yosys/techlibs/xilinx/xcu_brams_map.v

387 lines
8.5 KiB
Verilog

// Ultrascale and Ultrascale Plus block RAM mapping.
module \$__XILINX_RAMB36_SDP (CLK2, CLK3, A1ADDR, A1DATA, A1EN, B1ADDR, B1DATA, B1EN);
parameter CLKPOL2 = 1;
parameter CLKPOL3 = 1;
parameter [36863:0] INIT = 36864'bx;
input CLK2;
input CLK3;
input [8:0] A1ADDR;
output [71:0] A1DATA;
input A1EN;
input [8:0] B1ADDR;
input [71:0] B1DATA;
input [7:0] B1EN;
wire [15:0] A1ADDR_16 = {A1ADDR, 6'b0};
wire [15:0] B1ADDR_16 = {B1ADDR, 6'b0};
wire [7:0] DIP, DOP;
wire [63:0] DI, DO;
assign A1DATA = { DOP[7], DO[63:56], DOP[6], DO[55:48], DOP[5], DO[47:40], DOP[4], DO[39:32],
DOP[3], DO[31:24], DOP[2], DO[23:16], DOP[1], DO[15: 8], DOP[0], DO[ 7: 0] };
assign { DIP[7], DI[63:56], DIP[6], DI[55:48], DIP[5], DI[47:40], DIP[4], DI[39:32],
DIP[3], DI[31:24], DIP[2], DI[23:16], DIP[1], DI[15: 8], DIP[0], DI[ 7: 0] } = B1DATA;
RAMB36E2 #(
.READ_WIDTH_A(72),
.WRITE_WIDTH_B(72),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_36.vh"
) _TECHMAP_REPLACE_ (
.DOUTBDOUT(DO[63:32]),
.DOUTADOUT(DO[31:0]),
.DOUTPBDOUTP(DOP[7:4]),
.DOUTPADOUTP(DOP[3:0]),
.DINBDIN(DI[63:32]),
.DINADIN(DI[31:0]),
.DINPBDINP(DIP[7:4]),
.DINPADINP(DIP[3:0]),
.ADDRARDADDR(A1ADDR_16),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(4'b0),
.ADDRBWRADDR(B1ADDR_16),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|1),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN),
.SLEEP(|0)
);
endmodule
// ------------------------------------------------------------------------
module \$__XILINX_RAMB18_SDP (CLK2, CLK3, A1ADDR, A1DATA, A1EN, B1ADDR, B1DATA, B1EN);
parameter CLKPOL2 = 1;
parameter CLKPOL3 = 1;
parameter [18431:0] INIT = 18432'bx;
input CLK2;
input CLK3;
input [8:0] A1ADDR;
output [35:0] A1DATA;
input A1EN;
input [8:0] B1ADDR;
input [35:0] B1DATA;
input [3:0] B1EN;
wire [13:0] A1ADDR_14 = {A1ADDR, 5'b0};
wire [13:0] B1ADDR_14 = {B1ADDR, 5'b0};
wire [3:0] DIP, DOP;
wire [31:0] DI, DO;
assign A1DATA = { DOP[3], DO[31:24], DOP[2], DO[23:16], DOP[1], DO[15: 8], DOP[0], DO[ 7: 0] };
assign { DIP[3], DI[31:24], DIP[2], DI[23:16], DIP[1], DI[15: 8], DIP[0], DI[ 7: 0] } = B1DATA;
RAMB18E2 #(
.READ_WIDTH_A(36),
.WRITE_WIDTH_B(36),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_18.vh"
) _TECHMAP_REPLACE_ (
.DOUTBDOUT(DO[31:16]),
.DOUTADOUT(DO[15:0]),
.DOUTPBDOUTP(DOP[3:2]),
.DOUTPADOUTP(DOP[1:0]),
.DINBDIN(DI[31:16]),
.DINADIN(DI[15:0]),
.DINPBDINP(DIP[3:2]),
.DINPADINP(DIP[1:0]),
.ADDRARDADDR(A1ADDR_14),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(2'b0),
.ADDRBWRADDR(B1ADDR_14),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|1),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN),
.SLEEP(|0)
);
endmodule
// ------------------------------------------------------------------------
module \$__XILINX_RAMB36_TDP (CLK2, CLK3, A1ADDR, A1DATA, A1EN, B1ADDR, B1DATA, B1EN);
parameter CFG_ABITS = 10;
parameter CFG_DBITS = 36;
parameter CFG_ENABLE_B = 4;
parameter CLKPOL2 = 1;
parameter CLKPOL3 = 1;
parameter [36863:0] INIT = 36864'bx;
input CLK2;
input CLK3;
input [CFG_ABITS-1:0] A1ADDR;
output [CFG_DBITS-1:0] A1DATA;
input A1EN;
input [CFG_ABITS-1:0] B1ADDR;
input [CFG_DBITS-1:0] B1DATA;
input [CFG_ENABLE_B-1:0] B1EN;
wire [15:0] A1ADDR_16 = A1ADDR << (15 - CFG_ABITS);
wire [15:0] B1ADDR_16 = B1ADDR << (15 - CFG_ABITS);
wire [7:0] B1EN_8 = B1EN;
wire [3:0] DIP, DOP;
wire [31:0] DI, DO;
wire [31:0] DOBDO;
wire [3:0] DOPBDOP;
assign A1DATA = { DOP[3], DO[31:24], DOP[2], DO[23:16], DOP[1], DO[15: 8], DOP[0], DO[ 7: 0] };
assign { DIP[3], DI[31:24], DIP[2], DI[23:16], DIP[1], DI[15: 8], DIP[0], DI[ 7: 0] } = B1DATA;
