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[/] [rtf68ksys/] [trunk/] [rtl/] [verilog/] [syncRam4kx9_1rw1r.v] - Rev 2
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// ============================================================================ // 2008,2011 Robert Finch // robfinch@<remove>sympatico.ca // // syncRam4kx9_1rw1r.v // // This source file is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published // by the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This source file is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // // // ============================================================================ // `define SYNTHESIS `define VENDOR_XILINX `define SPARTAN3 module syncRam4kx9_1rw1r( input wrst, input wclk, input wce, input we, input [11:0] wadr, input [8:0] i, output [8:0] wo, input rrst, input rclk, input rce, input [11:0] radr, output [8:0] o ); `ifdef SYNTHESIS `ifdef VENDOR_XILINX `ifdef SPARTAN3 wire [8:0] o0; wire [8:0] o1; wire [8:0] wo0; wire [8:0] wo1; wire rrst0 = radr[11]; wire rrst1 = ~radr[11]; wire wrst0 = wadr[11]; wire wrst1 = ~wadr[11]; wire we0 = we & ~wadr[11]; wire we1 = we & wadr[11]; RAMB16_S9_S9 ram0( .CLKA(wclk), .ADDRA(wadr), .DIA(i[7:0]), .DIPA(i[8]), .DOA(wo0[7:0]), .DOPA(wo0[8]), .ENA(wce), .WEA(we0), .SSRA(wrst0), .CLKB(rclk), .ADDRB(radr), .DIB(8'hFF), .DIPB(1'b1), .DOB(o0[7:0]), .DOPB(o0[8]), .ENB(rce), .WEB(1'b0), .SSRB(rrst0) ); RAMB16_S9_S9 ram1( .CLKA(wclk), .ADDRA(wadr), .DIA(i[7:0]), .DIPA(i[8]), .DOA(wo1[7:0]), .DOPA(wo1[8]), .ENA(wce), .WEA(we1), .SSRA(wrst1), .CLKB(rclk), .ADDRB(radr), .DIB(8'hFF), .DIPB(1'b1), .DOB(o1[7:0]), .DOPB(o1[8]), .ENB(rce), .WEB(1'b0), .SSRB(rrst1) ); assign o = o0|o1; assign wo = wo0|wo1; `endif `ifdef SPARTAN2 RAMB4_S1_S1 ram0( .CLKA(wclk), .ADDRA(wadr), .DIA(i[0]), .DOA(wo[0]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[0]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram1( .CLKA(wclk), .ADDRA(wadr), .DIA(i[1]), .DOA(wo[1]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[1]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram2( .CLKA(wclk), .ADDRA(wadr), .DIA(i[2]), .DOA(wo[2]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[2]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram3( .CLKA(wclk), .ADDRA(wadr), .DIA(i[3]), .DOA(wo[3]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[3]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram4( .CLKA(wclk), .ADDRA(wadr), .DIA(i[4]), .DOA(wo[4]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[4]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram5( .CLKA(wclk), .ADDRA(wadr), .DIA(i[5]), .DOA(wo[5]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[5]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram6( .CLKA(wclk), .ADDRA(wadr), .DIA(i[6]), .DOA(wo[6]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[6]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram7( .CLKA(wclk), .ADDRA(wadr), .DIA(i[7]), .DOA(wo[7]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[7]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); RAMB4_S1_S1 ram8( .CLKA(wclk), .ADDRA(wadr), .DIA(i[8]), .DOA(wo[8]), .ENA(wce), .WEA(we), .RSTA(wrst), .CLKB(rclk), .ADDRB(radr), .DIB(1'b1), .DOB(o[8]), .ENB(rce), .WEB(1'b0), .RSTB(rrst) ); `endif `endif `ifdef VENDOR_ALTERA reg [8:0] mem [4095:0]; reg [10:0] rradr; reg [10:0] rwadr; // register read addresses always @(posedge rclk) if (rce) rradr <= radr; assign o = mem[rradr]; // write side always @(posedge wclk) if (wce) rwadr <= wadr; always @(posedge wclk) if (wce) mem[wadr] <= i; assign wo = mem[rwadr]; `endif `else reg [8:0] mem [4095:0]; reg [10:0] rradr; reg [10:0] rwadr; // register read addresses always @(posedge rclk) if (rce) rradr <= radr; assign o = mem[rradr]; // write side always @(posedge wclk) if (wce) rwadr <= wadr; always @(posedge wclk) if (wce) mem[wadr] <= i; assign wo = mem[rwadr]; `endif endmodule