, s_dbl_wren, s_dbl_dout,
- r_plus_s_addr, r_plus_s_wren, r_plus_s_dout,
- u_half_addr, u_half_wren, u_half_dout,
- v_half_addr, v_half_wren, v_half_dout,
- u_minus_v_addr, u_minus_v_wren, u_minus_v_dout, u_minus_v_din,
- v_minus_u_addr, v_minus_u_wren, v_minus_u_dout, v_minus_u_din,
- u_minus_v_half_addr, u_minus_v_half_wren, u_minus_v_half_dout,
- v_minus_u_half_addr, v_minus_u_half_wren, v_minus_u_half_dout
- );
-
-
- //
- // Parameters
- //
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = 2 * BUFFER_NUM_WORDS + 4;
- localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
- input wire ena;
- output wire rdy;
-
- output wire [BUFFER_ADDR_BITS-1:0] r_addr;
- 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;
-
- input wire [ 32-1:0] r_din;
- input wire [ 32-1:0] s_din;
- input wire [ 32-1:0] u_din;
- input wire [ 32-1:0] v_din;
-
- output wire [BUFFER_ADDR_BITS-1:0] r_dbl_addr;
- output wire [BUFFER_ADDR_BITS-1:0] s_dbl_addr;
- output wire [BUFFER_ADDR_BITS-1:0] r_plus_s_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_half_addr;
-
- output wire [ 32-1:0] r_dbl_dout;
- output wire [ 32-1:0] s_dbl_dout;
- output wire [ 32-1:0] r_plus_s_dout;
- output wire [ 32-1:0] u_half_dout;
- output wire [ 32-1:0] v_half_dout;
- output wire [ 32-1:0] u_minus_v_dout;
- output wire [ 32-1:0] v_minus_u_dout;
- output wire [ 32-1:0] u_minus_v_half_dout;
- output wire [ 32-1:0] v_minus_u_half_dout;
-
- output wire r_dbl_wren;
- output wire s_dbl_wren;
- output wire r_plus_s_wren;
- output wire u_half_wren;
- output wire v_half_wren;
- output wire u_minus_v_wren;
- output wire v_minus_u_wren;
- output wire u_minus_v_half_wren;
- output wire v_minus_u_half_wren;
-
- input wire [ 32-1:0] u_minus_v_din;
- input wire [ 32-1:0] v_minus_u_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_last = 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_last) ?
- addr_in + 1'b1 : addr_in_zero;
- wire [BUFFER_ADDR_BITS-1:0] addr_in_prev = (addr_in > addr_in_zero) ?
- addr_in - 1'b1 : addr_in_zero;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_out1;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_next = (addr_out1 < addr_out1_last) ?
- addr_out1 + 1'b1 : addr_out1_zero;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_out2;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_next = (addr_out2 < addr_out2_last) ?
- addr_out2 + 1'b1 : addr_out2_zero;
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_prev = (addr_out2 > addr_out2_zero) ?
- addr_out2 - 1'b1 : addr_out2_zero;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_out3;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_prev = (addr_out3 > addr_out3_zero) ?
- addr_out3 - 1'b1 : addr_out3_last;
-
- reg [BUFFER_ADDR_BITS-1:0] addr_out4;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out4_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out4_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out4_prev = (addr_out4 > addr_out4_zero) ?
- addr_out4 - 1'b1 : addr_out4_last;
-
-
- assign r_addr = addr_in;
- assign s_addr = addr_in;
- assign u_addr = addr_in;
- assign v_addr = addr_in;
-
- assign r_dbl_addr = addr_out1;
- assign s_dbl_addr = addr_out1;
- assign r_plus_s_addr = addr_out2;
- assign u_half_addr = addr_out3;
- assign v_half_addr = addr_out3;
- assign u_minus_v_addr = addr_out2;
- assign v_minus_u_addr = addr_out2;
- assign u_minus_v_half_addr = addr_out4;
- assign v_minus_u_half_addr = addr_out4;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Increment/Decrement Logic
- //
- wire inc_addr_in;
- wire dec_addr_in;
- wire inc_addr_out1;
- wire inc_addr_out2;
- wire dec_addr_out2;
- wire dec_addr_out3;
- wire dec_addr_out4;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_start = 0 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_stop = 1 * BUFFER_NUM_WORDS - 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_start = 0 * BUFFER_NUM_WORDS + 2;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out2_start = 0 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out2_stop = 1 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_start = 1 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_stop = 2 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_start = 1 * BUFFER_NUM_WORDS + 0;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_stop = 2 * BUFFER_NUM_WORDS - 2;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_start = 1 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_stop = 2 * BUFFER_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out4_start = 1 * BUFFER_NUM_WORDS + 4;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out4_stop = 2 * BUFFER_NUM_WORDS + 3;
-
- assign inc_addr_in = (proc_cnt >= cnt_inc_addr_in_start) && (proc_cnt <= cnt_inc_addr_in_stop);
- assign dec_addr_in = (proc_cnt >= cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop);
- assign inc_addr_out1 = (proc_cnt >= cnt_inc_addr_out1_start) && (proc_cnt <= cnt_inc_addr_out1_stop);
- assign inc_addr_out2 = (proc_cnt >= cnt_inc_addr_out2_start) && (proc_cnt <= cnt_inc_addr_out2_stop);
- assign dec_addr_out2 = (proc_cnt >= cnt_dec_addr_out2_start) && (proc_cnt <= cnt_dec_addr_out2_stop);
- assign dec_addr_out3 = (proc_cnt >= cnt_dec_addr_out3_start) && (proc_cnt <= cnt_dec_addr_out3_stop);
- assign dec_addr_out4 = (proc_cnt >= cnt_dec_addr_out4_start) && (proc_cnt <= cnt_dec_addr_out4_stop);
-
-
- always @(posedge clk) begin
- //
- if (rdy) begin
- //
- addr_in <= addr_in_zero;
- addr_out1 <= addr_out1_zero;
- addr_out2 <= addr_out2_zero;
- addr_out3 <= addr_out3_last;
- addr_out4 <= addr_out4_last;
- //
- end else begin
- //
- if (inc_addr_in) addr_in <= addr_in_next;
- else if (dec_addr_in) addr_in <= addr_in_prev;
- //
- if (inc_addr_out1) addr_out1 <= addr_out1_next;
- else addr_out1 <= addr_out1_zero;
- //
- if (inc_addr_out2) addr_out2 <= addr_out2_next;
- else if (dec_addr_out2) addr_out2 <= addr_out2_prev;
- //
- if (dec_addr_out3) addr_out3 <= addr_out3_prev;
- else addr_out3 <= addr_out3_last;
- //
- if (dec_addr_out4) addr_out4 <= addr_out4_prev;
- else addr_out4 <= addr_out4_last;
- //
- end
- //
- end
-
-
- //
- // Write Enable Logic
- //
- wire wren_out1;
- wire wren_out2;
- wire wren_out3;
- wire wren_out4;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out1_start = 0 * BUFFER_NUM_WORDS + 2;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out2_start = 0 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out2_stop = 1 * BUFFER_NUM_WORDS + 2;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out3_start = 1 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out3_stop = 2 * BUFFER_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out4_start = 1 * BUFFER_NUM_WORDS + 4;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out4_stop = 2 * BUFFER_NUM_WORDS + 3;
-
- assign wren_out1 = (proc_cnt >= cnt_wren_out1_start) && (proc_cnt <= cnt_wren_out1_stop);
- assign wren_out2 = (proc_cnt >= cnt_wren_out2_start) && (proc_cnt <= cnt_wren_out2_stop);
- assign wren_out3 = (proc_cnt >= cnt_wren_out3_start) && (proc_cnt <= cnt_wren_out3_stop);
- assign wren_out4 = (proc_cnt >= cnt_wren_out4_start) && (proc_cnt <= cnt_wren_out4_stop);
-
- assign r_dbl_wren = wren_out1;
- assign s_dbl_wren = wren_out1;
- assign r_plus_s_wren = wren_out2;
- assign u_half_wren = wren_out3;
- assign v_half_wren = wren_out3;
- assign u_minus_v_wren = wren_out2;
- assign v_minus_u_wren = wren_out2;
- assign u_minus_v_half_wren = wren_out4;
- assign v_minus_u_half_wren = wren_out4;
-
-
- //
- // Adder (r + s)
- //
- wire [31: 0] add32_r_plus_s_sum_out;
- wire add32_r_plus_s_carry_in;
- wire add32_r_plus_s_carry_out;
-
- adder32_wrapper add32_r_plus_s
- (
- .clk (clk),
- .a (r_din),
- .b (s_din),
- .s (add32_r_plus_s_sum_out),
- .c_in (add32_r_plus_s_carry_in),
- .c_out (add32_r_plus_s_carry_out)
- );
-
- //
- // Subtractor (u - v)
- //
- wire [31: 0] sub32_u_minus_v_difference_out;
- wire sub32_u_minus_v_borrow_in;
- wire sub32_u_minus_v_borrow_out;
-
- subtractor32_wrapper sub32_u_minus_v
- (
- .clk (clk),
- .a (u_din),
- .b (v_din),
- .d (sub32_u_minus_v_difference_out),
- .b_in (sub32_u_minus_v_borrow_in),
- .b_out (sub32_u_minus_v_borrow_out)
- );
-
- //
- // Subtractor (v - u)
- //
- wire [31: 0] sub32_v_minus_u_difference_out;
- wire sub32_v_minus_u_borrow_in;
- wire sub32_v_minus_u_borrow_out;
-
- subtractor32_wrapper sub32_v_minus_u
- (
- .clk (clk),
- .a (v_din),
- .b (u_din),
- .d (sub32_v_minus_u_difference_out),
- .b_in (sub32_v_minus_u_borrow_in),
- .b_out (sub32_v_minus_u_borrow_out)
- );
-
-
- //
- // Carry & Borrow Masking Logic
- //
- reg mask_carry_borrow;
-
- always @(posedge clk)
- //
- mask_carry_borrow <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
- 1'b0 : 1'b1;
-
- assign add32_r_plus_s_carry_in = add32_r_plus_s_carry_out & ~mask_carry_borrow;
- assign sub32_u_minus_v_borrow_in = sub32_u_minus_v_borrow_out & ~mask_carry_borrow;
- assign sub32_v_minus_u_borrow_in = sub32_v_minus_u_borrow_out & ~mask_carry_borrow;
-
-
- //
- // Carry Bits
- //
- reg r_dbl_carry;
- reg s_dbl_carry;
- reg u_half_carry;
- reg v_half_carry;
- reg u_minus_v_half_carry;
- reg v_minus_u_half_carry;
-
- always @(posedge clk) begin
-
- r_dbl_carry <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
- r_din[31] : 1'b0;
-
- s_dbl_carry <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
- s_din[31] : 1'b0;
-
- u_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
- u_din[0] : 1'b0;
-
- v_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
- v_din[0] : 1'b0;
-
- u_minus_v_half_carry <= ((proc_cnt >= cnt_wren_out4_start) && (proc_cnt < cnt_wren_out4_stop)) ?
- u_minus_v_din[0] : 1'b0;
-
- v_minus_u_half_carry <= ((proc_cnt >= cnt_wren_out4_start) && (proc_cnt < cnt_wren_out4_stop)) ?
- v_minus_u_din[0] : 1'b0;
-
- end
-
-
- //
- // Data Mapper
- //
- assign r_dbl_dout = {r_din[30:0], r_dbl_carry};
- assign s_dbl_dout = {s_din[30:0], s_dbl_carry};
- assign r_plus_s_dout = add32_r_plus_s_sum_out;
- assign u_half_dout = {u_half_carry, u_din[31:1]};
- assign v_half_dout = {v_half_carry, v_din[31:1]};
- assign u_minus_v_dout = sub32_u_minus_v_difference_out;
- assign v_minus_u_dout = sub32_v_minus_u_difference_out;
- assign u_minus_v_half_dout = {u_minus_v_half_carry, u_minus_v_din[31:1]};
- assign v_minus_u_half_dout = {v_minus_u_half_carry, v_minus_u_din[31:1]};
-
-
- //
- // 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_invert_precalc
+ (
+ clk, rst_n,
+ ena, rdy,
+
+ r_addr, r_din,
+ s_addr, s_din,
+ u_addr, u_din,
+ v_addr, v_din,
+
+ r_dbl_addr, r_dbl_wren, r_dbl_dout,
+ s_dbl_addr, s_dbl_wren, s_dbl_dout,
+ r_plus_s_addr, r_plus_s_wren, r_plus_s_dout,
+ u_half_addr, u_half_wren, u_half_dout,
+ v_half_addr, v_half_wren, v_half_dout,
+ u_minus_v_addr, u_minus_v_wren, u_minus_v_dout, u_minus_v_din,
+ v_minus_u_addr, v_minus_u_wren, v_minus_u_dout, v_minus_u_din,
+ u_minus_v_half_addr, u_minus_v_half_wren, u_minus_v_half_dout,
+ v_minus_u_half_addr, v_minus_u_half_wren, v_minus_u_half_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter BUFFER_NUM_WORDS = 9;
+ parameter BUFFER_ADDR_BITS = 4;
+
+
+ //
+ // clog2
+ //
+`include "../modinv_clog2.v"
+
+
+ //
+ // Constants
+ //
+ localparam PROC_NUM_CYCLES = 2 * BUFFER_NUM_WORDS + 4;
+ localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
+
+
+ //
+ // Ports
+ //
+ input wire clk;
+ input wire rst_n;
+ input wire ena;
+ output wire rdy;
+
+ output wire [BUFFER_ADDR_BITS-1:0] r_addr;
+ 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;
+
+ input wire [ 32-1:0] r_din;
+ input wire [ 32-1:0] s_din;
+ input wire [ 32-1:0] u_din;
+ input wire [ 32-1:0] v_din;
+
+ output wire [BUFFER_ADDR_BITS-1:0] r_dbl_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] s_dbl_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] r_plus_s_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] u_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_half_addr;
+
+ output wire [ 32-1:0] r_dbl_dout;
+ output wire [ 32-1:0] s_dbl_dout;
+ output wire [ 32-1:0] r_plus_s_dout;
+ output wire [ 32-1:0] u_half_dout;
+ output wire [ 32-1:0] v_half_dout;
+ output wire [ 32-1:0] u_minus_v_dout;
+ output wire [ 32-1:0] v_minus_u_dout;
+ output wire [ 32-1:0] u_minus_v_half_dout;
+ output wire [ 32-1:0] v_minus_u_half_dout;
+
+ output wire r_dbl_wren;
+ output wire s_dbl_wren;
+ output wire r_plus_s_wren;
+ output wire u_half_wren;
+ output wire v_half_wren;
+ output wire u_minus_v_wren;
+ output wire v_minus_u_wren;
+ output wire u_minus_v_half_wren;
+ output wire v_minus_u_half_wren;
+
+ input wire [ 32-1:0] u_minus_v_din;
+ input wire [ 32-1:0] v_minus_u_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_last = 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_last) ?
+ addr_in + 1'b1 : addr_in_zero;
+ wire [BUFFER_ADDR_BITS-1:0] addr_in_prev = (addr_in > addr_in_zero) ?
+ addr_in - 1'b1 : addr_in_zero;
+
+ reg [BUFFER_ADDR_BITS-1:0] addr_out1;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_next = (addr_out1 < addr_out1_last) ?
+ addr_out1 + 1'b1 : addr_out1_zero;
+
+ reg [BUFFER_ADDR_BITS-1:0] addr_out2;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_next = (addr_out2 < addr_out2_last) ?
+ addr_out2 + 1'b1 : addr_out2_zero;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_prev = (addr_out2 > addr_out2_zero) ?
+ addr_out2 - 1'b1 : addr_out2_zero;
+
+ reg [BUFFER_ADDR_BITS-1:0] addr_out3;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_prev = (addr_out3 > addr_out3_zero) ?
+ addr_out3 - 1'b1 : addr_out3_last;
+
+ reg [BUFFER_ADDR_BITS-1:0] addr_out4;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out4_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out4_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out4_prev = (addr_out4 > addr_out4_zero) ?
+ addr_out4 - 1'b1 : addr_out4_last;
+
+
+ assign r_addr = addr_in;
+ assign s_addr = addr_in;
+ assign u_addr = addr_in;
+ assign v_addr = addr_in;
+
+ assign r_dbl_addr = addr_out1;
+ assign s_dbl_addr = addr_out1;
+ assign r_plus_s_addr = addr_out2;
+ assign u_half_addr = addr_out3;
+ assign v_half_addr = addr_out3;
+ assign u_minus_v_addr = addr_out2;
+ assign v_minus_u_addr = addr_out2;
+ assign u_minus_v_half_addr = addr_out4;
+ assign v_minus_u_half_addr = addr_out4;
+
+
+ //
+ // Ready Flag
+ //
+ assign rdy = (proc_cnt == proc_cnt_zero);
+
+
+ //
+ // Address Increment/Decrement Logic
+ //
+ wire inc_addr_in;
+ wire dec_addr_in;
+ wire inc_addr_out1;
+ wire inc_addr_out2;
+ wire dec_addr_out2;
+ wire dec_addr_out3;
+ wire dec_addr_out4;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_start = 0 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_in_stop = 1 * BUFFER_NUM_WORDS - 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_start = 0 * BUFFER_NUM_WORDS + 2;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out2_start = 0 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out2_stop = 1 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_start = 1 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_stop = 2 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_start = 1 * BUFFER_NUM_WORDS + 0;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_in_stop = 2 * BUFFER_NUM_WORDS - 2;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_start = 1 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_stop = 2 * BUFFER_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out4_start = 1 * BUFFER_NUM_WORDS + 4;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out4_stop = 2 * BUFFER_NUM_WORDS + 3;
+
+ assign inc_addr_in = (proc_cnt >= cnt_inc_addr_in_start) && (proc_cnt <= cnt_inc_addr_in_stop);
+ assign dec_addr_in = (proc_cnt >= cnt_dec_addr_in_start) && (proc_cnt <= cnt_dec_addr_in_stop);
+ assign inc_addr_out1 = (proc_cnt >= cnt_inc_addr_out1_start) && (proc_cnt <= cnt_inc_addr_out1_stop);
+ assign inc_addr_out2 = (proc_cnt >= cnt_inc_addr_out2_start) && (proc_cnt <= cnt_inc_addr_out2_stop);
+ assign dec_addr_out2 = (proc_cnt >= cnt_dec_addr_out2_start) && (proc_cnt <= cnt_dec_addr_out2_stop);
+ assign dec_addr_out3 = (proc_cnt >= cnt_dec_addr_out3_start) && (proc_cnt <= cnt_dec_addr_out3_stop);
+ assign dec_addr_out4 = (proc_cnt >= cnt_dec_addr_out4_start) && (proc_cnt <= cnt_dec_addr_out4_stop);
+
+
+ always @(posedge clk) begin
+ //
+ if (rdy) begin
+ //
+ addr_in <= addr_in_zero;
+ addr_out1 <= addr_out1_zero;
+ addr_out2 <= addr_out2_zero;
+ addr_out3 <= addr_out3_last;
+ addr_out4 <= addr_out4_last;
+ //
+ end else begin
+ //
+ if (inc_addr_in) addr_in <= addr_in_next;
+ else if (dec_addr_in) addr_in <= addr_in_prev;
+ //
+ if (inc_addr_out1) addr_out1 <= addr_out1_next;
+ else addr_out1 <= addr_out1_zero;
+ //
+ if (inc_addr_out2) addr_out2 <= addr_out2_next;
+ else if (dec_addr_out2) addr_out2 <= addr_out2_prev;
+ //
+ if (dec_addr_out3) addr_out3 <= addr_out3_prev;
+ else addr_out3 <= addr_out3_last;
+ //
+ if (dec_addr_out4) addr_out4 <= addr_out4_prev;
+ else addr_out4 <= addr_out4_last;
+ //
+ end
+ //
+ end
+
+
+ //
+ // Write Enable Logic
+ //
+ wire wren_out1;
+ wire wren_out2;
+ wire wren_out3;
+ wire wren_out4;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out1_start = 0 * BUFFER_NUM_WORDS + 2;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out2_start = 0 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out2_stop = 1 * BUFFER_NUM_WORDS + 2;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out3_start = 1 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out3_stop = 2 * BUFFER_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out4_start = 1 * BUFFER_NUM_WORDS + 4;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out4_stop = 2 * BUFFER_NUM_WORDS + 3;
+
+ assign wren_out1 = (proc_cnt >= cnt_wren_out1_start) && (proc_cnt <= cnt_wren_out1_stop);
+ assign wren_out2 = (proc_cnt >= cnt_wren_out2_start) && (proc_cnt <= cnt_wren_out2_stop);
+ assign wren_out3 = (proc_cnt >= cnt_wren_out3_start) && (proc_cnt <= cnt_wren_out3_stop);
+ assign wren_out4 = (proc_cnt >= cnt_wren_out4_start) && (proc_cnt <= cnt_wren_out4_stop);
+
+ assign r_dbl_wren = wren_out1;
+ assign s_dbl_wren = wren_out1;
+ assign r_plus_s_wren = wren_out2;
+ assign u_half_wren = wren_out3;
+ assign v_half_wren = wren_out3;
+ assign u_minus_v_wren = wren_out2;
+ assign v_minus_u_wren = wren_out2;
+ assign u_minus_v_half_wren = wren_out4;
+ assign v_minus_u_half_wren = wren_out4;
+
+
+ //
+ // Adder (r + s)
+ //
+ wire [31: 0] add32_r_plus_s_sum_out;
+ wire add32_r_plus_s_carry_in;
+ wire add32_r_plus_s_carry_out;
+
+ adder32_wrapper add32_r_plus_s
+ (
+ .clk (clk),
+ .a (r_din),
+ .b (s_din),
+ .s (add32_r_plus_s_sum_out),
+ .c_in (add32_r_plus_s_carry_in),
+ .c_out (add32_r_plus_s_carry_out)
+ );
+
+ //
+ // Subtractor (u - v)
+ //
+ wire [31: 0] sub32_u_minus_v_difference_out;
+ wire sub32_u_minus_v_borrow_in;
+ wire sub32_u_minus_v_borrow_out;
+
+ subtractor32_wrapper sub32_u_minus_v
+ (
+ .clk (clk),
+ .a (u_din),
+ .b (v_din),
+ .d (sub32_u_minus_v_difference_out),
+ .b_in (sub32_u_minus_v_borrow_in),
+ .b_out (sub32_u_minus_v_borrow_out)
+ );
+
+ //
+ // Subtractor (v - u)
+ //
+ wire [31: 0] sub32_v_minus_u_difference_out;
+ wire sub32_v_minus_u_borrow_in;
+ wire sub32_v_minus_u_borrow_out;
+
+ subtractor32_wrapper sub32_v_minus_u
+ (
+ .clk (clk),
+ .a (v_din),
+ .b (u_din),
+ .d (sub32_v_minus_u_difference_out),
+ .b_in (sub32_v_minus_u_borrow_in),
+ .b_out (sub32_v_minus_u_borrow_out)
+ );
+
+
+ //
+ // Carry & Borrow Masking Logic
+ //
+ reg mask_carry_borrow;
+
+ always @(posedge clk)
+ //
+ mask_carry_borrow <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
+ 1'b0 : 1'b1;
+
+ assign add32_r_plus_s_carry_in = add32_r_plus_s_carry_out & ~mask_carry_borrow;
+ assign sub32_u_minus_v_borrow_in = sub32_u_minus_v_borrow_out & ~mask_carry_borrow;
+ assign sub32_v_minus_u_borrow_in = sub32_v_minus_u_borrow_out & ~mask_carry_borrow;
+
+
+ //
+ // Carry Bits
+ //
+ reg r_dbl_carry;
+ reg s_dbl_carry;
+ reg u_half_carry;
+ reg v_half_carry;
+ reg u_minus_v_half_carry;
+ reg v_minus_u_half_carry;
+
+ always @(posedge clk) begin
+
+ r_dbl_carry <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
+ r_din[31] : 1'b0;
+
+ s_dbl_carry <= ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ?
