OpenCores

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`// register.`	`// register.`
`//`	`//`
`// Creator: Dan Gisselquist`	`// Creator: Dan Gisselquist`
`// Gisselquist Technology, LLC`	`// Gisselquist Technology, LLC`
`//`	`//`
`// Copyright: 2015`
`//`
`//`
`////////////////////////////////////////////////////////////////////////////////`	`////////////////////////////////////////////////////////////////////////////////`
`//`	`//`
`// Copyright (C) 2015, Gisselquist Technology, LLC`	`// Copyright (C) 2015-2016, Gisselquist Technology, LLC`
`//`	`//`
`// This program is free software (firmware): you can redistribute it and/or`	`// This program is free software (firmware): you can redistribute it and/or`
`// modify it under the terms of the GNU General Public License as published`	`// modify it under the terms of the GNU General Public License as published`
`// by the Free Software Foundation, either version 3 of the License, or (at`	`// by the Free Software Foundation, either version 3 of the License, or (at`
`// your option) any later version.`	`// your option) any later version.`
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`//`	`//`
`//`	`//`
`///////////////////////////////////////////////////////////////////////////`	`///////////////////////////////////////////////////////////////////////////`
`//`	`//`
`//`	`//`
`module wbdmac(i_clk,`	`define DMA_IDLE 3'b000
	`define DMA_WAIT 3'b001
	`define DMA_READ_REQ 3'b010
	`define DMA_READ_ACK 3'b011
	`define DMA_PRE_WRITE 3'b100
	`define DMA_WRITE_REQ 3'b101
	`define DMA_WRITE_ACK 3'b110

	`module wbdmac(i_clk, i_rst,`
`i_swb_cyc, i_swb_stb, i_swb_we, i_swb_addr, i_swb_data,`	`i_swb_cyc, i_swb_stb, i_swb_we, i_swb_addr, i_swb_data,`
`o_swb_ack, o_swb_stall, o_swb_data,`	`o_swb_ack, o_swb_stall, o_swb_data,`
`o_mwb_cyc, o_mwb_stb, o_mwb_we, o_mwb_addr, o_mwb_data,`	`o_mwb_cyc, o_mwb_stb, o_mwb_we, o_mwb_addr, o_mwb_data,`
`i_mwb_ack, i_mwb_stall, i_mwb_data, i_mwb_err,`	`i_mwb_ack, i_mwb_stall, i_mwb_data, i_mwb_err,`
`i_dev_ints,`	`i_dev_ints,`
`o_interrupt);`	`o_interrupt);`
`parameter ADDRESS_WIDTH=32, LGMEMLEN = 10,`	`parameter ADDRESS_WIDTH=32, LGMEMLEN = 10,`
`DW=32, LGDV=5,AW=ADDRESS_WIDTH;`	`DW=32, LGDV=5,AW=ADDRESS_WIDTH;`
`input i_clk;`	`input i_clk, i_rst;`
`// Slave/control wishbone inputs`	`// Slave/control wishbone inputs`
`input i_swb_cyc, i_swb_stb, i_swb_we;`	`input i_swb_cyc, i_swb_stb, i_swb_we;`
`input [1:0] i_swb_addr;`	`input [1:0] i_swb_addr;`
`input [(DW-1):0] i_swb_data;`	`input [(DW-1):0] i_swb_data;`
`// Slave/control wishbone outputs`	`// Slave/control wishbone outputs`
`output reg o_swb_ack;`	`output reg o_swb_ack;`
`output wire o_swb_stall;`	`output wire o_swb_stall;`
`output reg [(DW-1):0] o_swb_data;`	`output reg [(DW-1):0] o_swb_data;`
`// Master/DMA wishbone control`	`// Master/DMA wishbone control`
`output reg o_mwb_cyc, o_mwb_stb, o_mwb_we;`	`output wire o_mwb_cyc, o_mwb_stb, o_mwb_we;`
`output reg [(AW-1):0] o_mwb_addr;`	`output reg [(AW-1):0] o_mwb_addr;`
`output reg [(DW-1):0] o_mwb_data;`	`output reg [(DW-1):0] o_mwb_data;`
`// Master/DMA wishbone responses from the bus`	`// Master/DMA wishbone responses from the bus`
`input i_mwb_ack, i_mwb_stall;`	`input i_mwb_ack, i_mwb_stall;`
`input [(DW-1):0] i_mwb_data;`	`input [(DW-1):0] i_mwb_data;`
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`//`	`//`
`// input i_other_busmaster_requests_bus;`	`// input i_other_busmaster_requests_bus;`
`//`	`//`


`reg cfg_wp; // Write protect`	`reg [2:0] dma_state;`
`reg cfg_err;`	`reg cfg_err, cfg_len_nonzero;`
`reg [(AW-1):0] cfg_waddr, cfg_raddr, cfg_len;`	`reg [(AW-1):0] cfg_waddr, cfg_raddr, cfg_len;`
`reg [(LGMEMLEN-1):0] cfg_blocklen_sub_one;`	`reg [(LGMEMLEN-1):0] cfg_blocklen_sub_one;`
`reg cfg_incs, cfg_incd;`	`reg cfg_incs, cfg_incd;`
`reg [(LGDV-1):0] cfg_dev_trigger;`	`reg [(LGDV-1):0] cfg_dev_trigger;`
`reg cfg_on_dev_trigger;`	`reg cfg_on_dev_trigger;`

`// Single block operations: We'll read, then write, up to a single`	`// Single block operations: We'll read, then write, up to a single`
`// memory block here.`	`// memory block here.`

`reg [(DW-1):0] dma_mem [0:(((1<<LGMEMLEN))-1)];`	`reg [(DW-1):0] dma_mem [0:(((1<<LGMEMLEN))-1)];`
`reg [(LGMEMLEN):0] nread, nwritten, nacks;`	`reg [(LGMEMLEN):0] nread, nwritten, nwacks, nracks;`
`wire [(AW-1):0] bus_nacks;`	`wire [(AW-1):0] bus_nracks;`
`assign bus_nacks = { {(AW-LGMEMLEN-1){1'b0}}, nacks };`	`assign bus_nracks = { {(AW-LGMEMLEN-1){1'b0}}, nracks };`

