`include "VX_define.v" module VX_gpr ( input wire clk, input wire valid_write_request, VX_gpr_read_inter VX_gpr_read, VX_wb_inter VX_writeback_inter, output reg[`NT_M1:0][31:0] out_a_reg_data, output reg[`NT_M1:0][31:0] out_b_reg_data ); wire write_enable; assign write_enable = valid_write_request && ((VX_writeback_inter.wb != 0) && (VX_writeback_inter.rd != 5'h0)); // <<<<<<< HEAD // always @(*) begin // if(write_enable) $display("Writing to %d: %d = %h",VX_writeback_inter.wb_warp_num, VX_writeback_inter.rd, VX_writeback_inter.write_data[0][31:0]); // end // byte_enabled_simple_dual_port_ram first_ram( // .we (write_enable), // .clk (clk), // .waddr (VX_writeback_inter.rd), // .raddr1(VX_gpr_read.rs1), // .raddr2(VX_gpr_read.rs2), // .be (VX_writeback_inter.wb_valid), // .wdata (VX_writeback_inter.write_data), // .q1 (out_a_reg_data), // .q2 (out_b_reg_data) // ); // ======= // byte_enabled_simple_dual_port_ram first_ram( // .we (write_enable), // .clk (clk), // .waddr (VX_writeback_inter.rd), // .raddr1(VX_gpr_read.rs1), // .be (VX_writeback_inter.wb_valid), // .wdata (VX_writeback_inter.write_data), // .q1 (out_a_reg_data) // ); // byte_enabled_simple_dual_port_ram first_ram( // .we (write_enable), // .clk (clk), // .waddr (VX_writeback_inter.rd), // .raddr1(VX_gpr_read.rs2), // .be (VX_writeback_inter.wb_valid), // .wdata (VX_writeback_inter.write_data), // .q1 (out_b_reg_data) // ); wire[127:0] write_bit_mask = {{32{~(VX_writeback_inter.wb_valid[3])}}, {32{~(VX_writeback_inter.wb_valid[2])}}, {32{~(VX_writeback_inter.wb_valid[1])}}, {32{~(VX_writeback_inter.wb_valid[0])}}}; // Port A is a read port, Port B is a write port /* verilator lint_off PINCONNECTEMPTY */ rf2_32x128_wm1 first_ram ( .CENYA(), .AYA(), .CENYB(), .WENYB(), .AYB(), .QA(out_a_reg_data), .SOA(), .SOB(), .CLKA(clk), .CENA(1'b0), .AA(VX_gpr_read.rs1), .CLKB(clk), .CENB(1'b0), .WENB(write_bit_mask), .AB(VX_writeback_inter.rd), .DB(VX_writeback_inter.write_data), .EMAA(3'b011), .EMASA(1'b0), .EMAB(3'b011), .TENA(1'b1), .TCENA(1'b0), .TAA(5'b0), .TENB(1'b1), .TCENB(1'b0), .TWENB(128'b0), .TAB(5'b0), .TDB(128'b0), .RET1N(1'b1), .SIA(2'b0), .SEA(1'b0), .DFTRAMBYP(1'b0), .SIB(2'b0), .SEB(1'b0), .COLLDISN(1'b1) ); /* verilator lint_on PINCONNECTEMPTY */ /* verilator lint_off PINCONNECTEMPTY */ rf2_32x128_wm1 second_ram ( .CENYA(), .AYA(), .CENYB(), .WENYB(), .AYB(), .QA(out_b_reg_data), .SOA(), .SOB(), .CLKA(clk), .CENA(1'b0), .AA(VX_gpr_read.rs2), .CLKB(clk), .CENB(1'b0), .WENB(write_bit_mask), .AB(VX_writeback_inter.rd), .DB(VX_writeback_inter.write_data), .EMAA(3'b011), .EMASA(1'b0), .EMAB(3'b011), .TENA(1'b1), .TCENA(1'b0), .TAA(5'b0), .TENB(1'b1), .TCENB(1'b0), .TWENB(128'b0), .TAB(5'b0), .TDB(128'b0), .RET1N(1'b1), .SIA(2'b0), .SEA(1'b0), .DFTRAMBYP(1'b0), .SIB(2'b0), .SEB(1'b0), .COLLDISN(1'b1) ); /* verilator lint_on PINCONNECTEMPTY */ // >>>>>>> 5680b997b599ce2900997cab976681fe3881e880 // // USING RAM blocks // // First RAM // byte_enabled_simple_dual_port_ram first_ram( // .we (write_enable), // .clk (clk), // .waddr(VX_writeback_inter.rd), // .raddr(VX_gpr_read.rs1), // .be (VX_writeback_inter.wb_valid), // .wdata(VX_writeback_inter.write_data), // .q (out_a_reg_data) // ); // // Second RAM block // byte_enabled_simple_dual_port_ram second_ram( // .we (write_enable), // .clk (clk), // .waddr(VX_writeback_inter.rd), // .raddr(VX_gpr_read.rs2), // .be (VX_writeback_inter.wb_valid), // .wdata(VX_writeback_inter.write_data), // .q (out_b_reg_data) // ); // logic[`NT_M1:0][31:0] gpr[31:0]; // gpr[register_number][thread_number][data_bits] // wire write_enable; // assign write_enable = valid_write_request && ((VX_writeback_inter.wb != 0) && (VX_writeback_inter.rd != 5'h0)); // assign read_enable = valid_request; // // Using Registers // integer thread_index; // always_ff@(posedge clk) // begin // if (write_enable) begin // for (thread_index = 0; thread_index <= `NT_M1; thread_index = thread_index + 1) begin // if (VX_writeback_inter.wb_valid[thread_index]) begin // gpr[VX_writeback_inter.rd][thread_index] <= VX_writeback_inter.write_data[thread_index]; // end // end // end // out_a_reg_data <= gpr[VX_gpr_read.rs1]; // out_b_reg_data <= gpr[VX_gpr_read.rs2]; // end endmodule