+ s_din[31] : 1'b0;
+
+ u_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
+ u_din[0] : 1'b0;
+
+ v_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
+ v_din[0] : 1'b0;
+
+ u_minus_v_half_carry <= ((proc_cnt >= cnt_wren_out4_start) && (proc_cnt < cnt_wren_out4_stop)) ?
+ u_minus_v_din[0] : 1'b0;
+
+ v_minus_u_half_carry <= ((proc_cnt >= cnt_wren_out4_start) && (proc_cnt < cnt_wren_out4_stop)) ?
+ v_minus_u_din[0] : 1'b0;
+
+ end
+
+
+ //
+ // Data Mapper
+ //
+ assign r_dbl_dout = {r_din[30:0], r_dbl_carry};
+ assign s_dbl_dout = {s_din[30:0], s_dbl_carry};
+ assign r_plus_s_dout = add32_r_plus_s_sum_out;
+ assign u_half_dout = {u_half_carry, u_din[31:1]};
+ assign v_half_dout = {v_half_carry, v_din[31:1]};
+ assign u_minus_v_dout = sub32_u_minus_v_difference_out;
+ assign v_minus_u_dout = sub32_v_minus_u_difference_out;
+ assign u_minus_v_half_dout = {u_minus_v_half_carry, u_minus_v_din[31:1]};
+ assign v_minus_u_half_dout = {v_minus_u_half_carry, v_minus_u_din[31:1]};
+
+
+ //
+ // 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
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_invert_update.v b/rtl/modular/modular_invertor/helper/modinv_helper_invert_update.v
index 0cd6ac5..ede2fc1 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_invert_update.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_invert_update.v
@@ -1,257 +1,257 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_invert_update
- (
- clk, rst_n,
- ena, rdy,
-
- u_gt_v, v_eq_1,
- u_is_even, v_is_even,
-
- r_addr, r_wren, r_dout,
- s_addr, s_wren, s_dout,
- u_addr, u_wren, u_dout,
- v_addr, v_wren, v_dout,
-
- r_dbl_addr, r_dbl_din,
- s_dbl_addr, s_dbl_din,
- r_plus_s_addr, r_plus_s_din,
- u_half_addr, u_half_din,
- v_half_addr, v_half_din,
- u_minus_v_half_addr, u_minus_v_half_din,
- v_minus_u_half_addr, v_minus_u_half_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 u_gt_v;
- input wire v_eq_1;
- input wire u_is_even;
- input wire v_is_even;
-
- output wire [BUFFER_ADDR_BITS-1:0] r_addr;
- 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 r_wren;
- output wire s_wren;
- output wire u_wren;
- output wire v_wren;
-
- output wire [ 32-1:0] r_dout;
- output wire [ 32-1:0] s_dout;
- output wire [ 32-1:0] u_dout;
- output wire [ 32-1:0] v_dout;
-
- output wire [BUFFER_ADDR_BITS-1:0] r_dbl_addr;
- output wire [BUFFER_ADDR_BITS-1:0] s_dbl_addr;
- output wire [BUFFER_ADDR_BITS-1:0] r_plus_s_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_half_addr;
- output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_half_addr;
-
- input wire [ 32-1:0] r_dbl_din;
- input wire [ 32-1:0] s_dbl_din;
- input wire [ 32-1:0] r_plus_s_din;
- input wire [ 32-1:0] u_half_din;
- input wire [ 32-1:0] v_half_din;
- input wire [ 32-1:0] u_minus_v_half_din;
- input wire [ 32-1:0] v_minus_u_half_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 r_addr = addr_out;
- assign s_addr = addr_out;
- assign u_addr = addr_out;
- assign v_addr = addr_out;
-
- assign r_dbl_addr = addr_in;
- assign s_dbl_addr = addr_in;
- assign r_plus_s_addr = addr_in;
- assign u_half_addr = addr_in;
- assign v_half_addr = addr_in;
- assign u_minus_v_half_addr = addr_in;
- assign v_minus_u_half_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);
-
- reg r_wren_allow;
- reg s_wren_allow;
- reg u_wren_allow;
- reg v_wren_allow;
-
- assign r_wren = wren_out && r_wren_allow && !v_eq_1 && !rdy;
- assign s_wren = wren_out && s_wren_allow && !v_eq_1 && !rdy;
- assign u_wren = wren_out && u_wren_allow && !v_eq_1 && !rdy;
- assign v_wren = wren_out && v_wren_allow && !v_eq_1 && !rdy;
-
-
- //
- // Data Logic
- //
- reg [31: 0] r_dout_mux;
- reg [31: 0] s_dout_mux;
- reg [31: 0] u_dout_mux;
- reg [31: 0] v_dout_mux;
-
- assign r_dout = r_dout_mux;
- assign s_dout = s_dout_mux;
- assign u_dout = u_dout_mux;
- assign v_dout = v_dout_mux;
-
- always @(*) begin
- //
- // r, s, u, v
- //
- if (u_is_even) begin
- //
- u_dout_mux = u_half_din;
- v_dout_mux = {32{1'bX}};
- r_dout_mux = {32{1'bX}};
- s_dout_mux = s_dbl_din;
- //
- u_wren_allow = 1'b1;
- v_wren_allow = 1'b0;
- r_wren_allow = 1'b0;
- s_wren_allow = 1'b1;
- //
- end else begin
- //
- if (v_is_even) begin
- //
- u_dout_mux = {32{1'bX}};
- v_dout_mux = v_half_din;
- r_dout_mux = r_dbl_din;
- s_dout_mux = {32{1'bX}};
- //
- u_wren_allow = 1'b0;
- v_wren_allow = 1'b1;
- r_wren_allow = 1'b1;
- s_wren_allow = 1'b0;
- //
- end else begin
- //
- u_dout_mux = u_gt_v ? u_minus_v_half_din : {32{1'bX}};
- v_dout_mux = u_gt_v ? {32{1'bX}} : v_minus_u_half_din;
- r_dout_mux = u_gt_v ? r_plus_s_din : r_dbl_din;
- s_dout_mux = u_gt_v ? s_dbl_din : r_plus_s_din;
- //
- u_wren_allow = u_gt_v;
- v_wren_allow = !u_gt_v;
- r_wren_allow = 1'b1;
- s_wren_allow = 1'b1;
- //
- end
- //
- end
- //
- end
-
-
- //
- // 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_invert_update
+ (
+ clk, rst_n,
+ ena, rdy,
+
+ u_gt_v, v_eq_1,
+ u_is_even, v_is_even,
+
+ r_addr, r_wren, r_dout,
+ s_addr, s_wren, s_dout,
+ u_addr, u_wren, u_dout,
+ v_addr, v_wren, v_dout,
+
+ r_dbl_addr, r_dbl_din,
+ s_dbl_addr, s_dbl_din,
+ r_plus_s_addr, r_plus_s_din,
+ u_half_addr, u_half_din,
+ v_half_addr, v_half_din,
+ u_minus_v_half_addr, u_minus_v_half_din,
+ v_minus_u_half_addr, v_minus_u_half_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 u_gt_v;
+ input wire v_eq_1;
+ input wire u_is_even;
+ input wire v_is_even;
+
+ output wire [BUFFER_ADDR_BITS-1:0] r_addr;
+ 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 r_wren;
+ output wire s_wren;
+ output wire u_wren;
+ output wire v_wren;
+
+ output wire [ 32-1:0] r_dout;
+ output wire [ 32-1:0] s_dout;
+ output wire [ 32-1:0] u_dout;
+ output wire [ 32-1:0] v_dout;
+
+ output wire [BUFFER_ADDR_BITS-1:0] r_dbl_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] s_dbl_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] r_plus_s_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] u_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] u_minus_v_half_addr;
+ output wire [BUFFER_ADDR_BITS-1:0] v_minus_u_half_addr;
+
+ input wire [ 32-1:0] r_dbl_din;
+ input wire [ 32-1:0] s_dbl_din;
+ input wire [ 32-1:0] r_plus_s_din;
+ input wire [ 32-1:0] u_half_din;
+ input wire [ 32-1:0] v_half_din;
+ input wire [ 32-1:0] u_minus_v_half_din;
+ input wire [ 32-1:0] v_minus_u_half_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 r_addr = addr_out;
+ assign s_addr = addr_out;
+ assign u_addr = addr_out;
+ assign v_addr = addr_out;
+
+ assign r_dbl_addr = addr_in;
+ assign s_dbl_addr = addr_in;
+ assign r_plus_s_addr = addr_in;
+ assign u_half_addr = addr_in;
+ assign v_half_addr = addr_in;
+ assign u_minus_v_half_addr = addr_in;
+ assign v_minus_u_half_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);
+
+ reg r_wren_allow;
+ reg s_wren_allow;
+ reg u_wren_allow;
+ reg v_wren_allow;
+
+ assign r_wren = wren_out && r_wren_allow && !v_eq_1 && !rdy;
+ assign s_wren = wren_out && s_wren_allow && !v_eq_1 && !rdy;
+ assign u_wren = wren_out && u_wren_allow && !v_eq_1 && !rdy;
+ assign v_wren = wren_out && v_wren_allow && !v_eq_1 && !rdy;
+
+
+ //
+ // Data Logic
+ //
+ reg [31: 0] r_dout_mux;
+ reg [31: 0] s_dout_mux;
+ reg [31: 0] u_dout_mux;
+ reg [31: 0] v_dout_mux;
+
+ assign r_dout = r_dout_mux;
+ assign s_dout = s_dout_mux;
+ assign u_dout = u_dout_mux;
+ assign v_dout = v_dout_mux;
+
+ always @(*) begin
+ //
+ // r, s, u, v
+ //
+ if (u_is_even) begin
+ //
+ u_dout_mux = u_half_din;
+ v_dout_mux = {32{1'bX}};
+ r_dout_mux = {32{1'bX}};
+ s_dout_mux = s_dbl_din;
+ //
+ u_wren_allow = 1'b1;
+ v_wren_allow = 1'b0;
+ r_wren_allow = 1'b0;
+ s_wren_allow = 1'b1;
+ //
+ end else begin
+ //
+ if (v_is_even) begin
+ //
+ u_dout_mux = {32{1'bX}};
+ v_dout_mux = v_half_din;
+ r_dout_mux = r_dbl_din;
+ s_dout_mux = {32{1'bX}};
+ //
+ u_wren_allow = 1'b0;
+ v_wren_allow = 1'b1;
+ r_wren_allow = 1'b1;
+ s_wren_allow = 1'b0;
+ //
+ end else begin
+ //
+ u_dout_mux = u_gt_v ? u_minus_v_half_din : {32{1'bX}};
+ v_dout_mux = u_gt_v ? {32{1'bX}} : v_minus_u_half_din;
+ r_dout_mux = u_gt_v ? r_plus_s_din : r_dbl_din;
+ s_dout_mux = u_gt_v ? s_dbl_din : r_plus_s_din;
+ //
+ u_wren_allow = u_gt_v;
+ v_wren_allow = !u_gt_v;
+ r_wren_allow = 1'b1;
+ s_wren_allow = 1'b1;
+ //
+ end
+ //
+ end
+ //
+ end
+
+
+ //
+ // 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
diff --git a/rtl/modular/modular_invertor/helper/modinv_helper_reduce_precalc.v b/rtl/modular/modular_invertor/helper/modinv_helper_reduce_precalc.v
index fb858a6..b64b8e7 100644
--- a/rtl/modular/modular_invertor/helper/modinv_helper_reduce_precalc.v
+++ b/rtl/modular/modular_invertor/helper/modinv_helper_reduce_precalc.v
@@ -1,328 +1,328 @@
-`timescale 1ns / 1ps
-
-module modinv_helper_reduce_precalc
- (
- clk, rst_n,
- ena, rdy,
-
- k,
-
- s_is_odd, k_is_nul,
-
- r_addr, r_din, r_wren, r_dout,
- s_addr, s_din,
- u_addr, u_wren, u_dout,
- v_addr, v_wren, v_dout,
- q_addr, q_din
- );
-
-
- //
- // Parameters
- //
- parameter OPERAND_NUM_WORDS = 8;
- parameter OPERAND_ADDR_BITS = 3;
- parameter BUFFER_NUM_WORDS = 9;
- parameter BUFFER_ADDR_BITS = 4;
- parameter K_NUM_BITS = 10;
-
-
- //
- // clog2
- //
-`include "..\modinv_clog2.v"
-
-
- //
- // Constants
- //
- localparam PROC_NUM_CYCLES = 2 * BUFFER_NUM_WORDS + 4;
- localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
- input wire ena;
- output wire rdy;
-
- input wire [ K_NUM_BITS-1:0] k;
-
- output wire s_is_odd;
- output wire k_is_nul;
-
- output wire [ BUFFER_ADDR_BITS-1:0] r_addr;
- 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 [OPERAND_ADDR_BITS-1:0] q_addr;
-
- input wire [ 32-1:0] r_din;
- input wire [ 32-1:0] s_din;
- input wire [ 32-1:0] q_din;
-
- output wire r_wren;
- output wire u_wren;
- output wire v_wren;
-
- output wire [ 32-1:0] r_dout;
- output wire [ 32-1:0] u_dout;
- output wire [ 32-1:0] v_dout;
-
-
- //
- // 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_buf;
- reg [OPERAND_ADDR_BITS-1:0] addr_in_op;
- reg [ BUFFER_ADDR_BITS-1:0] addr_out1;
- reg [ BUFFER_ADDR_BITS-1:0] addr_out2;
- reg [ BUFFER_ADDR_BITS-1:0] addr_out3;
-
- wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_last = BUFFER_NUM_WORDS - 1;
- wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_next = (addr_in_buf < addr_in_buf_last) ?
- addr_in_buf + 1'b1 : addr_in_buf_zero;
- wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_prev = (addr_in_buf > addr_in_buf_zero) ?
- addr_in_buf - 1'b1 : addr_in_buf_zero;
-
- wire [OPERAND_ADDR_BITS-1:0] addr_in_op_last = OPERAND_NUM_WORDS - 1;
- wire [OPERAND_ADDR_BITS-1:0] addr_in_op_zero = {OPERAND_ADDR_BITS{1'b0}};
- wire [OPERAND_ADDR_BITS-1:0] addr_in_op_next = (addr_in_op < addr_in_op_last) ?
- addr_in_op + 1'b1 : addr_in_op_zero;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_next = (addr_out1 < addr_out1_last) ?
- addr_out1 + 1'b1 : addr_out1_zero;
- wire [BUFFER_ADDR_BITS-1:0] addr_out1_prev = (addr_out1 > addr_out1_zero) ?
- addr_out1 - 1'b1 : addr_out1_zero;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out2_prev = (addr_out2 > addr_out2_zero) ?
- addr_out2 - 1'b1 : addr_out2_last;
-
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_last = BUFFER_NUM_WORDS - 1;
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_zero = {BUFFER_ADDR_BITS{1'b0}};
- wire [BUFFER_ADDR_BITS-1:0] addr_out3_prev = (addr_out3 > addr_out3_zero) ?
- addr_out3 - 1'b1 : addr_out3_last;
-
-
- assign s_addr = addr_in_buf;
- assign q_addr = addr_in_op;
- assign r_addr = addr_out1;
- assign u_addr = addr_out2;
- assign v_addr = addr_out3;
-
-
- //
- // Ready Flag
- //
- assign rdy = (proc_cnt == proc_cnt_zero);
-
-
- //
- // Address Increment/Decrement Logic
- //
- wire inc_addr_buf_in;
- wire dec_addr_buf_in;
- wire inc_addr_op_in;
- wire inc_addr_out1;
- wire dec_addr_out1;
- wire dec_addr_out2;
- wire dec_addr_out3;
-
- wire [PROC_CNT_BITS-1:0] cnt_calc_flags = 0 * BUFFER_NUM_WORDS + 2;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_buf_in_start = 0 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_buf_in_stop = 1 * BUFFER_NUM_WORDS - 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_buf_in_start = 1 * BUFFER_NUM_WORDS + 0;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_buf_in_stop = 2 * BUFFER_NUM_WORDS - 2;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_op_in_start = 0 * OPERAND_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_op_in_stop = 1 * OPERAND_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_start = 0 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out1_start = 1 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out1_stop = 2 * BUFFER_NUM_WORDS + 1;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_start = 1 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_stop = 2 * BUFFER_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_start = 1 * BUFFER_NUM_WORDS + 4;
- wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_stop = 2 * BUFFER_NUM_WORDS + 3;
-
- assign inc_addr_buf_in = (proc_cnt >= cnt_inc_addr_buf_in_start) && (proc_cnt <= cnt_inc_addr_buf_in_stop);
- assign dec_addr_buf_in = (proc_cnt >= cnt_dec_addr_buf_in_start) && (proc_cnt <= cnt_dec_addr_buf_in_stop);
- assign inc_addr_op_in = (proc_cnt >= cnt_inc_addr_op_in_start) && (proc_cnt <= cnt_inc_addr_op_in_stop);
- assign inc_addr_out1 = (proc_cnt >= cnt_inc_addr_out1_start) && (proc_cnt <= cnt_inc_addr_out1_stop);
- assign dec_addr_out1 = (proc_cnt >= cnt_dec_addr_out1_start) && (proc_cnt <= cnt_dec_addr_out1_stop);
- assign dec_addr_out2 = (proc_cnt >= cnt_dec_addr_out2_start) && (proc_cnt <= cnt_dec_addr_out2_stop);
- assign dec_addr_out3 = (proc_cnt >= cnt_dec_addr_out3_start) && (proc_cnt <= cnt_dec_addr_out3_stop);
-
- always @(posedge clk) begin
- //
- if (rdy) begin
- //
- addr_in_buf <= addr_in_buf_zero;
- addr_in_op <= addr_in_op_zero;
- addr_out1 <= addr_out1_zero;
- addr_out2 <= addr_out2_last;
- addr_out3 <= addr_out3_last;
- //
- end else begin
- //
- if (inc_addr_buf_in) addr_in_buf <= addr_in_buf_next;
- else if (dec_addr_buf_in) addr_in_buf <= addr_in_buf_prev;
- //
- if (inc_addr_op_in) addr_in_op <= addr_in_op_next;
- else addr_in_op <= addr_in_op_zero;
- //
- if (inc_addr_out1) addr_out1 <= addr_out1_next;
- else if (dec_addr_out1) addr_out1 <= addr_out1_prev;
- //
- if (dec_addr_out2) addr_out2 <= addr_out2_prev;
- else addr_out2 <= addr_out2_last;
- //
- if (dec_addr_out3) addr_out3 <= addr_out3_prev;
- else addr_out3 <= addr_out3_last;
- //
- end
- //
- end
-
-
- //
- // Write Enable Logic
- //
- wire wren_out1;
- wire wren_out2;
- wire wren_out3;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out1_start = 0 * BUFFER_NUM_WORDS + 3;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out1_stop = 1 * BUFFER_NUM_WORDS + 2;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out2_start = 1 * BUFFER_NUM_WORDS + 1;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out2_stop = 2 * BUFFER_NUM_WORDS + 0;
-
- wire [PROC_CNT_BITS-1:0] cnt_wren_out3_start = 1 * BUFFER_NUM_WORDS + 4;
- wire [PROC_CNT_BITS-1:0] cnt_wren_out3_stop = 2 * BUFFER_NUM_WORDS + 3;
-
- assign wren_out1 = (proc_cnt >= cnt_wren_out1_start) && (proc_cnt <= cnt_wren_out1_stop);
- assign wren_out2 = (proc_cnt >= cnt_wren_out2_start) && (proc_cnt <= cnt_wren_out2_stop);
- assign wren_out3 = (proc_cnt >= cnt_wren_out3_start) && (proc_cnt <= cnt_wren_out3_stop);
-
- assign r_wren = wren_out1;
- assign u_wren = wren_out2;
- assign v_wren = wren_out3;
-
- //
- // Adder (s + q)
- //
- wire [31: 0] q_din_masked;
- wire [31: 0] add32_s_plus_q_sum_out;
- wire add32_s_plus_q_carry_in;
- wire add32_s_plus_q_carry_out;
-
- adder32_wrapper add32_r_plus_s
- (
- .clk (clk),
- .a (s_din),
- .b (q_din_masked),
- .s (add32_s_plus_q_sum_out),
- .c_in (add32_s_plus_q_carry_in),
- .c_out (add32_s_plus_q_carry_out)
- );
-
-
- //
- // Carry Masking Logic
- //
- wire mask_carry;
-
- assign mask_carry = ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ? 1'b0 : 1'b1;
-
-
- //
- // Addend Masking Logic
- //
- reg q_din_mask;
-
- always @(posedge clk)
- q_din_mask <= (addr_in_buf == addr_in_buf_last) ? 1'b1 : 1'b0;
-
- assign q_din_masked = q_din_mask ? {32{1'b0}} : q_din;
-
- assign add32_s_plus_q_carry_in = add32_s_plus_q_carry_out & ~mask_carry;
-
-
- //
- // Carry Bits
- //
- reg s_half_carry;
- reg s_plus_q_half_carry;
-
- always @(posedge clk) begin
- //
- s_half_carry <= ((proc_cnt >= cnt_wren_out2_start) && (proc_cnt < cnt_wren_out2_stop)) ?
- s_din[0] : 1'b0;
- //
- s_plus_q_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
- r_din[0] : 1'b0;
- //
- end
-
- //
- // Data Mapper
- //
- assign r_dout = add32_s_plus_q_sum_out;
- assign u_dout = {s_half_carry, s_din[31:1]};
- assign v_dout = {s_plus_q_half_carry, r_din[31:1]};
-
-
- //
- // 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
-
-
- //
- // Output Flags
- //
- reg s_is_odd_reg;
- reg k_is_nul_reg;
-
- assign s_is_odd = s_is_odd_reg;
- assign k_is_nul = k_is_nul_reg;
-
- always @(posedge clk)
- //
- if (proc_cnt == cnt_calc_flags) begin
- s_is_odd_reg <= s_din[0];
- k_is_nul_reg <= (k == {K_NUM_BITS{1'b0}}) ? 1'b1 : 1'b0;
- end
-
-
-endmodule
+`timescale 1ns / 1ps
+
+module modinv_helper_reduce_precalc
+ (
+ clk, rst_n,
+ ena, rdy,
+
+ k,
+
+ s_is_odd, k_is_nul,
+
+ r_addr, r_din, r_wren, r_dout,
+ s_addr, s_din,
+ u_addr, u_wren, u_dout,
+ v_addr, v_wren, v_dout,
+ q_addr, q_din
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter OPERAND_NUM_WORDS = 8;
+ parameter OPERAND_ADDR_BITS = 3;
+ parameter BUFFER_NUM_WORDS = 9;
+ parameter BUFFER_ADDR_BITS = 4;
+ parameter K_NUM_BITS = 10;
+
+
+ //
+ // clog2
+ //
+`include "../modinv_clog2.v"
+
+
+ //
+ // Constants
+ //
+ localparam PROC_NUM_CYCLES = 2 * BUFFER_NUM_WORDS + 4;
+ localparam PROC_CNT_BITS = clog2(PROC_NUM_CYCLES);
+
+
+ //
+ // Ports
+ //
+ input wire clk;
+ input wire rst_n;
+ input wire ena;
+ output wire rdy;
+
+ input wire [ K_NUM_BITS-1:0] k;
+
+ output wire s_is_odd;
+ output wire k_is_nul;
+
+ output wire [ BUFFER_ADDR_BITS-1:0] r_addr;
+ 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 [OPERAND_ADDR_BITS-1:0] q_addr;
+
+ input wire [ 32-1:0] r_din;
+ input wire [ 32-1:0] s_din;
+ input wire [ 32-1:0] q_din;
+
+ output wire r_wren;
+ output wire u_wren;
+ output wire v_wren;
+
+ output wire [ 32-1:0] r_dout;
+ output wire [ 32-1:0] u_dout;
+ output wire [ 32-1:0] v_dout;
+
+
+ //
+ // 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_buf;
+ reg [OPERAND_ADDR_BITS-1:0] addr_in_op;
+ reg [ BUFFER_ADDR_BITS-1:0] addr_out1;
+ reg [ BUFFER_ADDR_BITS-1:0] addr_out2;
+ reg [ BUFFER_ADDR_BITS-1:0] addr_out3;
+
+ wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_last = BUFFER_NUM_WORDS - 1;
+ wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_next = (addr_in_buf < addr_in_buf_last) ?
