`define SB_DFF_REG reg Q = 0 // `define SB_DFF_REG reg Q // SiliconBlue IO Cells module SB_IO ( inout PACKAGE_PIN, input LATCH_INPUT_VALUE, input CLOCK_ENABLE, input INPUT_CLK, input OUTPUT_CLK, input OUTPUT_ENABLE, input D_OUT_0, input D_OUT_1, output D_IN_0, output D_IN_1 ); parameter [5:0] PIN_TYPE = 6'b000000; parameter [0:0] PULLUP = 1'b0; parameter [0:0] NEG_TRIGGER = 1'b0; parameter IO_STANDARD = "SB_LVCMOS"; `ifndef BLACKBOX reg dout, din_0, din_1; reg din_q_0, din_q_1; reg dout_q_0, dout_q_1; reg outena_q; generate if (!NEG_TRIGGER) begin always @(posedge INPUT_CLK) if (CLOCK_ENABLE) din_q_0 <= PACKAGE_PIN; always @(negedge INPUT_CLK) if (CLOCK_ENABLE) din_q_1 <= PACKAGE_PIN; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_0 <= D_OUT_0; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_1 <= D_OUT_1; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) outena_q <= OUTPUT_ENABLE; end else begin always @(negedge INPUT_CLK) if (CLOCK_ENABLE) din_q_0 <= PACKAGE_PIN; always @(posedge INPUT_CLK) if (CLOCK_ENABLE) din_q_1 <= PACKAGE_PIN; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_0 <= D_OUT_0; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_1 <= D_OUT_1; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) outena_q <= OUTPUT_ENABLE; end endgenerate always @* begin if (!PIN_TYPE[1] || !LATCH_INPUT_VALUE) din_0 = PIN_TYPE[0] ? PACKAGE_PIN : din_q_0; din_1 = din_q_1; end // work around simulation glitches on dout in DDR mode reg outclk_delayed_1; reg outclk_delayed_2; always @* outclk_delayed_1 <= OUTPUT_CLK; always @* outclk_delayed_2 <= outclk_delayed_1; always @* begin if (PIN_TYPE[3]) dout = PIN_TYPE[2] ? !dout_q_0 : D_OUT_0; else dout = (outclk_delayed_2 ^ NEG_TRIGGER) || PIN_TYPE[2] ? dout_q_0 : dout_q_1; end assign D_IN_0 = din_0, D_IN_1 = din_1; generate if (PIN_TYPE[5:4] == 2'b01) assign PACKAGE_PIN = dout; if (PIN_TYPE[5:4] == 2'b10) assign PACKAGE_PIN = OUTPUT_ENABLE ? dout : 1'bz; if (PIN_TYPE[5:4] == 2'b11) assign PACKAGE_PIN = outena_q ? dout : 1'bz; endgenerate `endif endmodule module SB_GB_IO ( inout PACKAGE_PIN, output GLOBAL_BUFFER_OUTPUT, input LATCH_INPUT_VALUE, input CLOCK_ENABLE, input INPUT_CLK, input OUTPUT_CLK, input OUTPUT_ENABLE, input D_OUT_0, input D_OUT_1, output D_IN_0, output D_IN_1 ); parameter [5:0] PIN_TYPE = 6'b000000; parameter [0:0] PULLUP = 1'b0; parameter [0:0] NEG_TRIGGER = 1'b0; parameter IO_STANDARD = "SB_LVCMOS"; assign GLOBAL_BUFFER_OUTPUT = PACKAGE_PIN; SB_IO #( .PIN_TYPE(PIN_TYPE), .PULLUP(PULLUP), .NEG_TRIGGER(NEG_TRIGGER), .IO_STANDARD(IO_STANDARD) ) IO ( .PACKAGE_PIN(PACKAGE_PIN), .LATCH_INPUT_VALUE(LATCH_INPUT_VALUE), .CLOCK_ENABLE(CLOCK_ENABLE), .INPUT_CLK(INPUT_CLK), .OUTPUT_CLK(OUTPUT_CLK), .OUTPUT_ENABLE(OUTPUT_ENABLE), .D_OUT_0(D_OUT_0), .D_OUT_1(D_OUT_1), .D_IN_0(D_IN_0), .D_IN_1(D_IN_1) ); endmodule module SB_GB ( input USER_SIGNAL_TO_GLOBAL_BUFFER, output GLOBAL_BUFFER_OUTPUT ); assign GLOBAL_BUFFER_OUTPUT = USER_SIGNAL_TO_GLOBAL_BUFFER; endmodule // SiliconBlue Logic Cells module SB_LUT4 (output O, input I0, I1, I2, I3); parameter [15:0] LUT_INIT = 0; wire [7:0] s3 = I3 ? LUT_INIT[15:8] : LUT_INIT[7:0]; wire [3:0] s2 = I2 ? s3[ 7:4] : s3[3:0]; wire [1:0] s1 = I1 ? s2[ 3:2] : s2[1:0]; assign O = I0 ? s1[1] : s1[0]; endmodule module SB_CARRY (output CO, input I0, I1, CI); assign CO = (I0 && I1) || ((I0 || I1) && CI); endmodule // Positive Edge SiliconBlue FF Cells module SB_DFF ((* abc_flop_q *) output `SB_DFF_REG, input C, D); always @(posedge C) Q <= D; endmodule module SB_DFFE ((* abc_flop_q *) output `SB_DFF_REG, input C, E, D); always @(posedge C) if (E) Q <= D; endmodule module SB_DFFSR ((* abc_flop_q *) output `SB_DFF_REG, input C, R, D); always @(posedge C) if (R) Q <= 0; else Q <= D; endmodule module SB_DFFR ((* abc_flop_q *) output `SB_DFF_REG, input C, R, D); always @(posedge C, posedge R) if (R) Q <= 0; else Q <= D; endmodule module SB_DFFSS ((* abc_flop_q *) output `SB_DFF_REG, input C, S, D); always @(posedge C) if (S) Q <= 1; else Q <= D; endmodule module SB_DFFS ((* abc_flop_q *) output `SB_DFF_REG, input C, S, D); always @(posedge C, posedge S) if (S) Q <= 1; else Q <= D; endmodule module SB_DFFESR ((* abc_flop_q *) output `SB_DFF_REG, input C, E, R, D); always @(posedge C) if (E) begin if (R) Q <= 0; else Q <= D; end endmodule module SB_DFFER ((* abc_flop_q *) output `SB_DFF_REG, input