	`reg last_read_request, last_read_ack,`
	`last_write_request, last_write_ack;`
	`reg trigger, abort;`

	initial dma_state = `DMA_IDLE;
`initial o_interrupt = 1'b0;`	`initial o_interrupt = 1'b0;`
`initial o_mwb_cyc = 1'b0;`
`initial cfg_err = 1'b0;`
`initial cfg_wp = 1'b0;`
`initial cfg_len = {(AW){1'b0}};`	`initial cfg_len = {(AW){1'b0}};`
`initial cfg_blocklen_sub_one = {(LGMEMLEN){1'b1}};`	`initial cfg_blocklen_sub_one = {(LGMEMLEN){1'b1}};`
`initial cfg_on_dev_trigger = 1'b0;`	`initial cfg_on_dev_trigger = 1'b0;`
	`initial cfg_len_nonzero = 1'b0;`
`always @(posedge i_clk)`	`always @(posedge i_clk)`
`if ((o_mwb_cyc)&&(o_mwb_we)) // Write cycle`	`case(dma_state)`
	`DMA_IDLE: begin
	`o_mwb_addr <= cfg_raddr;`
	`nwritten <= 0;`
	`nread <= 0;`
	`nracks <= 0;`
	`nwacks <= 0;`
	`cfg_len_nonzero <= (\|cfg_len);`

	`// When the slave wishbone writes, and we are in this`
	`// (ready) configuration, then allow the DMA to be controlled`
	`// and thus to start.`
	`if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we))`
`begin`	`begin`
`if ((o_mwb_stb)&&(~i_mwb_stall))`	`case(i_swb_addr)`
	`2'b00: begin`
	`if ((i_swb_data[27:16] == 12'hfed)`
	`&&(cfg_len_nonzero))`
	dma_state <= `DMA_WAIT;
	`cfg_blocklen_sub_one`
	`<= i_swb_data[(LGMEMLEN-1):0]`
	`+ {(LGMEMLEN){1'b1}};`
	`// i.e. -1;`
	`cfg_dev_trigger <= i_swb_data[14:10];`
	`cfg_on_dev_trigger <= i_swb_data[15];`
	`cfg_incs <= ~i_swb_data[29];`
	`cfg_incd <= ~i_swb_data[28];`
	`end`
	`2'b01: begin`
	`cfg_len <= i_swb_data[(AW-1):0];`
	`cfg_len_nonzero <= (\|i_swb_data[(AW-1):0]);`
	`end`
	`2'b10: cfg_raddr <= i_swb_data[(AW-1):0];`
	`2'b11: cfg_waddr <= i_swb_data[(AW-1):0];`
	`endcase`
	`end end`
	`DMA_WAIT: begin
	`o_mwb_addr <= cfg_raddr;`
	`nracks <= 0;`
	`nwacks <= 0;`
	`nwritten <= 0;`
	`nread <= 0;`
	`if (abort)`
	dma_state <= `DMA_IDLE;
	`else if (trigger)`
	dma_state <= `DMA_READ_REQ;
	`end`
	`DMA_READ_REQ: begin
	`nwritten <= 0;`

	`if (~i_mwb_stall)`
`begin`	`begin`
`nwritten <= nwritten+1;`	`// Number of read acknowledgements needed`
`if (nwritten == nread-1)`	`nracks <= nracks+1;`
	`if (last_read_request)`
	`//((nracks == {1'b0, cfg_blocklen_sub_one})\|\|(bus_nracks == cfg_len-1))`
`// Wishbone interruptus`	`// Wishbone interruptus`
`o_mwb_stb <= 1'b0;`	dma_state <= `DMA_READ_ACK;
`else if (cfg_incd) begin`	`if (cfg_incs)`
`o_mwb_addr <= o_mwb_addr + 1;`	`o_mwb_addr <= o_mwb_addr`
`cfg_waddr <= cfg_waddr + 1;`	`+ {{(AW-1){1'b0}},1'b1};`
`end`	`end`
`// o_mwb_data <= dma_mem[nwritten + 1];`
	`if (i_mwb_err)`
	`begin`
	`cfg_len <= 0;`
	dma_state <= `DMA_IDLE;
`end`	`end`
	`if (abort)`
	dma_state <= `DMA_IDLE;
	`if (i_mwb_ack)`
	`begin`
	`nread <= nread+1;`
	`if (cfg_incs)`
	`cfg_raddr <= cfg_raddr`
	`+ {{(AW-1){1'b0}},1'b1};`
	`end end`
	`DMA_READ_ACK: begin
	`nwritten <= 0;`

`if (i_mwb_err)`	`if (i_mwb_err)`
`begin`	`begin`
`o_mwb_cyc <= 1'b0;`
`cfg_err <= 1'b1;`
`cfg_len <= 0;`	`cfg_len <= 0;`
`nread <= 0;`	dma_state <= `DMA_IDLE;
`end else if (i_mwb_ack)`	`end else if (i_mwb_ack)`
`begin`	`begin`
`nacks <= nacks+1;`	`nread <= nread+1;`
`cfg_len <= cfg_len - 1;`	`if (last_read_ack) // (nread+1 == nracks)`
`if ((nacks+1 == nwritten)&&(~o_mwb_stb))`	dma_state <= `DMA_PRE_WRITE;
`begin`	`if (cfg_incs)`
`o_mwb_cyc <= 1'b0;`	`cfg_raddr <= cfg_raddr`
`nread <= 0;`	`+ {{(AW-1){1'b0}},1'b1};`
`o_interrupt <= (cfg_len == 1);`
`// Turn write protect back on`
`cfg_wp <= 1'b1;`
`end`	`end`
	`if (abort)`
	dma_state <= `DMA_IDLE;
`end`	`end`
`end else if ((o_mwb_cyc)&&(~o_mwb_we)) // Read cycle`	`DMA_PRE_WRITE: begin
`begin`	`o_mwb_addr <= cfg_waddr;`
`if ((o_mwb_stb)&&(~i_mwb_stall))`	dma_state <= (abort)?`DMA_IDLE:`DMA_WRITE_REQ;
	`end`
	`DMA_WRITE_REQ: begin
	`if (~i_mwb_stall)`
`begin`	`begin`
`nacks <= nacks+1;`	`nwritten <= nwritten+1;`
`if ((nacks == {1'b0, cfg_blocklen_sub_one})`	`if (last_write_request) // (nwritten == nread-1)`
`\|\|(bus_nacks <= cfg_len-1))`
`// Wishbone interruptus`	`// Wishbone interruptus`
`o_mwb_stb <= 1'b0;`	dma_state <= `DMA_WRITE_ACK;
`else if (cfg_incs) begin`	`if (cfg_incd)`
`o_mwb_addr <= o_mwb_addr + 1;`	`begin`
	`o_mwb_addr <= o_mwb_addr`
	`+ {{(AW-1){1'b0}},1'b1};`
	`cfg_waddr <= cfg_waddr`
	`+ {{(AW-1){1'b0}},1'b1};`
`end`	`end`
`end`	`end`

