mirrors/yosys
3
0
Fork 0
mirror of https://github.com/YosysHQ/yosys synced 2025-06-23 22:33:41 +00:00
Code Activity

Merge branch 'master' into mmicko/efinix

Browse source
This commit is contained in:
Miodrag Milanović 2019-10-18 10:54:28 +02:00 committed by GitHub
commit b4d7650548
No known key found for this signature in database
GPG key ID: 4AEE18F83AFDEB23
156 changed files with 3166 additions and 906 deletions
Download patch file Download diff file Expand all files Collapse all files

4
tests/anlogic/.gitignore vendored Normal file
View file

@ -0,0 +1,4 @@
*.log
/run-test.mk
+*_synth.v
+*_testbench

13
tests/anlogic/add_sub.v Normal file
View file

@ -0,0 +1,13 @@
module top
(
input [3:0] x,
input [3:0] y,
output [3:0] A,
output [3:0] B
);
assign A = x + y;
assign B = x - y;
endmodule

10
tests/anlogic/add_sub.ys Normal file
View file

@ -0,0 +1,10 @@
read_verilog add_sub.v
hierarchy -top top
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 10 t:AL_MAP_ADDER
select -assert-count 4 t:AL_MAP_LUT1
select -assert-none t:AL_MAP_LUT1 t:AL_MAP_ADDER %% t:* %D

17
tests/anlogic/counter.v Normal file
View file

@ -0,0 +1,17 @@
module top (
out,
clk,
reset
);
output [7:0] out;
input clk, reset;
reg [7:0] out;
always @(posedge clk, posedge reset)
if (reset) begin
out <= 8'b0 ;
end else
out <= out + 1;
endmodule

11
tests/anlogic/counter.ys Normal file
View file

@ -0,0 +1,11 @@
read_verilog counter.v
hierarchy -top top
proc
flatten
equiv_opt -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 9 t:AL_MAP_ADDER
select -assert-count 8 t:AL_MAP_SEQ
select -assert-none t:AL_MAP_SEQ t:AL_MAP_ADDER %% t:* %D

15
tests/anlogic/dffs.v Normal file
View file

@ -0,0 +1,15 @@
module dff
( input d, clk, output reg q );
always @( posedge clk )
q <= d;
endmodule
module dffe
( input d, clk, en, output reg q );
initial begin
q = 0;
end
always @( posedge clk )
if ( en )
q <= d;
endmodule

20
tests/anlogic/dffs.ys Normal file
View file

@ -0,0 +1,20 @@
read_verilog dffs.v
design -save read
hierarchy -top dff
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dff # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_SEQ
select -assert-none t:AL_MAP_SEQ %% t:* %D
design -load read
hierarchy -top dffe
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dffe # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT3
select -assert-count 1 t:AL_MAP_SEQ
select -assert-none t:AL_MAP_LUT3 t:AL_MAP_SEQ %% t:* %D

55
tests/anlogic/fsm.v Normal file
View file

@ -0,0 +1,55 @@
module fsm (
clock,
reset,
req_0,
req_1,
gnt_0,
gnt_1
);
input clock,reset,req_0,req_1;
output gnt_0,gnt_1;
wire clock,reset,req_0,req_1;
reg gnt_0,gnt_1;
parameter SIZE = 3 ;
parameter IDLE = 3'b001,GNT0 = 3'b010,GNT1 = 3'b100,GNT2 = 3'b101 ;
reg [SIZE-1:0] state;
reg [SIZE-1:0] next_state;
always @ (posedge clock)
begin : FSM
if (reset == 1'b1) begin
state <= #1 IDLE;
gnt_0 <= 0;
gnt_1 <= 0;
end else
case(state)
IDLE : if (req_0 == 1'b1) begin
state <= #1 GNT0;
gnt_0 <= 1;
end else if (req_1 == 1'b1) begin
gnt_1 <= 1;
state <= #1 GNT0;
end else begin
state <= #1 IDLE;
end
GNT0 : if (req_0 == 1'b1) begin
state <= #1 GNT0;
end else begin
gnt_0 <= 0;
state <= #1 IDLE;
end
GNT1 : if (req_1 == 1'b1) begin
state <= #1 GNT2;
gnt_1 <= req_0;
end
GNT2 : if (req_0 == 1'b1) begin
state <= #1 GNT1;
gnt_1 <= req_1;
end
default : state <= #1 IDLE;
endcase
end
endmodule

15
tests/anlogic/fsm.ys Normal file
View file

@ -0,0 +1,15 @@
read_verilog fsm.v
hierarchy -top fsm
proc
#flatten
#ERROR: Found 4 unproven $equiv cells in 'equiv_status -assert'.
#equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
equiv_opt -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd fsm # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT2
select -assert-count 5 t:AL_MAP_LUT5
select -assert-count 1 t:AL_MAP_LUT6
select -assert-count 6 t:AL_MAP_SEQ
select -assert-none t:AL_MAP_LUT2 t:AL_MAP_LUT5 t:AL_MAP_LUT6 t:AL_MAP_SEQ %% t:* %D

24
tests/anlogic/latches.v Normal file
View file

@ -0,0 +1,24 @@
module latchp
( input d, clk, en, output reg q );
always @*
if ( en )
q <= d;
endmodule
module latchn
( input d, clk, en, output reg q );
always @*
if ( !en )
q <= d;
endmodule
module latchsr
( input d, clk, en, clr, pre, output reg q );
always @*
if ( clr )
q <= 1'b0;
else if ( pre )
q <= 1'b1;
else if ( en )
q <= d;
endmodule

33
tests/anlogic/latches.ys Normal file
View file

@ -0,0 +1,33 @@
read_verilog latches.v
design -save read
hierarchy -top latchp
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_anlogic
cd latchp # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT3
select -assert-none t:AL_MAP_LUT3 %% t:* %D
design -load read
hierarchy -top latchn
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_anlogic
cd latchn # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT3
select -assert-none t:AL_MAP_LUT3 %% t:* %D
design -load read
hierarchy -top latchsr
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_anlogic
cd latchsr # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT5
select -assert-none t:AL_MAP_LUT5 %% t:* %D

21
tests/anlogic/memory.v Normal file
View file

@ -0,0 +1,21 @@
module top
(
input [7:0] data_a,
input [6:1] addr_a,
input we_a, clk,
output reg [7:0] q_a
);
// Declare the RAM variable
reg [7:0] ram[63:0];
// Port A
always @ (posedge clk)
begin
if (we_a)
begin
ram[addr_a] <= data_a;
q_a <= data_a;
end
q_a <= ram[addr_a];
end
endmodule