+ addr_in_buf + 1'b1 : addr_in_buf_zero;
+ wire [ BUFFER_ADDR_BITS-1:0] addr_in_buf_prev = (addr_in_buf > addr_in_buf_zero) ?
+ addr_in_buf - 1'b1 : addr_in_buf_zero;
+
+ wire [OPERAND_ADDR_BITS-1:0] addr_in_op_last = OPERAND_NUM_WORDS - 1;
+ wire [OPERAND_ADDR_BITS-1:0] addr_in_op_zero = {OPERAND_ADDR_BITS{1'b0}};
+ wire [OPERAND_ADDR_BITS-1:0] addr_in_op_next = (addr_in_op < addr_in_op_last) ?
+ addr_in_op + 1'b1 : addr_in_op_zero;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_next = (addr_out1 < addr_out1_last) ?
+ addr_out1 + 1'b1 : addr_out1_zero;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out1_prev = (addr_out1 > addr_out1_zero) ?
+ addr_out1 - 1'b1 : addr_out1_zero;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out2_prev = (addr_out2 > addr_out2_zero) ?
+ addr_out2 - 1'b1 : addr_out2_last;
+
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_last = BUFFER_NUM_WORDS - 1;
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_zero = {BUFFER_ADDR_BITS{1'b0}};
+ wire [BUFFER_ADDR_BITS-1:0] addr_out3_prev = (addr_out3 > addr_out3_zero) ?
+ addr_out3 - 1'b1 : addr_out3_last;
+
+
+ assign s_addr = addr_in_buf;
+ assign q_addr = addr_in_op;
+ assign r_addr = addr_out1;
+ assign u_addr = addr_out2;
+ assign v_addr = addr_out3;
+
+
+ //
+ // Ready Flag
+ //
+ assign rdy = (proc_cnt == proc_cnt_zero);
+
+
+ //
+ // Address Increment/Decrement Logic
+ //
+ wire inc_addr_buf_in;
+ wire dec_addr_buf_in;
+ wire inc_addr_op_in;
+ wire inc_addr_out1;
+ wire dec_addr_out1;
+ wire dec_addr_out2;
+ wire dec_addr_out3;
+
+ wire [PROC_CNT_BITS-1:0] cnt_calc_flags = 0 * BUFFER_NUM_WORDS + 2;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_buf_in_start = 0 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_buf_in_stop = 1 * BUFFER_NUM_WORDS - 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_buf_in_start = 1 * BUFFER_NUM_WORDS + 0;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_buf_in_stop = 2 * BUFFER_NUM_WORDS - 2;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_op_in_start = 0 * OPERAND_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_op_in_stop = 1 * OPERAND_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_start = 0 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_inc_addr_out1_stop = 1 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out1_start = 1 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out1_stop = 2 * BUFFER_NUM_WORDS + 1;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_start = 1 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out2_stop = 2 * BUFFER_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_start = 1 * BUFFER_NUM_WORDS + 4;
+ wire [PROC_CNT_BITS-1:0] cnt_dec_addr_out3_stop = 2 * BUFFER_NUM_WORDS + 3;
+
+ assign inc_addr_buf_in = (proc_cnt >= cnt_inc_addr_buf_in_start) && (proc_cnt <= cnt_inc_addr_buf_in_stop);
+ assign dec_addr_buf_in = (proc_cnt >= cnt_dec_addr_buf_in_start) && (proc_cnt <= cnt_dec_addr_buf_in_stop);
+ assign inc_addr_op_in = (proc_cnt >= cnt_inc_addr_op_in_start) && (proc_cnt <= cnt_inc_addr_op_in_stop);
+ assign inc_addr_out1 = (proc_cnt >= cnt_inc_addr_out1_start) && (proc_cnt <= cnt_inc_addr_out1_stop);
+ assign dec_addr_out1 = (proc_cnt >= cnt_dec_addr_out1_start) && (proc_cnt <= cnt_dec_addr_out1_stop);
+ assign dec_addr_out2 = (proc_cnt >= cnt_dec_addr_out2_start) && (proc_cnt <= cnt_dec_addr_out2_stop);
+ assign dec_addr_out3 = (proc_cnt >= cnt_dec_addr_out3_start) && (proc_cnt <= cnt_dec_addr_out3_stop);
+
+ always @(posedge clk) begin
+ //
+ if (rdy) begin
+ //
+ addr_in_buf <= addr_in_buf_zero;
+ addr_in_op <= addr_in_op_zero;
+ addr_out1 <= addr_out1_zero;
+ addr_out2 <= addr_out2_last;
+ addr_out3 <= addr_out3_last;
+ //
+ end else begin
+ //
+ if (inc_addr_buf_in) addr_in_buf <= addr_in_buf_next;
+ else if (dec_addr_buf_in) addr_in_buf <= addr_in_buf_prev;
+ //
+ if (inc_addr_op_in) addr_in_op <= addr_in_op_next;
+ else addr_in_op <= addr_in_op_zero;
+ //
+ if (inc_addr_out1) addr_out1 <= addr_out1_next;
+ else if (dec_addr_out1) addr_out1 <= addr_out1_prev;
+ //
+ if (dec_addr_out2) addr_out2 <= addr_out2_prev;
+ else addr_out2 <= addr_out2_last;
+ //
+ if (dec_addr_out3) addr_out3 <= addr_out3_prev;
+ else addr_out3 <= addr_out3_last;
+ //
+ end
+ //
+ end
+
+
+ //
+ // Write Enable Logic
+ //
+ wire wren_out1;
+ wire wren_out2;
+ wire wren_out3;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out1_start = 0 * BUFFER_NUM_WORDS + 3;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out1_stop = 1 * BUFFER_NUM_WORDS + 2;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out2_start = 1 * BUFFER_NUM_WORDS + 1;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out2_stop = 2 * BUFFER_NUM_WORDS + 0;
+
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out3_start = 1 * BUFFER_NUM_WORDS + 4;
+ wire [PROC_CNT_BITS-1:0] cnt_wren_out3_stop = 2 * BUFFER_NUM_WORDS + 3;
+
+ assign wren_out1 = (proc_cnt >= cnt_wren_out1_start) && (proc_cnt <= cnt_wren_out1_stop);
+ assign wren_out2 = (proc_cnt >= cnt_wren_out2_start) && (proc_cnt <= cnt_wren_out2_stop);
+ assign wren_out3 = (proc_cnt >= cnt_wren_out3_start) && (proc_cnt <= cnt_wren_out3_stop);
+
+ assign r_wren = wren_out1;
+ assign u_wren = wren_out2;
+ assign v_wren = wren_out3;
+
+ //
+ // Adder (s + q)
+ //
+ wire [31: 0] q_din_masked;
+ wire [31: 0] add32_s_plus_q_sum_out;
+ wire add32_s_plus_q_carry_in;
+ wire add32_s_plus_q_carry_out;
+
+ adder32_wrapper add32_r_plus_s
+ (
+ .clk (clk),
+ .a (s_din),
+ .b (q_din_masked),
+ .s (add32_s_plus_q_sum_out),
+ .c_in (add32_s_plus_q_carry_in),
+ .c_out (add32_s_plus_q_carry_out)
+ );
+
+
+ //
+ // Carry Masking Logic
+ //
+ wire mask_carry;
+
+ assign mask_carry = ((proc_cnt >= cnt_wren_out1_start) && (proc_cnt < cnt_wren_out1_stop)) ? 1'b0 : 1'b1;
+
+
+ //
+ // Addend Masking Logic
+ //
+ reg q_din_mask;
+
+ always @(posedge clk)
+ q_din_mask <= (addr_in_buf == addr_in_buf_last) ? 1'b1 : 1'b0;
+
+ assign q_din_masked = q_din_mask ? {32{1'b0}} : q_din;
+
+ assign add32_s_plus_q_carry_in = add32_s_plus_q_carry_out & ~mask_carry;
+
+
+ //
+ // Carry Bits
+ //
+ reg s_half_carry;
+ reg s_plus_q_half_carry;
+
+ always @(posedge clk) begin
+ //
+ s_half_carry <= ((proc_cnt >= cnt_wren_out2_start) && (proc_cnt < cnt_wren_out2_stop)) ?
+ s_din[0] : 1'b0;
+ //
+ s_plus_q_half_carry <= ((proc_cnt >= cnt_wren_out3_start) && (proc_cnt < cnt_wren_out3_stop)) ?
+ r_din[0] : 1'b0;
+ //
+ end
+
+ //
+ // Data Mapper
+ //
+ assign r_dout = add32_s_plus_q_sum_out;
+ assign u_dout = {s_half_carry, s_din[31:1]};
+ assign v_dout = {s_plus_q_half_carry, r_din[31:1]};
+
+
+ //
+ // 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
+
+
+ //
+ // Output Flags
+ //
+ reg s_is_odd_reg;
+ reg k_is_nul_reg;
+
+ assign s_is_odd = s_is_odd_reg;
+ assign k_is_nul = k_is_nul_reg;
+
+ always @(posedge clk)
+ //
+ if (proc_cnt == cnt_calc_flags) begin
+ s_is_odd_reg <= s_din[0];
+ k_is_nul_reg <= (k == {K_NUM_BITS{1'b0}}) ? 1'b1 : 1'b0;
+ end
+
+
+endmodule
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
diff --git a/rtl/modular/modular_invertor/modinv_clog2.v b/rtl/modular/modular_invertor/modinv_clog2.v
index 2f7b64d..04a7739 100644
--- a/rtl/modular/modular_invertor/modinv_clog2.v
+++ b/rtl/modular/modular_invertor/modinv_clog2.v
@@ -1,10 +1,10 @@
-function integer clog2;
- input integer value;
- integer result;
- begin
- value = value - 1;
- for (result = 0; value > 0; result = result + 1)
- value = value >> 1;
- clog2 = result;
- end
-endfunction
+function integer clog2;
+ input integer value;
+ integer result;
+ begin
+ value = value - 1;
+ for (result = 0; value > 0; result = result + 1)
+ value = value >> 1;
+ clog2 = result;
+ end
+endfunction
diff --git a/rtl/modular/modular_invertor/modular_invertor.v b/rtl/modular/modular_invertor/modular_invertor.v
index e9f2460..9fafa2d 100644
--- a/rtl/modular/modular_invertor/modular_invertor.v
+++ b/rtl/modular/modular_invertor/modular_invertor.v
@@ -2,7 +2,7 @@
//
// modular_invertor.v
// -----------------------------------------------------------------------------
-// Modular invertor.
+// Modular invertor.
//
// Authors: Pavel Shatov
//
@@ -34,948 +34,948 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module modular_invertor
- (
- clk, rst_n,
- ena, rdy,
- a_addr, q_addr, a1_addr, a1_wren,
- a_din, q_din, a1_dout
- );
-
-
- //
- // Parameters
- //
- parameter MAX_OPERAND_WIDTH = 256;
-
-
- //
- // clog2
- //
-`include "modinv_clog2.v"
-
-
- //
- // More Parameters
- //
- localparam OPERAND_NUM_WORDS = MAX_OPERAND_WIDTH / 32;
- localparam OPERAND_ADDR_BITS = clog2(OPERAND_NUM_WORDS);
-
- localparam BUFFER_NUM_WORDS = OPERAND_NUM_WORDS + 1;
- localparam BUFFER_ADDR_BITS = clog2(BUFFER_NUM_WORDS);
-
- localparam LOOP_NUM_ROUNDS = 2 * MAX_OPERAND_WIDTH;
- localparam ROUND_COUNTER_BITS = clog2(LOOP_NUM_ROUNDS);
-
- localparam K_NUM_BITS = clog2(LOOP_NUM_ROUNDS + 1);
-
-
- //
- // Ports
- //
- input wire clk;
- input wire rst_n;
-
- input wire ena;
- output wire rdy;
-
- output wire [OPERAND_ADDR_BITS-1:0] a_addr;
- output reg [OPERAND_ADDR_BITS-1:0] q_addr;
- output wire [OPERAND_ADDR_BITS-1:0] a1_addr;
- output wire a1_wren;
-
- input wire [32-1:0] a_din;
- input wire [32-1:0] q_din;
- output wire [32-1:0] a1_dout;
-
-
- //
- // "Redundant" Power of 2 (K)
- //
- reg [K_NUM_BITS-1:0] k;
-
-
- //
- // Buffers
- //
- reg [BUFFER_ADDR_BITS-1:0] buf_r_wr_addr;
- reg [BUFFER_ADDR_BITS-1:0] buf_r_rd_addr;
- reg buf_r_wr_en;
- reg [ 32-1:0] buf_r_wr_din;
- wire [ 32-1:0] buf_r_wr_dout;
- wire [ 32-1:0] buf_r_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_r
- ( .clk(clk),
- .a_addr(buf_r_wr_addr), .a_out(buf_r_wr_dout), .a_wr(buf_r_wr_en), .a_in(buf_r_wr_din),
- .b_addr(buf_r_rd_addr), .b_out(buf_r_rd_dout)
- );
-
- reg [BUFFER_ADDR_BITS-1:0] buf_s_wr_addr;
- reg [BUFFER_ADDR_BITS-1:0] buf_s_rd_addr;
- reg buf_s_wr_en;
- reg [ 32-1:0] buf_s_wr_din;
- wire [ 32-1:0] buf_s_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_s
- ( .clk(clk),
- .a_addr(buf_s_wr_addr), .a_out(), .a_wr(buf_s_wr_en), .a_in(buf_s_wr_din),
- .b_addr(buf_s_rd_addr), .b_out(buf_s_rd_dout)
- );
-
- reg [BUFFER_ADDR_BITS-1:0] buf_u_wr_addr;
- reg [BUFFER_ADDR_BITS-1:0] buf_u_rd_addr;
- reg buf_u_wr_en;
- reg [ 32-1:0] buf_u_wr_din;
- wire [ 32-1:0] buf_u_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_u
- ( .clk(clk),
- .a_addr(buf_u_wr_addr), .a_out(), .a_wr(buf_u_wr_en), .a_in(buf_u_wr_din),
- .b_addr(buf_u_rd_addr), .b_out(buf_u_rd_dout)
- );
-
- reg [BUFFER_ADDR_BITS-1:0] buf_v_wr_addr;
- reg [BUFFER_ADDR_BITS-1:0] buf_v_rd_addr;
- reg buf_v_wr_en;
- reg [ 32-1:0] buf_v_wr_din;
- wire [ 32-1:0] buf_v_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_v
- ( .clk(clk),
- .a_addr(buf_v_wr_addr), .a_out(), .a_wr(buf_v_wr_en), .a_in(buf_v_wr_din),
- .b_addr(buf_v_rd_addr), .b_out(buf_v_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_r_dbl_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_r_dbl_rd_addr;
- wire buf_r_dbl_wr_en;
- wire [ 32-1:0] buf_r_dbl_wr_din;
- wire [ 32-1:0] buf_r_dbl_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_r_dbl
- ( .clk(clk),
- .a_addr(buf_r_dbl_wr_addr), .a_out(), .a_wr(buf_r_dbl_wr_en), .a_in(buf_r_dbl_wr_din),
- .b_addr(buf_r_dbl_rd_addr), .b_out(buf_r_dbl_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_s_dbl_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_s_dbl_rd_addr;
- wire buf_s_dbl_wr_en;
- wire [ 32-1:0] buf_s_dbl_wr_din;
- wire [ 32-1:0] buf_s_dbl_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_s_dbl
- ( .clk(clk),
- .a_addr(buf_s_dbl_wr_addr), .a_out(), .a_wr(buf_s_dbl_wr_en), .a_in(buf_s_dbl_wr_din),
- .b_addr(buf_s_dbl_rd_addr), .b_out(buf_s_dbl_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_r_plus_s_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_r_plus_s_rd_addr;
- wire buf_r_plus_s_wr_en;
- wire [ 32-1:0] buf_r_plus_s_wr_din;
- wire [ 32-1:0] buf_r_plus_s_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_r_plus_s
- ( .clk(clk),
- .a_addr(buf_r_plus_s_wr_addr), .a_out(), .a_wr(buf_r_plus_s_wr_en), .a_in(buf_r_plus_s_wr_din),
- .b_addr(buf_r_plus_s_rd_addr), .b_out(buf_r_plus_s_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_rd_addr;
- wire buf_u_minus_v_wr_en;
- wire [ 32-1:0] buf_u_minus_v_wr_din;
- wire [ 32-1:0] buf_u_minus_v_wr_dout;
-
- assign buf_u_minus_v_rd_addr = ~buf_u_minus_v_wr_addr;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_u_minus_v
- ( .clk(clk),
- .a_addr(buf_u_minus_v_wr_addr), .a_out(buf_u_minus_v_wr_dout), .a_wr(buf_u_minus_v_wr_en), .a_in(buf_u_minus_v_wr_din),
- .b_addr(buf_u_minus_v_rd_addr), .b_out()
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_rd_addr;
- wire buf_v_minus_u_wr_en;
- wire [ 32-1:0] buf_v_minus_u_wr_din;
- wire [ 32-1:0] buf_v_minus_u_wr_dout;
-
- assign buf_v_minus_u_rd_addr = ~buf_v_minus_u_wr_addr;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_v_minus_u
- ( .clk(clk),
- .a_addr(buf_v_minus_u_wr_addr), .a_out(buf_v_minus_u_wr_dout), .a_wr(buf_v_minus_u_wr_en), .a_in(buf_v_minus_u_wr_din),
- .b_addr(buf_v_minus_u_rd_addr), .b_out()
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_u_half_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_u_half_rd_addr;
- wire buf_u_half_wr_en;
- wire [ 32-1:0] buf_u_half_wr_din;
- wire [ 32-1:0] buf_u_half_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_u_half
- ( .clk(clk),
- .a_addr(buf_u_half_wr_addr), .a_out(), .a_wr(buf_u_half_wr_en), .a_in(buf_u_half_wr_din),
- .b_addr(buf_u_half_rd_addr), .b_out(buf_u_half_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_v_half_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_v_half_rd_addr;
- wire buf_v_half_wr_en;
- wire [ 32-1:0] buf_v_half_wr_din;
- wire [ 32-1:0] buf_v_half_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_v_half
- ( .clk(clk),
- .a_addr(buf_v_half_wr_addr), .a_out(), .a_wr(buf_v_half_wr_en), .a_in(buf_v_half_wr_din),
- .b_addr(buf_v_half_rd_addr), .b_out(buf_v_half_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_half_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_half_rd_addr;
- wire buf_u_minus_v_half_wr_en;
- wire [ 32-1:0] buf_u_minus_v_half_wr_din;
- wire [ 32-1:0] buf_u_minus_v_half_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_u_minus_v_half
- ( .clk(clk),
- .a_addr(buf_u_minus_v_half_wr_addr), .a_out(), .a_wr(buf_u_minus_v_half_wr_en), .a_in(buf_u_minus_v_half_wr_din),
- .b_addr(buf_u_minus_v_half_rd_addr), .b_out(buf_u_minus_v_half_rd_dout)
- );
-
- wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_half_wr_addr;
- wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_half_rd_addr;
- wire buf_v_minus_u_half_wr_en;
- wire [ 32-1:0] buf_v_minus_u_half_wr_din;
- wire [ 32-1:0] buf_v_minus_u_half_rd_dout;
-
- bram_1rw_1ro_readfirst #
- ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
- )
- buf_v_minus_u_half
- ( .clk(clk),
- .a_addr(buf_v_minus_u_half_wr_addr), .a_out(), .a_wr(buf_v_minus_u_half_wr_en), .a_in(buf_v_minus_u_half_wr_din),
- .b_addr(buf_v_minus_u_half_rd_addr), .b_out(buf_v_minus_u_half_rd_dout)
- );
-
-
- //
- // Helper Modules
- //
- wire helper_init_ena;
- wire helper_invert_precalc_ena;
- wire helper_invert_compare_ena;
- wire helper_invert_update_ena;
- wire helper_reduce_precalc_ena;
- wire helper_reduce_update_ena;
- wire helper_copy_ena;
-
- wire helper_init_rdy;
- wire helper_invert_precalc_rdy;
- wire helper_invert_compare_rdy;
- wire helper_invert_update_rdy;
- wire helper_reduce_precalc_rdy;
- wire helper_reduce_update_rdy;
- wire helper_copy_rdy;
-
- wire helper_init_done = helper_init_rdy && !helper_init_ena;
- wire helper_invert_precalc_done = helper_invert_precalc_rdy && !helper_invert_precalc_ena;
- wire helper_invert_compare_done = helper_invert_compare_rdy && !helper_invert_compare_ena;
- wire helper_invert_update_done = helper_invert_update_rdy && !helper_invert_update_ena;
- wire helper_reduce_precalc_done = helper_reduce_precalc_rdy && !helper_reduce_precalc_ena;
- wire helper_reduce_update_done = helper_reduce_update_rdy && !helper_reduce_update_ena;
- wire helper_copy_done = helper_copy_rdy && !helper_copy_ena;
-
-
- //
- // Helper Module - Initialization
- //
- wire [ BUFFER_ADDR_BITS-1:0] helper_init_r_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_init_s_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_init_u_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_init_v_addr;
- wire [OPERAND_ADDR_BITS-1:0] helper_init_q_addr;
-
- wire helper_init_r_wren;
- wire helper_init_s_wren;
- wire helper_init_u_wren;
- wire helper_init_v_wren;
-
- wire [ 32-1:0] helper_init_r_data;
- wire [ 32-1:0] helper_init_s_data;
- wire [ 32-1:0] helper_init_u_data;
- wire [ 32-1:0] helper_init_v_data;
-
- modinv_helper_init #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
-
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_init
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_init_ena),
- .rdy (helper_init_rdy),
-
- .a_addr (a_addr),
- .q_addr (helper_init_q_addr),
-
- .r_addr (helper_init_r_addr),
- .s_addr (helper_init_s_addr),
- .u_addr (helper_init_u_addr),
- .v_addr (helper_init_v_addr),
-
- .q_din (q_din),
- .a_din (a_din),
-
- .r_dout (helper_init_r_data),
- .s_dout (helper_init_s_data),
- .u_dout (helper_init_u_data),
- .v_dout (helper_init_v_data),
-
- .r_wren (helper_init_r_wren),
- .s_wren (helper_init_s_wren),
- .u_wren (helper_init_u_wren),
- .v_wren (helper_init_v_wren)
- );
-
-
- //
- // Helper Module - Inversion Pre-Calculation