`if (i_mwb_err)`	`if (i_mwb_err)`
`begin`	`begin`
`o_mwb_cyc <= 1'b0;`
`cfg_err <= 1'b1;`
`cfg_len <= 0;`	`cfg_len <= 0;`
`nread <= 0;`	dma_state <= `DMA_IDLE;
`end else if (i_mwb_ack)`	`end`
`begin`	`if (i_mwb_ack)`
`nread <= nread+1;`
`if ((~o_mwb_stb)&&(nread+1 == nacks))`
`begin`	`begin`
`o_mwb_cyc <= 1'b0;`	`nwacks <= nwacks+1;`
`nacks <= 0;`	`cfg_len <= cfg_len +{(AW){1'b1}}; // -1`
`end`	`end`
`if (cfg_incs)`	`if (abort)`
`cfg_raddr <= cfg_raddr + 1;`	dma_state <= `DMA_IDLE;
`// dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;`
`end`	`end`
`end else if ((~o_mwb_cyc)&&(nread > 0)&&(~cfg_err))`	`DMA_WRITE_ACK: begin
`begin // Initiate/continue a write cycle`	`if (i_mwb_err)`
`o_mwb_cyc <= 1'b1;`	`begin`
`o_mwb_stb <= 1'b1;`	`cfg_len <= 0;`
`o_mwb_we <= 1'b1;`
`// o_mwb_data <= dma_mem[0];`
`o_mwb_addr <= cfg_waddr;`
`// nwritten <= 0; // Can't set to zero, in case we're`
`// nacks <= 0; // continuing a cycle`
`end else if ((~o_mwb_cyc)&&(nread == 0)&&(cfg_len>0)&&(~cfg_wp)`
`&&((~cfg_on_dev_trigger)`
`\|\|(i_dev_ints[cfg_dev_trigger])))`
`begin // Initiate a read cycle`
`o_mwb_cyc <= 1'b1;`
`o_mwb_stb <= 1'b1;`
`o_mwb_we <= 1'b0;`
`o_mwb_addr<= cfg_raddr;`
`nwritten <= 0;`
`nread <= 0;`	`nread <= 0;`
`nacks <= 0;`	dma_state <= `DMA_IDLE;
`end else begin`	`end else if (i_mwb_ack)`
`o_mwb_cyc <= 1'b0;`
`o_mwb_stb <= 1'b0;`
`o_mwb_we <= 1'b0;`
`o_mwb_addr <= cfg_raddr;`
`o_interrupt<= 1'b0;`
`nwritten <= 0;`
`if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we))`
`begin`	`begin`
`cfg_wp <= 1'b1;`	`nwacks <= nwacks+1;`
`case(i_swb_addr)`	`cfg_len <= cfg_len +{(AW){1'b1}};//cfg_len -= 1;`
`2'b00: begin`	`if (last_write_ack) // (nwacks+1 == nwritten)`
`cfg_wp <= (i_swb_data[27:16]!=12'hfed);`	`begin`
`cfg_blocklen_sub_one`	`nread <= 0;`
`<= i_swb_data[(LGMEMLEN-1):0]`	dma_state <= (cfg_len == 1)?`DMA_IDLE:`DMA_WAIT;
`+ {(LGMEMLEN){1'b1}};`
`// i.e. -1;`
`cfg_dev_trigger <= i_swb_data[14:10];`
`cfg_on_dev_trigger <= i_swb_data[15];`
`cfg_incs <= ~i_swb_data[29];`
`cfg_incd <= ~i_swb_data[28];`
`cfg_err <= 1'b0;`
`end`	`end`
`2'b01: cfg_len <= i_swb_data[(AW-1):0];`
`2'b10: cfg_raddr <= i_swb_data[(AW-1):0];`
`2'b11: cfg_waddr <= i_swb_data[(AW-1):0];`
`endcase`
`end`	`end`

	`if (abort)`
	dma_state <= `DMA_IDLE;
`end`	`end`
	`default:`
	dma_state <= `DMA_IDLE;
	`endcase`

	`initial o_interrupt = 1'b0;`
	`always @(posedge i_clk)`
	o_interrupt <= (dma_state == `DMA_WRITE_ACK)&&(i_mwb_ack)
	`&&(last_write_ack)`
	`&&(cfg_len == {{(AW-1){1'b0}},1'b1});`

	`initial cfg_err = 1'b0;`
	`always @(posedge i_clk)`
	if (dma_state == `DMA_IDLE)
	`begin`
	`if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)`
	`&&(i_swb_addr==2'b00))`
	`cfg_err <= 1'b0;`
	`end else if (((i_mwb_err)&&(o_mwb_cyc))\|\|(abort))`
	`cfg_err <= 1'b1;`

	`initial last_read_request = 1'b0;`
	`always @(posedge i_clk)`
	if ((dma_state == `DMA_WAIT)\|\|(dma_state == `DMA_READ_REQ))
	`begin`
	if ((~i_mwb_stall)&&(dma_state == `DMA_READ_REQ))
	`begin`
	`last_read_request <=`
	`(nracks + 1 == { 1'b0, cfg_blocklen_sub_one})`
	`\|\|(bus_nracks == cfg_len-2);`
	`end else`
	`last_read_request <=`
	`(nracks== { 1'b0, cfg_blocklen_sub_one})`
	`\|\|(bus_nracks == cfg_len-1);`
	`end else`
	`last_read_request <= 1'b0;`

	`initial last_read_ack = 1'b0;`
	`always @(posedge i_clk)`
	if ((dma_state == `DMA_READ_REQ)\|\|(dma_state == `DMA_READ_ACK))
	`begin`
	`if (i_mwb_ack)`
	`last_read_ack <= (nread+2 == nracks);`
	`else`
	`last_read_ack <= (nread+1 == nracks);`
	`end else`
	`last_read_ack <= 1'b0;`

	`initial last_write_request = 1'b0;`
	`always @(posedge i_clk)`
	if (dma_state == `DMA_PRE_WRITE)
	`last_write_request <= (nread <= 1);`
	else if (dma_state == `DMA_WRITE_REQ)
	`begin`
	`if (i_mwb_stall)`
	`last_write_request <= (nwritten >= nread-1);`
	`else`
	`last_write_request <= (nwritten >= nread-2);`
	`end else`
	`last_write_request <= 1'b0;`