C, E, R, D); always @(posedge C, posedge R) if (R) Q <= 0; else if (E) Q <= D; endmodule module SB_DFFESS ((* abc_flop_q *) output `SB_DFF_REG, input C, E, S, D); always @(posedge C) if (E) begin if (S) Q <= 1; else Q <= D; end endmodule module SB_DFFES ((* abc_flop_q *) output `SB_DFF_REG, input C, E, S, D); always @(posedge C, posedge S) if (S) Q <= 1; else if (E) Q <= D; endmodule // Negative Edge SiliconBlue FF Cells module SB_DFFN ((* abc_flop_q *) output `SB_DFF_REG, input C, D); always @(negedge C) Q <= D; endmodule module SB_DFFNE ((* abc_flop_q *) output `SB_DFF_REG, input C, E, D); always @(negedge C) if (E) Q <= D; endmodule module SB_DFFNSR ((* abc_flop_q *) output `SB_DFF_REG, input C, R, D); always @(negedge C) if (R) Q <= 0; else Q <= D; endmodule module SB_DFFNR ((* abc_flop_q *) output `SB_DFF_REG, input C, R, D); always @(negedge C, posedge R) if (R) Q <= 0; else Q <= D; endmodule module SB_DFFNSS ((* abc_flop_q *) output `SB_DFF_REG, input C, S, D); always @(negedge C) if (S) Q <= 1; else Q <= D; endmodule module SB_DFFNS ((* abc_flop_q *) output `SB_DFF_REG, input C, S, D); always @(negedge C, posedge S) if (S) Q <= 1; else Q <= D; endmodule module SB_DFFNESR ((* abc_flop_q *) output `SB_DFF_REG, input C, E, R, D); always @(negedge C) if (E) begin if (R) Q <= 0; else Q <= D; end endmodule module SB_DFFNER ((* abc_flop_q *) output `SB_DFF_REG, input C, E, R, D); always @(negedge C, posedge R) if (R) Q <= 0; else if (E) Q <= D; endmodule module SB_DFFNESS ((* abc_flop_q *) output `SB_DFF_REG, input C, E, S, D); always @(negedge C) if (E) begin if (S) Q <= 1; else Q <= D; end endmodule module SB_DFFNES ((* abc_flop_q *) output `SB_DFF_REG, input C, E, S, D); always @(negedge C, posedge S) if (S) Q <= 1; else if (E) Q <= D; endmodule // SiliconBlue RAM Cells module SB_RAM40_4K ( (* abc_flop_q *) output [15:0] RDATA, input RCLK, RCLKE, RE, input [10:0] RADDR, input WCLK, WCLKE, WE, input [10:0] WADDR, input [15:0] MASK, WDATA ); // MODE 0: 256 x 16 // MODE 1: 512 x 8 // MODE 2: 1024 x 4 // MODE 3: 2048 x 2 parameter WRITE_MODE = 0; parameter READ_MODE = 0; parameter INIT_0 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_1 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_2 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_3 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_4 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_5 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_6 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_7 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_8 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_9 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_A = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_B = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_C = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_D = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_E = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_F = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_FILE = ""; `ifndef BLACKBOX wire [15:0] WMASK_I; wire [15:0] RMASK_I; reg [15:0] RDATA_I; wire [15:0] WDATA_I; generate case (WRITE_MODE) 0: assign WMASK_I = MASK; 1: assign WMASK_I = WADDR[ 8] == 0 ? 16'b 1010_1010_1010_1010 : WADDR[ 8] == 1 ? 16'b 0101_0101_0101_0101 : 16'bx; 2: assign WMASK_I = WADDR[ 9:8] == 0 ? 16'b 1110_1110_1110_1110 : WADDR[ 9:8] == 1 ? 16'b 1101_1101_1101_1101 : WADDR[ 9:8] == 2 ? 16'b 1011_1011_1011_1011 : WADDR[ 9:8] == 3 ? 16'b 0111_0111_0111_0111 : 16'bx; 3: assign WMASK_I = WADDR[10:8] == 0 ? 16'b 1111_1110_1111_1110 : WADDR[10:8] == 1 ? 16'b 1111_1101_1111_1101 : WADDR[10:8] == 2 ? 16'b 1111_1011_1111_1011 : WADDR[10:8] == 3 ? 16'b 1111_0111_1111_0111 : WADDR[10:8] == 4 ? 16'b 1110_1111_1110_1111 : WADDR[10:8] == 5 ? 16'b 1101_1111_1101_1111 : WADDR[10:8] == 6 ? 16'b 1011_1111_1011_1111 : WADDR[10:8] == 7 ? 16'b 0111_1111_0111_1111 : 16'bx; endcase case (READ_MODE) 0: assign RMASK_I = 16'b 0000_0000_0000_0000; 1: assign RMASK_I = RADDR[ 8] == 0 ? 16'b 1010_1010_1010_1010 : RADDR[ 8] == 1 ? 16'b 0101_0101_0101_0101 : 16'bx; 2: assign RMASK_I = RADDR[ 9:8] == 0 ? 16'b 1110_1110_1110_1110 : RADDR[ 9:8] == 1 ? 16'b 1101_1101_1101_1101 : RADDR[ 9:8] == 2 ? 16'b 1011_1011_1011_1011 : RADDR[ 9:8] == 3 ? 16'b 0111_0111_0111_0111 : 16'bx; 3: assign RMASK_I = RADDR[10:8] == 0 ? 