- //
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_r_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_s_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_u_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_v_addr;
-
- modinv_helper_invert_precalc #
- (
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_invert_precalc
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_invert_precalc_ena),
- .rdy (helper_invert_precalc_rdy),
-
- .r_addr (helper_invert_precalc_r_addr),
- .s_addr (helper_invert_precalc_s_addr),
- .u_addr (helper_invert_precalc_u_addr),
- .v_addr (helper_invert_precalc_v_addr),
-
- .r_din (buf_r_rd_dout),
- .s_din (buf_s_rd_dout),
- .u_din (buf_u_rd_dout),
- .v_din (buf_v_rd_dout),
-
- .r_dbl_addr (buf_r_dbl_wr_addr),
- .s_dbl_addr (buf_s_dbl_wr_addr),
- .r_plus_s_addr (buf_r_plus_s_wr_addr),
-
- .u_half_addr (buf_u_half_wr_addr),
- .v_half_addr (buf_v_half_wr_addr),
- .u_minus_v_addr (buf_u_minus_v_wr_addr),
- .v_minus_u_addr (buf_v_minus_u_wr_addr),
- .u_minus_v_half_addr (buf_u_minus_v_half_wr_addr),
- .v_minus_u_half_addr (buf_v_minus_u_half_wr_addr),
-
- .r_dbl_dout (buf_r_dbl_wr_din),
- .s_dbl_dout (buf_s_dbl_wr_din),
- .r_plus_s_dout (buf_r_plus_s_wr_din),
-
- .u_half_dout (buf_u_half_wr_din),
- .v_half_dout (buf_v_half_wr_din),
- .u_minus_v_dout (buf_u_minus_v_wr_din),
- .v_minus_u_dout (buf_v_minus_u_wr_din),
- .u_minus_v_half_dout (buf_u_minus_v_half_wr_din),
- .v_minus_u_half_dout (buf_v_minus_u_half_wr_din),
-
- .r_dbl_wren (buf_r_dbl_wr_en),
- .s_dbl_wren (buf_s_dbl_wr_en),
- .r_plus_s_wren (buf_r_plus_s_wr_en),
-
- .u_half_wren (buf_u_half_wr_en),
- .v_half_wren (buf_v_half_wr_en),
- .u_minus_v_wren (buf_u_minus_v_wr_en),
- .v_minus_u_wren (buf_v_minus_u_wr_en),
- .u_minus_v_half_wren (buf_u_minus_v_half_wr_en),
- .v_minus_u_half_wren (buf_v_minus_u_half_wr_en),
-
- .u_minus_v_din (buf_u_minus_v_wr_dout),
- .v_minus_u_din (buf_v_minus_u_wr_dout)
- );
-
-
- //
- // Helper Module - Inversion Comparison
- //
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_compare_u_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_compare_v_addr;
-
- wire flag_invert_u_gt_v;
- wire flag_invert_v_eq_1;
- wire flag_invert_u_is_even;
- wire flag_invert_v_is_even;
-
- modinv_helper_invert_compare #
- (
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_invert_compare
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_invert_compare_ena),
- .rdy (helper_invert_compare_rdy),
-
- .u_addr (helper_invert_compare_u_addr),
- .v_addr (helper_invert_compare_v_addr),
-
- .u_din (buf_u_rd_dout),
- .v_din (buf_v_rd_dout),
-
- .u_gt_v (flag_invert_u_gt_v),
- .v_eq_1 (flag_invert_v_eq_1),
- .u_is_even (flag_invert_u_is_even),
- .v_is_even (flag_invert_v_is_even)
- );
-
-
- //
- // Helper Module - Inversion Update
- //
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_r_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_s_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_u_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_v_addr;
-
- wire helper_invert_update_r_wren;
- wire helper_invert_update_s_wren;
- wire helper_invert_update_u_wren;
- wire helper_invert_update_v_wren;
-
- wire [ 32-1:0] helper_invert_update_r_data;
- wire [ 32-1:0] helper_invert_update_s_data;
- wire [ 32-1:0] helper_invert_update_u_data;
- wire [ 32-1:0] helper_invert_update_v_data;
-
- modinv_helper_invert_update #
- (
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_invert_update
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_invert_update_ena),
- .rdy (helper_invert_update_rdy),
-
- .u_gt_v (flag_invert_u_gt_v),
- .v_eq_1 (flag_invert_v_eq_1),
- .u_is_even (flag_invert_u_is_even),
- .v_is_even (flag_invert_v_is_even),
-
- .r_addr (helper_invert_update_r_addr),
- .s_addr (helper_invert_update_s_addr),
- .u_addr (helper_invert_update_u_addr),
- .v_addr (helper_invert_update_v_addr),
-
- .r_wren (helper_invert_update_r_wren),
- .s_wren (helper_invert_update_s_wren),
- .u_wren (helper_invert_update_u_wren),
- .v_wren (helper_invert_update_v_wren),
-
- .r_dout (helper_invert_update_r_data),
- .s_dout (helper_invert_update_s_data),
- .u_dout (helper_invert_update_u_data),
- .v_dout (helper_invert_update_v_data),
-
- .r_dbl_addr (buf_r_dbl_rd_addr),
- .s_dbl_addr (buf_s_dbl_rd_addr),
- .r_plus_s_addr (buf_r_plus_s_rd_addr),
- .u_half_addr (buf_u_half_rd_addr),
- .v_half_addr (buf_v_half_rd_addr),
- .u_minus_v_half_addr (buf_u_minus_v_half_rd_addr),
- .v_minus_u_half_addr (buf_v_minus_u_half_rd_addr),
-
- .r_dbl_din (buf_r_dbl_rd_dout),
- .s_dbl_din (buf_s_dbl_rd_dout),
- .r_plus_s_din (buf_r_plus_s_rd_dout),
- .u_half_din (buf_u_half_rd_dout),
- .v_half_din (buf_v_half_rd_dout),
- .u_minus_v_half_din (buf_u_minus_v_half_rd_dout),
- .v_minus_u_half_din (buf_v_minus_u_half_rd_dout)
- );
-
-
- //
- // Helper Module - Reduction Pre-Calculation
- //
- wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_r_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_s_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_u_addr;
- wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_v_addr;
- wire [OPERAND_ADDR_BITS-1:0] helper_reduce_precalc_q_addr;
-
- wire helper_reduce_precalc_r_wren;
- wire helper_reduce_precalc_u_wren;
- wire helper_reduce_precalc_v_wren;
-
- wire [ 32-1:0] helper_reduce_precalc_r_data;
- wire [ 32-1:0] helper_reduce_precalc_u_data;
- wire [ 32-1:0] helper_reduce_precalc_v_data;
-
- wire flag_reduce_s_is_odd;
- wire flag_invert_k_is_nul;
-
- modinv_helper_reduce_precalc #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS),
- .K_NUM_BITS (K_NUM_BITS)
- )
- helper_reduce_precalc
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_reduce_precalc_ena),
- .rdy (helper_reduce_precalc_rdy),
-
- .r_addr (helper_reduce_precalc_r_addr),
- .s_addr (helper_reduce_precalc_s_addr),
- .u_addr (helper_reduce_precalc_u_addr),
- .v_addr (helper_reduce_precalc_v_addr),
- .q_addr (helper_reduce_precalc_q_addr),
-
- .k (k),
-
- .s_is_odd (flag_reduce_s_is_odd),
- .k_is_nul (flag_reduce_k_is_nul),
-
- .r_din (buf_r_wr_dout),
- .s_din (buf_s_rd_dout),
- .q_din (q_din),
-
- .r_wren (helper_reduce_precalc_r_wren),
- .u_wren (helper_reduce_precalc_u_wren),
- .v_wren (helper_reduce_precalc_v_wren),
-
- .r_dout (helper_reduce_precalc_r_data),
- .u_dout (helper_reduce_precalc_u_data),
- .v_dout (helper_reduce_precalc_v_data)
- );
-
- //
- // Helper Module - Reduction Update
- //
- wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_s_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_u_addr;
- wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_v_addr;
-
- wire helper_reduce_update_s_wren;
-
- wire [ 32-1:0] helper_reduce_update_s_data;
-
- modinv_helper_reduce_update #
- (
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_reduce_update
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_reduce_update_ena),
- .rdy (helper_reduce_update_rdy),
-
- .s_is_odd (flag_reduce_s_is_odd),
- .k_is_nul (flag_reduce_k_is_nul),
-
- .s_addr (helper_reduce_update_s_addr),
- .u_addr (helper_reduce_update_u_addr),
- .v_addr (helper_reduce_update_v_addr),
-
- .s_wren (helper_reduce_update_s_wren),
-
- .s_dout (helper_reduce_update_s_data),
-
- .u_din (buf_u_rd_dout),
- .v_din (buf_v_rd_dout)
- );
-
-
- //
- // Helper Module - Copying
- //
- wire [BUFFER_ADDR_BITS-1:0] helper_copy_s_addr;
-
- modinv_helper_copy #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
-
- .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
- .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
- )
- helper_copy
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (helper_copy_ena),
- .rdy (helper_copy_rdy),
-
- .s_addr (helper_copy_s_addr),
- .a1_addr (a1_addr),
-
- .s_din (buf_s_rd_dout),
-
- .a1_dout (a1_dout),
-
- .a1_wren (a1_wren)
- );
-
-
- //
- // Round Counter
- //
- reg [ROUND_COUNTER_BITS-1:0] round_counter;
- wire [ROUND_COUNTER_BITS-1:0] round_counter_max = LOOP_NUM_ROUNDS - 1;
- wire [ROUND_COUNTER_BITS-1:0] round_counter_zero = {ROUND_COUNTER_BITS{1'b0}};
- wire [ROUND_COUNTER_BITS-1:0] round_counter_next =
- (round_counter < round_counter_max) ? round_counter + 1'b1 : round_counter_zero;
-
-
- //
- // FSM
- //
- localparam FSM_STATE_IDLE = 4'd0;
-
- localparam FSM_STATE_INIT = 4'd1;
-
- localparam FSM_STATE_INVERT_PRECALC = 4'd11;
- localparam FSM_STATE_INVERT_COMPARE = 4'd12;
- localparam FSM_STATE_INVERT_UPDATE = 4'd13;
-
- localparam FSM_STATE_REDUCE_PRECALC = 4'd14;
- localparam FSM_STATE_REDUCE_UPDATE = 4'd15;
-
- localparam FSM_STATE_COPY = 4'd2;
-
- localparam FSM_STATE_DONE = 4'd3;
-
- reg [3:0] fsm_state = FSM_STATE_IDLE;
- reg [3:0] fsm_state_dly = FSM_STATE_IDLE;
-
- wire fsm_state_new = (fsm_state != fsm_state_dly);
-
- wire [3:0] fsm_state_invert_next = (round_counter < round_counter_max) ?
- FSM_STATE_INVERT_PRECALC : FSM_STATE_REDUCE_PRECALC;
-
- wire [3:0] fsm_state_reduce_next = (round_counter < round_counter_max) ?
- FSM_STATE_REDUCE_PRECALC : FSM_STATE_COPY;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) fsm_state <= FSM_STATE_IDLE;
- else case (fsm_state)
- FSM_STATE_IDLE: fsm_state <= ena ? FSM_STATE_INIT : FSM_STATE_IDLE;
- FSM_STATE_INIT: fsm_state <= helper_init_done ? FSM_STATE_INVERT_PRECALC : FSM_STATE_INIT;
- FSM_STATE_INVERT_PRECALC: fsm_state <= helper_invert_precalc_done ? FSM_STATE_INVERT_COMPARE : FSM_STATE_INVERT_PRECALC;
- FSM_STATE_INVERT_COMPARE: fsm_state <= helper_invert_compare_done ? FSM_STATE_INVERT_UPDATE : FSM_STATE_INVERT_COMPARE;
- FSM_STATE_INVERT_UPDATE: fsm_state <= helper_invert_update_done ? fsm_state_invert_next : FSM_STATE_INVERT_UPDATE;
- FSM_STATE_REDUCE_PRECALC: fsm_state <= helper_reduce_precalc_done ? FSM_STATE_REDUCE_UPDATE : FSM_STATE_REDUCE_PRECALC;
- FSM_STATE_REDUCE_UPDATE: fsm_state <= helper_reduce_update_done ? fsm_state_reduce_next : FSM_STATE_REDUCE_UPDATE;
- FSM_STATE_COPY: fsm_state <= helper_copy_done ? FSM_STATE_DONE : FSM_STATE_COPY;
- FSM_STATE_DONE: fsm_state <= FSM_STATE_IDLE;
- default: fsm_state <= FSM_STATE_IDLE;
- endcase
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) fsm_state_dly <= FSM_STATE_IDLE;
- else fsm_state_dly <= fsm_state;
-
-
- assign helper_init_ena = (fsm_state == FSM_STATE_INIT) && fsm_state_new;
- assign helper_invert_precalc_ena = (fsm_state == FSM_STATE_INVERT_PRECALC) && fsm_state_new;
- assign helper_invert_compare_ena = (fsm_state == FSM_STATE_INVERT_COMPARE) && fsm_state_new;
- assign helper_invert_update_ena = (fsm_state == FSM_STATE_INVERT_UPDATE) && fsm_state_new;
- assign helper_reduce_precalc_ena = (fsm_state == FSM_STATE_REDUCE_PRECALC) && fsm_state_new;
- assign helper_reduce_update_ena = (fsm_state == FSM_STATE_REDUCE_UPDATE) && fsm_state_new;
- assign helper_copy_ena = (fsm_state == FSM_STATE_COPY) && fsm_state_new;
-
-
- //
- // Counter Increment
- //
- always @(posedge clk) begin
- //
- if ((fsm_state == FSM_STATE_INIT) && helper_init_done)
- round_counter <= round_counter_zero;
- //
- if ((fsm_state == FSM_STATE_INVERT_UPDATE) && helper_invert_update_done)
- round_counter <= round_counter_next;
- //
- if ((fsm_state == FSM_STATE_REDUCE_UPDATE) && helper_reduce_update_done)
- round_counter <= round_counter_next;
- //
- end
-
-
- //
- // Q Address Selector
- //
- always @(*) begin
- //
- case (fsm_state)
- FSM_STATE_INIT: q_addr = helper_init_q_addr;
- FSM_STATE_REDUCE_PRECALC: q_addr = helper_reduce_precalc_q_addr;
- default: q_addr = {OPERAND_ADDR_BITS{1'bX}};
- endcase
- //
- end
-
-
- //
- // Buffer Address Selector
- //
- always @(*) begin
- //
- // Write Ports
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_r_wr_addr = helper_init_r_addr;
- FSM_STATE_INVERT_UPDATE: buf_r_wr_addr = helper_invert_update_r_addr;
- FSM_STATE_REDUCE_PRECALC: buf_r_wr_addr = helper_reduce_precalc_r_addr;
- default: buf_r_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_s_wr_addr = helper_init_s_addr;
- FSM_STATE_INVERT_UPDATE: buf_s_wr_addr = helper_invert_update_s_addr;
- FSM_STATE_REDUCE_UPDATE: buf_s_wr_addr = helper_reduce_update_s_addr;
- default: buf_s_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_u_wr_addr = helper_init_u_addr;
- FSM_STATE_INVERT_UPDATE: buf_u_wr_addr = helper_invert_update_u_addr;
- FSM_STATE_REDUCE_PRECALC: buf_u_wr_addr = helper_reduce_precalc_u_addr;
- default: buf_u_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_v_wr_addr = helper_init_v_addr;
- FSM_STATE_INVERT_UPDATE: buf_v_wr_addr = helper_invert_update_v_addr;
- FSM_STATE_REDUCE_PRECALC: buf_v_wr_addr = helper_reduce_precalc_v_addr;
- default: buf_v_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- // Read Ports
- //
- case (fsm_state)
- FSM_STATE_INVERT_PRECALC: buf_r_rd_addr = helper_invert_precalc_r_addr;
- default: buf_r_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INVERT_PRECALC: buf_s_rd_addr = helper_invert_precalc_s_addr;
- FSM_STATE_REDUCE_PRECALC: buf_s_rd_addr = helper_reduce_precalc_s_addr;
- FSM_STATE_COPY: buf_s_rd_addr = helper_copy_s_addr;
- default: buf_s_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INVERT_PRECALC: buf_u_rd_addr = helper_invert_precalc_u_addr;
- FSM_STATE_INVERT_COMPARE: buf_u_rd_addr = helper_invert_compare_u_addr;
- FSM_STATE_REDUCE_UPDATE: buf_u_rd_addr = helper_reduce_update_u_addr;
- default: buf_u_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INVERT_PRECALC: buf_v_rd_addr = helper_invert_precalc_v_addr;
- FSM_STATE_INVERT_COMPARE: buf_v_rd_addr = helper_invert_compare_v_addr;
- FSM_STATE_REDUCE_UPDATE: buf_v_rd_addr = helper_reduce_update_v_addr;
- default: buf_v_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
- endcase
- //
- end
-
-
- //
- // Buffer Write Enable Logic
- //
- always @(*) begin
- //
- // Write Ports
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_r_wr_en = helper_init_r_wren;
- FSM_STATE_INVERT_UPDATE: buf_r_wr_en = helper_invert_update_r_wren;
- FSM_STATE_REDUCE_PRECALC: buf_r_wr_en = helper_reduce_precalc_r_wren;
- default: buf_r_wr_en = 1'b0;
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_s_wr_en = helper_init_s_wren;
- FSM_STATE_INVERT_UPDATE: buf_s_wr_en = helper_invert_update_s_wren;
- FSM_STATE_REDUCE_UPDATE: buf_s_wr_en = helper_reduce_update_s_wren;
- default: buf_s_wr_en = 1'b0;
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_u_wr_en = helper_init_u_wren;
- FSM_STATE_INVERT_UPDATE: buf_u_wr_en = helper_invert_update_u_wren;
- FSM_STATE_REDUCE_PRECALC: buf_u_wr_en = helper_reduce_precalc_u_wren;
- default: buf_u_wr_en = 1'b0;
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_v_wr_en = helper_init_v_wren;
- FSM_STATE_INVERT_UPDATE: buf_v_wr_en = helper_invert_update_v_wren;
- FSM_STATE_REDUCE_PRECALC: buf_v_wr_en = helper_reduce_precalc_v_wren;
- default: buf_v_wr_en = 1'b0;
- endcase
- //
- end
-
-
- //
- // Buffer Write Data Selector
- //
- always @(*) begin
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_r_wr_din = helper_init_r_data;
- FSM_STATE_INVERT_UPDATE: buf_r_wr_din = helper_invert_update_r_data;
- FSM_STATE_REDUCE_PRECALC: buf_r_wr_din = helper_reduce_precalc_r_data;
- default: buf_r_wr_din = {32{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_s_wr_din = helper_init_s_data;
- FSM_STATE_INVERT_UPDATE: buf_s_wr_din = helper_invert_update_s_data;
- FSM_STATE_REDUCE_UPDATE: buf_s_wr_din = helper_reduce_update_s_data;
- default: buf_s_wr_din = {32{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_u_wr_din = helper_init_u_data;
- FSM_STATE_INVERT_UPDATE: buf_u_wr_din = helper_invert_update_u_data;
- FSM_STATE_REDUCE_PRECALC: buf_u_wr_din = helper_reduce_precalc_u_data;
- default: buf_u_wr_din = {32{1'bX}};
- endcase
- //
- case (fsm_state)
- FSM_STATE_INIT: buf_v_wr_din = helper_init_v_data;
- FSM_STATE_INVERT_UPDATE: buf_v_wr_din = helper_invert_update_v_data;
- FSM_STATE_REDUCE_PRECALC: buf_v_wr_din = helper_reduce_precalc_v_data;
- default: buf_v_wr_din = {32{1'bX}};
- endcase
- //
- end
-
-
- //
- // Ready Logic
- //
- reg rdy_reg = 1'b1;
-
- assign rdy = rdy_reg;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0) rdy_reg <= 1'b1;
- else begin
-
- /* clear */
- if (rdy && ena) rdy_reg <= 1'b0;
-
- /* set */
- if (!rdy && (fsm_state == FSM_STATE_DONE)) rdy_reg <= 1'b1;
-
- end
-
-
- //
- // Store Redundant Power of 2 (K)
- //
- always @(posedge clk)
- //
- if (helper_init_ena)
- k <= {K_NUM_BITS{1'b0}};
- else begin
-
- if (helper_invert_update_ena && !flag_invert_v_eq_1)
- k <= k + 1'b1;
-
- if (helper_reduce_update_ena && (k != {K_NUM_BITS{1'b0}}))
- k <= k - 1'b1;
-
- end
-
-endmodule
-
-
+//------------------------------------------------------------------------------
+
+module modular_invertor
+ (
+ clk, rst_n,
+ ena, rdy,
+ a_addr, q_addr, a1_addr, a1_wren,
+ a_din, q_din, a1_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter MAX_OPERAND_WIDTH = 256;
+
+
+ //
+ // clog2
+ //
+`include "modinv_clog2.v"
+
+
+ //
+ // More Parameters
+ //
+ localparam OPERAND_NUM_WORDS = MAX_OPERAND_WIDTH / 32;
+ localparam OPERAND_ADDR_BITS = clog2(OPERAND_NUM_WORDS);
+
+ localparam BUFFER_NUM_WORDS = OPERAND_NUM_WORDS + 1;
+ localparam BUFFER_ADDR_BITS = clog2(BUFFER_NUM_WORDS);
+
+ localparam LOOP_NUM_ROUNDS = 2 * MAX_OPERAND_WIDTH;
+ localparam ROUND_COUNTER_BITS = clog2(LOOP_NUM_ROUNDS);
+
+ localparam K_NUM_BITS = clog2(LOOP_NUM_ROUNDS + 1);
+
+
+ //
+ // Ports
+ //
+ input wire clk;
+ input wire rst_n;
+
+ input wire ena;
+ output wire rdy;
+
+ output wire [OPERAND_ADDR_BITS-1:0] a_addr;
+ output reg [OPERAND_ADDR_BITS-1:0] q_addr;