	`initial last_write_ack = 1'b0;`
	`always @(posedge i_clk)`
	if((dma_state == `DMA_WRITE_REQ)\|\|(dma_state == `DMA_WRITE_ACK))
	`begin`
	`if (i_mwb_ack)`
	`last_write_ack <= (nwacks+2 == nwritten);`
	`else`
	`last_write_ack <= (nwacks+1 == nwritten);`
	`end else`
	`last_write_ack <= 1'b0;`

	assign o_mwb_cyc = (dma_state == `DMA_READ_REQ)
	\|\|(dma_state == `DMA_READ_ACK)
	\|\|(dma_state == `DMA_WRITE_REQ)
	\|\|(dma_state == `DMA_WRITE_ACK);

	assign o_mwb_stb = (dma_state == `DMA_READ_REQ)
	\|\|(dma_state == `DMA_WRITE_REQ);

	assign o_mwb_we = (dma_state == `DMA_PRE_WRITE)
	\|\|(dma_state == `DMA_WRITE_REQ)
	\|\|(dma_state == `DMA_WRITE_ACK);

`//`	`//`
`// This is tricky. In order for Vivado to consider dma_mem to be a`	`// This is tricky. In order for Vivado to consider dma_mem to be a`
`// proper memory, it must have a simple address fed into it. Hence`	`// proper memory, it must have a simple address fed into it. Hence`
`// the read_address (rdaddr) register. The problem is that this`	`// the read_address (rdaddr) register. The problem is that this`
`// register must always be one greater than the address we actually`	`// register must always be one greater than the address we actually`
`// want to read from, unless we are idling. So ... the math is touchy.`	`// want to read from, unless we are idling. So ... the math is touchy.`
`//`	`//`
`reg [(LGMEMLEN-1):0] rdaddr;`	`reg [(LGMEMLEN-1):0] rdaddr;`
`always @(posedge i_clk)`	`always @(posedge i_clk)`
`if ((o_mwb_cyc)&&(o_mwb_we)&&(o_mwb_stb)&&(~i_mwb_stall))`	if((dma_state == `DMA_IDLE)\|\|(dma_state == `DMA_WAIT)
`// This would be the normal advance, save that we are`	\|\|(dma_state == `DMA_WRITE_ACK))
`// already one ahead of nwritten`	`rdaddr <= 0;`
`rdaddr <= rdaddr + 1; // {{(LGMEMLEN-1){1'b0}},1};`	else if ((dma_state == `DMA_PRE_WRITE)
`else if ((~o_mwb_cyc)&&(nread > 0)&&(~cfg_err))`	\|\|((dma_state==`DMA_WRITE_REQ)&&(~i_mwb_stall)))
`// Here's where we do our extra advance`	`rdaddr <= rdaddr + {{(LGMEMLEN-1){1'b0}},1'b1};`
`rdaddr <= nwritten[(LGMEMLEN-1):0]+1;`
`else if ((~o_mwb_cyc)\|\|(~o_mwb_we))`
`rdaddr <= nwritten[(LGMEMLEN-1):0];`
`always @(posedge i_clk)`	`always @(posedge i_clk)`
`if ((~o_mwb_cyc)\|\|((o_mwb_we)&&(o_mwb_stb)&&(~i_mwb_stall)))`	if ((dma_state != `DMA_WRITE_REQ)\|\|(~i_mwb_stall))
`o_mwb_data <= dma_mem[rdaddr];`	`o_mwb_data <= dma_mem[rdaddr];`
`always @(posedge i_clk)`	`always @(posedge i_clk)`
`if ((o_mwb_cyc)&&(~o_mwb_we)&&(i_mwb_ack))`	if((dma_state == `DMA_READ_REQ)\|\|(dma_state == `DMA_READ_ACK))
`dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;`	`dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;`

`always @(posedge i_clk)`	`always @(posedge i_clk)`
`casez(i_swb_addr)`	`casez(i_swb_addr)`
`2'b00: o_swb_data <= { ~cfg_wp, cfg_err,`	2'b00: o_swb_data <= { (dma_state != `DMA_IDLE), cfg_err,
`~cfg_incs, ~cfg_incd,`	`~cfg_incs, ~cfg_incd,`
`1'b0, nread,`	`1'b0, nread,`
`cfg_on_dev_trigger, cfg_dev_trigger,`	`cfg_on_dev_trigger, cfg_dev_trigger,`
`cfg_blocklen_sub_one`	`cfg_blocklen_sub_one`
`};`	`};`
`2'b01: o_swb_data <= { {(DW-AW){1'b0}}, cfg_len };`	`2'b01: o_swb_data <= { {(DW-AW){1'b0}}, cfg_len };`
`2'b10: o_swb_data <= { {(DW-AW){1'b0}}, cfg_raddr};`	`2'b10: o_swb_data <= { {(DW-AW){1'b0}}, cfg_raddr};`
`2'b11: o_swb_data <= { {(DW-AW){1'b0}}, cfg_waddr};`	`2'b11: o_swb_data <= { {(DW-AW){1'b0}}, cfg_waddr};`
`endcase`	`endcase`

	`// This causes us to wait a minimum of two clocks before starting: One`
	`// to go into the wait state, and then one while in the wait state to`
	`// develop the trigger.`
	`initial trigger = 1'b0;`
`always @(posedge i_clk)`	`always @(posedge i_clk)`
`if ((i_swb_cyc)&&(i_swb_stb)) // &&(~i_swb_we))`	trigger <= (dma_state == `DMA_WAIT)
`o_swb_ack <= 1'b1;`	`&&((~cfg_on_dev_trigger)`
`// else if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)&&(~o_mwb_cyc)&&(nread == 0))`	`\|\|(i_dev_ints[cfg_dev_trigger]));`
`else`
`o_swb_ack <= 1'b0;`	`// Ack any access. We'll quietly ignore any access where we are busy,`
	`// but ack it anyway. In other words, before writing to the device,`
	`// double check that it isn't busy, and then write.`
	`always @(posedge i_clk)`
	`o_swb_ack <= (i_swb_cyc)&&(i_swb_stb);`

`assign o_swb_stall = 1'b0;`	`assign o_swb_stall = 1'b0;`

	`initial abort = 1'b0;`
	`always @(posedge i_clk)`
	`abort <= (i_rst)\|\|((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)`
	`&&(i_swb_addr == 2'b00)`
	`&&(i_swb_data == 32'hffed0000));`

`endmodule`	`endmodule`


`No newline at end of file`	`No newline at end of file`

Line 79...

