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APS/Labs/06. Datapath/board files/nexys_riscv_unit.sv
BROsandr 28cda20170 ЛР6. Рефактор топ-левел модуля 
* Feat(06/board):Переписывание sv модуля

* Ref(06/board/top.sv):Изм-ие положения модулей

* Fix(06/board):Испр-ие синхронного сброса

* Feat(pic/06/board/struct):Доб-ие схемы

* Ref(06/board/top.sv):Доб-ие обработки всего opcode

* Feat(pic/04/board/op):Доб-ие пикчи

* Ref(pic/06/board/op):Обн-ие названий

* Feat(06/board/md):Обн-ие md

* Feat(06/board/md):Доб-ие инфы про инстр с памятью

* Ref(06/board/md):Изм-ие формулирвки для PC
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/* -----------------------------------------------------------------------------
* Project Name : Architectures of Processor Systems (APS) lab work
* Organization : National Research University of Electronic Technology (MIET)
* Department : Institute of Microdevices and Control Systems
* Author(s) : Alexander Kharlamov
* Email(s) : sasha_xarlamov@org.miet.ru
See https://github.com/MPSU/APS/blob/master/LICENSE file for licensing details.
* ------------------------------------------------------------------------------
*/
typedef enum {
INSTR_ALU , // branch and computational
INSTR_LI , // const load
INSTR_IN , // periphery load
INSTR_JUMP ,
INSTR_NOP // ws == 3
} Instruction_type;
typedef enum {
CH_0 = 0,
CH_1,
CH_2,
CH_3,
CH_4,
CH_5,
CH_6,
CH_7,
CH_8,
CH_9,
CH_A,
CH_b,
CH_c,
CH_d,
CH_E,
CH_F,
CH_G,
CH_L,
CH_n,
CH_o,
CH_r,
CH_S,
CH_t,
CH_u,
CH_X,
CH_P,
CH_J,
CH_q,
CH_i,
CH_m,
CH_y,
CH_h,
CH_SPACE
} Char;
typedef struct {
logic ca;
logic cb;
logic cc;
logic cd;
logic ce;
logic cf;
logic cg;
logic dp;
} Semseg;
module nexys_riscv_unit(
input logic clk_i,
input logic arstn_i,
input logic btnd_i,
output logic ca_o,
output logic cb_o,
output logic cc_o,
output logic cd_o,
output logic ce_o,
output logic cf_o,
output logic cg_o,
output logic dp_o,
output logic [ 7:0] an_o
);
logic btnd_sync;
sync sync (
.clk_i ,
.data_i (btnd_i ),
.data_o (btnd_sync)
);
logic btnd_debounce;
debounce debounce (
.clk_i ,
.arstn_i (1'b1 ),
.data_i (btnd_sync ),
.data_o (btnd_debounce)
);
logic bufg_clk;
BUFG dut_bufg(
.I (btnd_debounce),
.O (bufg_clk )
);
riscv_unit unit(
.clk_i (bufg_clk),
.rst_i (!arstn_i)
);
logic [31:0] instr_addr;
logic [31:0] instr;
assign instr_addr = unit.core.instr_addr_o;
assign instr = unit.core.instr_i;
import alu_opcodes_pkg::*;
logic illegal_instr;
logic [6:0] opcode;
assign opcode = instr[6:0];
Char op_chars[0:3];
import riscv_pkg::*;
always_comb begin
op_chars = '{4{CH_SPACE}};
case (opcode)
{LOAD_OPCODE , 2'b11}: op_chars = '{CH_L, CH_o, CH_A, CH_d};
{MISC_MEM_OPCODE, 2'b11}: op_chars = '{CH_m, CH_i, CH_S, CH_c};
{OP_IMM_OPCODE , 2'b11}: op_chars = '{CH_o, CH_P, CH_i, CH_m};
{AUIPC_OPCODE , 2'b11}: op_chars = '{CH_A, CH_u, CH_i, CH_P};
{STORE_OPCODE , 2'b11}: op_chars = '{CH_S, CH_t, CH_o, CH_r};
{OP_OPCODE , 2'b11}: op_chars[0:1] = '{CH_o, CH_P};
{LUI_OPCODE , 2'b11}: op_chars[0:2] = '{CH_L, CH_u, CH_i};
{BRANCH_OPCODE , 2'b11}: op_chars = '{CH_b, CH_r, CH_c, CH_h};
{JALR_OPCODE , 2'b11}: op_chars = '{CH_J, CH_A, CH_L, CH_r};
{JAL_OPCODE , 2'b11}: op_chars[0:2] = '{CH_J, CH_A, CH_L};
{SYSTEM_OPCODE , 2'b11}: op_chars[0:2] = '{CH_S, CH_y, CH_S};
default : op_chars[0:2] = '{CH_i, CH_L, CH_L};
endcase
end
Char all_chars[0:7];
assign all_chars[0:3] = {
Char'(instr_addr[15:12]),
Char'(instr_addr[11: 8]),
Char'(instr_addr[ 7: 4]),
Char'(instr_addr[ 3: 0])
};
assign all_chars[4:7] = op_chars;
Char current_char;
logic [7:0] an;
semseg_one2many #(
.DATA_T (Char)
) semseg_one2many (
.clk100m_i (clk_i ),
.arstn_i (arstn_i ),
.all_semsegs_i (all_chars ),
.current_semseg_o (current_char),
.an_o (an )
);
Semseg current_semseg;
char2semseg char2semseg (
.char_i (current_char ),
.semseg_o (current_semseg)
);
assign ca_o = current_semseg.ca;
assign cb_o = current_semseg.cb;
assign cc_o = current_semseg.cc;
