[raggedstone] / ethernet / source / pci / pci_pciw_fifo_control.v

//////////////////////////////////////////////////////////////////////
////                                                              ////
////  File name "pciw_fifo_control.v"                             ////
////                                                              ////
////  This file is part of the "PCI bridge" project               ////
////  http://www.opencores.org/cores/pci/                         ////
////                                                              ////
////  Author(s):                                                  ////
////      - Miha Dolenc (mihad@opencores.org)                     ////
////                                                              ////
////  All additional information is avaliable in the README       ////
////  file.                                                       ////
////                                                              ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
////                                                              ////
//// Copyright (C) 2001 Miha Dolenc, mihad@opencores.org          ////
////                                                              ////
//// This source file may be used and distributed without         ////
//// restriction provided that this copyright statement is not    ////
//// removed from the file and that any derivative work contains  ////
//// the original copyright notice and the associated disclaimer. ////
////                                                              ////
//// This source file is free software; you can redistribute it   ////
//// and/or modify it under the terms of the GNU Lesser General   ////
//// Public License as published by the Free Software Foundation; ////
//// either version 2.1 of the License, or (at your option) any   ////
//// later version.                                               ////
////                                                              ////
//// This source is distributed in the hope that it will be       ////
//// useful, but WITHOUT ANY WARRANTY; without even the implied   ////
//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR      ////
//// PURPOSE.  See the GNU Lesser General Public License for more ////
//// details.                                                     ////
////                                                              ////
//// You should have received a copy of the GNU Lesser General    ////
//// Public License along with this source; if not, download it   ////
//// from http://www.opencores.org/lgpl.shtml                     ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
//
// CVS Revision History
//
// $Log: pci_pciw_fifo_control.v,v $
// Revision 1.1  2007-03-20 17:50:56  sithglan
// add shit
//
// Revision 1.5  2003/08/14 13:06:03  simons
// synchronizer_flop replaced with pci_synchronizer_flop, artisan ram instance updated.
//
// Revision 1.4  2003/08/08 16:36:33  tadejm
// Added 'three_left_out' to pci_pciw_fifo signaling three locations before full. Added comparison between current registered cbe and next unregistered cbe to signal wb_master whether it is allowed to performe burst or not. Due to this, I needed 'three_left_out' so that writing to pci_pciw_fifo can be registered, otherwise timing problems would occure.
//
// Revision 1.3  2003/07/29 08:20:11  mihad
// Found and simulated the problem in the synchronization logic.
// Repaired the synchronization logic in the FIFOs.
//
//

/* FIFO_CONTROL module provides read/write address and status generation for
   FIFOs implemented with standard dual port SRAM cells in ASIC or FPGA designs */
`include "pci_constants.v"
// synopsys translate_off
`include "timescale.v"
// synopsys translate_on

module pci_pciw_fifo_control
(
    rclock_in,
    wclock_in,
    renable_in,
    wenable_in,
    reset_in,
    almost_full_out,
    full_out,
    almost_empty_out,
    empty_out,
    waddr_out,
    raddr_out,
    rallow_out,
    wallow_out,
    three_left_out,
    two_left_out
);

parameter ADDR_LENGTH = 7 ;

// independent clock inputs - rclock_in = read clock, wclock_in = write clock
input  rclock_in, wclock_in;

// enable inputs - read address changes on rising edge of rclock_in when reads are allowed
//                 write address changes on rising edge of wclock_in when writes are allowed
input  renable_in, wenable_in;

// reset input
input  reset_in;

// almost full and empy status outputs
output almost_full_out, almost_empty_out;

// full and empty status outputs
output full_out, empty_out;

// read and write addresses outputs
output [(ADDR_LENGTH - 1):0] waddr_out, raddr_out;

// read and write allow outputs
output rallow_out, wallow_out ;

// three and two locations left output indicator
output three_left_out ;
output two_left_out ;

// read address register
reg [(ADDR_LENGTH - 1):0] raddr ;

// write address register
reg [(ADDR_LENGTH - 1):0] waddr;
reg [(ADDR_LENGTH - 1):0] waddr_plus1;
assign waddr_out = waddr ;

// grey code registers
// grey code pipeline for write address
reg [(ADDR_LENGTH - 1):0] wgrey_minus1 ; // previous
reg [(ADDR_LENGTH - 1):0] wgrey_addr   ; // current
reg [(ADDR_LENGTH - 1):0] wgrey_next   ; // next

reg [(ADDR_LENGTH - 1):0] wgrey_next_plus1   ; // next plus 1


// next write gray address calculation - bitwise xor between address and shifted address
wire [(ADDR_LENGTH - 2):0] calc_wgrey_next  = waddr[(ADDR_LENGTH - 1):1] ^ waddr[(ADDR_LENGTH - 2):0] ;
wire [(ADDR_LENGTH - 2):0] calc_wgrey_next_plus1  = waddr_plus1[(ADDR_LENGTH - 1):1] ^ waddr_plus1[(ADDR_LENGTH - 2):0] ;