16'b 1111_1110_1111_1110 : RADDR[10:8] == 1 ? 16'b 1111_1101_1111_1101 : RADDR[10:8] == 2 ? 16'b 1111_1011_1111_1011 : RADDR[10:8] == 3 ? 16'b 1111_0111_1111_0111 : RADDR[10:8] == 4 ? 16'b 1110_1111_1110_1111 : RADDR[10:8] == 5 ? 16'b 1101_1111_1101_1111 : RADDR[10:8] == 6 ? 16'b 1011_1111_1011_1111 : RADDR[10:8] == 7 ? 16'b 0111_1111_0111_1111 : 16'bx; endcase case (WRITE_MODE) 0: assign WDATA_I = WDATA; 1: assign WDATA_I = {WDATA[14], WDATA[14], WDATA[12], WDATA[12], WDATA[10], WDATA[10], WDATA[ 8], WDATA[ 8], WDATA[ 6], WDATA[ 6], WDATA[ 4], WDATA[ 4], WDATA[ 2], WDATA[ 2], WDATA[ 0], WDATA[ 0]}; 2: assign WDATA_I = {WDATA[13], WDATA[13], WDATA[13], WDATA[13], WDATA[ 9], WDATA[ 9], WDATA[ 9], WDATA[ 9], WDATA[ 5], WDATA[ 5], WDATA[ 5], WDATA[ 5], WDATA[ 1], WDATA[ 1], WDATA[ 1], WDATA[ 1]}; 3: assign WDATA_I = {WDATA[11], WDATA[11], WDATA[11], WDATA[11], WDATA[11], WDATA[11], WDATA[11], WDATA[11], WDATA[ 3], WDATA[ 3], WDATA[ 3], WDATA[ 3], WDATA[ 3], WDATA[ 3], WDATA[ 3], WDATA[ 3]}; endcase case (READ_MODE) 0: assign RDATA = RDATA_I; 1: assign RDATA = {1'b0, |RDATA_I[15:14], 1'b0, |RDATA_I[13:12], 1'b0, |RDATA_I[11:10], 1'b0, |RDATA_I[ 9: 8], 1'b0, |RDATA_I[ 7: 6], 1'b0, |RDATA_I[ 5: 4], 1'b0, |RDATA_I[ 3: 2], 1'b0, |RDATA_I[ 1: 0]}; 2: assign RDATA = {2'b0, |RDATA_I[15:12], 3'b0, |RDATA_I[11: 8], 3'b0, |RDATA_I[ 7: 4], 3'b0, |RDATA_I[ 3: 0], 1'b0}; 3: assign RDATA = {4'b0, |RDATA_I[15: 8], 7'b0, |RDATA_I[ 7: 0], 3'b0}; endcase endgenerate integer i; reg [15:0] memory [0:255]; initial begin if (INIT_FILE != "") $readmemh(INIT_FILE, memory); else for (i=0; i<16; i=i+1) begin memory[ 0*16 + i] = INIT_0[16*i +: 16]; memory[ 1*16 + i] = INIT_1[16*i +: 16]; memory[ 2*16 + i] = INIT_2[16*i +: 16]; memory[ 3*16 + i] = INIT_3[16*i +: 16]; memory[ 4*16 + i] = INIT_4[16*i +: 16]; memory[ 5*16 + i] = INIT_5[16*i +: 16]; memory[ 6*16 + i] = INIT_6[16*i +: 16]; memory[ 7*16 + i] = INIT_7[16*i +: 16]; memory[ 8*16 + i] = INIT_8[16*i +: 16]; memory[ 9*16 + i] = INIT_9[16*i +: 16]; memory[10*16 + i] = INIT_A[16*i +: 16]; memory[11*16 + i] = INIT_B[16*i +: 16]; memory[12*16 + i] = INIT_C[16*i +: 16]; memory[13*16 + i] = INIT_D[16*i +: 16]; memory[14*16 + i] = INIT_E[16*i +: 16]; memory[15*16 + i] = INIT_F[16*i +: 16]; end end always @(posedge WCLK) begin if (WE && WCLKE) begin if (!WMASK_I[ 0]) memory[WADDR[7:0]][ 0] <= WDATA_I[ 0]; if (!WMASK_I[ 1]) memory[WADDR[7:0]][ 1] <= WDATA_I[ 1]; if (!WMASK_I[ 2]) memory[WADDR[7:0]][ 2] <= WDATA_I[ 2]; if (!WMASK_I[ 3]) memory[WADDR[7:0]][ 3] <= WDATA_I[ 3]; if (!WMASK_I[ 4]) memory[WADDR[7:0]][ 4] <= WDATA_I[ 4]; if (!WMASK_I[ 5]) memory[WADDR[7:0]][ 5] <= WDATA_I[ 5]; if (!WMASK_I[ 6]) memory[WADDR[7:0]][ 6] <= WDATA_I[ 6]; if (!WMASK_I[ 7]) memory[WADDR[7:0]][ 7] <= WDATA_I[ 7]; if (!WMASK_I[ 8]) memory[WADDR[7:0]][ 8] <= WDATA_I[ 8]; if (!WMASK_I[ 9]) memory[WADDR[7:0]][ 9] <= WDATA_I[ 9]; if (!WMASK_I[10]) memory[WADDR[7:0]][10] <= WDATA_I[10]; if (!WMASK_I[11]) memory[WADDR[7:0]][11] <= WDATA_I[11]; if (!WMASK_I[12]) memory[WADDR[7:0]][12] <= WDATA_I[12]; if (!WMASK_I[13]) memory[WADDR[7:0]][13] <= WDATA_I[13]; if (!WMASK_I[14]) memory[WADDR[7:0]][14] <= WDATA_I[14]; if (!WMASK_I[15]) memory[WADDR[7:0]][15] <= WDATA_I[15]; end end always @(posedge RCLK) begin if (RE && RCLKE) begin RDATA_I <= memory[RADDR[7:0]] & ~RMASK_I; end end `endif endmodule module SB_RAM40_4KNR ( (* abc_flop_q *) output [15:0] RDATA, input RCLKN, RCLKE, RE, input [10:0] RADDR, input WCLK, WCLKE, WE, input [10:0] WADDR, input [15:0] MASK, WDATA ); parameter WRITE_MODE = 0; parameter READ_MODE = 0; parameter INIT_0 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_1 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_2 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_3 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_4 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_5 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_6 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_7 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_8 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_9 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_A = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_B = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_C = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_D = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_E = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_F = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_FILE = ""; SB_RAM40_4K #( .WRITE_MODE(WRITE_MODE), .READ_MODE (READ_MODE ), .INIT_0 (INIT_0 ), .INIT_1 (INIT_1 ), .INIT_2 (INIT_2 ), .INIT_3 (INIT_3 ), .INIT_4 (INIT_4 ), .INIT_5 (INIT_5 ), .INIT_6 (INIT_6 ), .INIT_7 (INIT_7 ), .INIT_8 (INIT_8 ), .INIT_9 (INIT_9 ), .INIT_A (INIT_A ), .INIT_B (INIT_B ), .INIT_C (INIT_C ), .INIT_D (INIT_D ), .INIT_E (INIT_E ), .INIT_F (INIT_F ), .INIT_FILE (INIT_FILE ) ) RAM ( .RDATA(RDATA), .RCLK (~RCLKN), .RCLKE(RCLKE), .RE (RE ), .RADDR(RADDR), .WCLK (WCLK ), .WCLKE(WCLKE), .WE (WE ), .WADDR(WADDR), .MASK (MASK ), .WDATA(WDATA) ); endmodule module SB_RAM40_4KNW ( (* abc_flop_q *) output [15:0] RDATA, input RCLK, RCLKE, RE, input [10:0] RADDR, input WCLKN, WCLKE, WE, input [10:0] WADDR, input [15:0] MASK, WDATA ); parameter WRITE_MODE = 0; parameter READ_MODE = 0; parameter INIT_0 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_1 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_2 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_3 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_4 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_5 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_6 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_7 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_8 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_9 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_A = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_B = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_C = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_D = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_E = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_F = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_FILE = ""; SB_RAM40_4K #( .WRITE_MODE(WRITE_MODE), .READ_MODE (READ_MODE ), .INIT_0 (INIT_0 ), .INIT_1 (INIT_1 ), .INIT_2 (INIT_2 ), .INIT_3 (INIT_3 ), .INIT_4 (INIT_4 ), .INIT_5 (INIT_5 ), .INIT_6 (INIT_6 ), .INIT_7 (INIT_7 ), .INIT_8 (INIT_8 ), .INIT_9 (INIT_9 ), .INIT_A (INIT_A ), .INIT_B (INIT_B ), .INIT_C (INIT_C ), .INIT_D (INIT_D ), .INIT_E (INIT_E ), .INIT_F (INIT_F ), .INIT_FILE (INIT_FILE ) ) RAM ( .RDATA(RDATA), .RCLK (RCLK ), .RCLKE(RCLKE), .RE (RE ), .RADDR(RADDR), .WCLK (~WCLKN), .WCLKE(WCLKE), .WE (WE ), .WADDR(WADDR), .MASK (MASK ), .WDATA(WDATA) ); endmodule module SB_RAM40_4KNRNW ( (* abc_flop_q *) output [15:0] RDATA, input RCLKN, RCLKE, RE, input [10:0] RADDR, input WCLKN, WCLKE, WE, input [10:0] WADDR, input [15:0] MASK, WDATA ); parameter WRITE_MODE = 0; parameter READ_MODE = 0; parameter INIT_0 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_1 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_2 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_3 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_4 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_5 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_6 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_7 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_8 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_9 = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_A = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_B = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_C = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_D = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_E = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_F = 256'h0000000000000000000000000000000000000000000000000000000000000000; parameter INIT_FILE = ""; SB_RAM40_4K #( .WRITE_MODE(WRITE_MODE), .READ_MODE (READ_MODE ), .INIT_0 (INIT_0 ), .INIT_1 (INIT_1 ), .INIT_2 (INIT_2 ), .INIT_3 (INIT_3 ), .INIT_4 (INIT_4 ), .INIT_5 (INIT_5 ), .INIT_6 (INIT_6 ), .INIT_7 (INIT_7 ), .INIT_8 (INIT_8 ), .INIT_9 (INIT_9 ), .INIT_A (INIT_A ), .INIT_B (INIT_B ), .INIT_C (INIT_C ), .INIT_D (INIT_D ), .INIT_E (INIT_E ), .INIT_F (INIT_F ), .INIT_FILE (INIT_FILE ) ) RAM ( .RDATA(RDATA), .RCLK (~RCLKN), .RCLKE(RCLKE), .RE (RE ), .RADDR(RADDR), .WCLK (~WCLKN), .WCLKE(WCLKE), .WE (WE ), .WADDR(WADDR), .MASK (MASK ), .WDATA(WDATA) ); endmodule // Packed IceStorm Logic Cells module ICESTORM_LC ( input I0, I1, I2, I3, CIN, CLK, CEN, SR, output LO, O, COUT ); parameter [15:0] LUT_INIT = 0; parameter [0:0] NEG_CLK = 0; parameter [0:0] CARRY_ENABLE = 0; parameter [0:0] DFF_ENABLE = 0; parameter [0:0] SET_NORESET = 0; parameter [0:0] ASYNC_SR = 0; parameter [0:0] CIN_CONST = 0; parameter [0:0] CIN_SET = 0; wire mux_cin = CIN_CONST ? CIN_SET : CIN; assign COUT = CARRY_ENABLE ? (I1 && I2) || ((I1 || I2) && mux_cin) : 1'bx; wire [7:0] lut_s3 = I3 ? LUT_INIT[15:8] : LUT_INIT[7:0]; wire [3:0] lut_s2 = I2 ? lut_s3[ 7:4] : lut_s3[3:0]; wire [1:0] lut_s1 = I1 ? lut_s2[ 3:2] : lut_s2[1:0]; wire lut_o = I0 ? lut_s1[ 1] : lut_s1[ 0]; assign LO = lut_o; wire polarized_clk; assign polarized_clk = CLK ^ NEG_CLK; reg o_reg; always @(posedge polarized_clk) if (CEN) o_reg <= SR ? SET_NORESET : lut_o; reg o_reg_async; always @(posedge polarized_clk, posedge SR) if (SR) o_reg <= SET_NORESET; else if (CEN) o_reg <= lut_o; assign O = DFF_ENABLE ? ASYNC_SR ? o_reg_async : o_reg : lut_o; endmodule // SiliconBlue PLL Cells (* blackbox *) module SB_PLL40_CORE ( input REFERENCECLK, output PLLOUTCORE, output PLLOUTGLOBAL, input EXTFEEDBACK, input [7:0] DYNAMICDELAY, output LOCK, input BYPASS, input RESETB, input LATCHINPUTVALUE, output SDO, input SDI, input SCLK ); parameter FEEDBACK_PATH = "SIMPLE"; parameter DELAY_ADJUSTMENT_MODE_FEEDBACK = "FIXED"; parameter DELAY_ADJUSTMENT_MODE_RELATIVE = "FIXED"; parameter SHIFTREG_DIV_MODE = 1'b0; parameter FDA_FEEDBACK = 4'b0000; parameter FDA_RELATIVE = 4'b0000; parameter PLLOUT_SELECT = "GENCLK"; parameter DIVR = 4'b0000; parameter DIVF = 7'b0000000; parameter DIVQ = 3'b000; parameter FILTER_RANGE = 3'b000; parameter ENABLE_ICEGATE = 1'b0; parameter TEST_MODE = 1'b0; parameter EXTERNAL_DIVIDE_FACTOR = 1; endmodule (* blackbox *) module SB_PLL40_PAD ( input PACKAGEPIN, output PLLOUTCORE, output PLLOUTGLOBAL, input EXTFEEDBACK, input [7:0] DYNAMICDELAY, output LOCK, input BYPASS, input RESETB, input LATCHINPUTVALUE, output SDO, input SDI, input SCLK ); parameter FEEDBACK_PATH = "SIMPLE"; parameter DELAY_ADJUSTMENT_MODE_FEEDBACK = "FIXED"; parameter DELAY_ADJUSTMENT_MODE_RELATIVE = "FIXED"; parameter SHIFTREG_DIV_MODE = 1'b0; parameter FDA_FEEDBACK = 4'b0000; parameter FDA_RELATIVE = 4'b0000; parameter PLLOUT_SELECT = "GENCLK"; parameter DIVR = 4'b0000; parameter DIVF = 7'b0000000; parameter DIVQ = 3'b000; parameter FILTER_RANGE = 3'b000; parameter ENABLE_ICEGATE = 1'b0; parameter TEST_MODE = 1'b0; parameter EXTERNAL_DIVIDE_FACTOR = 1; endmodule (* blackbox *) module SB_PLL40_2_PAD ( input PACKAGEPIN, output PLLOUTCOREA, output PLLOUTGLOBALA, output PLLOUTCOREB, output PLLOUTGLOBALB, input EXTFEEDBACK, input [7:0] DYNAMICDELAY, output LOCK, input BYPASS, input RESETB, input LATCHINPUTVALUE, output SDO, input SDI, input SCLK ); parameter FEEDBACK_PATH = "SIMPLE"; parameter DELAY_ADJUSTMENT_MODE_FEEDBACK = "FIXED"; parameter DELAY_ADJUSTMENT_MODE_RELATIVE = "FIXED"; parameter SHIFTREG_DIV_MODE = 1'b0; parameter FDA_FEEDBACK = 4'b0000; parameter FDA_RELATIVE = 4'b0000; parameter PLLOUT_SELECT_PORTB = "GENCLK"; parameter DIVR = 4'b0000; parameter DIVF = 7'b0000000; parameter DIVQ = 3'b000; parameter FILTER_RANGE = 3'b000; parameter ENABLE_ICEGATE_PORTA = 1'b0; parameter ENABLE_ICEGATE_PORTB = 1'b0; parameter TEST_MODE = 1'b0; parameter EXTERNAL_DIVIDE_FACTOR = 1; endmodule (* blackbox *) module SB_PLL40_2F_CORE ( input REFERENCECLK, output PLLOUTCOREA, output PLLOUTGLOBALA, output PLLOUTCOREB, output PLLOUTGLOBALB, input EXTFEEDBACK, input [7:0] DYNAMICDELAY, output LOCK, input BYPASS, input RESETB, input LATCHINPUTVALUE, output SDO, input SDI, input SCLK ); parameter FEEDBACK_PATH = "SIMPLE"; parameter DELAY_ADJUSTMENT_MODE_FEEDBACK = "FIXED"; parameter DELAY_ADJUSTMENT_MODE_RELATIVE = "FIXED"; parameter SHIFTREG_DIV_MODE = 1'b0; parameter FDA_FEEDBACK = 4'b0000; parameter FDA_RELATIVE = 4'b0000; parameter PLLOUT_SELECT_PORTA = "GENCLK"; parameter PLLOUT_SELECT_PORTB = "GENCLK"; parameter DIVR = 4'b0000; parameter DIVF = 7'b0000000; parameter DIVQ = 3'b000; parameter FILTER_RANGE = 3'b000; parameter ENABLE_ICEGATE_PORTA = 1'b0; parameter ENABLE_ICEGATE_PORTB = 1'b0; parameter TEST_MODE = 1'b0; parameter EXTERNAL_DIVIDE_FACTOR = 1; endmodule (* blackbox *) module SB_PLL40_2F_PAD ( input PACKAGEPIN, output PLLOUTCOREA, output PLLOUTGLOBALA, output PLLOUTCOREB, output PLLOUTGLOBALB, input EXTFEEDBACK, input [7:0] DYNAMICDELAY, output LOCK, input BYPASS, input RESETB, input