+ output wire [OPERAND_ADDR_BITS-1:0] a1_addr;
+ output wire a1_wren;
+
+ input wire [32-1:0] a_din;
+ input wire [32-1:0] q_din;
+ output wire [32-1:0] a1_dout;
+
+
+ //
+ // "Redundant" Power of 2 (K)
+ //
+ reg [K_NUM_BITS-1:0] k;
+
+
+ //
+ // Buffers
+ //
+ reg [BUFFER_ADDR_BITS-1:0] buf_r_wr_addr;
+ reg [BUFFER_ADDR_BITS-1:0] buf_r_rd_addr;
+ reg buf_r_wr_en;
+ reg [ 32-1:0] buf_r_wr_din;
+ wire [ 32-1:0] buf_r_wr_dout;
+ wire [ 32-1:0] buf_r_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_r
+ ( .clk(clk),
+ .a_addr(buf_r_wr_addr), .a_out(buf_r_wr_dout), .a_wr(buf_r_wr_en), .a_in(buf_r_wr_din),
+ .b_addr(buf_r_rd_addr), .b_out(buf_r_rd_dout)
+ );
+
+ reg [BUFFER_ADDR_BITS-1:0] buf_s_wr_addr;
+ reg [BUFFER_ADDR_BITS-1:0] buf_s_rd_addr;
+ reg buf_s_wr_en;
+ reg [ 32-1:0] buf_s_wr_din;
+ wire [ 32-1:0] buf_s_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_s
+ ( .clk(clk),
+ .a_addr(buf_s_wr_addr), .a_out(), .a_wr(buf_s_wr_en), .a_in(buf_s_wr_din),
+ .b_addr(buf_s_rd_addr), .b_out(buf_s_rd_dout)
+ );
+
+ reg [BUFFER_ADDR_BITS-1:0] buf_u_wr_addr;
+ reg [BUFFER_ADDR_BITS-1:0] buf_u_rd_addr;
+ reg buf_u_wr_en;
+ reg [ 32-1:0] buf_u_wr_din;
+ wire [ 32-1:0] buf_u_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_u
+ ( .clk(clk),
+ .a_addr(buf_u_wr_addr), .a_out(), .a_wr(buf_u_wr_en), .a_in(buf_u_wr_din),
+ .b_addr(buf_u_rd_addr), .b_out(buf_u_rd_dout)
+ );
+
+ reg [BUFFER_ADDR_BITS-1:0] buf_v_wr_addr;
+ reg [BUFFER_ADDR_BITS-1:0] buf_v_rd_addr;
+ reg buf_v_wr_en;
+ reg [ 32-1:0] buf_v_wr_din;
+ wire [ 32-1:0] buf_v_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_v
+ ( .clk(clk),
+ .a_addr(buf_v_wr_addr), .a_out(), .a_wr(buf_v_wr_en), .a_in(buf_v_wr_din),
+ .b_addr(buf_v_rd_addr), .b_out(buf_v_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_r_dbl_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_r_dbl_rd_addr;
+ wire buf_r_dbl_wr_en;
+ wire [ 32-1:0] buf_r_dbl_wr_din;
+ wire [ 32-1:0] buf_r_dbl_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_r_dbl
+ ( .clk(clk),
+ .a_addr(buf_r_dbl_wr_addr), .a_out(), .a_wr(buf_r_dbl_wr_en), .a_in(buf_r_dbl_wr_din),
+ .b_addr(buf_r_dbl_rd_addr), .b_out(buf_r_dbl_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_s_dbl_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_s_dbl_rd_addr;
+ wire buf_s_dbl_wr_en;
+ wire [ 32-1:0] buf_s_dbl_wr_din;
+ wire [ 32-1:0] buf_s_dbl_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_s_dbl
+ ( .clk(clk),
+ .a_addr(buf_s_dbl_wr_addr), .a_out(), .a_wr(buf_s_dbl_wr_en), .a_in(buf_s_dbl_wr_din),
+ .b_addr(buf_s_dbl_rd_addr), .b_out(buf_s_dbl_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_r_plus_s_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_r_plus_s_rd_addr;
+ wire buf_r_plus_s_wr_en;
+ wire [ 32-1:0] buf_r_plus_s_wr_din;
+ wire [ 32-1:0] buf_r_plus_s_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_r_plus_s
+ ( .clk(clk),
+ .a_addr(buf_r_plus_s_wr_addr), .a_out(), .a_wr(buf_r_plus_s_wr_en), .a_in(buf_r_plus_s_wr_din),
+ .b_addr(buf_r_plus_s_rd_addr), .b_out(buf_r_plus_s_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_rd_addr;
+ wire buf_u_minus_v_wr_en;
+ wire [ 32-1:0] buf_u_minus_v_wr_din;
+ wire [ 32-1:0] buf_u_minus_v_wr_dout;
+
+ assign buf_u_minus_v_rd_addr = ~buf_u_minus_v_wr_addr;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_u_minus_v
+ ( .clk(clk),
+ .a_addr(buf_u_minus_v_wr_addr), .a_out(buf_u_minus_v_wr_dout), .a_wr(buf_u_minus_v_wr_en), .a_in(buf_u_minus_v_wr_din),
+ .b_addr(buf_u_minus_v_rd_addr), .b_out()
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_rd_addr;
+ wire buf_v_minus_u_wr_en;
+ wire [ 32-1:0] buf_v_minus_u_wr_din;
+ wire [ 32-1:0] buf_v_minus_u_wr_dout;
+
+ assign buf_v_minus_u_rd_addr = ~buf_v_minus_u_wr_addr;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_v_minus_u
+ ( .clk(clk),
+ .a_addr(buf_v_minus_u_wr_addr), .a_out(buf_v_minus_u_wr_dout), .a_wr(buf_v_minus_u_wr_en), .a_in(buf_v_minus_u_wr_din),
+ .b_addr(buf_v_minus_u_rd_addr), .b_out()
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_half_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_half_rd_addr;
+ wire buf_u_half_wr_en;
+ wire [ 32-1:0] buf_u_half_wr_din;
+ wire [ 32-1:0] buf_u_half_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_u_half
+ ( .clk(clk),
+ .a_addr(buf_u_half_wr_addr), .a_out(), .a_wr(buf_u_half_wr_en), .a_in(buf_u_half_wr_din),
+ .b_addr(buf_u_half_rd_addr), .b_out(buf_u_half_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_half_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_half_rd_addr;
+ wire buf_v_half_wr_en;
+ wire [ 32-1:0] buf_v_half_wr_din;
+ wire [ 32-1:0] buf_v_half_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_v_half
+ ( .clk(clk),
+ .a_addr(buf_v_half_wr_addr), .a_out(), .a_wr(buf_v_half_wr_en), .a_in(buf_v_half_wr_din),
+ .b_addr(buf_v_half_rd_addr), .b_out(buf_v_half_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_half_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_u_minus_v_half_rd_addr;
+ wire buf_u_minus_v_half_wr_en;
+ wire [ 32-1:0] buf_u_minus_v_half_wr_din;
+ wire [ 32-1:0] buf_u_minus_v_half_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_u_minus_v_half
+ ( .clk(clk),
+ .a_addr(buf_u_minus_v_half_wr_addr), .a_out(), .a_wr(buf_u_minus_v_half_wr_en), .a_in(buf_u_minus_v_half_wr_din),
+ .b_addr(buf_u_minus_v_half_rd_addr), .b_out(buf_u_minus_v_half_rd_dout)
+ );
+
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_half_wr_addr;
+ wire [BUFFER_ADDR_BITS-1:0] buf_v_minus_u_half_rd_addr;
+ wire buf_v_minus_u_half_wr_en;
+ wire [ 32-1:0] buf_v_minus_u_half_wr_din;
+ wire [ 32-1:0] buf_v_minus_u_half_rd_dout;
+
+ bram_1rw_1ro_readfirst #
+ ( .MEM_WIDTH(32), .MEM_ADDR_BITS(BUFFER_ADDR_BITS)
+ )
+ buf_v_minus_u_half
+ ( .clk(clk),
+ .a_addr(buf_v_minus_u_half_wr_addr), .a_out(), .a_wr(buf_v_minus_u_half_wr_en), .a_in(buf_v_minus_u_half_wr_din),
+ .b_addr(buf_v_minus_u_half_rd_addr), .b_out(buf_v_minus_u_half_rd_dout)
+ );
+
+
+ //
+ // Helper Modules
+ //
+ wire helper_init_ena;
+ wire helper_invert_precalc_ena;
+ wire helper_invert_compare_ena;
+ wire helper_invert_update_ena;
+ wire helper_reduce_precalc_ena;
+ wire helper_reduce_update_ena;
+ wire helper_copy_ena;
+
+ wire helper_init_rdy;
+ wire helper_invert_precalc_rdy;
+ wire helper_invert_compare_rdy;
+ wire helper_invert_update_rdy;
+ wire helper_reduce_precalc_rdy;
+ wire helper_reduce_update_rdy;
+ wire helper_copy_rdy;
+
+ wire helper_init_done = helper_init_rdy && !helper_init_ena;
+ wire helper_invert_precalc_done = helper_invert_precalc_rdy && !helper_invert_precalc_ena;
+ wire helper_invert_compare_done = helper_invert_compare_rdy && !helper_invert_compare_ena;
+ wire helper_invert_update_done = helper_invert_update_rdy && !helper_invert_update_ena;
+ wire helper_reduce_precalc_done = helper_reduce_precalc_rdy && !helper_reduce_precalc_ena;
+ wire helper_reduce_update_done = helper_reduce_update_rdy && !helper_reduce_update_ena;
+ wire helper_copy_done = helper_copy_rdy && !helper_copy_ena;
+
+
+ //
+ // Helper Module - Initialization
+ //
+ wire [ BUFFER_ADDR_BITS-1:0] helper_init_r_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_init_s_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_init_u_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_init_v_addr;
+ wire [OPERAND_ADDR_BITS-1:0] helper_init_q_addr;
+
+ wire helper_init_r_wren;
+ wire helper_init_s_wren;
+ wire helper_init_u_wren;
+ wire helper_init_v_wren;
+
+ wire [ 32-1:0] helper_init_r_data;
+ wire [ 32-1:0] helper_init_s_data;
+ wire [ 32-1:0] helper_init_u_data;
+ wire [ 32-1:0] helper_init_v_data;
+
+ modinv_helper_init #
+ (
+ .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
+ .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
+
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_init
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_init_ena),
+ .rdy (helper_init_rdy),
+
+ .a_addr (a_addr),
+ .q_addr (helper_init_q_addr),
+
+ .r_addr (helper_init_r_addr),
+ .s_addr (helper_init_s_addr),
+ .u_addr (helper_init_u_addr),
+ .v_addr (helper_init_v_addr),
+
+ .q_din (q_din),
+ .a_din (a_din),
+
+ .r_dout (helper_init_r_data),
+ .s_dout (helper_init_s_data),
+ .u_dout (helper_init_u_data),
+ .v_dout (helper_init_v_data),
+
+ .r_wren (helper_init_r_wren),
+ .s_wren (helper_init_s_wren),
+ .u_wren (helper_init_u_wren),
+ .v_wren (helper_init_v_wren)
+ );
+
+
+ //
+ // Helper Module - Inversion Pre-Calculation
+ //
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_r_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_s_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_u_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_precalc_v_addr;
+
+ modinv_helper_invert_precalc #
+ (
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_invert_precalc
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_invert_precalc_ena),
+ .rdy (helper_invert_precalc_rdy),
+
+ .r_addr (helper_invert_precalc_r_addr),
+ .s_addr (helper_invert_precalc_s_addr),
+ .u_addr (helper_invert_precalc_u_addr),
+ .v_addr (helper_invert_precalc_v_addr),
+
+ .r_din (buf_r_rd_dout),
+ .s_din (buf_s_rd_dout),
+ .u_din (buf_u_rd_dout),
+ .v_din (buf_v_rd_dout),
+
+ .r_dbl_addr (buf_r_dbl_wr_addr),
+ .s_dbl_addr (buf_s_dbl_wr_addr),
+ .r_plus_s_addr (buf_r_plus_s_wr_addr),
+
+ .u_half_addr (buf_u_half_wr_addr),
+ .v_half_addr (buf_v_half_wr_addr),
+ .u_minus_v_addr (buf_u_minus_v_wr_addr),
+ .v_minus_u_addr (buf_v_minus_u_wr_addr),
+ .u_minus_v_half_addr (buf_u_minus_v_half_wr_addr),
+ .v_minus_u_half_addr (buf_v_minus_u_half_wr_addr),
+
+ .r_dbl_dout (buf_r_dbl_wr_din),
+ .s_dbl_dout (buf_s_dbl_wr_din),
+ .r_plus_s_dout (buf_r_plus_s_wr_din),
+
+ .u_half_dout (buf_u_half_wr_din),
+ .v_half_dout (buf_v_half_wr_din),
+ .u_minus_v_dout (buf_u_minus_v_wr_din),
+ .v_minus_u_dout (buf_v_minus_u_wr_din),
+ .u_minus_v_half_dout (buf_u_minus_v_half_wr_din),
+ .v_minus_u_half_dout (buf_v_minus_u_half_wr_din),
+
+ .r_dbl_wren (buf_r_dbl_wr_en),
+ .s_dbl_wren (buf_s_dbl_wr_en),
+ .r_plus_s_wren (buf_r_plus_s_wr_en),
+
+ .u_half_wren (buf_u_half_wr_en),
+ .v_half_wren (buf_v_half_wr_en),
+ .u_minus_v_wren (buf_u_minus_v_wr_en),
+ .v_minus_u_wren (buf_v_minus_u_wr_en),
+ .u_minus_v_half_wren (buf_u_minus_v_half_wr_en),
+ .v_minus_u_half_wren (buf_v_minus_u_half_wr_en),
+
+ .u_minus_v_din (buf_u_minus_v_wr_dout),
+ .v_minus_u_din (buf_v_minus_u_wr_dout)
+ );
+
+
+ //
+ // Helper Module - Inversion Comparison
+ //
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_compare_u_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_compare_v_addr;
+
+ wire flag_invert_u_gt_v;
+ wire flag_invert_v_eq_1;
+ wire flag_invert_u_is_even;
+ wire flag_invert_v_is_even;
+
+ modinv_helper_invert_compare #
+ (
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_invert_compare
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_invert_compare_ena),
+ .rdy (helper_invert_compare_rdy),
+
+ .u_addr (helper_invert_compare_u_addr),
+ .v_addr (helper_invert_compare_v_addr),
+
+ .u_din (buf_u_rd_dout),
+ .v_din (buf_v_rd_dout),
+
+ .u_gt_v (flag_invert_u_gt_v),
+ .v_eq_1 (flag_invert_v_eq_1),
+ .u_is_even (flag_invert_u_is_even),
+ .v_is_even (flag_invert_v_is_even)
+ );
+
+
+ //
+ // Helper Module - Inversion Update
+ //
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_r_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_s_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_u_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_invert_update_v_addr;
+
+ wire helper_invert_update_r_wren;
+ wire helper_invert_update_s_wren;
+ wire helper_invert_update_u_wren;
+ wire helper_invert_update_v_wren;
+
+ wire [ 32-1:0] helper_invert_update_r_data;
+ wire [ 32-1:0] helper_invert_update_s_data;
+ wire [ 32-1:0] helper_invert_update_u_data;
+ wire [ 32-1:0] helper_invert_update_v_data;
+
+ modinv_helper_invert_update #
+ (
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_invert_update
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_invert_update_ena),
+ .rdy (helper_invert_update_rdy),
+
+ .u_gt_v (flag_invert_u_gt_v),
+ .v_eq_1 (flag_invert_v_eq_1),
+ .u_is_even (flag_invert_u_is_even),
+ .v_is_even (flag_invert_v_is_even),
+
+ .r_addr (helper_invert_update_r_addr),
+ .s_addr (helper_invert_update_s_addr),
+ .u_addr (helper_invert_update_u_addr),
+ .v_addr (helper_invert_update_v_addr),
+
+ .r_wren (helper_invert_update_r_wren),
+ .s_wren (helper_invert_update_s_wren),
+ .u_wren (helper_invert_update_u_wren),
+ .v_wren (helper_invert_update_v_wren),
+
+ .r_dout (helper_invert_update_r_data),
+ .s_dout (helper_invert_update_s_data),
+ .u_dout (helper_invert_update_u_data),
+ .v_dout (helper_invert_update_v_data),
+
+ .r_dbl_addr (buf_r_dbl_rd_addr),
+ .s_dbl_addr (buf_s_dbl_rd_addr),
+ .r_plus_s_addr (buf_r_plus_s_rd_addr),
+ .u_half_addr (buf_u_half_rd_addr),
+ .v_half_addr (buf_v_half_rd_addr),
+ .u_minus_v_half_addr (buf_u_minus_v_half_rd_addr),
+ .v_minus_u_half_addr (buf_v_minus_u_half_rd_addr),
+
+ .r_dbl_din (buf_r_dbl_rd_dout),
+ .s_dbl_din (buf_s_dbl_rd_dout),
+ .r_plus_s_din (buf_r_plus_s_rd_dout),
+ .u_half_din (buf_u_half_rd_dout),
+ .v_half_din (buf_v_half_rd_dout),
+ .u_minus_v_half_din (buf_u_minus_v_half_rd_dout),
+ .v_minus_u_half_din (buf_v_minus_u_half_rd_dout)
+ );
+
+
+ //
+ // Helper Module - Reduction Pre-Calculation
+ //
+ wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_r_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_s_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_u_addr;
+ wire [ BUFFER_ADDR_BITS-1:0] helper_reduce_precalc_v_addr;
+ wire [OPERAND_ADDR_BITS-1:0] helper_reduce_precalc_q_addr;
+
+ wire helper_reduce_precalc_r_wren;
+ wire helper_reduce_precalc_u_wren;
+ wire helper_reduce_precalc_v_wren;
+
+ wire [ 32-1:0] helper_reduce_precalc_r_data;
+ wire [ 32-1:0] helper_reduce_precalc_u_data;
+ wire [ 32-1:0] helper_reduce_precalc_v_data;
+
+ wire flag_reduce_s_is_odd;
+ wire flag_invert_k_is_nul;
+
+ modinv_helper_reduce_precalc #
+ (
+ .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
+ .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS),
+ .K_NUM_BITS (K_NUM_BITS)
+ )
+ helper_reduce_precalc
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_reduce_precalc_ena),
+ .rdy (helper_reduce_precalc_rdy),
+
+ .r_addr (helper_reduce_precalc_r_addr),
+ .s_addr (helper_reduce_precalc_s_addr),
+ .u_addr (helper_reduce_precalc_u_addr),
+ .v_addr (helper_reduce_precalc_v_addr),
+ .q_addr (helper_reduce_precalc_q_addr),
+
+ .k (k),
+
+ .s_is_odd (flag_reduce_s_is_odd),
+ .k_is_nul (flag_reduce_k_is_nul),
+
+ .r_din (buf_r_wr_dout),
+ .s_din (buf_s_rd_dout),
+ .q_din (q_din),
+
+ .r_wren (helper_reduce_precalc_r_wren),
+ .u_wren (helper_reduce_precalc_u_wren),
+ .v_wren (helper_reduce_precalc_v_wren),
+
+ .r_dout (helper_reduce_precalc_r_data),
+ .u_dout (helper_reduce_precalc_u_data),
+ .v_dout (helper_reduce_precalc_v_data)
+ );
+
+ //
+ // Helper Module - Reduction Update
+ //
+ wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_s_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_u_addr;
+ wire [BUFFER_ADDR_BITS-1:0] helper_reduce_update_v_addr;
+
+ wire helper_reduce_update_s_wren;
+
+ wire [ 32-1:0] helper_reduce_update_s_data;
+
+ modinv_helper_reduce_update #
+ (
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_reduce_update
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_reduce_update_ena),
+ .rdy (helper_reduce_update_rdy),
+
+ .s_is_odd (flag_reduce_s_is_odd),
+ .k_is_nul (flag_reduce_k_is_nul),
+
+ .s_addr (helper_reduce_update_s_addr),
+ .u_addr (helper_reduce_update_u_addr),
+ .v_addr (helper_reduce_update_v_addr),
+
+ .s_wren (helper_reduce_update_s_wren),
+
+ .s_dout (helper_reduce_update_s_data),
+
+ .u_din (buf_u_rd_dout),
+ .v_din (buf_v_rd_dout)
+ );
+
+
+ //
+ // Helper Module - Copying
+ //
+ wire [BUFFER_ADDR_BITS-1:0] helper_copy_s_addr;
+
+ modinv_helper_copy #
+ (
+ .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
+ .OPERAND_ADDR_BITS (OPERAND_ADDR_BITS),
+
+ .BUFFER_NUM_WORDS (BUFFER_NUM_WORDS),
+ .BUFFER_ADDR_BITS (BUFFER_ADDR_BITS)
+ )
+ helper_copy
+ (
+ .clk (clk),
+ .rst_n (rst_n),
+
+ .ena (helper_copy_ena),
+ .rdy (helper_copy_rdy),
+
+ .s_addr (helper_copy_s_addr),
+ .a1_addr (a1_addr),
+
+ .s_din (buf_s_rd_dout),
+
+ .a1_dout (a1_dout),
+
+ .a1_wren (a1_wren)
+ );
+
+
+ //
+ // Round Counter
+ //
+ reg [ROUND_COUNTER_BITS-1:0] round_counter;
+ wire [ROUND_COUNTER_BITS-1:0] round_counter_max = LOOP_NUM_ROUNDS - 1;
+ wire [ROUND_COUNTER_BITS-1:0] round_counter_zero = {ROUND_COUNTER_BITS{1'b0}};
+ wire [ROUND_COUNTER_BITS-1:0] round_counter_next =
+ (round_counter < round_counter_max) ? round_counter + 1'b1 : round_counter_zero;
+
+
+ //
+ // FSM
+ //
+ localparam FSM_STATE_IDLE = 4'd0;
+
+ localparam FSM_STATE_INIT = 4'd1;
+
+ localparam FSM_STATE_INVERT_PRECALC = 4'd11;
+ localparam FSM_STATE_INVERT_COMPARE = 4'd12;
+ localparam FSM_STATE_INVERT_UPDATE = 4'd13;
+
+ localparam FSM_STATE_REDUCE_PRECALC = 4'd14;
+ localparam FSM_STATE_REDUCE_UPDATE = 4'd15;
+
+ localparam FSM_STATE_COPY = 4'd2;
+
+ localparam FSM_STATE_DONE = 4'd3;
+
+ reg [3:0] fsm_state = FSM_STATE_IDLE;
+ reg [3:0] fsm_state_dly = FSM_STATE_IDLE;
+
+ wire fsm_state_new = (fsm_state != fsm_state_dly);
+
+ wire [3:0] fsm_state_invert_next = (round_counter < round_counter_max) ?
+ FSM_STATE_INVERT_PRECALC : FSM_STATE_REDUCE_PRECALC;
+
+ wire [3:0] fsm_state_reduce_next = (round_counter < round_counter_max) ?