21
tests/anlogic/memory.ys Normal file
View file

@ -0,0 +1,21 @@
read_verilog memory.v
hierarchy -top top
proc
memory -nomap
equiv_opt -run :prove -map +/anlogic/cells_sim.v synth_anlogic
memory
opt -full
miter -equiv -flatten -make_assert -make_outputs gold gate miter
#ERROR: Failed to import cell gate.mem.0.0.0 (type EG_LOGIC_DRAM16X4) to SAT database.
#sat -verify -prove-asserts -seq 3 -set-init-zero -show-inputs -show-outputs miter
design -load postopt
cd top
select -assert-count 8 t:AL_MAP_LUT2
select -assert-count 8 t:AL_MAP_LUT4
select -assert-count 8 t:AL_MAP_LUT5
select -assert-count 36 t:AL_MAP_SEQ
select -assert-count 8 t:EG_LOGIC_DRAM16X4 #Why not AL_LOGIC_BRAM?
select -assert-none t:AL_MAP_LUT2 t:AL_MAP_LUT4 t:AL_MAP_LUT5 t:AL_MAP_SEQ t:EG_LOGIC_DRAM16X4 %% t:* %D

65
tests/anlogic/mux.v Normal file
View file

@ -0,0 +1,65 @@
module mux2 (S,A,B,Y);
input S;
input A,B;
output reg Y;
always @(*)
Y = (S)? B : A;
endmodule
module mux4 ( S, D, Y );
input[1:0] S;
input[3:0] D;
output Y;
reg Y;
wire[1:0] S;
wire[3:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
endcase
end
endmodule
module mux8 ( S, D, Y );
input[2:0] S;
input[7:0] D;
output Y;
reg Y;
wire[2:0] S;
wire[7:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
4 : Y = D[4];
5 : Y = D[5];
6 : Y = D[6];
7 : Y = D[7];
endcase
end
endmodule
module mux16 (D, S, Y);
input [15:0] D;
input [3:0] S;
output Y;
assign Y = D[S];
endmodule

42
tests/anlogic/mux.ys Normal file
View file

@ -0,0 +1,42 @@
read_verilog mux.v
design -save read
hierarchy -top mux2
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux2 # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT3
select -assert-none t:AL_MAP_LUT3 %% t:* %D
design -load read
hierarchy -top mux4
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux4 # Constrain all select calls below inside the top module
select -assert-count 1 t:AL_MAP_LUT6
select -assert-none t:AL_MAP_LUT6 %% t:* %D
design -load read
hierarchy -top mux8
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux8 # Constrain all select calls below inside the top module
select -assert-count 3 t:AL_MAP_LUT4
select -assert-count 1 t:AL_MAP_LUT6
select -assert-none t:AL_MAP_LUT4 t:AL_MAP_LUT6 %% t:* %D
design -load read
hierarchy -top mux16
proc
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux16 # Constrain all select calls below inside the top module
select -assert-count 5 t:AL_MAP_LUT6
select -assert-none t:AL_MAP_LUT6 %% t:* %D

20
tests/anlogic/run-test.sh Executable file
View file

@ -0,0 +1,20 @@
#!/usr/bin/env bash
set -e
{
echo "all::"
for x in *.ys; do
echo "all:: run-$x"
echo "run-$x:"
echo " @echo 'Running $x..'"
echo " @../../yosys -ql ${x%.ys}.log -w 'Yosys has only limited support for tri-state logic at the moment.' $x"
done
for s in *.sh; do
if [ "$s" != "run-test.sh" ]; then
echo "all:: run-$s"
echo "run-$s:"
echo " @echo 'Running $s..'"
echo " @bash $s"
fi
done
} > run-test.mk
exec ${MAKE:-make} -f run-test.mk

16
tests/anlogic/shifter.v Normal file
View file

@ -0,0 +1,16 @@
module top (
out,
clk,
in
);
output [7:0] out;
input signed clk, in;
reg signed [7:0] out = 0;
always @(posedge clk)
begin
out <= out >> 1;
out[7] <= in;
end
endmodule

10
tests/anlogic/shifter.ys Normal file
View file

@ -0,0 +1,10 @@
read_verilog shifter.v
hierarchy -top top
proc
flatten
equiv_opt -assert -map +/anlogic/cells_sim.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 8 t:AL_MAP_SEQ
select -assert-none t:AL_MAP_SEQ %% t:* %D

8
tests/anlogic/tribuf.v Normal file
View file

@ -0,0 +1,8 @@
module tristate (en, i, o);
input en;
input i;
output o;
assign o = en ? i : 1'bz;
endmodule

9
tests/anlogic/tribuf.ys Normal file
View file

@ -0,0 +1,9 @@
read_verilog tribuf.v
hierarchy -top tristate
proc
flatten
equiv_opt -assert -map +/anlogic/cells_sim.v -map +/simcells.v synth_anlogic # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd tristate # Constrain all select calls below inside the top module
select -assert-count 1 t:$_TBUF_
select -assert-none t:$_TBUF_ %% t:* %D

2
tests/ecp5/.gitignore vendored Normal file
View file

@ -0,0 +1,2 @@
*.log
/run-test.mk

13
tests/ecp5/add_sub.v Normal file
View file

@ -0,0 +1,13 @@
module top
(
input [3:0] x,
input [3:0] y,
output [3:0] A,
output [3:0] B
);
assign A = x + y;
assign B = x - y;
endmodule

9
tests/ecp5/add_sub.ys Normal file
View file

@ -0,0 +1,9 @@
read_verilog add_sub.v
hierarchy -top top
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 10 t:LUT4
select -assert-none t:LUT4 %% t:* %D

47
tests/ecp5/adffs.v Normal file
View file

@ -0,0 +1,47 @@
module adff
( input d, clk, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk, posedge clr )
if ( clr )
q <= 1'b0;
else
q <= d;
endmodule
module adffn
( input d, clk, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk, negedge clr )
if ( !clr )
q <= 1'b0;
else
q <= d;
endmodule
module dffs
( input d, clk, pre, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk )
if ( pre )
q <= 1'b1;
else
q <= d;
endmodule
module ndffnr
( input d, clk, pre, clr, output reg q );
initial begin
q = 0;
end
always @( negedge clk )
if ( !clr )
q <= 1'b0;
else
q <= d;
endmodule