generate if (CFG_DBITS > 8) begin
RAMB36E2 #(
.READ_WIDTH_A(CFG_DBITS),
.READ_WIDTH_B(CFG_DBITS),
.WRITE_WIDTH_A(CFG_DBITS),
.WRITE_WIDTH_B(CFG_DBITS),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_36.vh"
) _TECHMAP_REPLACE_ (
.DINADIN(32'hFFFFFFFF),
.DINPADINP(4'hF),
.DOUTADOUT(DO[31:0]),
.DOUTPADOUTP(DOP[3:0]),
.ADDRARDADDR(A1ADDR_16),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(4'b0),
.DINBDIN(DI),
.DINPBDINP(DIP),
.DOUTBDOUT(DOBDO),
.DOUTPBDOUTP(DOPBDOP),
.ADDRBWRADDR(B1ADDR_16),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|0),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN_8),
.SLEEP(|0)
);
end else begin
RAMB36E2 #(
.READ_WIDTH_A(CFG_DBITS),
.READ_WIDTH_B(CFG_DBITS),
.WRITE_WIDTH_A(CFG_DBITS),
.WRITE_WIDTH_B(CFG_DBITS),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_32.vh"
) _TECHMAP_REPLACE_ (
.DINADIN(32'hFFFFFFFF),
.DINPADINP(4'hF),
.DOUTADOUT(DO[31:0]),
.DOUTPADOUTP(DOP[3:0]),
.ADDRARDADDR(A1ADDR_16),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(4'b0),
.DINBDIN(DI),
.DINPBDINP(DIP),
.DOUTBDOUT(DOBDO),
.DOUTPBDOUTP(DOPBDOP),
.ADDRBWRADDR(B1ADDR_16),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|0),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN_8),
.SLEEP(|0)
);
end endgenerate
endmodule
// ------------------------------------------------------------------------
module \$__XILINX_RAMB18_TDP (CLK2, CLK3, A1ADDR, A1DATA, A1EN, B1ADDR, B1DATA, B1EN);
parameter CFG_ABITS = 10;
parameter CFG_DBITS = 18;
parameter CFG_ENABLE_B = 2;
parameter CLKPOL2 = 1;
parameter CLKPOL3 = 1;
parameter [18431:0] INIT = 18432'bx;
input CLK2;
input CLK3;
input [CFG_ABITS-1:0] A1ADDR;
output [CFG_DBITS-1:0] A1DATA;
input A1EN;
input [CFG_ABITS-1:0] B1ADDR;
input [CFG_DBITS-1:0] B1DATA;
input [CFG_ENABLE_B-1:0] B1EN;
wire [13:0] A1ADDR_14 = A1ADDR << (14 - CFG_ABITS);
wire [13:0] B1ADDR_14 = B1ADDR << (14 - CFG_ABITS);
wire [3:0] B1EN_4 = B1EN;
wire [1:0] DIP, DOP;
wire [15:0] DI, DO;
wire [15:0] DOBDO;
wire [1:0] DOPBDOP;
assign A1DATA = { DOP[1], DO[15: 8], DOP[0], DO[ 7: 0] };
assign { DIP[1], DI[15: 8], DIP[0], DI[ 7: 0] } = B1DATA;
generate if (CFG_DBITS > 8) begin
RAMB18E2 #(
.READ_WIDTH_A(CFG_DBITS),
.READ_WIDTH_B(CFG_DBITS),
.WRITE_WIDTH_A(CFG_DBITS),
.WRITE_WIDTH_B(CFG_DBITS),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_18.vh"
) _TECHMAP_REPLACE_ (
.DINADIN(16'hFFFF),
.DINPADINP(2'b11),
.DOUTADOUT(DO),
.DOUTPADOUTP(DOP),
.ADDRARDADDR(A1ADDR_14),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(2'b0),
.DINBDIN(DI),
.DINPBDINP(DIP),
.DOUTBDOUT(DOBDO),
.DOUTPBDOUTP(DOPBDOP),
.ADDRBWRADDR(B1ADDR_14),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|0),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN_4),
.SLEEP(|0)
);
end else begin
RAMB18E2 #(
//.RAM_MODE("TDP"),
.READ_WIDTH_A(CFG_DBITS),
.READ_WIDTH_B(CFG_DBITS),
.WRITE_WIDTH_A(CFG_DBITS),
.WRITE_WIDTH_B(CFG_DBITS),
.WRITE_MODE_A("READ_FIRST"),
.WRITE_MODE_B("READ_FIRST"),
.DOA_REG(0),
.DOB_REG(0),
.IS_CLKARDCLK_INVERTED(!CLKPOL2),
.IS_CLKBWRCLK_INVERTED(!CLKPOL3),
`include "brams_init_16.vh"
) _TECHMAP_REPLACE_ (
.DINADIN(16'hFFFF),
.DINPADINP(2'b11),
.DOUTADOUT(DO),
.DOUTPADOUTP(DOP),
.ADDRARDADDR(A1ADDR_14),
.CLKARDCLK(CLK2),
.ENARDEN(A1EN),
.ADDRENA(|1),
.REGCEAREGCE(|1),
.RSTRAMARSTRAM(|0),
.RSTREGARSTREG(|0),
.WEA(2'b0),
.DINBDIN(DI),
.DINPBDINP(DIP),
.DOUTBDOUT(DOBDO),
.DOUTPBDOUTP(DOPBDOP),
.ADDRBWRADDR(B1ADDR_14),
.CLKBWRCLK(CLK3),
.ENBWREN(|1),
.ADDRENB(|1),
.REGCEB(|0),
.RSTRAMB(|0),
.RSTREGB(|0),
.WEBWE(B1EN_4),
.SLEEP(|0)
);
end endgenerate
endmodule