+ FSM_STATE_REDUCE_PRECALC : FSM_STATE_COPY;
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0) fsm_state <= FSM_STATE_IDLE;
+ else case (fsm_state)
+ FSM_STATE_IDLE: fsm_state <= ena ? FSM_STATE_INIT : FSM_STATE_IDLE;
+ FSM_STATE_INIT: fsm_state <= helper_init_done ? FSM_STATE_INVERT_PRECALC : FSM_STATE_INIT;
+ FSM_STATE_INVERT_PRECALC: fsm_state <= helper_invert_precalc_done ? FSM_STATE_INVERT_COMPARE : FSM_STATE_INVERT_PRECALC;
+ FSM_STATE_INVERT_COMPARE: fsm_state <= helper_invert_compare_done ? FSM_STATE_INVERT_UPDATE : FSM_STATE_INVERT_COMPARE;
+ FSM_STATE_INVERT_UPDATE: fsm_state <= helper_invert_update_done ? fsm_state_invert_next : FSM_STATE_INVERT_UPDATE;
+ FSM_STATE_REDUCE_PRECALC: fsm_state <= helper_reduce_precalc_done ? FSM_STATE_REDUCE_UPDATE : FSM_STATE_REDUCE_PRECALC;
+ FSM_STATE_REDUCE_UPDATE: fsm_state <= helper_reduce_update_done ? fsm_state_reduce_next : FSM_STATE_REDUCE_UPDATE;
+ FSM_STATE_COPY: fsm_state <= helper_copy_done ? FSM_STATE_DONE : FSM_STATE_COPY;
+ FSM_STATE_DONE: fsm_state <= FSM_STATE_IDLE;
+ default: fsm_state <= FSM_STATE_IDLE;
+ endcase
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0) fsm_state_dly <= FSM_STATE_IDLE;
+ else fsm_state_dly <= fsm_state;
+
+
+ assign helper_init_ena = (fsm_state == FSM_STATE_INIT) && fsm_state_new;
+ assign helper_invert_precalc_ena = (fsm_state == FSM_STATE_INVERT_PRECALC) && fsm_state_new;
+ assign helper_invert_compare_ena = (fsm_state == FSM_STATE_INVERT_COMPARE) && fsm_state_new;
+ assign helper_invert_update_ena = (fsm_state == FSM_STATE_INVERT_UPDATE) && fsm_state_new;
+ assign helper_reduce_precalc_ena = (fsm_state == FSM_STATE_REDUCE_PRECALC) && fsm_state_new;
+ assign helper_reduce_update_ena = (fsm_state == FSM_STATE_REDUCE_UPDATE) && fsm_state_new;
+ assign helper_copy_ena = (fsm_state == FSM_STATE_COPY) && fsm_state_new;
+
+
+ //
+ // Counter Increment
+ //
+ always @(posedge clk) begin
+ //
+ if ((fsm_state == FSM_STATE_INIT) && helper_init_done)
+ round_counter <= round_counter_zero;
+ //
+ if ((fsm_state == FSM_STATE_INVERT_UPDATE) && helper_invert_update_done)
+ round_counter <= round_counter_next;
+ //
+ if ((fsm_state == FSM_STATE_REDUCE_UPDATE) && helper_reduce_update_done)
+ round_counter <= round_counter_next;
+ //
+ end
+
+
+ //
+ // Q Address Selector
+ //
+ always @(*) begin
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: q_addr = helper_init_q_addr;
+ FSM_STATE_REDUCE_PRECALC: q_addr = helper_reduce_precalc_q_addr;
+ default: q_addr = {OPERAND_ADDR_BITS{1'bX}};
+ endcase
+ //
+ end
+
+
+ //
+ // Buffer Address Selector
+ //
+ always @(*) begin
+ //
+ // Write Ports
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_r_wr_addr = helper_init_r_addr;
+ FSM_STATE_INVERT_UPDATE: buf_r_wr_addr = helper_invert_update_r_addr;
+ FSM_STATE_REDUCE_PRECALC: buf_r_wr_addr = helper_reduce_precalc_r_addr;
+ default: buf_r_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_s_wr_addr = helper_init_s_addr;
+ FSM_STATE_INVERT_UPDATE: buf_s_wr_addr = helper_invert_update_s_addr;
+ FSM_STATE_REDUCE_UPDATE: buf_s_wr_addr = helper_reduce_update_s_addr;
+ default: buf_s_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_u_wr_addr = helper_init_u_addr;
+ FSM_STATE_INVERT_UPDATE: buf_u_wr_addr = helper_invert_update_u_addr;
+ FSM_STATE_REDUCE_PRECALC: buf_u_wr_addr = helper_reduce_precalc_u_addr;
+ default: buf_u_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_v_wr_addr = helper_init_v_addr;
+ FSM_STATE_INVERT_UPDATE: buf_v_wr_addr = helper_invert_update_v_addr;
+ FSM_STATE_REDUCE_PRECALC: buf_v_wr_addr = helper_reduce_precalc_v_addr;
+ default: buf_v_wr_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ // Read Ports
+ //
+ case (fsm_state)
+ FSM_STATE_INVERT_PRECALC: buf_r_rd_addr = helper_invert_precalc_r_addr;
+ default: buf_r_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INVERT_PRECALC: buf_s_rd_addr = helper_invert_precalc_s_addr;
+ FSM_STATE_REDUCE_PRECALC: buf_s_rd_addr = helper_reduce_precalc_s_addr;
+ FSM_STATE_COPY: buf_s_rd_addr = helper_copy_s_addr;
+ default: buf_s_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INVERT_PRECALC: buf_u_rd_addr = helper_invert_precalc_u_addr;
+ FSM_STATE_INVERT_COMPARE: buf_u_rd_addr = helper_invert_compare_u_addr;
+ FSM_STATE_REDUCE_UPDATE: buf_u_rd_addr = helper_reduce_update_u_addr;
+ default: buf_u_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INVERT_PRECALC: buf_v_rd_addr = helper_invert_precalc_v_addr;
+ FSM_STATE_INVERT_COMPARE: buf_v_rd_addr = helper_invert_compare_v_addr;
+ FSM_STATE_REDUCE_UPDATE: buf_v_rd_addr = helper_reduce_update_v_addr;
+ default: buf_v_rd_addr = {BUFFER_ADDR_BITS{1'bX}};
+ endcase
+ //
+ end
+
+
+ //
+ // Buffer Write Enable Logic
+ //
+ always @(*) begin
+ //
+ // Write Ports
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_r_wr_en = helper_init_r_wren;
+ FSM_STATE_INVERT_UPDATE: buf_r_wr_en = helper_invert_update_r_wren;
+ FSM_STATE_REDUCE_PRECALC: buf_r_wr_en = helper_reduce_precalc_r_wren;
+ default: buf_r_wr_en = 1'b0;
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_s_wr_en = helper_init_s_wren;
+ FSM_STATE_INVERT_UPDATE: buf_s_wr_en = helper_invert_update_s_wren;
+ FSM_STATE_REDUCE_UPDATE: buf_s_wr_en = helper_reduce_update_s_wren;
+ default: buf_s_wr_en = 1'b0;
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_u_wr_en = helper_init_u_wren;
+ FSM_STATE_INVERT_UPDATE: buf_u_wr_en = helper_invert_update_u_wren;
+ FSM_STATE_REDUCE_PRECALC: buf_u_wr_en = helper_reduce_precalc_u_wren;
+ default: buf_u_wr_en = 1'b0;
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_v_wr_en = helper_init_v_wren;
+ FSM_STATE_INVERT_UPDATE: buf_v_wr_en = helper_invert_update_v_wren;
+ FSM_STATE_REDUCE_PRECALC: buf_v_wr_en = helper_reduce_precalc_v_wren;
+ default: buf_v_wr_en = 1'b0;
+ endcase
+ //
+ end
+
+
+ //
+ // Buffer Write Data Selector
+ //
+ always @(*) begin
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_r_wr_din = helper_init_r_data;
+ FSM_STATE_INVERT_UPDATE: buf_r_wr_din = helper_invert_update_r_data;
+ FSM_STATE_REDUCE_PRECALC: buf_r_wr_din = helper_reduce_precalc_r_data;
+ default: buf_r_wr_din = {32{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_s_wr_din = helper_init_s_data;
+ FSM_STATE_INVERT_UPDATE: buf_s_wr_din = helper_invert_update_s_data;
+ FSM_STATE_REDUCE_UPDATE: buf_s_wr_din = helper_reduce_update_s_data;
+ default: buf_s_wr_din = {32{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_u_wr_din = helper_init_u_data;
+ FSM_STATE_INVERT_UPDATE: buf_u_wr_din = helper_invert_update_u_data;
+ FSM_STATE_REDUCE_PRECALC: buf_u_wr_din = helper_reduce_precalc_u_data;
+ default: buf_u_wr_din = {32{1'bX}};
+ endcase
+ //
+ case (fsm_state)
+ FSM_STATE_INIT: buf_v_wr_din = helper_init_v_data;
+ FSM_STATE_INVERT_UPDATE: buf_v_wr_din = helper_invert_update_v_data;
+ FSM_STATE_REDUCE_PRECALC: buf_v_wr_din = helper_reduce_precalc_v_data;
+ default: buf_v_wr_din = {32{1'bX}};
+ endcase
+ //
+ end
+
+
+ //
+ // Ready Logic
+ //
+ reg rdy_reg = 1'b1;
+
+ assign rdy = rdy_reg;
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0) rdy_reg <= 1'b1;
+ else begin
+
+ /* clear */
+ if (rdy && ena) rdy_reg <= 1'b0;
+
+ /* set */
+ if (!rdy && (fsm_state == FSM_STATE_DONE)) rdy_reg <= 1'b1;
+
+ end
+
+
+ //
+ // Store Redundant Power of 2 (K)
+ //
+ always @(posedge clk)
+ //
+ if (helper_init_ena)
+ k <= {K_NUM_BITS{1'b0}};
+ else begin
+
+ if (helper_invert_update_ena && !flag_invert_v_eq_1)
+ k <= k + 1'b1;
+
+ if (helper_reduce_update_ena && (k != {K_NUM_BITS{1'b0}}))
+ k <= k - 1'b1;
+
+ end
+
+ endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/modular/modular_multiplier_256.v b/rtl/modular/modular_multiplier_256.v
deleted file mode 100644
index c2f2661..0000000
--- a/rtl/modular/modular_multiplier_256.v
+++ /dev/null
@@ -1,402 +0,0 @@
-//------------------------------------------------------------------------------
-//
-// modular_multiplier_256.v
-// -----------------------------------------------------------------------------
-// Modular multiplier.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2015-2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module modular_multiplier_256
- (
- clk, rst_n,
- ena, rdy,
- a_addr, b_addr, n_addr, p_addr, p_wren,
- a_din, b_din, n_din, p_dout
- );
-
-
- //
- // Constants
- //
- localparam OPERAND_NUM_WORDS = 8;
- localparam WORD_COUNTER_WIDTH = 3;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
- WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
- end
- endfunction
-
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_PREVIOUS_OR_LAST;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_PREVIOUS_OR_LAST = (WORD_INDEX_CURRENT > WORD_INDEX_ZERO) ?
- WORD_INDEX_CURRENT - 1'b1 : WORD_INDEX_LAST;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-1:0] a_addr; // index of current A word
- output wire [WORD_COUNTER_WIDTH-1:0] b_addr; // index of current B word
- output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
- output wire [WORD_COUNTER_WIDTH-1:0] p_addr; // index of current P word
- output wire p_wren; // store current P word now
-
- input wire [ 31:0] a_din; // A
- input wire [ 31:0] b_din; // B
- input wire [ 31:0] n_din; // N (must be P-256!)
- output wire [ 31:0] p_dout; // P = A * B mod N
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH-1:0] index_a;
- reg [WORD_COUNTER_WIDTH-1:0] index_b;
-
- /* map registers to output ports */
- assign a_addr = index_a;
- assign b_addr = index_b;
-
- //
- // FSM
- //
- localparam FSM_SHREG_WIDTH = (1 * OPERAND_NUM_WORDS + 1) + (2 * OPERAND_NUM_WORDS + 1) + (2 * OPERAND_NUM_WORDS + 2) + (0 * OPERAND_NUM_WORDS + 2) + 1;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [1 * OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_a = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
- wire [1 * OPERAND_NUM_WORDS-1:0] fsm_shreg_store_word_a = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
- wire [2 * OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_b = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 1)];
- wire [2 * OPERAND_NUM_WORDS-2:0] fsm_shreg_store_si_msb = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 1)];
- wire [0 * OPERAND_NUM_WORDS-0:0] fsm_shreg_store_si_lsb = fsm_shreg[FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 2)];
- wire [2 * OPERAND_NUM_WORDS-2:0] fsm_shreg_shift_si = fsm_shreg[FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 1)];
- wire [0 * OPERAND_NUM_WORDS-0:0] fsm_shreg_mask_cw1_sum = fsm_shreg[FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 4)];
- wire [2 * OPERAND_NUM_WORDS-1:0] fsm_shreg_store_c_word = fsm_shreg[FSM_SHREG_WIDTH - (3 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 4)];
- wire [0 * OPERAND_NUM_WORDS-0:0] fsm_shreg_reduce_start = fsm_shreg[FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 5)];
- wire [0 * OPERAND_NUM_WORDS-0:0] fsm_shreg_reduce_stop = fsm_shreg[FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 6) : FSM_SHREG_WIDTH - (5 * OPERAND_NUM_WORDS + 6)];
-
- wire inc_index_a = |fsm_shreg_inc_index_a;
- wire store_word_a = |fsm_shreg_store_word_a;
- wire inc_index_b = |fsm_shreg_inc_index_b;
- wire clear_mac_ab = |fsm_shreg_inc_index_b;
- wire shift_wide_a = |fsm_shreg_inc_index_b;
- wire enable_mac_ab = |fsm_shreg_inc_index_b;
- wire store_si_msb = |fsm_shreg_store_si_msb;
- wire store_si_lsb = fsm_shreg_store_si_lsb;
- wire shift_si = |fsm_shreg_shift_si;
- wire mask_cw1_sum = fsm_shreg_mask_cw1_sum;
- wire store_c_word = |fsm_shreg_store_c_word;
- wire reduce_start = fsm_shreg_reduce_start;
- wire reduce_stop = fsm_shreg_reduce_stop;
-
-
- //
- // FSM Logic
- //
- wire reduce_done;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy)
- fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else if (!reduce_stop || reduce_done)
- fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- reg index_b_ff;
-
- always @(posedge clk)
- //
- if (inc_index_b) index_b_ff <= ~index_b_ff;
- else index_b_ff <= 1'b0;
-
- always @(posedge clk)
- //
- if (rdy) begin
- //
- index_a <= WORD_INDEX_ZERO;
- index_b <= WORD_INDEX_LAST;
- //
- end else begin
- //
- if (inc_index_a) index_a <= WORD_INDEX_NEXT_OR_ZERO(index_a);
- if (inc_index_b && !index_b_ff) index_b <= WORD_INDEX_PREVIOUS_OR_LAST(index_b);
- //
- end
-
-
- //
- // Wide Operand Buffer
- //
- reg [255:0] buf_a_wide;
-
- always @(posedge clk)
- //
- if (store_word_a)
- buf_a_wide <= {buf_a_wide[16 +: 256 - 3 * 16], {a_din[15:0], a_din[31:16]}, buf_a_wide[256 - 2 * 16 +: 16]};
- else if (shift_wide_a)
- buf_a_wide <= {buf_a_wide[256-(16+1):0], buf_a_wide[256-16+:16]};
-
-
- //
- // Multiplier Array
- //
- wire mac_inhibit; // control signal to pause all accumulators
-
- wire [46: 0] mac[0:15]; // outputs of all accumulators
- reg [15: 0] mac_clear; // individual per-accumulator clear flag
-
- assign mac_inhibit = ~enable_mac_ab;
-
- always @(posedge clk)
- //
- if (!clear_mac_ab)
- mac_clear <= {16{1'b1}};
- else begin
-
- if (mac_clear == {16{1'b1}})
- mac_clear <= {{14{1'b0}}, 1'b1, {1{1'b0}}};
- else
- mac_clear <= (mac_clear[15] == 1'b0) ? {mac_clear[14:0], 1'b0} : {16{1'b1}};
-
-
- end
-
- //
- // Array of parallel multipliers
- //
- genvar i;
- generate for (i=0; i<16; i=i+1)
- begin : gen_mac_array
- //
- mac16_wrapper mac16_inst
- (
- .clk (clk),
- .ce (~mac_inhibit),
-
- .clr (mac_clear[i]),
-
- .a (buf_a_wide[16*i+:16]),
- .b (index_b_ff ? b_din[15:0] : b_din[31:16]),
- .s (mac[i])
- );
- //
- end
- endgenerate
-
- //
- // Intermediate Words
- //
- reg [47*(2*OPERAND_NUM_WORDS-1)-1:0] si_msb;
- reg [47*(2*OPERAND_NUM_WORDS-0)-1:0] si_lsb;
-
-
- wire [47*(2*OPERAND_NUM_WORDS-1)-1:0] si_msb_new;
- wire [47*(2*OPERAND_NUM_WORDS-0)-1:0] si_lsb_new;
-
- generate for (i=0; i<16; i=i+1)
- begin : gen_si_lsb_new
- assign si_lsb_new[47*i+:47] = mac[15-i];
- end
- endgenerate
-
- generate for (i=1; i<16; i=i+1)
- begin : gen_si_msb_new
- assign si_msb_new[47*(15-i)+:47] = mac_clear[i] ? mac[i] : si_msb[47*(15-i)+:47];
- end
- endgenerate
-
- always @(posedge clk) begin
- //
- if (shift_si) begin
- si_msb <= {{2*47{1'b0}}, si_msb[15*47-1:2*47]};
- si_lsb <= {si_msb[2*47-1:0], si_lsb[16*47-1:2*47]};
- end else begin
-
- if (store_si_msb)
- si_msb <= si_msb_new;
-
- if (store_si_lsb)
- si_lsb <= si_lsb_new;
- end
-
- end
-
-
- //
- // Accumulators
- //
- wire [46: 0] add47_cw0_s;
- wire [46: 0] add47_cw1_s;
-
-
- //
- // cw0, b, cw1, b
- //
- reg [30: 0] si_prev_dly;
- reg [15: 0] si_next_dly;
-
- always @(posedge clk)
- //
- if (shift_si)
- si_prev_dly <= si_lsb[93:63];
- else
- si_prev_dly <= {31{1'b0}};
-
- always @(posedge clk)
- //
- si_next_dly <= si_lsb[62:47];
-
- wire [46: 0] add47_cw0_a = si_lsb[46:0];
- wire [46: 0] add47_cw0_b = {{16{1'b0}}, si_prev_dly};
-
- wire [46: 0] add47_cw1_a = add47_cw0_s;
- wire [46: 0] add47_cw1_b = {{15{1'b0}}, si_next_dly, mask_cw1_sum ? {16{1'b0}} : {1'b0, add47_cw1_s[46:32]}};
-
- adder47_wrapper add47_cw0_inst
- (
- .clk (clk),
- .a (add47_cw0_a),
- .b (add47_cw0_b),
- .s (add47_cw0_s)
- );
-
- adder47_wrapper add47_cw1_inst
- (
- .clk (clk),
- .a (add47_cw1_a),
- .b (add47_cw1_b),
- .s (add47_cw1_s)
- );
-
-
-
- //
- // Full-Size Product
- //
- reg [WORD_COUNTER_WIDTH:0] bram_c_addr;
-
- wire [WORD_COUNTER_WIDTH:0] reduce_c_addr;
- wire [ 31:0] reduce_c_word;
-
- always @(posedge clk)
- //
- if (store_c_word)
- bram_c_addr <= bram_c_addr + 1'b1;
- else
- bram_c_addr <= {2*WORD_COUNTER_WIDTH{1'b0}};
-
- bram_1rw_1ro_readfirst #
- (
- .MEM_WIDTH (32),
- .MEM_ADDR_BITS (WORD_COUNTER_WIDTH + 1)
- )
- bram_c_inst
- (
- .clk (clk),
-
- .a_addr (bram_c_addr),
- .a_wr (store_c_word),
- .a_in (add47_cw1_s[31:0]),
- .a_out (),
-
- .b_addr (reduce_c_addr),
- .b_out (reduce_c_word)
- );
-
-
- //
- // Reduction Stage
- //
- modular_reductor_256 reduce_256_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (reduce_start),
- .rdy (reduce_done),
-
- .x_addr (reduce_c_addr),
- .n_addr (n_addr),
- .p_addr (p_addr),
- .p_wren (p_wren),
-
- .x_din (reduce_c_word),
- .n_din (n_din),
- .p_dout (p_dout)
- );
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
diff --git a/rtl/modular/modular_reductor_256.v b/rtl/modular/modular_reductor_256.v
deleted file mode 100644
index e4b346a..0000000
--- a/rtl/modular/modular_reductor_256.v
+++ /dev/null
@@ -1,692 +0,0 @@
-//------------------------------------------------------------------------------
-//
-// modular_reductor_256.v
-// -----------------------------------------------------------------------------
-// Modular reductor.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2015-2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module modular_reductor_256
- (
- clk, rst_n,
- ena, rdy,
- x_addr, n_addr, p_addr, p_wren,
- x_din, n_din, p_dout
- );
-
- //
- // Constants
- //
- localparam OPERAND_NUM_WORDS = 8;
- localparam WORD_COUNTER_WIDTH = 3;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH:0] WORD_INDEX_LAST = 2 * OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH:0] WORD_INDEX_PREVIOUS_OR_LAST;
- input [WORD_COUNTER_WIDTH:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_PREVIOUS_OR_LAST = (WORD_INDEX_CURRENT > WORD_INDEX_ZERO) ?
- WORD_INDEX_CURRENT - 1'b1 : WORD_INDEX_LAST;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-0:0] x_addr; // index of current X word
- output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
- output wire [WORD_COUNTER_WIDTH-1:0] p_addr; // index of current P word
- output wire p_wren; // store current P word now
-
- input wire [ 31:0] x_din; // X
- input wire [ 31:0] n_din; // N (must be P-256!)
- output wire [ 31:0] p_dout; // P = X mod N
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH:0] index_x;
-
-
- /* map registers to output ports */
- assign x_addr = index_x;
-
-
- //
- // FSM
- //
- localparam FSM_SHREG_WIDTH = (2 * OPERAND_NUM_WORDS + 1) + (5 * 2) + 1;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [2 * OPERAND_NUM_WORDS - 1:0] fsm_shreg_inc_index_x = fsm_shreg[FSM_SHREG_WIDTH - 0*OPERAND_NUM_WORDS - 1 -: 2 * OPERAND_NUM_WORDS];
- wire [2 * OPERAND_NUM_WORDS - 1:0] fsm_shreg_store_word_z = fsm_shreg[FSM_SHREG_WIDTH - 0*OPERAND_NUM_WORDS - 2 -: 2 * OPERAND_NUM_WORDS];
- wire [2 * 5 - 1:0] fsm_shreg_reduce_stages = fsm_shreg[ 1 +: 2 * 5];
-
- wire [5-1:0] fsm_shreg_reduce_stage_start;
- wire [5-1:0] fsm_shreg_reduce_stage_stop;
-
- genvar s;
- generate for (s=0; s<5; s=s+1)
- begin : gen_fsm_shreg_reduce_stages
- assign fsm_shreg_reduce_stage_start[5 - (s + 1)] = fsm_shreg_reduce_stages[2 * (5 - s) - 1];
- assign fsm_shreg_reduce_stage_stop[5 - (s + 1)] = fsm_shreg_reduce_stages[2 * (5 - s) - 2];
- end
- endgenerate
-
- wire inc_index_x = |fsm_shreg_inc_index_x;
- wire store_word_z = |fsm_shreg_store_word_z;
- wire reduce_start = |fsm_shreg_reduce_stage_start;
- wire reduce_stop = |fsm_shreg_reduce_stage_stop;
- wire store_p = fsm_shreg_reduce_stage_stop[0];
-
-
- wire reduce_adder0_done;
- wire reduce_adder1_done;
- wire reduce_subtractor_done;
-
- wire reduce_done_all = reduce_adder0_done & reduce_adder1_done & reduce_subtractor_done;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy)
- //
- fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else if (!reduce_stop || reduce_done_all)
- //
- fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- always @(posedge clk)
- //
- if (rdy)
- //
- index_x <= WORD_INDEX_LAST;
- //
- else if (inc_index_x)
- //
- index_x <= WORD_INDEX_PREVIOUS_OR_LAST(index_x);
-
-
- //
- // Look-up Table
- //
-
- //
- // Take a look at the corresponding C model for more information
- // on how exactly the math behind reduction works. The first step
- // is to assemble nine 256-bit values ("z-words") from 32-bit parts
- // of the full 512-bit product ("c-word"). The problem with z5 is
- // that it contains c13 two times. This implementation scans from
- // c15 to c0 and writes current part of c-word into corresponding
- // parts of z-words. Since those 32-bit parts are stored in block
- // memories, one source word can only be written to one location in
- // every z-word at a time. The trick is to delay c13 and then write
- // the delayed value at the corresponding location in z5 instead of
- // the next c12. "z_save" flag is used to indicate that the current
- // word should be delayed and written once again during the next cycle.