40
tests/ecp5/adffs.ys Normal file
View file

@ -0,0 +1,40 @@
read_verilog adffs.v
design -save read
hierarchy -top adff
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd adff # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-none t:TRELLIS_FF %% t:* %D
design -load read
hierarchy -top adffn
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd adffn # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-count 1 t:LUT4
select -assert-none t:TRELLIS_FF t:LUT4 %% t:* %D
design -load read
hierarchy -top dffs
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dffs # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-count 1 t:LUT4
select -assert-none t:TRELLIS_FF t:LUT4 %% t:* %D
design -load read
hierarchy -top ndffnr
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd ndffnr # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-count 1 t:LUT4
select -assert-none t:TRELLIS_FF t:LUT4 %% t:* %D

17
tests/ecp5/counter.v Normal file
View file

@ -0,0 +1,17 @@
module top (
out,
clk,
reset
);
output [7:0] out;
input clk, reset;
reg [7:0] out;
always @(posedge clk, posedge reset)
if (reset) begin
out <= 8'b0 ;
end else
out <= out + 1;
endmodule

10
tests/ecp5/counter.ys Normal file
View file

@ -0,0 +1,10 @@
read_verilog counter.v
hierarchy -top top
proc
flatten
equiv_opt -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 4 t:CCU2C
select -assert-count 8 t:TRELLIS_FF
select -assert-none t:CCU2C t:TRELLIS_FF %% t:* %D

15
tests/ecp5/dffs.v Normal file
View file

@ -0,0 +1,15 @@
module dff
( input d, clk, output reg q );
always @( posedge clk )
q <= d;
endmodule
module dffe
( input d, clk, en, output reg q );
initial begin
q = 0;
end
always @( posedge clk )
if ( en )
q <= d;
endmodule

19
tests/ecp5/dffs.ys Normal file
View file

@ -0,0 +1,19 @@
read_verilog dffs.v
design -save read
hierarchy -top dff
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dff # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-none t:TRELLIS_FF %% t:* %D
design -load read
hierarchy -top dffe
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dffe # Constrain all select calls below inside the top module
select -assert-count 1 t:TRELLIS_FF
select -assert-none t:TRELLIS_FF %% t:* %D

23
tests/ecp5/dpram.v Normal file
View file

@ -0,0 +1,23 @@
/*
Example from: https://www.latticesemi.com/-/media/LatticeSemi/Documents/UserManuals/EI/iCEcube201701UserGuide.ashx?document_id=52071 [p. 72].
*/
module top (din, write_en, waddr, wclk, raddr, rclk, dout);
parameter addr_width = 8;
parameter data_width = 8;
input [addr_width-1:0] waddr, raddr;
input [data_width-1:0] din;
input write_en, wclk, rclk;
output [data_width-1:0] dout;
reg [data_width-1:0] dout;
reg [data_width-1:0] mem [(1<<addr_width)-1:0]
/* synthesis syn_ramstyle = "no_rw_check" */ ;
always @(posedge wclk) // Write memory.
begin
if (write_en)
mem[waddr] <= din; // Using write address bus.
end
always @(posedge rclk) // Read memory.
begin
dout <= mem[raddr]; // Using read address bus.
end
endmodule

18
tests/ecp5/dpram.ys Normal file
View file

@ -0,0 +1,18 @@
read_verilog dpram.v
hierarchy -top top
proc
memory -nomap
equiv_opt -run :prove -map +/ecp5/cells_sim.v synth_ecp5
memory
opt -full
miter -equiv -flatten -make_assert -make_outputs gold gate miter
#Blocked by issue #1358 (Missing ECP5 simulation models)
#ERROR: Failed to import cell gate.mem.0.0.0 (type DP16KD) to SAT database.
#sat -verify -prove-asserts -seq 3 -set-init-zero -show-inputs -show-outputs miter
design -load postopt
cd top
select -assert-count 1 t:DP16KD
select -assert-none t:DP16KD %% t:* %D

55
tests/ecp5/fsm.v Normal file
View file

@ -0,0 +1,55 @@
module fsm (
clock,
reset,
req_0,
req_1,
gnt_0,
gnt_1
);
input clock,reset,req_0,req_1;
output gnt_0,gnt_1;
wire clock,reset,req_0,req_1;
reg gnt_0,gnt_1;
parameter SIZE = 3 ;
parameter IDLE = 3'b001,GNT0 = 3'b010,GNT1 = 3'b100,GNT2 = 3'b101 ;
reg [SIZE-1:0] state;
reg [SIZE-1:0] next_state;
always @ (posedge clock)
begin : FSM
if (reset == 1'b1) begin
state <= #1 IDLE;
gnt_0 <= 0;
gnt_1 <= 0;
end else
case(state)
IDLE : if (req_0 == 1'b1) begin
state <= #1 GNT0;
gnt_0 <= 1;
end else if (req_1 == 1'b1) begin
gnt_1 <= 1;
state <= #1 GNT0;
end else begin
state <= #1 IDLE;
end
GNT0 : if (req_0 == 1'b1) begin
state <= #1 GNT0;
end else begin
gnt_0 <= 0;
state <= #1 IDLE;
end
GNT1 : if (req_1 == 1'b1) begin
state <= #1 GNT2;
gnt_1 <= req_0;
end
GNT2 : if (req_0 == 1'b1) begin
state <= #1 GNT1;
gnt_1 <= req_1;
end
default : state <= #1 IDLE;
endcase
end
endmodule

12
tests/ecp5/fsm.ys Normal file
View file

@ -0,0 +1,12 @@
read_verilog fsm.v
hierarchy -top fsm
proc
flatten
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd fsm # Constrain all select calls below inside the top module
select -assert-count 1 t:L6MUX21
select -assert-count 13 t:LUT4
select -assert-count 5 t:PFUMX
select -assert-count 5 t:TRELLIS_FF
select -assert-none t:L6MUX21 t:LUT4 t:PFUMX t:TRELLIS_FF %% t:* %D

24
tests/ecp5/latches.v Normal file
View file

@ -0,0 +1,24 @@
module latchp
( input d, clk, en, output reg q );
always @*
if ( en )
q <= d;
endmodule
module latchn
( input d, clk, en, output reg q );
always @*
if ( !en )
q <= d;
endmodule
module latchsr
( input d, clk, en, clr, pre, output reg q );
always @*
if ( clr )
q <= 1'b0;
else if ( pre )
q <= 1'b1;
else if ( en )
q <= d;
endmodule

