interface if_dma (); localparam [1:0] NUM_DEVICES = sc64::__ID_DMA_END; sc64::e_dma_id id; logic rx_empty; logic rx_read; logic [7:0] rx_rdata; logic tx_full; logic tx_write; logic [7:0] tx_wdata; logic request; logic ack; logic write; logic [31:0] address; logic [15:0] rdata; logic [15:0] wdata; modport controller ( output id, input rx_empty, output rx_read, input rx_rdata, input tx_full, output tx_write, output tx_wdata, output request, input ack, output write, output address, input rdata, output wdata ); modport memory ( input request, output ack, input write, input address, output rdata, input wdata ); logic [7:0] device_rx_rdata [(NUM_DEVICES - 1):0]; logic device_rx_empty [(NUM_DEVICES - 1):0]; logic device_tx_full [(NUM_DEVICES - 1):0]; always_comb begin rx_rdata = 8'd0; rx_empty = 1'b0; tx_full = 1'b0; for (integer i = 0; i < NUM_DEVICES; i++) begin rx_rdata = rx_rdata | (id == i[1:0] ? device_rx_rdata[i] : 8'd0); rx_empty = rx_empty | (device_rx_empty[i] && id == i[1:0]); tx_full = tx_full | (device_tx_full[i] && id == i[1:0]); end end genvar n; generate for (n = 0; n < NUM_DEVICES; n++) begin : at logic device_selected; logic device_rx_read; logic device_tx_write; always_comb begin device_selected = id == n[1:0]; device_rx_read = device_selected && rx_read; device_tx_write = device_selected && tx_write; end modport device ( output .rx_empty(device_rx_empty[n]), input .rx_read(device_rx_read), output .rx_rdata(device_rx_rdata[n]), output .tx_full(device_tx_full[n]), input .tx_write(device_tx_write), input .tx_wdata(tx_wdata) ); end endgenerate endinterface module cpu_dma ( if_system.sys sys, if_cpu_bus bus, if_dma.controller dma ); typedef enum bit [2:0] { S_IDLE, S_FETCH, S_TRANSFER } e_state; e_state state; logic direction; logic [27:0] length; logic [15:0] rdata_buffer; logic byte_counter; always_comb begin bus.rdata = 32'd0; if (bus.ack) begin case (bus.address[3:2]) 0: bus.rdata = {28'd0, state != S_IDLE, direction, 2'b00}; 1: bus.rdata = dma.address; 2: bus.rdata = {2'b00, dma.id, length}; endcase end end always_ff @(posedge sys.clk) begin bus.ack <= 1'b0; if (bus.request) begin bus.ack <= 1'b1; end dma.rx_read <= 1'b0; dma.tx_write <= 1'b0; if (sys.reset) begin state <= S_IDLE; dma.request <= 1'b0; end else begin case (state) S_IDLE: begin if (bus.request) begin case (bus.address[3:2]) 0: if (bus.wmask[0]) begin direction <= bus.wdata[2]; if (bus.wdata[0]) begin state <= S_FETCH; byte_counter <= 1'b0; end end 1: if (&bus.wmask) begin dma.address <= bus.wdata; end 2: if (&bus.wmask) begin {dma.id, length} <= {bus.wdata[29:1], 1'b0}; end endcase end end S_FETCH: begin if (length != 28'd0) begin if (direction) begin if (!dma.rx_empty && !dma.rx_read) begin dma.rx_read <= 1'b1; dma.wdata <= {dma.wdata[7:0], dma.rx_rdata}; byte_counter <= ~byte_counter; if (byte_counter) begin state <= S_TRANSFER; dma.request <= 1'b1; dma.write <= 1'b1; end end end else begin dma.request <= 1'b1; dma.write <= 1'b0; if (dma.ack) begin state <= S_TRANSFER; dma.request <= 1'b0; rdata_buffer <= dma.rdata; end end end else begin state <= S_IDLE; end end S_TRANSFER: begin if (direction) begin if (dma.ack) begin state <= S_FETCH; dma.request <= 1'b0; dma.address <= dma.address + 2'd2; length <= length - 2'd2; end end else begin if (!dma.tx_full && !dma.tx_write) begin dma.tx_write <= 1'b1; dma.tx_wdata <= byte_counter ? rdata_buffer[7:0] : rdata_buffer[15:8]; byte_counter <= ~byte_counter; if (byte_counter) begin state <= S_FETCH; dma.address <= dma.address + 2'd2; length <= length - 2'd2; end end end end default: begin state <= S_IDLE; dma.request <= 1'b0; end endcase end end endmodule