//              register.

//              register.

//

//

// Creator:     Dan Gisselquist

// Creator:     Dan Gisselquist

//              Gisselquist Technology, LLC

//              Gisselquist Technology, LLC

//

//

// Copyright:   2015

//

//

////////////////////////////////////////////////////////////////////////////////

////////////////////////////////////////////////////////////////////////////////

//

//

// Copyright (C) 2015, Gisselquist Technology, LLC

// Copyright (C) 2015-2016, Gisselquist Technology, LLC

//

//

// This program is free software (firmware): you can redistribute it and/or

// This program is free software (firmware): you can redistribute it and/or

// modify it under the terms of  the GNU General Public License as published

// modify it under the terms of  the GNU General Public License as published

// by the Free Software Foundation, either version 3 of the License, or (at

// by the Free Software Foundation, either version 3 of the License, or (at

// your option) any later version.

// your option) any later version.

Line 103...

Line 100...

//

//

//

//

///////////////////////////////////////////////////////////////////////////

///////////////////////////////////////////////////////////////////////////

//

//

//

//

module wbdmac(i_clk,

`define DMA_IDLE        3'b000

`define DMA_WAIT        3'b001

`define DMA_READ_REQ    3'b010

`define DMA_READ_ACK    3'b011

`define DMA_PRE_WRITE   3'b100

`define DMA_WRITE_REQ   3'b101

`define DMA_WRITE_ACK   3'b110

module wbdmac(i_clk, i_rst,

                i_swb_cyc, i_swb_stb, i_swb_we, i_swb_addr, i_swb_data,

                i_swb_cyc, i_swb_stb, i_swb_we, i_swb_addr, i_swb_data,

                        o_swb_ack, o_swb_stall, o_swb_data,

                        o_swb_ack, o_swb_stall, o_swb_data,

                o_mwb_cyc, o_mwb_stb, o_mwb_we, o_mwb_addr, o_mwb_data,

                o_mwb_cyc, o_mwb_stb, o_mwb_we, o_mwb_addr, o_mwb_data,

                        i_mwb_ack, i_mwb_stall, i_mwb_data, i_mwb_err,

                        i_mwb_ack, i_mwb_stall, i_mwb_data, i_mwb_err,

                i_dev_ints,

                i_dev_ints,

                o_interrupt);

                o_interrupt);

        parameter       ADDRESS_WIDTH=32, LGMEMLEN = 10,

        parameter       ADDRESS_WIDTH=32, LGMEMLEN = 10,

                        DW=32, LGDV=5,AW=ADDRESS_WIDTH;

                        DW=32, LGDV=5,AW=ADDRESS_WIDTH;

        input                   i_clk;

        input                   i_clk, i_rst;

        // Slave/control wishbone inputs

        // Slave/control wishbone inputs

        input                   i_swb_cyc, i_swb_stb, i_swb_we;

        input                   i_swb_cyc, i_swb_stb, i_swb_we;

        input   [1:0]            i_swb_addr;

        input   [1:0]            i_swb_addr;

        input   [(DW-1):0]       i_swb_data;

        input   [(DW-1):0]       i_swb_data;

        // Slave/control wishbone outputs

        // Slave/control wishbone outputs

        output  reg             o_swb_ack;

        output  reg             o_swb_ack;

        output  wire            o_swb_stall;

        output  wire            o_swb_stall;

        output  reg [(DW-1):0]   o_swb_data;

        output  reg [(DW-1):0]   o_swb_data;

        // Master/DMA wishbone control

        // Master/DMA wishbone control

        output  reg             o_mwb_cyc, o_mwb_stb, o_mwb_we;

        output  wire            o_mwb_cyc, o_mwb_stb, o_mwb_we;

        output  reg [(AW-1):0]   o_mwb_addr;

        output  reg [(AW-1):0]   o_mwb_addr;

        output  reg [(DW-1):0]   o_mwb_data;

        output  reg [(DW-1):0]   o_mwb_data;

        // Master/DMA wishbone responses from the bus

        // Master/DMA wishbone responses from the bus

        input                   i_mwb_ack, i_mwb_stall;

        input                   i_mwb_ack, i_mwb_stall;

        input   [(DW-1):0]       i_mwb_data;

        input   [(DW-1):0]       i_mwb_data;

Line 143...

Line 148...

//

//

        // input                        i_other_busmaster_requests_bus;

        // input                        i_other_busmaster_requests_bus;

//

//

        reg                     cfg_wp; // Write protect

        reg     [2:0]            dma_state;

        reg                     cfg_err;

        reg                     cfg_err, cfg_len_nonzero;

        reg     [(AW-1):0]       cfg_waddr, cfg_raddr, cfg_len;

        reg     [(AW-1):0]       cfg_waddr, cfg_raddr, cfg_len;

        reg [(LGMEMLEN-1):0]     cfg_blocklen_sub_one;

        reg [(LGMEMLEN-1):0]     cfg_blocklen_sub_one;

        reg                     cfg_incs, cfg_incd;

        reg                     cfg_incs, cfg_incd;

        reg     [(LGDV-1):0]     cfg_dev_trigger;

        reg     [(LGDV-1):0]     cfg_dev_trigger;

        reg                     cfg_on_dev_trigger;

        reg                     cfg_on_dev_trigger;

        // Single block operations: We'll read, then write, up to a single

        // Single block operations: We'll read, then write, up to a single

        // memory block here.