35
tests/ecp5/latches.ys Normal file
View file

@ -0,0 +1,35 @@
read_verilog latches.v
design -save read
hierarchy -top latchp
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_ecp5
cd latchp # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT4
select -assert-none t:LUT4 %% t:* %D
design -load read
hierarchy -top latchn
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_ecp5
cd latchn # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT4
select -assert-none t:LUT4 %% t:* %D
design -load read
hierarchy -top latchsr
proc
# Can't run any sort of equivalence check because latches are blown to LUTs
synth_ecp5
cd latchsr # Constrain all select calls below inside the top module
select -assert-count 2 t:LUT4
select -assert-count 1 t:PFUMX
select -assert-none t:LUT4 t:PFUMX %% t:* %D

18
tests/ecp5/logic.v Normal file
View file

@ -0,0 +1,18 @@
module top
(
input [0:7] in,
output B1,B2,B3,B4,B5,B6,B7,B8,B9,B10
);
assign B1 = in[0] & in[1];
assign B2 = in[0] | in[1];
assign B3 = in[0] ~& in[1];
assign B4 = in[0] ~| in[1];
assign B5 = in[0] ^ in[1];
assign B6 = in[0] ~^ in[1];
assign B7 = ~in[0];
assign B8 = in[0];
assign B9 = in[0:1] && in [2:3];
assign B10 = in[0:1] || in [2:3];
endmodule

8
tests/ecp5/logic.ys Normal file
View file

@ -0,0 +1,8 @@
read_verilog logic.v
hierarchy -top top
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 9 t:LUT4
select -assert-none t:LUT4 %% t:* %D

25
tests/ecp5/macc.v Normal file
View file

@ -0,0 +1,25 @@
/*
Example from: https://www.latticesemi.com/-/media/LatticeSemi/Documents/UserManuals/EI/iCEcube201701UserGuide.ashx?document_id=52071 [p. 77].
*/
module top(clk,a,b,c,set);
parameter A_WIDTH = 4;
parameter B_WIDTH = 3;
input set;
input clk;
input signed [(A_WIDTH - 1):0] a;
input signed [(B_WIDTH - 1):0] b;
output signed [(A_WIDTH + B_WIDTH - 1):0] c;
reg [(A_WIDTH + B_WIDTH - 1):0] reg_tmp_c;
assign c = reg_tmp_c;
always @(posedge clk)
begin
if(set)
begin
reg_tmp_c <= 0;
end
else
begin
reg_tmp_c <= a * b + c;
end
end
endmodule

13
tests/ecp5/macc.ys Normal file
View file

@ -0,0 +1,13 @@
read_verilog macc.v
hierarchy -top top
proc
# Blocked by issue #1358 (Missing ECP5 simulation models)
#equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
equiv_opt -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:MULT18X18D
select -assert-count 4 t:CCU2C
select -assert-count 7 t:TRELLIS_FF
select -assert-none t:CCU2C t:MULT18X18D t:TRELLIS_FF %% t:* %D

21
tests/ecp5/memory.v Normal file
View file

@ -0,0 +1,21 @@
module top
(
input [7:0] data_a,
input [6:1] addr_a,
input we_a, clk,
output reg [7:0] q_a
);
// Declare the RAM variable
reg [7:0] ram[63:0];
// Port A
always @ (posedge clk)
begin
if (we_a)
begin
ram[addr_a] <= data_a;
q_a <= data_a;
end
q_a <= ram[addr_a];
end
endmodule

19
tests/ecp5/memory.ys Normal file
View file

@ -0,0 +1,19 @@
read_verilog memory.v
hierarchy -top top
proc
memory -nomap
equiv_opt -run :prove -map +/ecp5/cells_sim.v synth_ecp5
memory
opt -full
miter -equiv -flatten -make_assert -make_outputs gold gate miter
sat -verify -prove-asserts -seq 5 -set-init-zero -show-inputs -show-outputs miter
design -load postopt
cd top
select -assert-count 24 t:L6MUX21
select -assert-count 71 t:LUT4
select -assert-count 32 t:PFUMX
select -assert-count 8 t:TRELLIS_DPR16X4
select -assert-count 35 t:TRELLIS_FF
select -assert-none t:L6MUX21 t:LUT4 t:PFUMX t:TRELLIS_DPR16X4 t:TRELLIS_FF %% t:* %D

11
tests/ecp5/mul.v Normal file
View file

@ -0,0 +1,11 @@
module top
(
input [5:0] x,
input [5:0] y,
output [11:0] A,
);
assign A = x * y;
endmodule

11
tests/ecp5/mul.ys Normal file
View file

@ -0,0 +1,11 @@
read_verilog mul.v
hierarchy -top top
proc
# Blocked by issue #1358 (Missing ECP5 simulation models)
#equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
equiv_opt -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:MULT18X18D
select -assert-none t:MULT18X18D %% t:* %D

66
tests/ecp5/mux.v Normal file
View file

@ -0,0 +1,66 @@
module mux2 (S,A,B,Y);
input S;
input A,B;
output reg Y;
always @(*)
Y = (S)? B : A;
endmodule
module mux4 ( S, D, Y );
input[1:0] S;
input[3:0] D;
output Y;
reg Y;
wire[1:0] S;
wire[3:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
endcase
end
endmodule
module mux8 ( S, D, Y );
input[2:0] S;
input[7:0] D;
output Y;
reg Y;
wire[2:0] S;
wire[7:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
4 : Y = D[4];
5 : Y = D[5];
6 : Y = D[6];
7 : Y = D[7];
endcase
end
endmodule
module mux16 (D, S, Y);
input [15:0] D;
input [3:0] S;
output Y;
assign Y = D[S];
endmodule

46
tests/ecp5/mux.ys Normal file
View file

@ -0,0 +1,46 @@
read_verilog mux.v
design -save read
hierarchy -top mux2
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux2 # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT4
select -assert-none t:LUT4 %% t:* %D
design -load read
hierarchy -top mux4
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux4 # Constrain all select calls below inside the top module
select -assert-count 1 t:L6MUX21
select -assert-count 4 t:LUT4
select -assert-count 2 t:PFUMX
select -assert-none t:LUT4 t:L6MUX21 t:PFUMX %% t:* %D
design -load read
hierarchy -top mux8
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux8 # Constrain all select calls below inside the top module
select -assert-count 1 t:L6MUX21
select -assert-count 7 t:LUT4
select -assert-count 2 t:PFUMX
select -assert-none t:LUT4 t:L6MUX21 t:PFUMX %% t:* %D
design -load read
hierarchy -top mux16
proc
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux16 # Constrain all select calls below inside the top module
select -assert-count 8 t:L6MUX21
select -assert-count 26 t:LUT4
select -assert-count 12 t:PFUMX
select -assert-none t:LUT4 t:L6MUX21 t:PFUMX %% t:* %D