LATCHINPUTVALUE, output SDO, input SDI, input SCLK ); parameter FEEDBACK_PATH = "SIMPLE"; parameter DELAY_ADJUSTMENT_MODE_FEEDBACK = "FIXED"; parameter DELAY_ADJUSTMENT_MODE_RELATIVE = "FIXED"; parameter SHIFTREG_DIV_MODE = 2'b00; parameter FDA_FEEDBACK = 4'b0000; parameter FDA_RELATIVE = 4'b0000; parameter PLLOUT_SELECT_PORTA = "GENCLK"; parameter PLLOUT_SELECT_PORTB = "GENCLK"; parameter DIVR = 4'b0000; parameter DIVF = 7'b0000000; parameter DIVQ = 3'b000; parameter FILTER_RANGE = 3'b000; parameter ENABLE_ICEGATE_PORTA = 1'b0; parameter ENABLE_ICEGATE_PORTB = 1'b0; parameter TEST_MODE = 1'b0; parameter EXTERNAL_DIVIDE_FACTOR = 1; endmodule // SiliconBlue Device Configuration Cells (* blackbox, keep *) module SB_WARMBOOT ( input BOOT, input S1, input S0 ); endmodule (* nomem2reg *) module SB_SPRAM256KA ( input [13:0] ADDRESS, input [15:0] DATAIN, input [3:0] MASKWREN, input WREN, CHIPSELECT, CLOCK, STANDBY, SLEEP, POWEROFF, (* abc_flop_q *) output reg [15:0] DATAOUT ); `ifndef BLACKBOX `ifndef EQUIV reg [15:0] mem [0:16383]; wire off = SLEEP || !POWEROFF; integer i; always @(negedge POWEROFF) begin for (i = 0; i <= 16383; i = i+1) mem[i] = 'bx; end always @(posedge CLOCK, posedge off) begin if (off) begin DATAOUT <= 0; end else if (CHIPSELECT && !STANDBY && !WREN) begin DATAOUT <= mem[ADDRESS]; end else begin if (CHIPSELECT && !STANDBY && WREN) begin if (MASKWREN[0]) mem[ADDRESS][ 3: 0] = DATAIN[ 3: 0]; if (MASKWREN[1]) mem[ADDRESS][ 7: 4] = DATAIN[ 7: 4]; if (MASKWREN[2]) mem[ADDRESS][11: 8] = DATAIN[11: 8]; if (MASKWREN[3]) mem[ADDRESS][15:12] = DATAIN[15:12]; end DATAOUT <= 'bx; end end `endif `endif endmodule (* blackbox *) module SB_HFOSC( input CLKHFPU, input CLKHFEN, output CLKHF ); parameter CLKHF_DIV = "0b00"; endmodule (* blackbox *) module SB_LFOSC( input CLKLFPU, input CLKLFEN, output CLKLF ); endmodule (* blackbox *) module SB_RGBA_DRV( input CURREN, input RGBLEDEN, input RGB0PWM, input RGB1PWM, input RGB2PWM, output RGB0, output RGB1, output RGB2 ); parameter CURRENT_MODE = "0b0"; parameter RGB0_CURRENT = "0b000000"; parameter RGB1_CURRENT = "0b000000"; parameter RGB2_CURRENT = "0b000000"; endmodule (* blackbox *) module SB_I2C( input SBCLKI, input SBRWI, input SBSTBI, input SBADRI7, input SBADRI6, input SBADRI5, input SBADRI4, input SBADRI3, input SBADRI2, input SBADRI1, input SBADRI0, input SBDATI7, input SBDATI6, input SBDATI5, input SBDATI4, input SBDATI3, input SBDATI2, input SBDATI1, input SBDATI0, input SCLI, input SDAI, output SBDATO7, output SBDATO6, output SBDATO5, output SBDATO4, output SBDATO3, output SBDATO2, output SBDATO1, output SBDATO0, output SBACKO, output I2CIRQ, output I2CWKUP, output SCLO, //inout in the SB verilog library, but output in the VHDL and PDF libs and seemingly in the HW itself output SCLOE, output SDAO, output SDAOE ); parameter I2C_SLAVE_INIT_ADDR = "0b1111100001"; parameter BUS_ADDR74 = "0b0001"; endmodule (* blackbox *) module SB_SPI ( input SBCLKI, input SBRWI, input SBSTBI, input SBADRI7, input SBADRI6, input SBADRI5, input SBADRI4, input SBADRI3, input SBADRI2, input SBADRI1, input SBADRI0, input SBDATI7, input SBDATI6, input SBDATI5, input SBDATI4, input SBDATI3, input SBDATI2, input SBDATI1, input SBDATI0, input MI, input SI, input SCKI, input SCSNI, output SBDATO7, output SBDATO6, output SBDATO5, output SBDATO4, output SBDATO3, output SBDATO2, output SBDATO1, output SBDATO0, output SBACKO, output SPIIRQ, output SPIWKUP, output SO, output SOE, output MO, output MOE, output SCKO, //inout in the SB verilog library, but output in the VHDL and PDF libs and seemingly in the HW itself output SCKOE, output MCSNO3, output MCSNO2, output MCSNO1, output MCSNO0, output MCSNOE3, output MCSNOE2, output MCSNOE1, output MCSNOE0 ); parameter BUS_ADDR74 = "0b0000"; endmodule (* blackbox *) module SB_LEDDA_IP( input LEDDCS, input LEDDCLK, input LEDDDAT7, input LEDDDAT6, input LEDDDAT5, input LEDDDAT4, input LEDDDAT3, input LEDDDAT2, input LEDDDAT1, input LEDDDAT0, input LEDDADDR3, input LEDDADDR2, input LEDDADDR1, input LEDDADDR0, input LEDDDEN, input LEDDEXE, input LEDDRST, output PWMOUT0, output PWMOUT1, output PWMOUT2, output LEDDON ); endmodule (* blackbox *) module SB_FILTER_50NS( input FILTERIN, output FILTEROUT ); endmodule module SB_IO_I3C ( inout PACKAGE_PIN, input LATCH_INPUT_VALUE, input CLOCK_ENABLE, input INPUT_CLK, input OUTPUT_CLK, input