Merge pull request #1435 from YosysHQ/mmicko/efinix

Add tests for Efinix architecture (contd)
2025-06-11 08:33:26 +00:00 · 2019-10-18 10:54:35 +02:00 · 2019-10-18 10:54:35 +02:00 · 0568920d79
commit 0568920d79
parent ab4899a2d0 b4d7650548
27 changed files with 572 additions and 1 deletions
--- a/1
+++ b/1
@ -715,6 +715,7 @@ test: $(TARGETS) $(EXTRA_TARGETS)
 	+cd tests/arch && bash run-test.sh
 	+cd tests/ice40 && bash run-test.sh $(SEEDOPT)
 	+cd tests/rpc && bash run-test.sh
 	+cd tests/efinix && bash run-test.sh $(SEEDOPT)
 	+cd tests/anlogic && bash run-test.sh $(SEEDOPT)
 	+cd tests/ecp5 && bash run-test.sh $(SEEDOPT)
 	+cd tests/xilinx && bash run-test.sh $(SEEDOPT)
--- a/techlibs/efinix/cells_map.v
+++ b/techlibs/efinix/cells_map.v
@ -17,6 +17,18 @@ module  \$_DFF_NP1_ (input D, C, R, output Q); EFX_FF #(.CLK_POLARITY(1'b0), .CE
 module  \$_DFF_PP0_ (input D, C, R, output Q); EFX_FF #(.CLK_POLARITY(1'b1), .CE_POLARITY(1'b1), .SR_POLARITY(1'b1), .D_POLARITY(1'b1), .SR_SYNC(1'b0), .SR_VALUE(1'b0), .SR_SYNC_PRIORITY(1'b1)) _TECHMAP_REPLACE_ (.D(D), .CE(1'b1), .CLK(C), .SR(R), .Q(Q)); endmodule
 module  \$_DFF_PP1_ (input D, C, R, output Q); EFX_FF #(.CLK_POLARITY(1'b1), .CE_POLARITY(1'b1), .SR_POLARITY(1'b1), .D_POLARITY(1'b1), .SR_SYNC(1'b0), .SR_VALUE(1'b1), .SR_SYNC_PRIORITY(1'b1)) _TECHMAP_REPLACE_ (.D(D), .CE(1'b1), .CLK(C), .SR(R), .Q(Q)); endmodule
 module \$_DLATCH_N_ (E, D, Q);
  wire [1023:0] _TECHMAP_DO_ = "simplemap; opt";
  input E, D;
  output Q = !E ? D : Q;
 endmodule
 module \$_DLATCH_P_ (E, D, Q);
  wire [1023:0] _TECHMAP_DO_ = "simplemap; opt";
  input E, D;
  output Q = E ? D : Q;
 endmodule
 `ifndef NO_LUT
 module \$lut (A, Y);
  parameter WIDTH = 0;
--- a/techlibs/efinix/cells_sim.v
+++ b/techlibs/efinix/cells_sim.v
@ -59,7 +59,9 @@ module EFX_FF(
   assign ce = CE_POLARITY ? CE : ~CE;
   assign sr = SR_POLARITY ? SR : ~SR;
   assign d = D_POLARITY ? D : ~D;
-  
+
 	initial Q = 1'b0;
   generate
   	if (SR_SYNC == 1) 
      begin
--- a/tests/efinix/.gitignore
+++ b/tests/efinix/.gitignore
@ -0,0 +1,3 @@
 /*.log
 /*.out
 /run-test.mk
--- a/tests/efinix/add_sub.v
+++ b/tests/efinix/add_sub.v
@ -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
--- a/tests/efinix/add_sub.ys
+++ b/tests/efinix/add_sub.ys
@ -0,0 +1,10 @@
 read_verilog add_sub.v
 hierarchy -top top
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_ADD
 select -assert-count 4  t:EFX_LUT4
 select -assert-none t:EFX_ADD t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/adffs.v
+++ b/tests/efinix/adffs.v
@ -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
--- a/tests/efinix/adffs.ys
+++ b/tests/efinix/adffs.ys
@ -0,0 +1,50 @@
 read_verilog adffs.v
 design -save read
 hierarchy -top adff
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-none t:EFX_FF t:EFX_GBUFCE %% t:* %D
 design -load read
 hierarchy -top adffn
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-none t:EFX_FF t:EFX_GBUFCE %% t:* %D
 design -load read
 hierarchy -top dffs
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-count 1 t:EFX_LUT4
 select -assert-none t:EFX_FF t:EFX_GBUFCE t:EFX_LUT4 %% t:* %D
 design -load read
 hierarchy -top ndffnr
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-count 1 t:EFX_LUT4
 select -assert-none t:EFX_FF t:EFX_GBUFCE t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/counter.v
+++ b/tests/efinix/counter.v
@ -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
--- a/tests/efinix/counter.ys
+++ b/tests/efinix/counter.ys
@ -0,0 +1,12 @@
 read_verilog counter.v
 hierarchy -top top
 proc
 flatten
 equiv_opt -map +/efinix/cells_sim.v synth_efinix # 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:EFX_GBUFCE
 select -assert-count 8 t:EFX_FF
 select -assert-count 9 t:EFX_ADD
 select -assert-none t:EFX_GBUFCE t:EFX_FF t:EFX_ADD %% t:* %D
--- a/tests/efinix/dffs.v
+++ b/tests/efinix/dffs.v
@ -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
--- a/tests/efinix/dffs.ys
+++ b/tests/efinix/dffs.ys
@ -0,0 +1,24 @@
 read_verilog dffs.v
 design -save read
 hierarchy -top dff
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-none t:EFX_FF t:EFX_GBUFCE %% t:* %D
 design -load read
 hierarchy -top dffe
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_FF
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-count 1 t:EFX_LUT4
 select -assert-none t:EFX_FF t:EFX_GBUFCE t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/fsm.v
+++ b/tests/efinix/fsm.v
@ -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
--- a/tests/efinix/fsm.ys
+++ b/tests/efinix/fsm.ys
@ -0,0 +1,14 @@
 read_verilog fsm.v
 hierarchy -top fsm
 proc
 flatten
 #ERROR: Found 4 unproven $equiv cells in 'equiv_status -assert'.