18
tests/ecp5/rom.v Normal file
View file

@ -0,0 +1,18 @@
/*
Example from: https://www.latticesemi.com/-/media/LatticeSemi/Documents/UserManuals/EI/iCEcube201701UserGuide.ashx?document_id=52071 [p. 74].
*/
module top(data, addr);
output [3:0] data;
input [4:0] addr;
always @(addr) begin
case (addr)
0 : data = 'h4;
1 : data = 'h9;
2 : data = 'h1;
15 : data = 'h8;
16 : data = 'h1;
17 : data = 'h0;
default : data = 'h0;
endcase
end
endmodule

10
tests/ecp5/rom.ys Normal file
View file

@ -0,0 +1,10 @@
read_verilog rom.v
hierarchy -top top
proc
flatten
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 6 t:LUT4
select -assert-count 3 t:PFUMX
select -assert-none t:LUT4 t:PFUMX %% t:* %D

20
tests/ecp5/run-test.sh Executable file
View file

@ -0,0 +1,20 @@
#!/usr/bin/env bash
set -e
{
echo "all::"
for x in *.ys; do
echo "all:: run-$x"
echo "run-$x:"
echo " @echo 'Running $x..'"
echo " @../../yosys -ql ${x%.ys}.log -w 'Yosys has only limited support for tri-state logic at the moment.' $x"
done
for s in *.sh; do
if [ "$s" != "run-test.sh" ]; then
echo "all:: run-$s"
echo "run-$s:"
echo " @echo 'Running $s..'"
echo " @bash $s"
fi
done
} > run-test.mk
exec ${MAKE:-make} -f run-test.mk

16
tests/ecp5/shifter.v Normal file
View file

@ -0,0 +1,16 @@
module top (
out,
clk,
in
);
output [7:0] out;
input signed clk, in;
reg signed [7:0] out = 0;
always @(posedge clk)
begin
out <= out >> 1;
out[7] <= in;
end
endmodule

10
tests/ecp5/shifter.ys Normal file
View file

@ -0,0 +1,10 @@
read_verilog shifter.v
hierarchy -top top
proc
flatten
equiv_opt -assert -map +/ecp5/cells_sim.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 8 t:TRELLIS_FF
select -assert-none t:TRELLIS_FF %% t:* %D

8
tests/ecp5/tribuf.v Normal file
View file

@ -0,0 +1,8 @@
module tristate (en, i, o);
input en;
input i;
output o;
assign o = en ? i : 1'bz;
endmodule

9
tests/ecp5/tribuf.ys Normal file
View file

@ -0,0 +1,9 @@
read_verilog tribuf.v
hierarchy -top tristate
proc
flatten
equiv_opt -assert -map +/ecp5/cells_sim.v -map +/simcells.v synth_ecp5 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd tristate # Constrain all select calls below inside the top module
select -assert-count 1 t:$_TBUF_
select -assert-none t:$_TBUF_ %% t:* %D

9
tests/ice40/latches.ys
View file

@ -1,14 +1,11 @@
read_verilog latches.v
design -save read
proc
async2sync # converts latches to a 'sync' variant clocked by a 'super'-clock
flatten
synth_ice40
equiv_opt -assert -map +/ice40/cells_sim.v synth_ice40 # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
# Can't run any sort of equivalence check because latches are blown to LUTs
#equiv_opt -async2sync -assert -map +/ice40/cells_sim.v synth_ice40 # equivalency check
design -load read
#design -load preopt
synth_ice40
cd top
select -assert-count 4 t:SB_LUT4

22
tests/ice40/wrapcarry.ys Normal file
View file

@ -0,0 +1,22 @@
read_verilog <<EOT
module top(input A, B, CI, output O, CO);
SB_CARRY carry (
.I0(A),
.I1(B),
.CI(CI),
.CO(CO)
);
SB_LUT4 #(
.LUT_INIT(16'b 0110_1001_1001_0110)
) adder (
.I0(1'b0),
.I1(A),
.I2(B),
.I3(1'b0),
.O(O)
);
endmodule
EOT
ice40_wrapcarry
select -assert-count 1 t:$__ICE40_CARRY_WRAPPER

3
tests/svtypes/.gitignore vendored Normal file
View file

@ -0,0 +1,3 @@
/*.log
/*.out
/run-test.mk

20
tests/svtypes/run-test.sh Executable file
View file

@ -0,0 +1,20 @@
#!/usr/bin/env bash
set -e
{
echo "all::"
for x in *.ys; do
echo "all:: run-$x"
echo "run-$x:"
echo " @echo 'Running $x..'"
echo " @../../yosys -ql ${x%.ys}.log $x"
done
for x in *.sv; do
if [ ! -f "${x%.sv}.ys" ]; then
echo "all:: check-$x"
echo "check-$x:"
echo " @echo 'Checking $x..'"
echo " @../../yosys -ql ${x%.sv}.log -p \"prep -top top; sat -verify -prove-asserts\" $x"
fi
done
} > run-test.mk
exec ${MAKE:-make} -f run-test.mk

10
tests/svtypes/typedef_memory.sv Normal file
View file

@ -0,0 +1,10 @@
module top(input [3:0] addr, wdata, input clk, wen, output reg [3:0] rdata);
typedef logic [3:0] ram16x4_t[0:15];
(ram16x4_t) mem;
always @(posedge clk) begin
if (wen) mem[addr] <= wdata;
rdata <= mem[addr];
end
endmodule

3
tests/svtypes/typedef_memory.ys Normal file
View file

@ -0,0 +1,3 @@
read_verilog -sv typedef_memory.sv
prep -top top
select -assert-count 1 t:$mem r:SIZE=16 %i r:WIDTH=4 %i

10
tests/svtypes/typedef_memory_2.sv Normal file
View file

@ -0,0 +1,10 @@
module top(input [3:0] addr, wdata, input clk, wen, output reg [3:0] rdata);
typedef logic [3:0] nibble;
(nibble) mem[0:15];
always @(posedge clk) begin
if (wen) mem[addr] <= wdata;
rdata <= mem[addr];
end
endmodule

4
tests/svtypes/typedef_memory_2.ys Normal file
View file

@ -0,0 +1,4 @@
read_verilog -sv typedef_memory_2.sv
prep -top top
dump
select -assert-count 1 t:$mem r:SIZE=16 %i r:WIDTH=4 %i

11
tests/svtypes/typedef_package.sv Normal file
View file

@ -0,0 +1,11 @@
package pkg;
typedef logic [7:0] uint8_t;
endpackage
module top;
(* keep *) (pkg::uint8_t) a = 8'hAA;
always @* assert(a == 8'hAA);
endmodule