OUTPUT_ENABLE, input D_OUT_0, input D_OUT_1, output D_IN_0, output D_IN_1, input PU_ENB, input WEAK_PU_ENB ); parameter [5:0] PIN_TYPE = 6'b000000; parameter [0:0] PULLUP = 1'b0; parameter [0:0] WEAK_PULLUP = 1'b0; parameter [0:0] NEG_TRIGGER = 1'b0; parameter IO_STANDARD = "SB_LVCMOS"; `ifndef BLACKBOX reg dout, din_0, din_1; reg din_q_0, din_q_1; reg dout_q_0, dout_q_1; reg outena_q; generate if (!NEG_TRIGGER) begin always @(posedge INPUT_CLK) if (CLOCK_ENABLE) din_q_0 <= PACKAGE_PIN; always @(negedge INPUT_CLK) if (CLOCK_ENABLE) din_q_1 <= PACKAGE_PIN; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_0 <= D_OUT_0; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_1 <= D_OUT_1; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) outena_q <= OUTPUT_ENABLE; end else begin always @(negedge INPUT_CLK) if (CLOCK_ENABLE) din_q_0 <= PACKAGE_PIN; always @(posedge INPUT_CLK) if (CLOCK_ENABLE) din_q_1 <= PACKAGE_PIN; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_0 <= D_OUT_0; always @(posedge OUTPUT_CLK) if (CLOCK_ENABLE) dout_q_1 <= D_OUT_1; always @(negedge OUTPUT_CLK) if (CLOCK_ENABLE) outena_q <= OUTPUT_ENABLE; end endgenerate always @* begin if (!PIN_TYPE[1] || !LATCH_INPUT_VALUE) din_0 = PIN_TYPE[0] ? PACKAGE_PIN : din_q_0; din_1 = din_q_1; end // work around simulation glitches on dout in DDR mode reg outclk_delayed_1; reg outclk_delayed_2; always @* outclk_delayed_1 <= OUTPUT_CLK; always @* outclk_delayed_2 <= outclk_delayed_1; always @* begin if (PIN_TYPE[3]) dout = PIN_TYPE[2] ? !dout_q_0 : D_OUT_0; else dout = (outclk_delayed_2 ^ NEG_TRIGGER) || PIN_TYPE[2] ? dout_q_0 : dout_q_1; end assign D_IN_0 = din_0, D_IN_1 = din_1; generate if (PIN_TYPE[5:4] == 2'b01) assign PACKAGE_PIN = dout; if (PIN_TYPE[5:4] == 2'b10) assign PACKAGE_PIN = OUTPUT_ENABLE ? dout : 1'bz; if (PIN_TYPE[5:4] == 2'b11) assign PACKAGE_PIN = outena_q ? dout : 1'bz; endgenerate `endif endmodule module SB_IO_OD ( inout PACKAGEPIN, input LATCHINPUTVALUE, input CLOCKENABLE, input INPUTCLK, input OUTPUTCLK, input OUTPUTENABLE, input DOUT1, input DOUT0, output DIN1, output DIN0 ); parameter [5:0] PIN_TYPE = 6'b000000; parameter [0:0] NEG_TRIGGER = 1'b0; `ifndef BLACKBOX reg dout, din_0, din_1; reg din_q_0, din_q_1; reg dout_q_0, dout_q_1; reg outena_q; generate if (!NEG_TRIGGER) begin always @(posedge INPUTCLK) if (CLOCKENABLE) din_q_0 <= PACKAGEPIN; always @(negedge INPUTCLK) if (CLOCKENABLE) din_q_1 <= PACKAGEPIN; always @(posedge OUTPUTCLK) if (CLOCKENABLE) dout_q_0 <= DOUT0; always @(negedge OUTPUTCLK) if (CLOCKENABLE) dout_q_1 <= DOUT1; always @(posedge OUTPUTCLK) if (CLOCKENABLE) outena_q <= OUTPUTENABLE; end else begin always @(negedge INPUTCLK) if (CLOCKENABLE) din_q_0 <= PACKAGEPIN; always @(posedge INPUTCLK) if (CLOCKENABLE) din_q_1 <= PACKAGEPIN; always @(negedge OUTPUTCLK) if (CLOCKENABLE) dout_q_0 <= DOUT0; always @(posedge OUTPUTCLK) if (CLOCKENABLE) dout_q_1 <= DOUT1; always @(negedge OUTPUTCLK) if (CLOCKENABLE) outena_q <= OUTPUTENABLE; end endgenerate always @* begin if (!PIN_TYPE[1] || !LATCHINPUTVALUE) din_0 = PIN_TYPE[0] ? PACKAGEPIN : din_q_0; din_1 = din_q_1; end // work around simulation glitches on dout in DDR mode reg outclk_delayed_1; reg outclk_delayed_2; always @* outclk_delayed_1 <= OUTPUTCLK; always @* outclk_delayed_2 <= outclk_delayed_1; always @* begin if (PIN_TYPE[3]) dout = PIN_TYPE[2] ? !dout_q_0 : DOUT0; else dout = (outclk_delayed_2 ^ NEG_TRIGGER) || PIN_TYPE[2] ? dout_q_0 : dout_q_1; end assign DIN0 = din_0, DIN1 = din_1; generate if (PIN_TYPE[5:4] == 2'b01) assign PACKAGEPIN = dout ? 1'bz : 1'b0; if (PIN_TYPE[5:4] == 2'b10) assign PACKAGEPIN = OUTPUTENABLE ? (dout ? 1'bz : 1'b0) : 1'bz; if (PIN_TYPE[5:4] == 2'b11) assign PACKAGEPIN = outena_q ? (dout ? 