- //
-
- reg [9*WORD_COUNTER_WIDTH-1:0] z_addr; //
- reg [9 -1:0] z_wren; //
- reg [9 -1:0] z_mask; // mask input to store zero word
- reg [9 -1:0] z_save; // save previous word once again
-
- always @(posedge clk)
- //
- if (inc_index_x)
- //
- case (index_x)
- //
- // s9 s8 s7 s6 s5 s4 s3 s2 s1
- // || || || || || || || || ||
- 4'd00: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd00};
- 4'd01: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd01};
- 4'd02: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd02};
- 4'd03: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd03};
- 4'd04: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd04};
- 4'd05: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd05};
- 4'd06: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd06};
- 4'd07: z_addr <= {3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'dxx, 3'd07};
- 4'd08: z_addr <= {3'd02, 3'd03, 3'd04, 3'd06, 3'd07, 3'd00, 3'd00, 3'd00, 3'dxx};
- 4'd09: z_addr <= {3'd03, 3'd04, 3'd06, 3'd03, 3'd00, 3'd01, 3'd01, 3'd01, 3'dxx};
- 4'd10: z_addr <= {3'd04, 3'd05, 3'd05, 3'd07, 3'd01, 3'd02, 3'd02, 3'd02, 3'dxx};
- 4'd11: z_addr <= {3'd05, 3'd06, 3'd07, 3'd00, 3'd02, 3'd03, 3'd07, 3'd03, 3'dxx};
- 4'd12: z_addr <= {3'd06, 3'd07, 3'd00, 3'd01, 3'd06, 3'd04, 3'd03, 3'd04, 3'dxx};
- 4'd13: z_addr <= {3'd07, 3'd00, 3'd01, 3'd02, 3'd03, 3'd05, 3'd04, 3'd05, 3'dxx};
- 4'd14: z_addr <= {3'd00, 3'd01, 3'd02, 3'd04, 3'd04, 3'd06, 3'd05, 3'd06, 3'dxx};
- 4'd15: z_addr <= {3'd01, 3'd02, 3'd03, 3'd05, 3'd05, 3'd07, 3'd06, 3'd07, 3'dxx};
- //
- default: z_addr <= {9*WORD_COUNTER_WIDTH{1'bX}};
- //
- endcase
-
- always @(posedge clk)
- //
- case (index_x)
- //
- // 9 8 7 6 5 4 3 2 1
- // | | | | | | | | |
- 4'd00: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd01: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd02: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd03: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd04: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd05: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd06: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd07: z_wren <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1};
- 4'd08: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd09: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd10: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd11: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd12: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd13: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd14: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- 4'd15: z_wren <= {1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b1, 1'b0};
- //
- default: z_wren <= {9{1'b0}};
- //
- endcase
-
- always @(posedge clk)
- //
- if (inc_index_x)
- //
- case (index_x)
- //
- // 9 8 7 6 5 4 3 2 1
- // | | | | | | | | |
- 4'd00: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd01: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd02: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd03: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd04: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd05: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd06: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd07: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd08: z_mask <= {1'b1, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b1, 1'b1, 1'b0};
- 4'd09: z_mask <= {1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b1, 1'b1, 1'b0};
- 4'd10: z_mask <= {1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b1, 1'b1, 1'b0};
- 4'd11: z_mask <= {1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b1, 1'b1, 1'b0, 1'b0};
- 4'd12: z_mask <= {1'b1, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0};
- 4'd13: z_mask <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0};
- 4'd14: z_mask <= {1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd15: z_mask <= {1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- //
- default: z_mask <= {9{1'bX}};
- //
- endcase
-
- always @(posedge clk)
- //
- if (inc_index_x)
- //
- case (index_x)
- //
- // 9 8 7 6 5 4 3 2 1
- // | | | | | | | | |
- 4'd00: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd01: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd02: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd03: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd04: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd05: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd06: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd07: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd08: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd09: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd10: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd11: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd12: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b1, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd13: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd14: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- 4'd15: z_save <= {1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0, 1'b0};
- //
- default: z_save <= {9{1'bX}};
- //
- endcase
-
-
- //
- // Intermediate Numbers
- //
- reg [WORD_COUNTER_WIDTH-1:0] reduce_z_addr[1:9];
- wire [ 32-1:0] reduce_z_dout[1:9];
-
- reg [31: 0] x_din_dly;
- always @(posedge clk)
- //
- x_din_dly <= x_din;
-
-
- genvar z;
- generate for (z=1; z<=9; z=z+1)
- //
- begin : gen_z_bram
- //
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH))
- bram_c_inst
- (
- .clk (clk),
-
- .a_addr (z_addr[(z-1) * WORD_COUNTER_WIDTH +: WORD_COUNTER_WIDTH]),
- .a_wr (z_wren[z-1] & store_word_z),
- .a_in (z_mask[z-1] ? {32{1'b0}} : (z_save[z-1] ? x_din_dly : x_din)),
- .a_out (),
-
- .b_addr (reduce_z_addr[z]),
- .b_out (reduce_z_dout[z])
- );
- //
- end
- //
- endgenerate
-
-
-
-
- wire [ 32-1:0] bram_sum0_wr_din;
- wire [WORD_COUNTER_WIDTH-1:0] bram_sum0_wr_addr;
- wire bram_sum0_wr_wren;
-
- wire [ 32-1:0] bram_sum1_wr_din;
- wire [WORD_COUNTER_WIDTH-1:0] bram_sum1_wr_addr;
- wire bram_sum1_wr_wren;
-
- wire [ 32-1:0] bram_diff_wr_din;
- wire [WORD_COUNTER_WIDTH-1:0] bram_diff_wr_addr;
- wire bram_diff_wr_wren;
-
- wire [ 32-1:0] bram_sum0_rd_dout;
- reg [WORD_COUNTER_WIDTH-1:0] bram_sum0_rd_addr;
-
- wire [ 32-1:0] bram_sum1_rd_dout;
- reg [WORD_COUNTER_WIDTH-1:0] bram_sum1_rd_addr;
-
- wire [ 32-1:0] bram_diff_rd_dout;
- reg [WORD_COUNTER_WIDTH-1:0] bram_diff_rd_addr;
-
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH))
- bram_sum0_inst
- (
- .clk (clk),
-
- .a_addr (bram_sum0_wr_addr),
- .a_wr (bram_sum0_wr_wren),
- .a_in (bram_sum0_wr_din),
- .a_out (),
-
- .b_addr (bram_sum0_rd_addr),
- .b_out (bram_sum0_rd_dout)
- );
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH))
- bram_sum1_inst
- (
- .clk (clk),
-
- .a_addr (bram_sum1_wr_addr),
- .a_wr (bram_sum1_wr_wren),
- .a_in (bram_sum1_wr_din),
- .a_out (),
-
- .b_addr (bram_sum1_rd_addr),
- .b_out (bram_sum1_rd_dout)
- );
-
- bram_1rw_1ro_readfirst # (.MEM_WIDTH(32), .MEM_ADDR_BITS(WORD_COUNTER_WIDTH))
- bram_diff_inst
- (
- .clk (clk),
-
- .a_addr (bram_diff_wr_addr),
- .a_wr (bram_diff_wr_wren),
- .a_in (bram_diff_wr_din),
- .a_out (),
-
- .b_addr (bram_diff_rd_addr),
- .b_out (bram_diff_rd_dout)
- );
-
-
- wire [WORD_COUNTER_WIDTH-1:0] adder0_ab_addr;
- wire [WORD_COUNTER_WIDTH-1:0] adder1_ab_addr;
- wire [WORD_COUNTER_WIDTH-1:0] subtractor_ab_addr;
-
- reg [ 32-1:0] adder0_a_din;
- reg [ 32-1:0] adder0_b_din;
-
- reg [ 32-1:0] adder1_a_din;
- reg [ 32-1:0] adder1_b_din;
-
- reg [ 32-1:0] subtractor_a_din;
- reg [ 32-1:0] subtractor_b_din;
-
- // n_addr - only 1 output, because all modules are in sync
-
- modular_adder #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH)
- )
- adder_inst0
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (reduce_start),
- .rdy (reduce_adder0_done),
-
- .ab_addr (adder0_ab_addr),
- .n_addr (),
- .s_addr (bram_sum0_wr_addr),
- .s_wren (bram_sum0_wr_wren),
-
- .a_din (adder0_a_din),
- .b_din (adder0_b_din),
- .n_din (n_din),
- .s_dout (bram_sum0_wr_din)
- );
-
- modular_adder #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH)
- )
- adder_inst1
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (reduce_start),
- .rdy (reduce_adder1_done),
-
- .ab_addr (adder1_ab_addr),
- .n_addr (),
- .s_addr (bram_sum1_wr_addr),
- .s_wren (bram_sum1_wr_wren),
-
- .a_din (adder1_a_din),
- .b_din (adder1_b_din),
- .n_din (n_din),
- .s_dout (bram_sum1_wr_din)
- );
-
- modular_subtractor #
- (
- .OPERAND_NUM_WORDS (OPERAND_NUM_WORDS),
- .WORD_COUNTER_WIDTH (WORD_COUNTER_WIDTH)
- )
- subtractor_inst
- (
- .clk (clk),
- .rst_n (rst_n),
-
- .ena (reduce_start),
- .rdy (reduce_subtractor_done),
-
- .ab_addr (subtractor_ab_addr),
- .n_addr (n_addr),
- .d_addr (bram_diff_wr_addr),
- .d_wren (bram_diff_wr_wren),
-
- .a_din (subtractor_a_din),
- .b_din (subtractor_b_din),
- .n_din (n_din),
- .d_dout (bram_diff_wr_din)
- );
-
-
- //
- // Address (Operand) Selector
- //
- always @(*)
- //
- case (fsm_shreg_reduce_stage_stop)
- //
- 5'b10000: begin
- reduce_z_addr[1] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[2] = adder0_ab_addr;
- reduce_z_addr[3] = adder1_ab_addr;
- reduce_z_addr[4] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[5] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[6] = subtractor_ab_addr;
- reduce_z_addr[7] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[8] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[9] = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum0_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum1_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- bram_diff_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- 5'b01000: begin
- reduce_z_addr[1] = adder0_ab_addr;
- reduce_z_addr[2] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[3] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[4] = adder1_ab_addr;
- reduce_z_addr[5] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[6] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[7] = subtractor_ab_addr;
- reduce_z_addr[8] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[9] = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum0_rd_addr = adder0_ab_addr;
- bram_sum1_rd_addr = adder1_ab_addr;
- bram_diff_rd_addr = subtractor_ab_addr;
- end
- //
- 5'b00100: begin
- reduce_z_addr[1] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[2] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[3] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[4] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[5] = adder0_ab_addr;
- reduce_z_addr[6] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[7] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[8] = subtractor_ab_addr;
- reduce_z_addr[9] = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum0_rd_addr = adder0_ab_addr;
- bram_sum1_rd_addr = adder1_ab_addr;
- bram_diff_rd_addr = subtractor_ab_addr;
- end
- //
- 5'b00010: begin
- reduce_z_addr[1] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[2] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[3] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[4] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[5] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[6] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[7] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[8] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[9] = subtractor_ab_addr;
- bram_sum0_rd_addr = adder0_ab_addr;
- bram_sum1_rd_addr = adder0_ab_addr;
- bram_diff_rd_addr = subtractor_ab_addr;
- end
- //
- 5'b00001: begin
- reduce_z_addr[1] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[2] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[3] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[4] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[5] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[6] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[7] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[8] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[9] = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum0_rd_addr = adder0_ab_addr;
- bram_sum1_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- bram_diff_rd_addr = adder0_ab_addr;
- end
- //
- default: begin
- reduce_z_addr[1] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[2] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[3] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[4] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[5] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[6] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[7] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[8] = {WORD_COUNTER_WIDTH{1'bX}};
- reduce_z_addr[9] = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum0_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- bram_sum1_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- bram_diff_rd_addr = {WORD_COUNTER_WIDTH{1'bX}};
- end
- //
- endcase
-
-
- //
- // adder 0
- //
- always @(*) begin
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: adder0_a_din = reduce_z_dout[2];
- 5'b01000: adder0_a_din = bram_sum0_rd_dout;
- 5'b00100: adder0_a_din = bram_sum0_rd_dout;
- 5'b00010: adder0_a_din = bram_sum0_rd_dout;
- 5'b00001: adder0_a_din = bram_sum0_rd_dout;
- default: adder0_a_din = {32{1'bX}};
- endcase
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: adder0_b_din = reduce_z_dout[2];
- 5'b01000: adder0_b_din = reduce_z_dout[1];
- 5'b00100: adder0_b_din = reduce_z_dout[5];
- 5'b00010: adder0_b_din = bram_sum1_rd_dout;
- 5'b00001: adder0_b_din = bram_diff_rd_dout;
- default: adder0_b_din = {32{1'bX}};
- endcase
- //
- end
-
- //
- // adder 1
- //
- always @(*) begin
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: adder1_a_din = reduce_z_dout[3];
- 5'b01000: adder1_a_din = bram_sum1_rd_dout;
- 5'b00100: adder1_a_din = bram_sum1_rd_dout;
- 5'b00010: adder1_a_din = {32{1'bX}};
- 5'b00001: adder1_a_din = {32{1'bX}};
- default: adder1_a_din = {32{1'bX}};
- endcase
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: adder1_b_din = reduce_z_dout[3];
- 5'b01000: adder1_b_din = reduce_z_dout[4];
- 5'b00100: adder1_b_din = {32{1'b0}};
- 5'b00010: adder1_b_din = {32{1'bX}};
- 5'b00001: adder1_b_din = {32{1'bX}};
- default: adder1_b_din = {32{1'bX}};
- endcase
- //
- end
-
-
- //
- // subtractor
- //
- always @(*) begin
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: subtractor_a_din = {32{1'b0}};
- 5'b01000: subtractor_a_din = bram_diff_rd_dout;
- 5'b00100: subtractor_a_din = bram_diff_rd_dout;
- 5'b00010: subtractor_a_din = bram_diff_rd_dout;
- 5'b00001: subtractor_a_din = {32{1'bX}};
- default: subtractor_a_din = {32{1'bX}};
- endcase
- //
- case (fsm_shreg_reduce_stage_stop)
- 5'b10000: subtractor_b_din = reduce_z_dout[6];
- 5'b01000: subtractor_b_din = reduce_z_dout[7];
- 5'b00100: subtractor_b_din = reduce_z_dout[8];
- 5'b00010: subtractor_b_din = reduce_z_dout[9];
- 5'b00001: subtractor_b_din = {32{1'bX}};
- default: subtractor_b_din = {32{1'bX}};
- endcase
- //
- end
-
-
- //
- // Address Mapping
- //
- assign p_addr = bram_sum0_wr_addr;
- assign p_wren = bram_sum0_wr_wren & store_p;
- assign p_dout = bram_sum0_wr_din;
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
diff --git a/rtl/modular/modular_subtractor.v b/rtl/modular/modular_subtractor.v
index 322aec4..1637f45 100644
--- a/rtl/modular/modular_subtractor.v
+++ b/rtl/modular/modular_subtractor.v
@@ -2,7 +2,7 @@
//
// modular_subtractor.v
// -----------------------------------------------------------------------------
-// Modular subtractor.
+// Modular subtractor.
//
// Authors: Pavel Shatov
//
@@ -34,259 +34,259 @@
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
-//------------------------------------------------------------------------------
-
-module modular_subtractor
- (
- clk, rst_n,
- ena, rdy,
- ab_addr, n_addr, d_addr, d_wren,
- a_din, b_din, n_din, d_dout
- );
-
-
- //
- // Parameters
- //
- parameter OPERAND_NUM_WORDS = 8;
- parameter WORD_COUNTER_WIDTH = 3;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
- WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-1:0] ab_addr; // index of current A and B words
- output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
- output wire [WORD_COUNTER_WIDTH-1:0] d_addr; // index of current D word
- output wire d_wren; // store current D word now
-
- input wire [ 31:0] a_din; // A
- input wire [ 31:0] b_din; // B
- input wire [ 31:0] n_din; // N
- output wire [ 31:0] d_dout; // D = (A - B) mod N
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH-1:0] index_ab;
- reg [WORD_COUNTER_WIDTH-1:0] index_n;
- reg [WORD_COUNTER_WIDTH-1:0] index_d;
-
- /* map registers to output ports */
- assign ab_addr = index_ab;
- assign n_addr = index_n;
- assign d_addr = index_d;
-
-
- //
- // Subtractor
- //
- wire [31: 0] sub32_d;
- wire sub32_b_in;
- wire sub32_b_out;
-
- subtractor32_wrapper subtractor32
- (
- .clk (clk),
- .a (a_din),
- .b (b_din),
- .d (sub32_d),
- .b_in (sub32_b_in),
- .b_out (sub32_b_out)
- );
-
-
- //
- // Adder
- //
- wire [31: 0] add32_s;
- wire add32_c_in;
- wire add32_c_out;
-
- adder32_wrapper adder32
- (
- .clk (clk),
- .a (sub32_d),
- .b (n_din),
- .s (add32_s),
- .c_in (add32_c_in),
- .c_out (add32_c_out)
- );
-
-
- //
- // FSM
- //
-
- localparam FSM_SHREG_WIDTH = 2*OPERAND_NUM_WORDS + 5;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_dif_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_dif_ab_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_data_d = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 3)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_d = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 4)];
-
- wire fsm_latch_msb_borrow = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
-
- wire inc_index_ab = |fsm_shreg_inc_index_ab;
- wire inc_index_n = |fsm_shreg_inc_index_n;
- wire store_dif_ab = |fsm_shreg_store_dif_ab;
- wire store_dif_ab_n = |fsm_shreg_store_dif_ab_n;
- wire store_data_d = |fsm_shreg_store_data_d;
- wire inc_index_d = |fsm_shreg_inc_index_d;
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
- //
- // Borrow & Carry Masking Logic
- //
- reg sub32_b_mask;
- reg add32_c_mask;
-
-
- always @(posedge clk) begin
- //
- sub32_b_mask <= (index_ab == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
- add32_c_mask <= (index_n == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
- //
- end
-
- assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
- assign add32_c_in = add32_c_out & ~add32_c_mask;
-
-
-
- //
- // Borrow & Carry Latch Logic
- //
- reg sub32_borrow_latch;
-
- always @(posedge clk) begin
- //
- if (fsm_latch_msb_borrow) sub32_borrow_latch <= sub32_b_out;
- //
- end
-
-
- //
- // Intermediate Results
- //
- reg [32*OPERAND_NUM_WORDS-1:0] d_ab;
- reg [32*OPERAND_NUM_WORDS-1:0] d_ab_n;
-
- always @(posedge clk)
- //
- if (store_data_d) begin
- //
- d_ab <= {{32{1'bX}}, d_ab[32*OPERAND_NUM_WORDS-1:32]};
- d_ab_n <= {{32{1'bX}}, d_ab_n[32*OPERAND_NUM_WORDS-1:32]};
- //
- end else begin
- //
- if (store_dif_ab) d_ab <= {sub32_d, d_ab[32*OPERAND_NUM_WORDS-1:32]};
- if (store_dif_ab_n) d_ab_n <= {add32_s, d_ab_n[32*OPERAND_NUM_WORDS-1:32]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- always @(posedge clk)
- //
- if (rdy) begin
- //
- index_ab <= WORD_INDEX_ZERO;
- index_n <= WORD_INDEX_ZERO;
- index_d <= WORD_INDEX_ZERO;
- //
- end else begin
- //
- if (inc_index_ab) index_ab <= WORD_INDEX_NEXT_OR_ZERO(index_ab);
- if (inc_index_n) index_n <= WORD_INDEX_NEXT_OR_ZERO(index_n);
- if (inc_index_d) index_d <= WORD_INDEX_NEXT_OR_ZERO(index_d);
- //
- end
-
-
- //
- // Output Sum Selector
- //
- wire mux_select_ab_n = sub32_borrow_latch;
-
-
- //
- // Output Data and Write Enable Logic
- //
- reg d_wren_reg;
- reg [31: 0] d_dout_reg;
- wire [31: 0] d_dout_mux = mux_select_ab_n ? d_ab_n[31:0] : d_ab[31:0];
-
- assign d_wren = d_wren_reg;
- assign d_dout = d_dout_reg;
-
- always @(posedge clk)
- //
- if (rdy) begin
- //
- d_wren_reg <= 1'b0;
- d_dout_reg <= {32{1'bX}};
- //
- end else begin
- //
- d_wren_reg <= store_data_d;
- d_dout_reg <= store_data_d ? d_dout_mux : {32{1'bX}};
- //
- end
-
-
-endmodule
-
-
+//------------------------------------------------------------------------------
+
+module modular_subtractor
+ (
+ clk, rst_n,
+ ena, rdy,
+ ab_addr, n_addr, d_addr, d_wren,
+ a_din, b_din, n_din, d_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter OPERAND_NUM_WORDS = 8;
+ parameter WORD_COUNTER_WIDTH = 3;
+
+
+ //
+ // Handy Numbers
+ //
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
+
+
+ //
+ // Handy Functions
+ //
+ function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
+ input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
+ begin
+ WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
+ WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
+ end
+ endfunction
+
+
+ //
+ // Ports
+ //
+ input wire clk; // system clock
+ input wire rst_n; // active-low async reset
+
+ input wire ena; // enable input
+ output wire rdy; // ready output
+
+ output wire [WORD_COUNTER_WIDTH-1:0] ab_addr; // index of current A and B words
+ output wire [WORD_COUNTER_WIDTH-1:0] n_addr; // index of current N word
+ output wire [WORD_COUNTER_WIDTH-1:0] d_addr; // index of current D word
+ output wire d_wren; // store current D word now
+
+ input wire [ 31:0] a_din; // A
+ input wire [ 31:0] b_din; // B
+ input wire [ 31:0] n_din; // N
+ output wire [ 31:0] d_dout; // D = (A - B) mod N
+
+
+ //
+ // Word Indices
+ //
+ reg [WORD_COUNTER_WIDTH-1:0] index_ab;
+ reg [WORD_COUNTER_WIDTH-1:0] index_n;
+ reg [WORD_COUNTER_WIDTH-1:0] index_d;
+
+ /* map registers to output ports */
+ assign ab_addr = index_ab;
+ assign n_addr = index_n;
+ assign d_addr = index_d;
+
+
+ //
+ // Subtractor
+ //
+ wire [31: 0] sub32_d;
+ wire sub32_b_in;
+ wire sub32_b_out;
+
+ subtractor32_wrapper subtractor32
+ (
+ .clk (clk),
+ .a (a_din),
+ .b (b_din),
+ .d (sub32_d),
+ .b_in (sub32_b_in),
+ .b_out (sub32_b_out)
+ );
+
+
+ //
+ // Adder
+ //
+ wire [31: 0] add32_s;
+ wire add32_c_in;
+ wire add32_c_out;
+
+ adder32_wrapper adder32
+ (
+ .clk (clk),
+ .a (sub32_d),
+ .b (n_din),
+ .s (add32_s),
+ .c_in (add32_c_in),
+ .c_out (add32_c_out)
+ );
+
+
+ //
+ // FSM
+ //
+
+ localparam FSM_SHREG_WIDTH = 2*OPERAND_NUM_WORDS + 5;
+
+ reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
+
+ assign rdy = fsm_shreg[0];
+
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_dif_ab = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_dif_ab_n = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 3)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_store_data_d = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 4) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 3)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_d = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 5) : FSM_SHREG_WIDTH - (2 * OPERAND_NUM_WORDS + 4)];
+
+ wire fsm_latch_msb_borrow = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+
+ wire inc_index_ab = |fsm_shreg_inc_index_ab;
+ wire inc_index_n = |fsm_shreg_inc_index_n;
+ wire store_dif_ab = |fsm_shreg_store_dif_ab;
+ wire store_dif_ab_n = |fsm_shreg_store_dif_ab_n;
+ wire store_data_d = |fsm_shreg_store_data_d;
+ wire inc_index_d = |fsm_shreg_inc_index_d;
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0)
+ //
+ fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
+ //
+ else begin
+ //
+ if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
+ //
+ else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
+ //
+ end
+
+
+ //
+ // Borrow & Carry Masking Logic
+ //
+ reg sub32_b_mask;
+ reg add32_c_mask;
+
+
+ always @(posedge clk) begin
+ //
+ sub32_b_mask <= (index_ab == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
+ add32_c_mask <= (index_n == WORD_INDEX_ZERO) ? 1'b1 : 1'b0;
+ //
+ end
+
+ assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
+ assign add32_c_in = add32_c_out & ~add32_c_mask;
+
+
+
+ //
+ // Borrow & Carry Latch Logic
+ //
+ reg sub32_borrow_latch;
+
+ always @(posedge clk) begin
+ //
+ if (fsm_latch_msb_borrow) sub32_borrow_latch <= sub32_b_out;
+ //
+ end
+
+
+ //
+ // Intermediate Results
+ //
+ reg [32*OPERAND_NUM_WORDS-1:0] d_ab;
+ reg [32*OPERAND_NUM_WORDS-1:0] d_ab_n;
+
+ always @(posedge clk)
+ //
+ if (store_data_d) begin
+ //
+ d_ab <= {{32{1'bX}}, d_ab[32*OPERAND_NUM_WORDS-1:32]};
+ d_ab_n <= {{32{1'bX}}, d_ab_n[32*OPERAND_NUM_WORDS-1:32]};
+ //
+ end else begin
+ //
+ if (store_dif_ab) d_ab <= {sub32_d, d_ab[32*OPERAND_NUM_WORDS-1:32]};
+ if (store_dif_ab_n) d_ab_n <= {add32_s, d_ab_n[32*OPERAND_NUM_WORDS-1:32]};
+ //
+ end
+
+
+ //
+ // Word Index Increment Logic
+ //
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ index_ab <= WORD_INDEX_ZERO;
+ index_n <= WORD_INDEX_ZERO;
+ index_d <= WORD_INDEX_ZERO;
+ //
+ end else begin
+ //
+ if (inc_index_ab) index_ab <= WORD_INDEX_NEXT_OR_ZERO(index_ab);
+ if (inc_index_n) index_n <= WORD_INDEX_NEXT_OR_ZERO(index_n);
+ if (inc_index_d) index_d <= WORD_INDEX_NEXT_OR_ZERO(index_d);
+ //
+ end
+
+
+ //
+ // Output Sum Selector
+ //
+ wire mux_select_ab_n = sub32_borrow_latch;
+
+
+ //
+ // Output Data and Write Enable Logic
+ //
+ reg d_wren_reg;
+ reg [31: 0] d_dout_reg;
+ wire [31: 0] d_dout_mux = mux_select_ab_n ? d_ab_n[31:0] : d_ab[31:0];
+
+ assign d_wren = d_wren_reg;
+ assign d_dout = d_dout_reg;
+
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ d_wren_reg <= 1'b0;
+ d_dout_reg <= {32{1'bX}};
+ //
+ end else begin
+ //
+ d_wren_reg <= store_data_d;
+ d_dout_reg <= store_data_d ? d_dout_mux : {32{1'bX}};
+ //
+ end
+
+
+endmodule
+
+
//------------------------------------------------------------------------------
// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
diff --git a/rtl/multiword/mw_comparator.v b/rtl/multiword/mw_comparator.v
index b97a6cf..756ee83 100644
--- a/rtl/multiword/mw_comparator.v
+++ b/rtl/multiword/mw_comparator.v
@@ -1,220 +1,220 @@
-//------------------------------------------------------------------------------
-//
-// mw_comparator.v
-// -----------------------------------------------------------------------------
-// Multi-word comparator.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2015-2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module mw_comparator
- (
- clk, rst_n,
- ena, rdy,
- xy_addr, x_din, y_din,
- cmp_l, cmp_e, cmp_g
- );
-
-
- //
- // Parameters
- //
- parameter WORD_COUNTER_WIDTH = 3;
- parameter OPERAND_NUM_WORDS = 8;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_PREV_OR_LAST;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_PREV_OR_LAST = (WORD_INDEX_CURRENT > WORD_INDEX_ZERO) ?