        // memory block here.

        reg     [(DW-1):0]       dma_mem [0:(((1<<LGMEMLEN))-1)];

        reg     [(DW-1):0]       dma_mem [0:(((1<<LGMEMLEN))-1)];

        reg     [(LGMEMLEN):0]   nread, nwritten, nacks;

        reg     [(LGMEMLEN):0]   nread, nwritten, nwacks, nracks;

        wire    [(AW-1):0]       bus_nacks;

        wire    [(AW-1):0]       bus_nracks;

        assign  bus_nacks = { {(AW-LGMEMLEN-1){1'b0}}, nacks };

        assign  bus_nracks = { {(AW-LGMEMLEN-1){1'b0}}, nracks };

        reg     last_read_request, last_read_ack,

                last_write_request, last_write_ack;

        reg     trigger, abort;

        initial dma_state = `DMA_IDLE;

        initial o_interrupt = 1'b0;

        initial o_interrupt = 1'b0;

        initial o_mwb_cyc   = 1'b0;

        initial cfg_err     = 1'b0;

        initial cfg_wp      = 1'b0;

        initial cfg_len     = {(AW){1'b0}};

        initial cfg_len     = {(AW){1'b0}};

        initial cfg_blocklen_sub_one = {(LGMEMLEN){1'b1}};

        initial cfg_blocklen_sub_one = {(LGMEMLEN){1'b1}};

        initial cfg_on_dev_trigger = 1'b0;

        initial cfg_on_dev_trigger = 1'b0;

        initial cfg_len_nonzero = 1'b0;

        always @(posedge i_clk)

        always @(posedge i_clk)

                if ((o_mwb_cyc)&&(o_mwb_we)) // Write cycle

        case(dma_state)

        `DMA_IDLE: begin

                o_mwb_addr <= cfg_raddr;

                nwritten   <= 0;

                nread      <= 0;

                nracks     <= 0;

                nwacks     <= 0;

                cfg_len_nonzero <= (|cfg_len);

                // When the slave wishbone writes, and we are in this

                // (ready) configuration, then allow the DMA to be controlled

                // and thus to start.

                if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we))

                begin

                begin

                        if ((o_mwb_stb)&&(~i_mwb_stall))

                        case(i_swb_addr)

                        2'b00: begin

                                if ((i_swb_data[27:16] == 12'hfed)

                                                &&(cfg_len_nonzero))

                                        dma_state <= `DMA_WAIT;

                                cfg_blocklen_sub_one

                                        <= i_swb_data[(LGMEMLEN-1):0]

                                        + {(LGMEMLEN){1'b1}};

                                        // i.e. -1;

                                cfg_dev_trigger    <= i_swb_data[14:10];

                                cfg_on_dev_trigger <= i_swb_data[15];

                                cfg_incs  <= ~i_swb_data[29];

                                cfg_incd  <= ~i_swb_data[28];

end

                        2'b01: begin

                                cfg_len   <=  i_swb_data[(AW-1):0];

                                cfg_len_nonzero <= (|i_swb_data[(AW-1):0]);

end

                        2'b10: cfg_raddr <=  i_swb_data[(AW-1):0];

                        2'b11: cfg_waddr <=  i_swb_data[(AW-1):0];

                        endcase

                end end

        `DMA_WAIT: begin

                o_mwb_addr <= cfg_raddr;

                nracks     <= 0;

                nwacks     <= 0;

                nwritten   <= 0;

                nread      <= 0;

                if (abort)

                        dma_state <= `DMA_IDLE;

                else if (trigger)

                        dma_state <= `DMA_READ_REQ;

end

        `DMA_READ_REQ: begin

                nwritten  <= 0;

                if (~i_mwb_stall)

                        begin

                        begin

                                nwritten <= nwritten+1;

                        // Number of read acknowledgements needed

                                if (nwritten == nread-1)

                        nracks <= nracks+1;

                        if (last_read_request)

        //((nracks == {1'b0, cfg_blocklen_sub_one})||(bus_nracks == cfg_len-1))

                                        // Wishbone interruptus

                                        // Wishbone interruptus

                                        o_mwb_stb <= 1'b0;

                                dma_state <= `DMA_READ_ACK;

                                else if (cfg_incd) begin

                        if (cfg_incs)

                                        o_mwb_addr <= o_mwb_addr + 1;

                                o_mwb_addr <= o_mwb_addr

                                        cfg_waddr  <= cfg_waddr  + 1;

                                                + {{(AW-1){1'b0}},1'b1};

end

end

                                // o_mwb_data <= dma_mem[nwritten + 1];

                if (i_mwb_err)

                begin

                        cfg_len <= 0;

                        dma_state <= `DMA_IDLE;

end

end

                if (abort)

                        dma_state <= `DMA_IDLE;

                if (i_mwb_ack)

                begin

                        nread <= nread+1;

                        if (cfg_incs)

                                cfg_raddr  <= cfg_raddr

                                                + {{(AW-1){1'b0}},1'b1};

                end end

        `DMA_READ_ACK: begin

                nwritten  <= 0;

                        if (i_mwb_err)

                        if (i_mwb_err)

                        begin

                        begin

                                o_mwb_cyc <= 1'b0;

                                cfg_err <= 1'b1;

                                cfg_len <= 0;

                                cfg_len <= 0;

                                nread   <= 0;

                        dma_state <= `DMA_IDLE;

                        end else if (i_mwb_ack)

                        end else if (i_mwb_ack)

                        begin

                        begin

                                nacks <= nacks+1;

                        nread <= nread+1;

                                cfg_len <= cfg_len - 1;

                        if (last_read_ack) // (nread+1 == nracks)

                                if ((nacks+1 == nwritten)&&(~o_mwb_stb))

                                dma_state  <= `DMA_PRE_WRITE;

                                begin

                        if (cfg_incs)

                                        o_mwb_cyc <= 1'b0;

                                cfg_raddr  <= cfg_raddr

                                        nread <= 0;

                                                + {{(AW-1){1'b0}},1'b1};

                                        o_interrupt <= (cfg_len == 1);

                                        // Turn write protect back on

                                        cfg_wp    <= 1'b1;

end

end

                if (abort)

                        dma_state <= `DMA_IDLE;

end

end

                end else if ((o_mwb_cyc)&&(~o_mwb_we)) // Read cycle

        `DMA_PRE_WRITE: begin

                begin

                o_mwb_addr <= cfg_waddr;

                        if ((o_mwb_stb)&&(~i_mwb_stall))

                dma_state <= (abort)?`DMA_IDLE:`DMA_WRITE_REQ;

end

        `DMA_WRITE_REQ: begin

                if (~i_mwb_stall)

                        begin

                        begin

                                nacks <= nacks+1;

                        nwritten <= nwritten+1;

                                if ((nacks == {1'b0, cfg_blocklen_sub_one})

                        if (last_write_request) // (nwritten == nread-1)

                                        ||(bus_nacks <= cfg_len-1))

                                        // Wishbone interruptus

                                        // Wishbone interruptus

                                        o_mwb_stb <= 1'b0;

                                dma_state <= `DMA_WRITE_ACK;

                                else if (cfg_incs) begin

                        if (cfg_incd)

                                        o_mwb_addr <= o_mwb_addr + 1;