1'bz : 1'b0) : 1'bz; endgenerate `endif endmodule module SB_MAC16 ( input CLK, CE, input [15:0] C, A, B, D, input AHOLD, BHOLD, CHOLD, DHOLD, input IRSTTOP, IRSTBOT, input ORSTTOP, ORSTBOT, input OLOADTOP, OLOADBOT, input ADDSUBTOP, ADDSUBBOT, input OHOLDTOP, OHOLDBOT, input CI, ACCUMCI, SIGNEXTIN, output [31:0] O, output CO, ACCUMCO, SIGNEXTOUT ); parameter [0:0] NEG_TRIGGER = 0; parameter [0:0] C_REG = 0; parameter [0:0] A_REG = 0; parameter [0:0] B_REG = 0; parameter [0:0] D_REG = 0; parameter [0:0] TOP_8x8_MULT_REG = 0; parameter [0:0] BOT_8x8_MULT_REG = 0; parameter [0:0] PIPELINE_16x16_MULT_REG1 = 0; parameter [0:0] PIPELINE_16x16_MULT_REG2 = 0; parameter [1:0] TOPOUTPUT_SELECT = 0; parameter [1:0] TOPADDSUB_LOWERINPUT = 0; parameter [0:0] TOPADDSUB_UPPERINPUT = 0; parameter [1:0] TOPADDSUB_CARRYSELECT = 0; parameter [1:0] BOTOUTPUT_SELECT = 0; parameter [1:0] BOTADDSUB_LOWERINPUT = 0; parameter [0:0] BOTADDSUB_UPPERINPUT = 0; parameter [1:0] BOTADDSUB_CARRYSELECT = 0; parameter [0:0] MODE_8x8 = 0; parameter [0:0] A_SIGNED = 0; parameter [0:0] B_SIGNED = 0; wire clock = CLK ^ NEG_TRIGGER; // internal wires, compare Figure on page 133 of ICE Technology Library 3.0 and Fig 2 on page 2 of Lattice TN1295-DSP // http://www.latticesemi.com/~/media/LatticeSemi/Documents/TechnicalBriefs/SBTICETechnologyLibrary201608.pdf // https://www.latticesemi.com/-/media/LatticeSemi/Documents/ApplicationNotes/AD/DSPFunctionUsageGuideforICE40Devices.ashx wire [15:0] iA, iB, iC, iD; wire [15:0] iF, iJ, iK, iG; wire [31:0] iL, iH; wire [15:0] iW, iX, iP, iQ; wire [15:0] iY, iZ, iR, iS; wire HCI, LCI, LCO; // Regs C and A reg [15:0] rC, rA; always @(posedge clock, posedge IRSTTOP) begin if (IRSTTOP) begin rC <= 0; rA <= 0; end else if (CE) begin if (!CHOLD) rC <= C; if (!AHOLD) rA <= A; end end assign iC = C_REG ? rC : C; assign iA = A_REG ? rA : A; // Regs B and D reg [15:0] rB, rD; always @(posedge clock, posedge IRSTBOT) begin if (IRSTBOT) begin rB <= 0; rD <= 0; end else if (CE) begin if (!BHOLD) rB <= B; if (!DHOLD) rD <= D; end end assign iB = B_REG ? rB : B; assign iD = D_REG ? rD : D; // Multiplier Stage wire [15:0] p_Ah_Bh, p_Al_Bh, p_Ah_Bl, p_Al_Bl; wire [15:0] Ah, Al, Bh, Bl; assign Ah = {A_SIGNED ? {8{iA[15]}} : 8'b0, iA[15: 8]}; assign Al = {A_SIGNED ? {8{iA[ 7]}} : 8'b0, iA[ 7: 0]}; assign Bh = {B_SIGNED ? {8{iB[15]}} : 8'b0, iB[15: 8]}; assign Bl = {B_SIGNED ? {8{iB[ 7]}} : 8'b0, iB[ 7: 0]}; assign p_Ah_Bh = Ah * Bh; assign p_Al_Bh = Al * Bh; assign p_Ah_Bl = Ah * Bl; assign p_Al_Bl = Al * Bl; // Regs F and J reg [15:0] rF, rJ; always @(posedge clock, posedge IRSTTOP) begin if (IRSTTOP) begin rF <= 0; rJ <= 0; end else if (CE) begin rF <= p_Ah_Bh; if (!MODE_8x8) rJ <= p_Al_Bh; end end assign iF = TOP_8x8_MULT_REG ? rF : p_Ah_Bh; assign iJ = PIPELINE_16x16_MULT_REG1 ? rJ : p_Al_Bh; // Regs K and G reg [15:0] rK, rG; always @(posedge clock, posedge IRSTBOT) begin if (IRSTBOT) begin rK <= 0; rG <= 0; end else if (CE) begin if (!MODE_8x8) rK <= p_Ah_Bl; rG <= p_Al_Bl; end end assign iK = PIPELINE_16x16_MULT_REG1 ? rK : p_Ah_Bl; assign iG = BOT_8x8_MULT_REG ? rG : p_Al_Bl; // Adder Stage assign iL = iG + (iK << 8) + (iJ << 8) + (iF << 16); // Reg H reg [31:0] rH; always @(posedge clock, posedge IRSTBOT) begin if (IRSTBOT) begin rH <= 0; end else if (CE) begin if (!MODE_8x8) rH <= iL; end end assign iH = PIPELINE_16x16_MULT_REG2 ? rH : iL; // Hi Output Stage wire [15:0] XW, Oh; reg [15:0] rQ; assign iW = TOPADDSUB_UPPERINPUT ? iC : iQ; assign iX = (TOPADDSUB_LOWERINPUT == 0) ? iA : (TOPADDSUB_LOWERINPUT == 1) ? iF : (TOPADDSUB_LOWERINPUT == 2) ? iH[31:16] : {16{iZ[15]}}; assign {ACCUMCO, XW} = iX + (iW ^ {16{ADDSUBTOP}}) + HCI; assign CO = ACCUMCO ^ ADDSUBTOP; assign iP = OLOADTOP ? iC : XW ^ {16{ADDSUBTOP}}; always @(posedge clock, posedge ORSTTOP) begin if (ORSTTOP) begin rQ <= 0; end else if (CE) begin if (!OHOLDTOP) rQ <= iP; end end assign iQ = rQ; assign Oh = (TOPOUTPUT_SELECT == 0) ? iP : (TOPOUTPUT_SELECT == 1) ? iQ : (TOPOUTPUT_SELECT == 2) ? iF : iH[31:16]; assign HCI = (TOPADDSUB_CARRYSELECT == 0) ? 1'b0 : (TOPADDSUB_CARRYSELECT == 1) ? 1'b1 : (TOPADDSUB_CARRYSELECT == 2) ? LCO : LCO ^ ADDSUBBOT; assign SIGNEXTOUT = iX[15]; // Lo Output Stage wire [15:0] YZ, Ol; reg [15:0] rS; assign iY = BOTADDSUB_UPPERINPUT ? iD : iS; assign iZ = (BOTADDSUB_LOWERINPUT == 0) ? iB : (BOTADDSUB_LOWERINPUT == 1) ? iG : (BOTADDSUB_LOWERINPUT == 2) ? iH[15:0] : {16{SIGNEXTIN}}; assign {LCO, YZ} = iZ + (iY ^ {16{ADDSUBBOT}}) + LCI; assign iR = OLOADBOT ? iD : YZ ^ {16{ADDSUBBOT}}; always @(posedge clock, posedge ORSTBOT) begin if (ORSTBOT) begin rS <= 0; end else if (CE) begin if (!OHOLDBOT) rS <= iR; end end assign iS = rS; assign Ol = (BOTOUTPUT_SELECT == 0) ? iR : (BOTOUTPUT_SELECT == 1) ? iS : (BOTOUTPUT_SELECT == 2) ? iG : iH[15:0]; assign LCI = (BOTADDSUB_CARRYSELECT == 0) ? 1'b0 : (BOTADDSUB_CARRYSELECT == 1) ? 1'b1 : (BOTADDSUB_CARRYSELECT == 2) ? ACCUMCI : CI; assign O = {Oh, Ol}; endmodule