22
tests/svtypes/typedef_param.sv Normal file
View file

@ -0,0 +1,22 @@
`define STRINGIFY(x) `"x`"
`define STATIC_ASSERT(x) if(!(x)) $error({"assert failed: ", `STRINGIFY(x)})
module top;
typedef logic [1:0] uint2_t;
typedef logic signed [3:0] int4_t;
typedef logic signed [7:0] int8_t;
typedef (int8_t) char_t;
parameter (uint2_t) int2 = 2'b10;
localparam (int4_t) int4 = -1;
localparam (int8_t) int8 = int4;
localparam (char_t) ch = int8;
`STATIC_ASSERT(int2 == 2'b10);
`STATIC_ASSERT(int4 == 4'b1111);
`STATIC_ASSERT(int8 == 8'b11111111);
`STATIC_ASSERT(ch == 8'b11111111);
endmodule

23
tests/svtypes/typedef_scopes.sv Normal file
View file

@ -0,0 +1,23 @@
typedef logic [3:0] outer_uint4_t;
module top;
(outer_uint4_t) u4_i = 8'hA5;
always @(*) assert(u4_i == 4'h5);
typedef logic [3:0] inner_type;
(inner_type) inner_i1 = 8'h5A;
always @(*) assert(inner_i1 == 4'hA);
if (1) begin: genblock
typedef logic [7:0] inner_type;
(inner_type) inner_gb_i = 8'hA5;
always @(*) assert(inner_gb_i == 8'hA5);
end
(inner_type) inner_i2 = 8'h42;
always @(*) assert(inner_i2 == 4'h2);
endmodule

19
tests/svtypes/typedef_simple.sv Normal file
View file

@ -0,0 +1,19 @@
module top;
typedef logic [1:0] uint2_t;
typedef logic signed [3:0] int4_t;
typedef logic signed [7:0] int8_t;
typedef (int8_t) char_t;
(* keep *) (uint2_t) int2 = 2'b10;
(* keep *) (int4_t) int4 = -1;
(* keep *) (int8_t) int8 = int4;
(* keep *) (char_t) ch = int8;
always @* assert(int2 == 2'b10);
always @* assert(int4 == 4'b1111);
always @* assert(int8 == 8'b11111111);
always @* assert(ch == 8'b11111111);
endmodule

42
tests/various/peepopt.ys
View file

@ -131,8 +131,8 @@ EOT
proc
equiv_opt -assert peepopt
design -load postopt
select -assert-count 1 t:$dff r:WIDTH=5 %i
select -assert-count 1 t:$mux r:WIDTH=5 %i
select -assert-count 1 t:$dff r:WIDTH=4 %i
select -assert-count 1 t:$mux r:WIDTH=4 %i
select -assert-count 0 t:$dff t:$mux %% t:* %D
####################
@ -173,3 +173,41 @@ select -assert-count 1 t:$dff r:WIDTH=2 %i
select -assert-count 2 t:$mux
select -assert-count 2 t:$mux r:WIDTH=2 %i
select -assert-count 0 t:$logic_not t:$dff t:$mux %% t:* %D
####################
design -reset
read_verilog <<EOT
module peepopt_dffmuxext_signed_rst_init(input clk, ce, rstn, input signed [1:0] i, output reg signed [3:0] o);
initial o <= 4'b0010;
always @(posedge clk) begin
if (ce) o <= i;
if (!rstn) o <= 4'b1111;
end
endmodule
EOT
proc
# NB: equiv_opt uses equiv_induct which covers
# only the induction half of temporal induction
# --- missing the base-case half
# This makes it akin to `sat -tempinduct-inductonly`
# instead of `sat -tempinduct-baseonly` or
# `sat -tempinduct` which is necessary for this
# testcase
#equiv_opt -assert peepopt
design -save gold
peepopt
wreduce
design -stash gate
design -import gold -as gold
design -import gate -as gate
miter -equiv -flatten -make_assert -make_outputs gold gate miter
sat -tempinduct -verify -prove-asserts -show-ports miter
design -load gate
select -assert-count 1 t:$dff r:WIDTH=4 %i
select -assert-count 2 t:$mux
select -assert-count 2 t:$mux r:WIDTH=4 %i
select -assert-count 0 t:$logic_not t:$dff t:$mux %% t:* %D

1
tests/xilinx/.gitignore vendored
View file

@ -2,3 +2,4 @@
/*.out
/run-test.mk
/*_uut.v
/test_macc

13
tests/xilinx/add_sub.v Normal file
View file

@ -0,0 +1,13 @@
module top
(
input [3:0] x,
input [3:0] y,
output [3:0] A,
output [3:0] B
);
assign A = x + y;
assign B = x - y;
endmodule

11
tests/xilinx/add_sub.ys Normal file
View file

@ -0,0 +1,11 @@
read_verilog add_sub.v
hierarchy -top top
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 14 t:LUT2
select -assert-count 6 t:MUXCY
select -assert-count 8 t:XORCY
select -assert-none t:LUT2 t:MUXCY t:XORCY %% t:* %D

47
tests/xilinx/adffs.v Normal file
View file

@ -0,0 +1,47 @@
module adff
( input d, clk, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk, posedge clr )
if ( clr )
q <= 1'b0;
else
q <= d;
endmodule
module adffn
( input d, clk, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk, negedge clr )
if ( !clr )
q <= 1'b0;
else
q <= d;
endmodule
module dffs
( input d, clk, pre, clr, output reg q );
initial begin
q = 0;
end
always @( posedge clk )
if ( pre )
q <= 1'b1;
else
q <= d;
endmodule
module ndffnr
( input d, clk, pre, clr, output reg q );
initial begin
q = 0;
end
always @( negedge clk )
if ( !clr )
q <= 1'b0;
else
q <= d;
endmodule

51
tests/xilinx/adffs.ys Normal file
View file

@ -0,0 +1,51 @@
read_verilog adffs.v
design -save read
hierarchy -top adff
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd adff # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDCE
select -assert-none t:BUFG t:FDCE %% t:* %D
design -load read
hierarchy -top adffn
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd adffn # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDCE
select -assert-count 1 t:LUT1
select -assert-none t:BUFG t:FDCE t:LUT1 %% t:* %D
design -load read
hierarchy -top dffs
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dffs # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDRE
select -assert-count 1 t:LUT2
select -assert-none t:BUFG t:FDRE t:LUT2 %% t:* %D
design -load read
hierarchy -top ndffnr
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd ndffnr # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDRE_1
select -assert-count 1 t:LUT2
select -assert-none t:BUFG t:FDRE_1 t:LUT2 %% t:* %D