 #equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # equivalency check
 equiv_opt -map +/efinix/cells_sim.v synth_efinix # 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:EFX_GBUFCE
 select -assert-count 6  t:EFX_FF
 select -assert-count 15 t:EFX_LUT4
 select -assert-none t:EFX_GBUFCE t:EFX_FF t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/latches.v
+++ b/tests/efinix/latches.v
@ -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
--- a/tests/efinix/latches.ys
+++ b/tests/efinix/latches.ys
@ -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_efinix
 cd latchp # Constrain all select calls below inside the top module
 select -assert-count 1 t:EFX_LUT4
 select -assert-none t:EFX_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_efinix
 cd latchn # Constrain all select calls below inside the top module
 select -assert-count 1 t:EFX_LUT4
 select -assert-none t:EFX_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_efinix
 cd latchsr # Constrain all select calls below inside the top module
 select -assert-count 2 t:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/logic.v
+++ b/tests/efinix/logic.v
@ -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
--- a/tests/efinix/logic.ys
+++ b/tests/efinix/logic.ys
@ -0,0 +1,9 @@
 read_verilog logic.v
 hierarchy -top top
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/memory.v
+++ b/tests/efinix/memory.v
@ -0,0 +1,21 @@
 module top
 (
 	input [7:0] data_a,
 	input [8:1] 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
--- a/tests/efinix/memory.ys
+++ b/tests/efinix/memory.ys
@ -0,0 +1,18 @@
 read_verilog memory.v
 hierarchy -top top
 proc
 memory -nomap
 equiv_opt -run :prove -map +/efinix/cells_sim.v synth_efinix
 memory
 opt -full
 miter -equiv -flatten -make_assert -make_outputs gold gate miter
 #ERROR: Called with -verify and proof did fail!
 #sat -verify -prove-asserts -seq 5 -set-init-zero -show-inputs -show-outputs miter
 sat -prove-asserts -seq 5 -set-init-zero -show-inputs -show-outputs miter
 design -load postopt
 cd top
 select -assert-count 1 t:EFX_GBUFCE
 select -assert-count 1 t:EFX_RAM_5K
 select -assert-none t:EFX_GBUFCE t:EFX_RAM_5K %% t:* %D
--- a/tests/efinix/mux.v
+++ b/tests/efinix/mux.v
@ -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
--- a/tests/efinix/mux.ys
+++ b/tests/efinix/mux.ys
@ -0,0 +1,41 @@
 read_verilog mux.v
 design -save read
 hierarchy -top mux2
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
 design -load read
 hierarchy -top mux4
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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 2 t:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
 design -load read
 hierarchy -top mux8
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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 5 t:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
 design -load read
 hierarchy -top mux16
 proc
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # 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 12 t:EFX_LUT4
 select -assert-none t:EFX_LUT4 %% t:* %D
--- a/tests/efinix/run-test.sh
+++ b/tests/efinix/run-test.sh
@ -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 ${MAKE:-make} -f run-test.mk
--- a/tests/efinix/shifter.v
+++ b/tests/efinix/shifter.v
@ -0,0 +1,16 @@
 module top    (
 out,
 clk,
 in
 );
    output [7:0] out;
    input signed clk, in;
    reg signed [7:0] out = 0;
    always @(posedge clk)
 	begin
 		out    <= out << 1;
 		out[7] <= in;
 	end
 endmodule
--- a/tests/efinix/shifter.ys
+++ b/tests/efinix/shifter.ys
@ -0,0 +1,11 @@
 read_verilog shifter.v
 hierarchy -top top
 proc
 flatten
 equiv_opt -assert -map +/efinix/cells_sim.v synth_efinix # equivalency check
 design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
 cd top # Constrain all select calls below inside the top module
 select -assert-count 1  t:EFX_GBUFCE
 select -assert-count 8  t:EFX_FF
 select -assert-none t:EFX_GBUFCE t:EFX_FF %% t:* %D
--- a/tests/efinix/tribuf.v
+++ b/tests/efinix/tribuf.v
@ -0,0 +1,8 @@
 module tristate (en, i, o);
    input en;
    input i;
    output reg o;
    always @(en or i)
 		o <= (en)? i : 1'bZ;
 endmodule
--- a/tests/efinix/tribuf.ys
+++ b/tests/efinix/tribuf.ys
@ -0,0 +1,12 @@
 read_verilog tribuf.v
 hierarchy -top tristate
 proc
 tribuf
 flatten
 synth
 equiv_opt -assert -map +/efinix/cells_sim.v -map +/simcells.v synth_efinix # equivalency check
 design -load postopt # load the post-opt design (otherwise equiv_opt loads the pre-opt design)
 cd tristate # Constrain all select calls below inside the top module
 #Internal cell type used. Need support it.
 select -assert-count 1 t:$_TBUF_
 select -assert-none t:$_TBUF_ %% t:* %D