                        begin

                                o_mwb_addr <= o_mwb_addr

                                                + {{(AW-1){1'b0}},1'b1};

                                cfg_waddr  <= cfg_waddr

                                                + {{(AW-1){1'b0}},1'b1};

end

end

end

end

                        if (i_mwb_err)

                        if (i_mwb_err)

                        begin

                        begin

                                o_mwb_cyc <= 1'b0;

                                cfg_err <= 1'b1;

                                cfg_len <= 0;

                                cfg_len <= 0;

                                nread <= 0;

                        dma_state <= `DMA_IDLE;

                        end else if (i_mwb_ack)

end

                        begin

                if (i_mwb_ack)

                                nread <= nread+1;

                                if ((~o_mwb_stb)&&(nread+1 == nacks))

                                begin

                                begin

                                        o_mwb_cyc <= 1'b0;

                        nwacks <= nwacks+1;

                                        nacks <= 0;

                        cfg_len <= cfg_len +{(AW){1'b1}}; // -1

end

end

                                if (cfg_incs)

                if (abort)

                                        cfg_raddr  <= cfg_raddr  + 1;

                        dma_state <= `DMA_IDLE;

                                // dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;

end

end

                end else if ((~o_mwb_cyc)&&(nread > 0)&&(~cfg_err))

        `DMA_WRITE_ACK: begin

                begin // Initiate/continue a write cycle

                if (i_mwb_err)

                        o_mwb_cyc  <= 1'b1;

                begin

                        o_mwb_stb  <= 1'b1;

                        cfg_len  <= 0;

                        o_mwb_we   <= 1'b1;

                        // o_mwb_data <= dma_mem[0];

                        o_mwb_addr <= cfg_waddr;

                        // nwritten  <= 0; // Can't set to zero, in case we're

                        // nacks     <= 0; //   continuing a cycle

                end else if ((~o_mwb_cyc)&&(nread == 0)&&(cfg_len>0)&&(~cfg_wp)

                                &&((~cfg_on_dev_trigger)

                                        ||(i_dev_ints[cfg_dev_trigger])))

                begin // Initiate a read cycle

                        o_mwb_cyc <= 1'b1;

                        o_mwb_stb <= 1'b1;

                        o_mwb_we  <= 1'b0;

                        o_mwb_addr<= cfg_raddr;

                        nwritten  <= 0;

                        nread     <= 0;

                        nread     <= 0;

                        nacks     <= 0;

                        dma_state <= `DMA_IDLE;

                end else begin

                end else if (i_mwb_ack)

                        o_mwb_cyc  <= 1'b0;

                        o_mwb_stb  <= 1'b0;

                        o_mwb_we   <= 1'b0;

                        o_mwb_addr <= cfg_raddr;

                        o_interrupt<= 1'b0;

                        nwritten   <= 0;

                        if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we))

                        begin

                        begin

                                cfg_wp <= 1'b1;

                        nwacks <= nwacks+1;

                                case(i_swb_addr)

                        cfg_len <= cfg_len +{(AW){1'b1}};//cfg_len -= 1;

                                2'b00: begin

                        if (last_write_ack) // (nwacks+1 == nwritten)

                                        cfg_wp    <= (i_swb_data[27:16]!=12'hfed);

                        begin

                                        cfg_blocklen_sub_one

                                nread <= 0;

                                                <= i_swb_data[(LGMEMLEN-1):0]

                                dma_state <= (cfg_len == 1)?`DMA_IDLE:`DMA_WAIT;

                                                + {(LGMEMLEN){1'b1}};

                                                // i.e. -1;

                                        cfg_dev_trigger    <= i_swb_data[14:10];

                                        cfg_on_dev_trigger <= i_swb_data[15];

                                        cfg_incs  <= ~i_swb_data[29];

                                        cfg_incd  <= ~i_swb_data[28];

                                        cfg_err   <= 1'b0;

end

end

                                2'b01: cfg_len   <=  i_swb_data[(AW-1):0];

                                2'b10: cfg_raddr <=  i_swb_data[(AW-1):0];

                                2'b11: cfg_waddr <=  i_swb_data[(AW-1):0];

                                endcase

end

end

                if (abort)

                        dma_state <= `DMA_IDLE;

end

end

        default:

                dma_state <= `DMA_IDLE;

        endcase

        initial o_interrupt = 1'b0;

        always @(posedge i_clk)

                o_interrupt <= (dma_state == `DMA_WRITE_ACK)&&(i_mwb_ack)

                                &&(last_write_ack)

                                &&(cfg_len == {{(AW-1){1'b0}},1'b1});

        initial cfg_err = 1'b0;

        always @(posedge i_clk)

                if (dma_state == `DMA_IDLE)

                begin

                        if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)

                                        &&(i_swb_addr==2'b00))

                                cfg_err <= 1'b0;

                end else if (((i_mwb_err)&&(o_mwb_cyc))||(abort))

                        cfg_err <= 1'b1;

        initial last_read_request = 1'b0;

        always @(posedge i_clk)

                if ((dma_state == `DMA_WAIT)||(dma_state == `DMA_READ_REQ))

                begin

                        if ((~i_mwb_stall)&&(dma_state == `DMA_READ_REQ))

                        begin

                                last_read_request <=

                                (nracks + 1 == { 1'b0, cfg_blocklen_sub_one})

                                        ||(bus_nracks == cfg_len-2);

                        end else

                                last_read_request <=

                                        (nracks== { 1'b0, cfg_blocklen_sub_one})

                                        ||(bus_nracks == cfg_len-1);

                end else

                        last_read_request <= 1'b0;

        initial last_read_ack = 1'b0;

        always @(posedge i_clk)

                if ((dma_state == `DMA_READ_REQ)||(dma_state == `DMA_READ_ACK))

                begin

                        if (i_mwb_ack)

                                last_read_ack <= (nread+2 == nracks);

                        else

                                last_read_ack <= (nread+1 == nracks);

                end else

                        last_read_ack <= 1'b0;

        initial last_write_request = 1'b0;

        always @(posedge i_clk)

                if (dma_state == `DMA_PRE_WRITE)

                        last_write_request <= (nread <= 1);

                else if (dma_state == `DMA_WRITE_REQ)

                begin

                        if (i_mwb_stall)

                                last_write_request <= (nwritten >= nread-1);

                        else

                                last_write_request <= (nwritten >= nread-2);

                end else

                        last_write_request <= 1'b0;

        initial last_write_ack = 1'b0;

        always @(posedge i_clk)

                if((dma_state == `DMA_WRITE_REQ)||(dma_state == `DMA_WRITE_ACK))

                begin

                        if (i_mwb_ack)

