URL
https://opencores.org/ocsvn/rf68000/rf68000/trunk
Subversion Repositories rf68000
[/] [rf68000/] [trunk/] [rtl/] [cpu/] [io_bitmap.sv] - Rev 2
Go to most recent revision | Compare with Previous | Blame | View Log
// ============================================================================// __// \\__/ o\ (C) 2022 Robert Finch, Waterloo// \ __ / All rights reserved.// \/_// robfinch<remove>@finitron.ca// ||//// io_bitmap.sv//// BSD 3-Clause License// Redistribution and use in source and binary forms, with or without// modification, are permitted provided that the following conditions are met://// 1. Redistributions of source code must retain the above copyright notice, this// list of conditions and the following disclaimer.//// 2. Redistributions in binary form must reproduce the above copyright notice,// this list of conditions and the following disclaimer in the documentation// and/or other materials provided with the distribution.//// 3. Neither the name of the copyright holder nor the names of its// contributors may be used to endorse or promote products derived from// this software without specific prior written permission.//// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.//// ============================================================================module io_bitmap(rst_i, clk_i, cs_i, cyc_i, stb_i, ack_o, we_i, asid_i, adr_i, dat_i, dat_o,iocs_i, gate_o, gate_en);input rst_i;input clk_i;input cs_i;input cyc_i;input stb_i;output ack_o;input we_i;input [5:0] asid_i;input [19:0] adr_i;input [31:0] dat_i;output reg [31:0] dat_o;input iocs_i;output reg gate_o;output gate_en;wire [31:0] douta, doutb;reg ena, enb;ack_gen #(.READ_STAGES(2),.WRITE_STAGES(1),.REGISTER_OUTPUT(1)) uag1(.rst_i(rst_i),.clk_i(clk_i),.ce_i(1'b1),.rid_i('d0),.wid_i('d0),.i(ena & ~we_i),.we_i(ena & we_i),.o(ack_o),.rid_o(),.wid_o());ack_gen #(.READ_STAGES(2),.WRITE_STAGES(1),.REGISTER_OUTPUT(1)) uag2(.rst_i(rst_i),.clk_i(clk_i),.ce_i(1'b1),.rid_i('d0),.wid_i('d0),.i(enb & ~we_i),.we_i(enb & we_i),.o(gate_en),.rid_o(),.wid_o());always_combena = cs_i & cyc_i & stb_i;always_combenb = iocs_i & cyc_i & stb_i;// xpm_memory_tdpram: True Dual Port RAM// Xilinx Parameterized Macro, version 2022.2xpm_memory_tdpram #(.ADDR_WIDTH_A(13), // DECIMAL.ADDR_WIDTH_B(13), // DECIMAL.AUTO_SLEEP_TIME(0), // DECIMAL.BYTE_WRITE_WIDTH_A(32), // DECIMAL.BYTE_WRITE_WIDTH_B(32), // DECIMAL.CASCADE_HEIGHT(0), // DECIMAL.CLOCKING_MODE("common_clock"), // String.ECC_MODE("no_ecc"), // String.MEMORY_INIT_FILE("none"), // String.MEMORY_INIT_PARAM("0"), // String.MEMORY_OPTIMIZATION("true"), // String.MEMORY_PRIMITIVE("auto"), // String.MEMORY_SIZE(4096*64), // DECIMAL.MESSAGE_CONTROL(0), // DECIMAL.READ_DATA_WIDTH_A(32), // DECIMAL.READ_DATA_WIDTH_B(32), // DECIMAL.READ_LATENCY_A(2), // DECIMAL.READ_LATENCY_B(1), // DECIMAL.READ_RESET_VALUE_A("0"), // String.READ_RESET_VALUE_B("0"), // String.RST_MODE_A("SYNC"), // String.RST_MODE_B("SYNC"), // String.SIM_ASSERT_CHK(0), // DECIMAL; 0=disable simulation messages, 1=enable simulation messages.USE_EMBEDDED_CONSTRAINT(0), // DECIMAL.USE_MEM_INIT(1), // DECIMAL.USE_MEM_INIT_MMI(0), // DECIMAL.WAKEUP_TIME("disable_sleep"), // String.WRITE_DATA_WIDTH_A(32), // DECIMAL.WRITE_DATA_WIDTH_B(32), // DECIMAL.WRITE_MODE_A("no_change"), // String.WRITE_MODE_B("no_change"), // String.WRITE_PROTECT(1) // DECIMAL)xpm_memory_tdpram_inst (.dbiterra(), // 1-bit output: Status signal to indicate double bit error occurrence// on the data output of port A..dbiterrb(), // 1-bit output: Status signal to indicate double bit error occurrence// on the data output of port A..douta(douta), // READ_DATA_WIDTH_A-bit output: Data output for port A read operations..doutb(doutb), // READ_DATA_WIDTH_B-bit output: Data output for port B read operations..sbiterra(), // 1-bit output: Status signal to indicate single bit error occurrence// on the data output of port A..sbiterrb(), // 1-bit output: Status signal to indicate single bit error occurrence// on the data output of port B..addra({asid_i[5:0],adr_i[ 8: 2]}), // ADDR_WIDTH_A-bit input: Address for port A write and read operations..addrb({asid_i[5:0],adr_i[19:13]}), // ADDR_WIDTH_B-bit input: Address for port B write and read operations..clka(clk_i), // 1-bit input: Clock signal for port A. Also clocks port B when// parameter CLOCKING_MODE is "common_clock"..clkb(clk_i), // 1-bit input: Clock signal for port B when parameter CLOCKING_MODE is// "independent_clock". Unused when parameter CLOCKING_MODE is// "common_clock"..dina(dat_i), // WRITE_DATA_WIDTH_A-bit input: Data input for port A write operations..dinb(32'h0), // WRITE_DATA_WIDTH_B-bit input: Data input for port B write operations..ena(ena), // 1-bit input: Memory enable signal for port A. Must be high on clock// cycles when read or write operations are initiated. Pipelined// internally..enb(enb), // 1-bit input: Memory enable signal for port B. Must be high on clock// cycles when read or write operations are initiated. Pipelined// internally..injectdbiterra(1'b0), // 1-bit input: Controls double bit error injection on input data when// ECC enabled (Error injection capability is not available in// "decode_only" mode)..injectdbiterrb(1'b0), // 1-bit input: Controls double bit error injection on input data when// ECC enabled (Error injection capability is not available in// "decode_only" mode)..injectsbiterra(1'b0), // 1-bit input: Controls single bit error injection on input data when// ECC enabled (Error injection capability is not available in// "decode_only" mode)..injectsbiterrb(1'b0), // 1-bit input: Controls single bit error injection on input data when// ECC enabled (Error injection capability is not available in// "decode_only" mode)..regcea(1'b1), // 1-bit input: Clock Enable for the last register stage on the output// data path..regceb(1'b1), // 1-bit input: Clock Enable for the last register stage on the output// data path..rsta(1'b0), // 1-bit input: Reset signal for the final port A output register stage.// Synchronously resets output port douta to the value specified by// parameter READ_RESET_VALUE_A..rstb(1'b0), // 1-bit input: Reset signal for the final port B output register stage.// Synchronously resets output port doutb to the value specified by// parameter READ_RESET_VALUE_B..sleep(1'b0), // 1-bit input: sleep signal to enable the dynamic power saving feature..wea(we_i), // WRITE_DATA_WIDTH_A/BYTE_WRITE_WIDTH_A-bit input: Write enable vector// for port A input data port dina. 1 bit wide when word-wide writes are// used. In byte-wide write configurations, each bit controls the// writing one byte of dina to address addra. For example, to// synchronously write only bits [15-8] of dina when WRITE_DATA_WIDTH_A// is 32, wea would be 4'b0010..web(1'b0) // WRITE_DATA_WIDTH_B/BYTE_WRITE_WIDTH_B-bit input: Write enable vector// for port B input data port dinb. 1 bit wide when word-wide writes are// used. In byte-wide write configurations, each bit controls the// writing one byte of dinb to address addrb. For example, to// synchronously write only bits [15-8] of dinb when WRITE_DATA_WIDTH_B// is 32, web would be 4'b0010.);always_ff @(posedge clk_i)if (ena)dat_o <= douta;elsedat_o <= 32'd0;always_combgate_o <= doutb[adr_i[12:8]];endmodule
Go to most recent revision | Compare with Previous | Blame | View Log