assign cd_o = current_semseg.cd;
assign ce_o = current_semseg.ce;
assign cf_o = current_semseg.cf;
assign cg_o = current_semseg.cg;
assign dp_o = current_semseg.dp;
assign an_o = an;
endmodule
module char2semseg #(
parameter bit HEX_ONLY = 1'b0
) (
input Char char_i,
output Semseg semseg_o
);
localparam bit [6:0] BLANK = '1;
logic [6:0] semseg;
always_comb begin
case (char_i)
CH_0 : semseg = ~7'h3F;
CH_1 : semseg = ~7'h06;
CH_2 : semseg = ~7'h5B;
CH_3 : semseg = ~7'h4F;
CH_4 : semseg = ~7'h66;
CH_5 : semseg = ~7'h6D;
CH_6 : semseg = ~7'h7D;
CH_7 : semseg = ~7'h07;
CH_8 : semseg = ~7'h7F;
CH_9 : semseg = ~7'h6F;
CH_A : semseg = ~7'h5F;
CH_b : semseg = ~7'h7C;
CH_c : semseg = ~7'h58;
CH_d : semseg = ~7'h5E;
CH_E : semseg = ~7'h79;
CH_F : semseg = ~7'h71;
CH_G : semseg = ~7'h3D;
CH_L : semseg = ~7'h38;
CH_n : semseg = ~7'h54;
CH_o : semseg = ~7'h5C;
CH_r : semseg = ~7'h50;
CH_S : semseg = ~7'h64;
CH_t : semseg = ~7'h78;
CH_u : semseg = ~7'h1C;
CH_X : semseg = ~7'h76;
CH_P : semseg = ~7'h73;
CH_J : semseg = ~7'h1E;
CH_q : semseg = ~7'h67;
CH_i : semseg = ~7'h30;
CH_m : semseg = ~7'h77;
CH_y : semseg = ~7'h6E;
CH_h : semseg = ~7'h74;
default : semseg = BLANK;
endcase
end
assign semseg_o.ca = semseg[0];
assign semseg_o.cb = semseg[1];
assign semseg_o.cc = semseg[2];
assign semseg_o.cd = semseg[3];
assign semseg_o.ce = semseg[4];
assign semseg_o.cf = semseg[5];
assign semseg_o.cg = semseg[6];
assign semseg_o.dp = 1'b1;
endmodule
module semseg_one2many #(
parameter int unsigned SEMSEGS_NUM = 8,
parameter type DATA_T
) (
input DATA_T all_semsegs_i[0:SEMSEGS_NUM-1],
input logic clk100m_i,
input logic arstn_i,
output DATA_T current_semseg_o,
output logic [7:0] an_o
);
logic clk_i;
assign clk_i = clk100m_i;
localparam int COUNTER_WIDTH = 10;
logic [COUNTER_WIDTH-1:0] counter_next;
logic [COUNTER_WIDTH-1:0] counter_ff;
assign counter_next = counter_ff + COUNTER_WIDTH'('b1);
always_ff @(posedge clk_i or negedge arstn_i) begin
if (!arstn_i) counter_ff <= '0;
else counter_ff <= counter_next;
end
logic [7:0] an_ff;
logic [7:0] an_next;
logic an_en;
assign an_next = {an_ff[$left(an_ff)-1:0], an_ff[$left(an_ff)]};
assign an_en = ~|counter_ff;
always_ff @(posedge clk_i or negedge arstn_i) begin
if (!arstn_i) an_ff <= ~8'b1;
else if (an_en) an_ff <= an_next;
end
DATA_T current_semseg;
always_comb begin
unique case (1'b0)
an_ff[0]: current_semseg = all_semsegs_i[7];
an_ff[1]: current_semseg = all_semsegs_i[6];
an_ff[2]: current_semseg = all_semsegs_i[5];
an_ff[3]: current_semseg = all_semsegs_i[4];
an_ff[4]: current_semseg = all_semsegs_i[3];
an_ff[5]: current_semseg = all_semsegs_i[2];
an_ff[6]: current_semseg = all_semsegs_i[1];
an_ff[7]: current_semseg = all_semsegs_i[0];
endcase
end
assign current_semseg_o = current_semseg;
assign an_o = an_ff;
endmodule
module debounce #(
parameter int unsigned MAX_COUNT = 10000
) (
input logic clk_i,
input logic arstn_i,
input logic data_i,
output logic data_o
);
localparam int COUNTER_WIDTH = $clog2(MAX_COUNT);
logic [COUNTER_WIDTH-1:0] counter_next;
logic [COUNTER_WIDTH-1:0] counter_ff;
assign counter_next = (data_o != data_i) ? counter_ff - COUNTER_WIDTH'('b1) :
COUNTER_WIDTH'(MAX_COUNT);
always_ff @(posedge clk_i or negedge arstn_i) begin
if (!arstn_i) counter_ff <= COUNTER_WIDTH'(MAX_COUNT);
else counter_ff <= counter_next;
end
always_ff @(posedge clk_i or negedge arstn_i) begin
if (!arstn_i) data_o <= '0;
else if (~|counter_ff) data_o <= data_i;
end
endmodule
module sync #(
parameter int unsigned SYNC_STAGES = 3
) (
input logic clk_i,
input logic data_i,
output logic data_o
);
logic [SYNC_STAGES-1:0] sync_buffer_ff;
logic [SYNC_STAGES-1:0] sync_buffer_next;
assign sync_buffer_next = {sync_buffer_ff[$left(sync_buffer_ff)-1:0], data_i};
always_ff @(posedge clk_i) begin
sync_buffer_ff <= sync_buffer_next;
end
assign data_o = sync_buffer_ff[$left(sync_buffer_ff)];
endmodule
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