                                last_write_ack <= (nwacks+2 == nwritten);

                        else

                                last_write_ack <= (nwacks+1 == nwritten);

                end else

                        last_write_ack <= 1'b0;

        assign  o_mwb_cyc = (dma_state == `DMA_READ_REQ)

                        ||(dma_state == `DMA_READ_ACK)

                        ||(dma_state == `DMA_WRITE_REQ)

                        ||(dma_state == `DMA_WRITE_ACK);

        assign  o_mwb_stb = (dma_state == `DMA_READ_REQ)

                        ||(dma_state == `DMA_WRITE_REQ);

        assign  o_mwb_we = (dma_state == `DMA_PRE_WRITE)

                        ||(dma_state == `DMA_WRITE_REQ)

                        ||(dma_state == `DMA_WRITE_ACK);

//

//

        // This is tricky.  In order for Vivado to consider dma_mem to be a

        // This is tricky.  In order for Vivado to consider dma_mem to be a

        // proper memory, it must have a simple address fed into it.  Hence

        // proper memory, it must have a simple address fed into it.  Hence

        // the read_address (rdaddr) register.  The problem is that this

        // the read_address (rdaddr) register.  The problem is that this

        // register must always be one greater than the address we actually

        // register must always be one greater than the address we actually

        // want to read from, unless we are idling.  So ... the math is touchy.

        // want to read from, unless we are idling.  So ... the math is touchy.

//

//

        reg     [(LGMEMLEN-1):0] rdaddr;

        reg     [(LGMEMLEN-1):0] rdaddr;

        always @(posedge i_clk)

        always @(posedge i_clk)

                if ((o_mwb_cyc)&&(o_mwb_we)&&(o_mwb_stb)&&(~i_mwb_stall))

                if((dma_state == `DMA_IDLE)||(dma_state == `DMA_WAIT)

                        // This would be the normal advance, save that we are

                                ||(dma_state == `DMA_WRITE_ACK))

                        // already one ahead of nwritten

                        rdaddr <= 0;

                        rdaddr <= rdaddr + 1; // {{(LGMEMLEN-1){1'b0}},1};

                else if ((dma_state == `DMA_PRE_WRITE)

                else if ((~o_mwb_cyc)&&(nread > 0)&&(~cfg_err))

                                ||((dma_state==`DMA_WRITE_REQ)&&(~i_mwb_stall)))

                        // Here's where we do our extra advance

                        rdaddr <= rdaddr + {{(LGMEMLEN-1){1'b0}},1'b1};

                        rdaddr <= nwritten[(LGMEMLEN-1):0]+1;

                else if ((~o_mwb_cyc)||(~o_mwb_we))

                        rdaddr <= nwritten[(LGMEMLEN-1):0];

        always @(posedge i_clk)

        always @(posedge i_clk)

                if ((~o_mwb_cyc)||((o_mwb_we)&&(o_mwb_stb)&&(~i_mwb_stall)))

                if ((dma_state != `DMA_WRITE_REQ)||(~i_mwb_stall))

                        o_mwb_data <= dma_mem[rdaddr];

                        o_mwb_data <= dma_mem[rdaddr];

        always @(posedge i_clk)

        always @(posedge i_clk)

                if ((o_mwb_cyc)&&(~o_mwb_we)&&(i_mwb_ack))

                if((dma_state == `DMA_READ_REQ)||(dma_state == `DMA_READ_ACK))

                        dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;

                        dma_mem[nread[(LGMEMLEN-1):0]] <= i_mwb_data;

        always @(posedge i_clk)

        always @(posedge i_clk)

                casez(i_swb_addr)

                casez(i_swb_addr)

                2'b00: o_swb_data <= {  ~cfg_wp, cfg_err,

                2'b00: o_swb_data <= {  (dma_state != `DMA_IDLE), cfg_err,

                                        ~cfg_incs, ~cfg_incd,

                                        ~cfg_incs, ~cfg_incd,

                                        1'b0, nread,

                                        1'b0, nread,

                                        cfg_on_dev_trigger, cfg_dev_trigger,

                                        cfg_on_dev_trigger, cfg_dev_trigger,

                                        cfg_blocklen_sub_one

                                        cfg_blocklen_sub_one

};

};

                2'b01: o_swb_data <= { {(DW-AW){1'b0}}, cfg_len  };

                2'b01: o_swb_data <= { {(DW-AW){1'b0}}, cfg_len  };

                2'b10: o_swb_data <= { {(DW-AW){1'b0}}, cfg_raddr};

                2'b10: o_swb_data <= { {(DW-AW){1'b0}}, cfg_raddr};

                2'b11: o_swb_data <= { {(DW-AW){1'b0}}, cfg_waddr};

                2'b11: o_swb_data <= { {(DW-AW){1'b0}}, cfg_waddr};

                endcase

                endcase

        // This causes us to wait a minimum of two clocks before starting: One

        // to go into the wait state, and then one while in the wait state to

        // develop the trigger.

        initial trigger = 1'b0;

        always @(posedge i_clk)

        always @(posedge i_clk)

                if ((i_swb_cyc)&&(i_swb_stb)) // &&(~i_swb_we))

                trigger <=  (dma_state == `DMA_WAIT)

                        o_swb_ack <= 1'b1;

                                &&((~cfg_on_dev_trigger)

                // else if ((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)&&(~o_mwb_cyc)&&(nread == 0))

                                        ||(i_dev_ints[cfg_dev_trigger]));

                else

                        o_swb_ack <= 1'b0;

        // Ack any access.  We'll quietly ignore any access where we are busy,

        // but ack it anyway.  In other words, before writing to the device,

        // double check that it isn't busy, and then write.

        always @(posedge i_clk)

                o_swb_ack <= (i_swb_cyc)&&(i_swb_stb);

        assign  o_swb_stall = 1'b0;

        assign  o_swb_stall = 1'b0;

        initial abort = 1'b0;

        always @(posedge i_clk)

                abort <= (i_rst)||((i_swb_cyc)&&(i_swb_stb)&&(i_swb_we)

                        &&(i_swb_addr == 2'b00)

                        &&(i_swb_data == 32'hffed0000));

endmodule

endmodule

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[/] [xulalx25soc/] [trunk/] [rtl/] [cpu/] [wbdmac.v] - Diff between revs 52 and 69