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[/] [minsoc/] [trunk/] [bench/] [verilog/] [sim_lib/] [fpga_memory_primitives.v] - Rev 82
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// //ALTERA_LPM // module lpm_ram_dq ( address, inclock, outclock, data, we, q ); parameter lpm_width = 8; parameter lpm_widthad = 11; parameter lpm_indata = "REGISTERED"; //This 4 parameters are included only to avoid warnings parameter lpm_address_control = "REGISTERED"; //they are not accessed inside the module. OR1200 uses this parameter lpm_outdata = "UNREGISTERED"; //configuration set on all its instantiations, so this is fine. parameter lpm_hint = "USE_EAB=ON"; //It may not be fine, if you are adding this library to your //own system, which uses this module with another configuration. localparam dw = lpm_width; localparam aw = lpm_widthad; input [aw-1:0] address; input inclock; input outclock; input [dw-1:0] data; input we; output [dw-1:0] q; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign q = mem[addr_reg]; // // RAM address register // always @(posedge inclock) addr_reg <= #1 address; // // RAM write // always @(posedge inclock) if (we) mem[address] <= #1 data; endmodule module altqpram ( wraddress_a, inclocken_a, wraddress_b, wren_a, inclocken_b, wren_b, inaclr_a, inaclr_b, inclock_a, inclock_b, data_a, data_b, q_a, q_b ); parameter width_write_a = 8; parameter widthad_write_a = 11; parameter width_write_b = 8; parameter widthad_write_b = 11; localparam dw = width_write_a; localparam aw = widthad_write_a; input inclock_a, inaclr_a, inclocken_a, wren_a, inclock_b, inaclr_b, inclocken_b, wren_b; input [dw-1:0] data_a, data_b; output [dw-1:0] q_a, q_b; input [aw-1:0] wraddress_a, wraddress_b; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg_a; // RAM address register reg [aw-1:0] addr_reg_b; // RAM address register // // Data output drivers // assign q_a = mem[addr_reg_a][dw-1:0]; assign q_b = mem[addr_reg_b][dw-1:0]; // // RAM address register // always @(posedge inclock_a or posedge inaclr_a) if ( inaclr_a == 1'b1 ) addr_reg_a <= #1 {aw{1'b0}}; else if ( inclocken_a ) addr_reg_a <= #1 wraddress_a; always @(posedge inclock_b or posedge inaclr_b) if ( inaclr_b == 1'b1 ) addr_reg_b <= #1 {aw{1'b0}}; else if ( inclocken_b ) addr_reg_b <= #1 wraddress_b; // // RAM write // always @(posedge inclock_a) if (inclocken_a && wren_a) mem[wraddress_a] <= #1 data_a; always @(posedge inclock_b) if (inclocken_b && wren_b) mem[wraddress_b] <= #1 data_b; endmodule // // ~ALTERA_LPM // // //XILINX_RAMB16 // module RAMB16_S36_S36 ( CLKA, SSRA, ADDRA, DIA, DIPA, ENA, WEA, DOA, DOPA, CLKB, SSRB, ADDRB, DIB, DIPB, ENB, WEB, DOB, DOPB ); parameter dw = 32; parameter dwp = 4; parameter aw = 9; input CLKA, SSRA, ENA, WEA, CLKB, SSRB, ENB, WEB; input [dw-1:0] DIA, DIB; output [dw-1:0] DOA, DOB; input [dwp-1:0] DIPA, DIPB; output [dwp-1:0] DOPA, DOPB; input [aw-1:0] ADDRA, ADDRB; reg [dw+dwp-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg_a; // RAM address register reg [aw-1:0] addr_reg_b; // RAM address register // // Data output drivers // assign DOA = mem[addr_reg_a][dw-1:0]; assign DOPA = mem[addr_reg_a][dwp+dw-1:dw]; assign DOB = mem[addr_reg_b][dw-1:0]; assign DOPB = mem[addr_reg_b][dwp+dw-1:dw]; // // RAM address register // always @(posedge CLKA or posedge SSRA) if ( SSRA == 1'b1 ) addr_reg_a <= #1 {aw{1'b0}}; else if ( ENA ) addr_reg_a <= #1 ADDRA; always @(posedge CLKB or posedge SSRB) if ( SSRB == 1'b1 ) addr_reg_b <= #1 {aw{1'b0}}; else if ( ENB ) addr_reg_b <= #1 ADDRB; // // RAM write // always @(posedge CLKA) if (ENA && WEA) mem[ADDRA] <= #1 { DIPA , DIA }; always @(posedge CLKB) if (ENB && WEB) mem[ADDRB] <= #1 { DIPB , DIB }; endmodule module RAMB16_S9 ( CLK, SSR, ADDR, DI, DIP, EN, WE, DO, DOP ); parameter dw = 8; parameter dwp = 1; parameter aw = 11; input CLK, SSR, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [dwp-1:0] DIP; output [dwp-1:0] DOP; input [aw-1:0] ADDR; reg [dw+dwp-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; assign DOP = mem[addr_reg][dwp+dw-1:dw]; // // RAM address register // always @(posedge CLK or posedge SSR) if ( SSR == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 { DIP , DI }; endmodule module RAMB16_S36 ( CLK, SSR, ADDR, DI, DIP, EN, WE, DO, DOP ); parameter dw = 32; parameter dwp = 4; parameter aw = 9; input CLK, SSR, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [dwp-1:0] DIP; output [dwp-1:0] DOP; input [aw-1:0] ADDR; reg [dw+dwp-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; assign DOP = mem[addr_reg][dwp+dw-1:dw]; // // RAM address