17
tests/xilinx/counter.v Normal file
View file

@ -0,0 +1,17 @@
module top (
out,
clk,
reset
);
output [7:0] out;
input clk, reset;
reg [7:0] out;
always @(posedge clk, posedge reset)
if (reset) begin
out <= 8'b0 ;
end else
out <= out + 1;
endmodule

14
tests/xilinx/counter.ys Normal file
View file

@ -0,0 +1,14 @@
read_verilog counter.v
hierarchy -top top
proc
flatten
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 8 t:FDCE
select -assert-count 1 t:LUT1
select -assert-count 7 t:MUXCY
select -assert-count 8 t:XORCY
select -assert-none t:BUFG t:FDCE t:LUT1 t:MUXCY t:XORCY %% t:* %D

15
tests/xilinx/dffs.v Normal file
View file

@ -0,0 +1,15 @@
module dff
( input d, clk, output reg q );
always @( posedge clk )
q <= d;
endmodule
module dffe
( input d, clk, en, output reg q );
initial begin
q = 0;
end
always @( posedge clk )
if ( en )
q <= d;
endmodule

25
tests/xilinx/dffs.ys Normal file
View file

@ -0,0 +1,25 @@
read_verilog dffs.v
design -save read
hierarchy -top dff
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dff # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDRE
select -assert-none t:BUFG t:FDRE %% t:* %D
design -load read
hierarchy -top dffe
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd dffe # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 1 t:FDRE
select -assert-none t:BUFG t:FDRE %% t:* %D

55
tests/xilinx/fsm.v Normal file
View file

@ -0,0 +1,55 @@
module fsm (
clock,
reset,
req_0,
req_1,
gnt_0,
gnt_1
);
input clock,reset,req_0,req_1;
output gnt_0,gnt_1;
wire clock,reset,req_0,req_1;
reg gnt_0,gnt_1;
parameter SIZE = 3 ;
parameter IDLE = 3'b001,GNT0 = 3'b010,GNT1 = 3'b100,GNT2 = 3'b101 ;
reg [SIZE-1:0] state;
reg [SIZE-1:0] next_state;
always @ (posedge clock)
begin : FSM
if (reset == 1'b1) begin
state <= #1 IDLE;
gnt_0 <= 0;
gnt_1 <= 0;
end else
case(state)
IDLE : if (req_0 == 1'b1) begin
state <= #1 GNT0;
gnt_0 <= 1;
end else if (req_1 == 1'b1) begin
gnt_1 <= 1;
state <= #1 GNT0;
end else begin
state <= #1 IDLE;
end
GNT0 : if (req_0 == 1'b1) begin
state <= #1 GNT0;
end else begin
gnt_0 <= 0;
state <= #1 IDLE;
end
GNT1 : if (req_1 == 1'b1) begin
state <= #1 GNT2;
gnt_1 <= req_0;
end
GNT2 : if (req_0 == 1'b1) begin
state <= #1 GNT1;
gnt_1 <= req_1;
end
default : state <= #1 IDLE;
endcase
end
endmodule

14
tests/xilinx/fsm.ys Normal file
View file

@ -0,0 +1,14 @@
read_verilog fsm.v
hierarchy -top fsm
proc
flatten
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd fsm # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 5 t:FDRE
select -assert-count 1 t:LUT3
select -assert-count 2 t:LUT4
select -assert-count 4 t:LUT6
select -assert-none t:BUFG t:FDRE t:LUT3 t:LUT4 t:LUT6 %% t:* %D

40
tests/xilinx/latches.v
View file

@ -1,19 +1,19 @@
module latchp
( input d, en, output reg q );
( input d, clk, en, output reg q );
always @*
if ( en )
q <= d;
endmodule
module latchn
( input d, en, output reg q );
( input d, clk, en, output reg q );
always @*
if ( !en )
q <= d;
endmodule
module latchsr
( input d, en, clr, pre, output reg q );
( input d, clk, en, clr, pre, output reg q );
always @*
if ( clr )
q <= 1'b0;
@ -22,37 +22,3 @@ module latchsr
else if ( en )
q <= d;
endmodule
module top (
input clk,
input clr,
input pre,
input a,
output b,b1,b2
);
latchp u_latchp (
.en (clk ),
.d (a ),
.q (b )
);
latchn u_latchn (
.en (clk ),
.d (a ),
.q (b1 )
);
latchsr u_latchsr (
.en (clk ),
.clr (clr),
.pre (pre),
.d (a ),
.q (b2 )
);
endmodule

38
tests/xilinx/latches.ys
View file

@ -1,15 +1,35 @@
read_verilog latches.v
design -save read
hierarchy -top latchp
proc
flatten
equiv_opt -assert -run :prove -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
async2sync
equiv_opt -assert -run prove: -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd latchp # Constrain all select calls below inside the top module
select -assert-count 1 t:LDCE
design -load preopt
synth_xilinx
cd top
select -assert-none t:LDCE %% t:* %D
design -load read
hierarchy -top latchn
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd latchn # Constrain all select calls below inside the top module
select -assert-count 1 t:LDCE
select -assert-count 1 t:LUT1
select -assert-none t:LDCE t:LUT1 %% t:* %D
design -load read
hierarchy -top latchsr
proc
equiv_opt -async2sync -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd latchsr # Constrain all select calls below inside the top module
select -assert-count 1 t:LDCE
select -assert-count 2 t:LUT3
select -assert-count 3 t:LDCE
select -assert-none t:LUT1 t:LUT3 t:LDCE %% t:* %D
select -assert-none t:LDCE t:LUT3 %% t:* %D

18
tests/xilinx/logic.v Normal file
View file

@ -0,0 +1,18 @@
module top
(
input [0:7] in,
output B1,B2,B3,B4,B5,B6,B7,B8,B9,B10
);
assign B1 = in[0] & in[1];
assign B2 = in[0] | in[1];
assign B3 = in[0] ~& in[1];
assign B4 = in[0] ~| in[1];
assign B5 = in[0] ^ in[1];
assign B6 = in[0] ~^ in[1];
assign B7 = ~in[0];
assign B8 = in[0];
assign B9 = in[0:1] && in [2:3];
assign B10 = in[0:1] || in [2:3];
endmodule

11
tests/xilinx/logic.ys Normal file
View file

@ -0,0 +1,11 @@
read_verilog logic.v
hierarchy -top top
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT1
select -assert-count 6 t:LUT2
select -assert-count 2 t:LUT4
select -assert-none t:LUT1 t:LUT2 t:LUT4 %% t:* %D