- WORD_INDEX_CURRENT - 1'b1 : WORD_INDEX_LAST;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-1:0] xy_addr; // address of current X and Y words
- input wire [ 32-1:0] x_din; // current X word
- input wire [ 32-1:0] y_din; // current Y word
-
- output wire cmp_l; // X < Y ?
- output wire cmp_e; // X = Y ?
- output wire cmp_g; // X > Y ?
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH-1:0] index_xy;
-
- reg reg_cmp_l;
- reg reg_cmp_e;
- reg reg_cmp_g;
-
-
- //
- // Output Mapping
- //
- assign xy_addr = index_xy;
-
- assign cmp_l = reg_cmp_l;
- assign cmp_e = reg_cmp_e;
- assign cmp_g = reg_cmp_g;
-
-
- //
- // FSM
- //
- localparam FSM_SHREG_WIDTH = 1 * OPERAND_NUM_WORDS + 3;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_dec_index_xy = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_calc_leg = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
- wire fsm_shreg_calc_leg_last = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
-
- wire dec_index_xy = |fsm_shreg_dec_index_xy;
- wire calc_leg = |fsm_shreg_calc_leg;
- wire calc_leg_last = fsm_shreg_calc_leg_last;
-
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- always @(posedge clk)
- //
- if (rdy) index_xy <= WORD_INDEX_LAST;
- else if (dec_index_xy) index_xy <= WORD_INDEX_PREV_OR_LAST(index_xy);
-
-
- //
- // 32-bit Subtractor
- //
- wire [31: 0] sub32_d_out;
- wire sub32_b_in;
- wire sub32_b_out;
-
- subtractor32_wrapper subtractor32_inst
- (
- .clk (clk),
-
- .a (x_din),
- .b (y_din),
-
- .d (sub32_d_out),
-
- .b_in (sub32_b_in),
- .b_out (sub32_b_out)
- );
-
-
- //
- // Borrow Masking Logic
- //
- reg sub32_b_mask;
-
- always @(posedge clk)
- //
- sub32_b_mask <= (index_xy == WORD_INDEX_LAST) ? 1'b1 : 1'b0;
-
- assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
-
- //
- // Output Logic
- //
- wire cmp_unresolved = !(cmp_l || cmp_g);
-
- wire cmp_borrow_is_set = (sub32_b_out == 1'b1) ? 1'b1 : 1'b0;
- wire cmp_difference_is_nonzero = (sub32_d_out != 32'd0) ? 1'b1 : 1'b0;
-
- always @(posedge clk)
- //
- if (rdy) begin
- //
- if (ena) begin
- //
- reg_cmp_l <= 1'b0;
- reg_cmp_e <= 1'b0;
- reg_cmp_g <= 1'b0;
- //
- end
- //
- end else if (cmp_unresolved && calc_leg) begin
- //
- if ( cmp_borrow_is_set) reg_cmp_l <= 1'b1;
- if (!cmp_borrow_is_set && cmp_difference_is_nonzero) reg_cmp_g <= 1'b1;
- if (!cmp_borrow_is_set && !cmp_difference_is_nonzero && calc_leg_last) reg_cmp_e <= 1'b1;
- //
- end
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
+//
+// mw_comparator.v
+// -----------------------------------------------------------------------------
+// Multi-word comparator.
+//
+// Authors: Pavel Shatov
+//
+// Copyright (c) 2015-2016, NORDUnet A/S
+//
+// Redistribution and use in source and binary forms, with or without
+// modification, are permitted provided that the following conditions are met:
+//
+// - Redistributions of source code must retain the above copyright notice,
+// this list of conditions and the following disclaimer.
+//
+// - Redistributions in binary form must reproduce the above copyright notice,
+// this list of conditions and the following disclaimer in the documentation
+// and/or other materials provided with the distribution.
+//
+// - Neither the name of the NORDUnet nor the names of its contributors may be
+// used to endorse or promote products derived from this software without
+// specific prior written permission.
+//
+// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
+// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+// POSSIBILITY OF SUCH DAMAGE.
+//
+//------------------------------------------------------------------------------
+
+module mw_comparator
+ (
+ clk, rst_n,
+ ena, rdy,
+ xy_addr, x_din, y_din,
+ cmp_l, cmp_e, cmp_g
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter WORD_COUNTER_WIDTH = 3;
+ parameter OPERAND_NUM_WORDS = 8;
+
+
+ //
+ // Handy Numbers
+ //
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
+
+
+ //
+ // Handy Functions
+ //
+ function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_PREV_OR_LAST;
+ input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
+ begin
+ WORD_INDEX_PREV_OR_LAST = (WORD_INDEX_CURRENT > WORD_INDEX_ZERO) ?
+ WORD_INDEX_CURRENT - 1'b1 : WORD_INDEX_LAST;
+ end
+ endfunction
+
+
+ //
+ // Ports
+ //
+ input wire clk; // system clock
+ input wire rst_n; // active-low async reset
+
+ input wire ena; // enable input
+ output wire rdy; // ready output
+
+ output wire [WORD_COUNTER_WIDTH-1:0] xy_addr; // address of current X and Y words
+ input wire [ 32-1:0] x_din; // current X word
+ input wire [ 32-1:0] y_din; // current Y word
+
+ output wire cmp_l; // X < Y ?
+ output wire cmp_e; // X = Y ?
+ output wire cmp_g; // X > Y ?
+
+
+ //
+ // Word Indices
+ //
+ reg [WORD_COUNTER_WIDTH-1:0] index_xy;
+
+ reg reg_cmp_l;
+ reg reg_cmp_e;
+ reg reg_cmp_g;
+
+
+ //
+ // Output Mapping
+ //
+ assign xy_addr = index_xy;
+
+ assign cmp_l = reg_cmp_l;
+ assign cmp_e = reg_cmp_e;
+ assign cmp_g = reg_cmp_g;
+
+
+ //
+ // FSM
+ //
+ localparam FSM_SHREG_WIDTH = 1 * OPERAND_NUM_WORDS + 3;
+
+ reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
+
+ assign rdy = fsm_shreg[0];
+
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_dec_index_xy = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_calc_leg = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 3) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+ wire fsm_shreg_calc_leg_last = fsm_shreg[FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 2)];
+
+ wire dec_index_xy = |fsm_shreg_dec_index_xy;
+ wire calc_leg = |fsm_shreg_calc_leg;
+ wire calc_leg_last = fsm_shreg_calc_leg_last;
+
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0)
+ //
+ fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
+ //
+ else begin
+ //
+ if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
+ //
+ else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
+ //
+ end
+
+
+ //
+ // Word Index Increment Logic
+ //
+ always @(posedge clk)
+ //
+ if (rdy) index_xy <= WORD_INDEX_LAST;
+ else if (dec_index_xy) index_xy <= WORD_INDEX_PREV_OR_LAST(index_xy);
+
+
+ //
+ // 32-bit Subtractor
+ //
+ wire [31: 0] sub32_d_out;
+ wire sub32_b_in;
+ wire sub32_b_out;
+
+ subtractor32_wrapper subtractor32_inst
+ (
+ .clk (clk),
+
+ .a (x_din),
+ .b (y_din),
+
+ .d (sub32_d_out),
+
+ .b_in (sub32_b_in),
+ .b_out (sub32_b_out)
+ );
+
+
+ //
+ // Borrow Masking Logic
+ //
+ reg sub32_b_mask;
+
+ always @(posedge clk)
+ //
+ sub32_b_mask <= (index_xy == WORD_INDEX_LAST) ? 1'b1 : 1'b0;
+
+ assign sub32_b_in = sub32_b_out & ~sub32_b_mask;
+
+ //
+ // Output Logic
+ //
+ wire cmp_unresolved = !(cmp_l || cmp_g);
+
+ wire cmp_borrow_is_set = (sub32_b_out == 1'b1) ? 1'b1 : 1'b0;
+ wire cmp_difference_is_nonzero = (sub32_d_out != 32'd0) ? 1'b1 : 1'b0;
+
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ //
+ if (ena) begin
+ //
+ reg_cmp_l <= 1'b0;
+ reg_cmp_e <= 1'b0;
+ reg_cmp_g <= 1'b0;
+ //
+ end
+ //
+ end else if (cmp_unresolved && calc_leg) begin
+ //
+ if ( cmp_borrow_is_set) reg_cmp_l <= 1'b1;
+ if (!cmp_borrow_is_set && cmp_difference_is_nonzero) reg_cmp_g <= 1'b1;
+ if (!cmp_borrow_is_set && !cmp_difference_is_nonzero && calc_leg_last) reg_cmp_e <= 1'b1;
+ //
+ end
+
+
+endmodule
+
+
+//------------------------------------------------------------------------------
+// End-of-File
+//------------------------------------------------------------------------------
diff --git a/rtl/multiword/mw_mover.v b/rtl/multiword/mw_mover.v
index 5db95a7..d6e025f 100644
--- a/rtl/multiword/mw_mover.v
+++ b/rtl/multiword/mw_mover.v
@@ -1,175 +1,175 @@
-//------------------------------------------------------------------------------
-//
-// mw_mover.v
-// -----------------------------------------------------------------------------
-// Multi-word data mover.
-//
-// Authors: Pavel Shatov
-//
-// Copyright (c) 2015-2016, NORDUnet A/S
-//
-// Redistribution and use in source and binary forms, with or without
-// modification, are permitted provided that the following conditions are met:
-//
-// - Redistributions of source code must retain the above copyright notice,
-// this list of conditions and the following disclaimer.
-//
-// - Redistributions in binary form must reproduce the above copyright notice,
-// this list of conditions and the following disclaimer in the documentation
-// and/or other materials provided with the distribution.
-//
-// - Neither the name of the NORDUnet nor the names of its contributors may be
-// used to endorse or promote products derived from this software without
-// specific prior written permission.
-//
-// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
-// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
-// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
-// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
-// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
-// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
-// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
-// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
-// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
-// POSSIBILITY OF SUCH DAMAGE.
-//
-//------------------------------------------------------------------------------
-
-module mw_mover
- (
- clk, rst_n,
- ena, rdy,
- x_addr, y_addr, y_wren,
- x_din, y_dout
- );
-
-
- //
- // Parameters
- //
- parameter WORD_COUNTER_WIDTH = 3;
- parameter OPERAND_NUM_WORDS = 8;
-
-
- //
- // Handy Numbers
- //
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
- localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
-
-
- //
- // Handy Functions
- //
- function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
- input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
- begin
- WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
- WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
- end
- endfunction
-
-
- //
- // Ports
- //
- input wire clk; // system clock
- input wire rst_n; // active-low async reset
-
- input wire ena; // enable input
- output wire rdy; // ready output
-
- output wire [WORD_COUNTER_WIDTH-1:0] x_addr; // address of current X word
- output wire [WORD_COUNTER_WIDTH-1:0] y_addr; // address of current Y word
- output wire y_wren; // store current Y word
-
- input wire [ 32-1:0] x_din; // current X word
- output wire [ 32-1:0] y_dout; // current Y word
-
-
- //
- // Word Indices
- //
- reg [WORD_COUNTER_WIDTH-1:0] index_x;
- reg [WORD_COUNTER_WIDTH-1:0] index_y;
-
-
- //
- // Output Mapping
- //
- assign x_addr = index_x;
- assign y_addr = index_y;
-
-
- //
- // FSM
- //
- localparam FSM_SHREG_WIDTH = 1 * OPERAND_NUM_WORDS + 2;
-
- reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
-
- assign rdy = fsm_shreg[0];
-
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_x = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
- wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_y = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
-
- wire inc_index_x = |fsm_shreg_inc_index_x;
- wire inc_index_y = |fsm_shreg_inc_index_y;
- wire store_word_y = |fsm_shreg_inc_index_x;
-
-
- always @(posedge clk or negedge rst_n)
- //
- if (rst_n == 1'b0)
- //
- fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
- //
- else begin
- //
- if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
- //
- else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
- //
- end
-
-
- //
- // Word Index Increment Logic
- //
- always @(posedge clk)
- //
- if (rdy) begin
- index_x <= WORD_INDEX_ZERO;
- index_y <= WORD_INDEX_ZERO;
- end else begin
- if (inc_index_x) index_x <= WORD_INDEX_NEXT_OR_ZERO(index_x);
- if (inc_index_y) index_y <= WORD_INDEX_NEXT_OR_ZERO(index_y);
- end
-
-
- //
- // Write Enable Logic
- //
- reg y_wren_reg;
-
- assign y_wren = y_wren_reg;
-
- always @(posedge clk)
- //
- if (rdy) y_wren_reg <= 1'b0;
- else y_wren_reg <= store_word_y;
-
-
- //
- // Output Logic
- //
- assign y_dout = x_din;
-
-
-endmodule
-
-
-//------------------------------------------------------------------------------
-// End-of-File
-//------------------------------------------------------------------------------
+//------------------------------------------------------------------------------
+//
+// mw_mover.v
+// -----------------------------------------------------------------------------
+// Multi-word data mover.
+//
+// Authors: Pavel Shatov
+//
+// Copyright (c) 2015-2016, NORDUnet A/S
+//
+// Redistribution and use in source and binary forms, with or without
+// modification, are permitted provided that the following conditions are met:
+//
+// - Redistributions of source code must retain the above copyright notice,
+// this list of conditions and the following disclaimer.
+//
+// - Redistributions in binary form must reproduce the above copyright notice,
+// this list of conditions and the following disclaimer in the documentation
+// and/or other materials provided with the distribution.
+//
+// - Neither the name of the NORDUnet nor the names of its contributors may be
+// used to endorse or promote products derived from this software without
+// specific prior written permission.
+//
+// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
+// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+// POSSIBILITY OF SUCH DAMAGE.
+//
+//------------------------------------------------------------------------------
+
+module mw_mover
+ (
+ clk, rst_n,
+ ena, rdy,
+ x_addr, y_addr, y_wren,
+ x_din, y_dout
+ );
+
+
+ //
+ // Parameters
+ //
+ parameter WORD_COUNTER_WIDTH = 3;
+ parameter OPERAND_NUM_WORDS = 8;
+
+
+ //
+ // Handy Numbers
+ //
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_ZERO = 0;
+ localparam [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_LAST = OPERAND_NUM_WORDS - 1;
+
+
+ //
+ // Handy Functions
+ //
+ function [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_NEXT_OR_ZERO;
+ input [WORD_COUNTER_WIDTH-1:0] WORD_INDEX_CURRENT;
+ begin
+ WORD_INDEX_NEXT_OR_ZERO = (WORD_INDEX_CURRENT < WORD_INDEX_LAST) ?
+ WORD_INDEX_CURRENT + 1'b1 : WORD_INDEX_ZERO;
+ end
+ endfunction
+
+
+ //
+ // Ports
+ //
+ input wire clk; // system clock
+ input wire rst_n; // active-low async reset
+
+ input wire ena; // enable input
+ output wire rdy; // ready output
+
+ output wire [WORD_COUNTER_WIDTH-1:0] x_addr; // address of current X word
+ output wire [WORD_COUNTER_WIDTH-1:0] y_addr; // address of current Y word
+ output wire y_wren; // store current Y word
+
+ input wire [ 32-1:0] x_din; // current X word
+ output wire [ 32-1:0] y_dout; // current Y word
+
+
+ //
+ // Word Indices
+ //
+ reg [WORD_COUNTER_WIDTH-1:0] index_x;
+ reg [WORD_COUNTER_WIDTH-1:0] index_y;
+
+
+ //
+ // Output Mapping
+ //
+ assign x_addr = index_x;
+ assign y_addr = index_y;
+
+
+ //
+ // FSM
+ //
+ localparam FSM_SHREG_WIDTH = 1 * OPERAND_NUM_WORDS + 2;
+
+ reg [FSM_SHREG_WIDTH-1:0] fsm_shreg;
+
+ assign rdy = fsm_shreg[0];
+
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_x = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 1) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 0)];
+ wire [OPERAND_NUM_WORDS-1:0] fsm_shreg_inc_index_y = fsm_shreg[FSM_SHREG_WIDTH - (0 * OPERAND_NUM_WORDS + 2) : FSM_SHREG_WIDTH - (1 * OPERAND_NUM_WORDS + 1)];
+
+ wire inc_index_x = |fsm_shreg_inc_index_x;
+ wire inc_index_y = |fsm_shreg_inc_index_y;
+ wire store_word_y = |fsm_shreg_inc_index_x;
+
+
+ always @(posedge clk or negedge rst_n)
+ //
+ if (rst_n == 1'b0)
+ //
+ fsm_shreg <= {{FSM_SHREG_WIDTH-1{1'b0}}, 1'b1};
+ //
+ else begin
+ //
+ if (rdy) fsm_shreg <= {ena, {FSM_SHREG_WIDTH-2{1'b0}}, ~ena};
+ //
+ else fsm_shreg <= {1'b0, fsm_shreg[FSM_SHREG_WIDTH-1:1]};
+ //
+ end
+
+
+ //
+ // Word Index Increment Logic
+ //
+ always @(posedge clk)
+ //
+ if (rdy) begin
+ index_x <= WORD_INDEX_ZERO;
+ index_y <= WORD_INDEX_ZERO;
+ end else begin
+ if (inc_index_x) index_x <= WORD_INDEX_NEXT_OR_ZERO(index_x);
+ if (inc_index_y) index_y <= WORD_INDEX_NEXT_OR_ZERO(index_y);
+ end
+
+
+ //
+ // Write Enable Logic
+ //
+ reg y_wren_reg;
+
+ assign y_wren = y_wren_reg;
+
+ always @(posedge clk)
+ //
+ if (rdy) y_wren_reg <= 1'b0;
+ else y_wren_reg <= store_word_y;
+
+
+ //
+ // Output Logic
+ //
+ assign y_dout = x_din;
+
+
+endmodule
+
+
+//------------------------------------------------------------------------------
+// End-of-File
+//------------------------------------------------------------------------------
diff --git a/rtl/util/bram_1rw_1ro_readfirst.v b/rtl/util/bram_1rw_1ro_readfirst.v
index 28782c2..db62726 100644
--- a/rtl/util/bram_1rw_1ro_readfirst.v
+++ b/rtl/util/bram_1rw_1ro_readfirst.v
@@ -36,11 +36,11 @@ module bram_1rw_1ro_readfirst
#(parameter MEM_WIDTH = 32,
parameter MEM_ADDR_BITS = 8)
(
- input wire clk,
+ input wire clk,
input wire [MEM_ADDR_BITS-1:0] a_addr,
- input wire a_wr,
- input wire [MEM_WIDTH-1:0] a_in,
+ input wire a_wr,
+ input wire [MEM_WIDTH-1:0] a_in,
output wire [MEM_WIDTH-1:0] a_out,
input wire [MEM_ADDR_BITS-1:0] b_addr,
@@ -52,27 +52,27 @@ module bram_1rw_1ro_readfirst
// BRAM
//
(* RAM_STYLE="BLOCK" *)
- reg [MEM_WIDTH-1:0] bram[0:(2**MEM_ADDR_BITS)-1];
-
-
- //
- // Initialization
- //
- /**
- integer c;
- initial begin
- for (c=0; c<(2**MEM_ADDR_BITS); c=c+1)
- bram[c] = {MEM_WIDTH{1'b0}};
- end
- **/
-
+ reg [MEM_WIDTH-1:0] bram[0:(2**MEM_ADDR_BITS)-1];
+
+
+ //
+ // Initialization
+ //
+ /**
+ integer c;
+ initial begin
+ for (c=0; c<(2**MEM_ADDR_BITS); c=c+1)
+ bram[c] = {MEM_WIDTH{1'b0}};
+ end
+ **/
+
//
// Output Registers
//
- reg [MEM_WIDTH-1:0] bram_reg_a;
- reg [MEM_WIDTH-1:0] bram_reg_b;
+ reg [MEM_WIDTH-1:0] bram_reg_a;
+ reg [MEM_WIDTH-1:0] bram_reg_b;
assign a_out = bram_reg_a;
assign b_out = bram_reg_b;
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