register // always @(posedge CLK or posedge SSR) if ( SSR == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 { DIP , DI }; endmodule module RAMB16_S18 ( CLK, SSR, ADDR, DI, DIP, EN, WE, DO, DOP ); parameter dw = 16; parameter dwp = 2; parameter aw = 10; input CLK, SSR, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [dwp-1:0] DIP; output [dwp-1:0] DOP; input [aw-1:0] ADDR; reg [dw+dwp-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; assign DOP = mem[addr_reg][dwp+dw-1:dw]; // // RAM address register // always @(posedge CLK or posedge SSR) if ( SSR == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 { DIP , DI }; endmodule // //~XILINX_RAMB16 // // //XILINX_RAMB4 // module RAMB4_S16_S16 ( CLKA, RSTA, ADDRA, DIA, ENA, WEA, DOA, CLKB, RSTB, ADDRB, DIB, ENB, WEB, DOB ); parameter dw = 16; parameter aw = 8; input CLKA, RSTA, ENA, WEA, CLKB, RSTB, ENB, WEB; input [dw-1:0] DIA, DIB; output [dw-1:0] DOA, DOB; input [aw-1:0] ADDRA, ADDRB; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg_a; // RAM address register reg [aw-1:0] addr_reg_b; // RAM address register // // Data output drivers // assign DOA = mem[addr_reg_a][dw-1:0]; assign DOB = mem[addr_reg_b][dw-1:0]; // // RAM address register // always @(posedge CLKA or posedge RSTA) if ( RSTA == 1'b1 ) addr_reg_a <= #1 {aw{1'b0}}; else if ( ENA ) addr_reg_a <= #1 ADDRA; always @(posedge CLKB or posedge RSTB) if ( RSTB == 1'b1 ) addr_reg_b <= #1 {aw{1'b0}}; else if ( ENB ) addr_reg_b <= #1 ADDRB; // // RAM write // always @(posedge CLKA) if (ENA && WEA) mem[ADDRA] <= #1 DIA; always @(posedge CLKB) if (ENB && WEB) mem[ADDRB] <= #1 DIB; endmodule module RAMB4_S4 ( CLK, RST, ADDR, DI, EN, WE, DO, ); parameter dw = 4; parameter aw = 10; input CLK, RST, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [aw-1:0] ADDR; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; // // RAM address register // always @(posedge CLK or posedge RST) if ( RST == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 DI; endmodule module RAMB4_S16 ( CLK, RST, ADDR, DI, EN, WE, DO ); parameter dw = 16; parameter aw = 8; input CLK, RST, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [aw-1:0] ADDR; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; // // RAM address register // always @(posedge CLK or posedge RST) if ( RST == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 DI; endmodule module RAMB4_S2 ( CLK, RST, ADDR, DI, EN, WE, DO, ); parameter dw = 2; parameter aw = 11; input CLK, RST, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [aw-1:0] ADDR; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; // // RAM address register // always @(posedge CLK or posedge RST) if ( RST == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 DI; endmodule module RAMB4_S8 ( CLK, RST, ADDR, DI, EN, WE, DO, ); parameter dw = 8; parameter aw = 9; input CLK, RST, EN, WE; input [dw-1:0] DI; output [dw-1:0] DO; input [aw-1:0] ADDR; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content reg [aw-1:0] addr_reg; // RAM address register // // Data output drivers // assign DO = mem[addr_reg][dw-1:0]; // // RAM address register // always @(posedge CLK or posedge RST) if ( RST == 1'b1 ) addr_reg <= #1 {aw{1'b0}}; else if ( EN ) addr_reg <= #1 ADDR; // // RAM write // always @(posedge CLK) if (EN && WE) mem[ADDR] <= #1 DI; endmodule // // ~XILINX_RAMB4 // // // XILINX_RAM32X1D // module RAM32X1D ( DPO, SPO, A0, A1, A2, A3, A4, D, DPRA0, DPRA1, DPRA2, DPRA3, DPRA4, WCLK, WE ); parameter dw = 1; parameter aw = 5; output DPO, SPO; input DPRA0, DPRA1, DPRA2, DPRA3, DPRA4; input A0, A1, A2, A3, A4; input D; input WCLK; input WE; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content // // Data output drivers // assign DPO = mem[{DPRA4 , DPRA3 , DPRA2 , DPRA1 , DPRA0}][dw-1:0]; assign SPO = mem[{A4 , A3 , A2 , A1 , A0}][dw-1:0]; // // RAM write // always @(posedge WCLK) if (WE) mem[{A4 , A3 , A2 , A1 , A0}] <= #1 D; endmodule // // ~XILINX_RAM32X1D // // // USE_RAM16X1D_FOR_RAM32X1D // module RAM16X1D ( DPO, SPO, A0, A1, A2, A3, D, DPRA0, DPRA1, DPRA2, DPRA3, WCLK, WE ); parameter dw = 1; parameter aw = 4; output DPO, SPO; input DPRA0, DPRA1, DPRA2, DPRA3; input A0, A1, A2, A3; input D; input WCLK; input WE; reg [dw-1:0] mem [(1<<aw)-1:0]; // RAM content // // Data output drivers // assign DPO = mem[{DPRA3 , DPRA2 , DPRA1 , DPRA0}][dw-1:0]; assign SPO = mem[{A3 , A2 , A1 , A0}][dw-1:0]; // // RAM write // always @(posedge WCLK) if (WE) mem[{A3 , A2 , A1 , A0}] <= #1 D; endmodule // // ~USE_RAM16X1D_FOR_RAM32X1D //
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