4
tests/xilinx/macc.ys
View file

@ -1,8 +1,8 @@
read_verilog macc.v
design -save read
proc
hierarchy -top macc
proc
#equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx ### TODO
equiv_opt -run :prove -map +/xilinx/cells_sim.v synth_xilinx
miter -equiv -flatten -make_assert -make_outputs gold gate miter
@ -15,8 +15,8 @@ select -assert-count 1 t:DSP48E1
select -assert-none t:BUFG t:FDRE t:DSP48E1 %% t:* %D
design -load read
proc
hierarchy -top macc2
proc
#equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx ### TODO
equiv_opt -run :prove -map +/xilinx/cells_sim.v synth_xilinx
miter -equiv -flatten -make_assert -make_outputs gold gate miter

21
tests/xilinx/memory.v Normal file
View file

@ -0,0 +1,21 @@
module top
(
input [7:0] data_a,
input [6:1] addr_a,
input we_a, clk,
output reg [7:0] q_a
);
// Declare the RAM variable
reg [7:0] ram[63:0];
// Port A
always @ (posedge clk)
begin
if (we_a)
begin
ram[addr_a] <= data_a;
q_a <= data_a;
end
q_a <= ram[addr_a];
end
endmodule

17
tests/xilinx/memory.ys Normal file
View file

@ -0,0 +1,17 @@
read_verilog memory.v
hierarchy -top top
proc
memory -nomap
equiv_opt -run :prove -map +/xilinx/cells_sim.v synth_xilinx
memory
opt -full
miter -equiv -flatten -make_assert -make_outputs gold gate miter
sat -verify -prove-asserts -seq 5 -set-init-zero -show-inputs -show-outputs miter
design -load postopt
cd top
select -assert-count 1 t:BUFG
select -assert-count 8 t:FDRE
select -assert-count 8 t:RAM64X1D
select -assert-none t:BUFG t:FDRE t:RAM64X1D %% t:* %D

11
tests/xilinx/mul.v Normal file
View file

@ -0,0 +1,11 @@
module top
(
input [5:0] x,
input [5:0] y,
output [11:0] A,
);
assign A = x * y;
endmodule

9
tests/xilinx/mul.ys Normal file
View file

@ -0,0 +1,9 @@
read_verilog mul.v
hierarchy -top top
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:DSP48E1
select -assert-none t:DSP48E1 %% t:* %D

3
tests/xilinx/mul_unsigned.ys
View file

@ -1,6 +1,7 @@
read_verilog mul_unsigned.v
proc
hierarchy -top mul_unsigned
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mul_unsigned # Constrain all select calls below inside the top module

65
tests/xilinx/mux.v Normal file
View file

@ -0,0 +1,65 @@
module mux2 (S,A,B,Y);
input S;
input A,B;
output reg Y;
always @(*)
Y = (S)? B : A;
endmodule
module mux4 ( S, D, Y );
input[1:0] S;
input[3:0] D;
output Y;
reg Y;
wire[1:0] S;
wire[3:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
endcase
end
endmodule
module mux8 ( S, D, Y );
input[2:0] S;
input[7:0] D;
output Y;
reg Y;
wire[2:0] S;
wire[7:0] D;
always @*
begin
case( S )
0 : Y = D[0];
1 : Y = D[1];
2 : Y = D[2];
3 : Y = D[3];
4 : Y = D[4];
5 : Y = D[5];
6 : Y = D[6];
7 : Y = D[7];
endcase
end
endmodule
module mux16 (D, S, Y);
input [15:0] D;
input [3:0] S;
output Y;
assign Y = D[S];
endmodule

45
tests/xilinx/mux.ys Normal file
View file

@ -0,0 +1,45 @@
read_verilog mux.v
design -save read
hierarchy -top mux2
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux2 # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT3
select -assert-none t:LUT3 %% t:* %D
design -load read
hierarchy -top mux4
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux4 # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT6
select -assert-none t:LUT6 %% t:* %D
design -load read
hierarchy -top mux8
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux8 # Constrain all select calls below inside the top module
select -assert-count 1 t:LUT3
select -assert-count 2 t:LUT6
select -assert-none t:LUT3 t:LUT6 %% t:* %D
design -load read
hierarchy -top mux16
proc
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd mux16 # Constrain all select calls below inside the top module
select -assert-count 5 t:LUT6
select -assert-none t:LUT6 %% t:* %D

2
tests/xilinx/run-test.sh
View file

@ -6,7 +6,7 @@ for x in *.ys; do
echo "all:: run-$x"
echo "run-$x:"
echo " @echo 'Running $x..'"
echo " @../../yosys -ql ${x%.ys}.log $x"
echo " @../../yosys -ql ${x%.ys}.log -w 'Yosys has only limited support for tri-state logic at the moment.' $x"
done
for s in *.sh; do
if [ "$s" != "run-test.sh" ]; then

16
tests/xilinx/shifter.v Normal file
View file

@ -0,0 +1,16 @@
module top (
out,
clk,
in
);
output [7:0] out;
input signed clk, in;
reg signed [7:0] out = 0;
always @(posedge clk)
begin
out <= out >> 1;
out[7] <= in;
end
endmodule

11
tests/xilinx/shifter.ys Normal file
View file

@ -0,0 +1,11 @@
read_verilog shifter.v
hierarchy -top top
proc
flatten
equiv_opt -assert -map +/xilinx/cells_sim.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd top # Constrain all select calls below inside the top module
select -assert-count 1 t:BUFG
select -assert-count 8 t:FDRE
select -assert-none t:BUFG t:FDRE %% t:* %D

8
tests/xilinx/tribuf.v Normal file
View file

@ -0,0 +1,8 @@
module tristate (en, i, o);
input en;
input i;
output reg o;
always @(en or i)
o <= (en)? i : 1'bZ;
endmodule

12
tests/xilinx/tribuf.ys Normal file
View file

@ -0,0 +1,12 @@
read_verilog tribuf.v
hierarchy -top tristate
proc
tribuf
flatten
synth
equiv_opt -assert -map +/xilinx/cells_sim.v -map +/simcells.v synth_xilinx # equivalency check
design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
cd tristate # Constrain all select calls below inside the top module
# TODO :: Tristate logic not yet supported; see https://github.com/YosysHQ/yosys/issues/1225
select -assert-count 1 t:$_TBUF_
select -assert-none t:$_TBUF_ %% t:* %D