// grey code pipeline for read address
reg [(ADDR_LENGTH - 1):0] rgrey_minus2 ; // two before current
reg [(ADDR_LENGTH - 1):0] rgrey_minus1 ; // one before current
reg [(ADDR_LENGTH - 1):0] rgrey_addr ; // current
reg [(ADDR_LENGTH - 1):0] rgrey_next ; // next

// next read gray address calculation - bitwise xor between address and shifted address
wire [(ADDR_LENGTH - 2):0] calc_rgrey_next  = raddr[(ADDR_LENGTH - 1):1] ^ raddr[(ADDR_LENGTH - 2):0] ;

// write allow - writes are allowed when fifo is not full
assign wallow_out = wenable_in & ~full_out ;

// clear generation for FFs and registers
wire clear = reset_in ;

//rallow generation
assign rallow_out = renable_in & ~empty_out ; // reads allowed if read enable is high and FIFO is not empty

// at any clock edge that rallow is high, this register provides next read address, so wait cycles are not necessary
// when FIFO is empty, this register provides actual read address, so first location can be read
reg [(ADDR_LENGTH - 1):0] raddr_plus_one ;


// read address mux - when read is performed, next address is driven, so next data is available immediately after read
// this is convenient for zero wait stait bursts
assign raddr_out = rallow_out ? raddr_plus_one : raddr ;

always@(posedge rclock_in or posedge clear)
begin
    if (clear)
    begin
        // initial values seem a bit odd - they are this way to allow easier grey pipeline implementation and to allow min fifo size of 8
        raddr_plus_one <= #`FF_DELAY 5 ;
        raddr          <= #`FF_DELAY 4 ;
//        raddr_plus_one <= #`FF_DELAY 6 ;
//        raddr          <= #`FF_DELAY 5 ;
    end
    else if (rallow_out)
    begin
        raddr_plus_one <= #`FF_DELAY raddr_plus_one + 1'b1 ;
        raddr          <= #`FF_DELAY raddr_plus_one ;
    end
end

/*-----------------------------------------------------------------------------------------------
Read address control consists of Read address counter and Grey Address pipeline
There are 4 Grey addresses:
    - rgrey_minus2 is Grey Code of address two before current address
    - rgrey_minus1 is Grey Code of address one before current address
    - rgrey_addr is Grey Code of current read address
    - rgrey_next is Grey Code of next read address
--------------------------------------------------------------------------------------------------*/
// grey coded address pipeline for status generation in read clock domain
always@(posedge rclock_in or posedge clear)
begin
    if (clear)
    begin
        rgrey_minus2 <= #1 0 ;
        rgrey_minus1 <= #`FF_DELAY 1 ;  
        rgrey_addr   <= #1 3 ;
        rgrey_next   <= #`FF_DELAY 2 ;
    end
    else
    if (rallow_out)
    begin
        rgrey_minus2 <= #1 rgrey_minus1 ;
        rgrey_minus1 <= #`FF_DELAY rgrey_addr ;
        rgrey_addr   <= #1 rgrey_next ;
        rgrey_next   <= #`FF_DELAY {raddr[ADDR_LENGTH - 1], calc_rgrey_next} ;
    end
end

/*--------------------------------------------------------------------------------------------
Write address control consists of write address counter and 3 Grey Code Registers:
    - wgrey_minus1 represents previous Grey coded write address
    - wgrey_addr   represents current Grey Coded write address
    - wgrey_next   represents next Grey Coded write address

    - wgrey_next_plus1 represents second next Grey Coded write address

----------------------------------------------------------------------------------------------*/
// grey coded address pipeline for status generation in write clock domain
always@(posedge wclock_in or posedge clear)
begin
    if (clear)
    begin
        wgrey_minus1 <= #`FF_DELAY 1 ;
        wgrey_addr   <= #`FF_DELAY 3 ;
        wgrey_next   <= #`FF_DELAY 2 ;

        wgrey_next_plus1 <= #`FF_DELAY 6;

    end
    else
    if (wallow_out)
    begin
        wgrey_minus1 <= #`FF_DELAY wgrey_addr ;
        wgrey_addr   <= #`FF_DELAY wgrey_next ;

        wgrey_next   <= #`FF_DELAY {waddr[(ADDR_LENGTH - 1)], calc_wgrey_next} ;
//        wgrey_next   <= #`FF_DELAY wgrey_next_plus1 ;
        wgrey_next_plus1 <= #`FF_DELAY {waddr_plus1[(ADDR_LENGTH - 1)], calc_wgrey_next_plus1} ;

    end
end

// write address counter - nothing special except initial value
always@(posedge wclock_in or posedge clear)
begin
    if (clear)
    begin
        // initial value 5

        waddr <= #`FF_DELAY 4 ;
        waddr_plus1 <= #`FF_DELAY 5 ;
    end
    else
    if (wallow_out)
    begin
        waddr <= #`FF_DELAY waddr + 1'b1 ;
        waddr_plus1 <= #`FF_DELAY waddr_plus1 + 1'b1 ;
    end
end

/*------------------------------------------------------------------------------------------------------------------------------
Gray coded address of read address decremented by two is synchronized to write clock domain and compared to:
- previous grey coded write address - if they are equal, the fifo is full

- gray coded write address. If they are equal, fifo is almost full.

- grey coded next write address. If they are equal, the fifo has two free locations left.
--------------------------------------------------------------------------------------------------------------------------------*/
wire [(ADDR_LENGTH - 1):0] wclk_sync_rgrey_minus2 ;
reg  [(ADDR_LENGTH - 1):0] wclk_rgrey_minus2 ;

pci_synchronizer_flop #(ADDR_LENGTH, 0) i_synchronizer_reg_rgrey_minus2
(
    .data_in        (rgrey_minus2),
    .clk_out        (wclock_in),
    .sync_data_out  (wclk_sync_rgrey_minus2),
    .async_reset    (clear)
) ;

always@(posedge wclock_in or posedge clear)
begin
    if (clear)
    begin
        wclk_rgrey_minus2 <= #`FF_DELAY 0 ;
    end
    else
    begin
        wclk_rgrey_minus2 <= #`FF_DELAY wclk_sync_rgrey_minus2 ;
    end
end

assign full_out        = (wgrey_minus1 == wclk_rgrey_minus2) ;
assign almost_full_out = (wgrey_addr   == wclk_rgrey_minus2) ;
assign two_left_out    = (wgrey_next   == wclk_rgrey_minus2) ;

assign three_left_out  = (wgrey_next_plus1 == wclk_rgrey_minus2) ;


/*------------------------------------------------------------------------------------------------------------------------------
Empty control:
Gray coded write address pointer is synchronized to read clock domain and compared to Gray coded read address pointer.
If they are equal, fifo is empty.

Almost empty control:
Synchronized write pointer is also compared to Gray coded next read address. If these two are
equal, fifo is almost empty.
--------------------------------------------------------------------------------------------------------------------------------*/
wire [(ADDR_LENGTH - 1):0] rclk_sync_wgrey_addr ;
reg  [(ADDR_LENGTH - 1):0] rclk_wgrey_addr ;
pci_synchronizer_flop #(ADDR_LENGTH, 3) i_synchronizer_reg_wgrey_addr
(
    .data_in        (wgrey_addr),
    .clk_out        (rclock_in),
    .sync_data_out  (rclk_sync_wgrey_addr),
    .async_reset    (clear)
) ;

always@(posedge rclock_in or posedge clear)
begin
    if (clear)
        rclk_wgrey_addr <= #`FF_DELAY 3 ;
    else
        rclk_wgrey_addr <= #`FF_DELAY rclk_sync_wgrey_addr ;
end

assign almost_empty_out = (rgrey_next == rclk_wgrey_addr) ;
assign empty_out        = (rgrey_addr == rclk_wgrey_addr) ;
endmodule
Commit	Line	Data
40a1f26c	1	//////////////////////////////////////////////////////////////////////
	2	//// ////
	3	//// File name "pciw_fifo_control.v" ////
	4	//// ////
	5	//// This file is part of the "PCI bridge" project ////
	6	//// http://www.opencores.org/cores/pci/ ////
	7	//// ////
	8	//// Author(s): ////
	9	//// - Miha Dolenc (mihad@opencores.org) ////
	10	//// ////
	11	//// All additional information is avaliable in the README ////
	12	//// file. ////
	13	//// ////
	14	//// ////
	15	//////////////////////////////////////////////////////////////////////
	16	//// ////
	17	//// Copyright (C) 2001 Miha Dolenc, mihad@opencores.org ////
	18	//// ////
	19	//// This source file may be used and distributed without ////
	20	//// restriction provided that this copyright statement is not ////
	21	//// removed from the file and that any derivative work contains ////
	22	//// the original copyright notice and the associated disclaimer. ////
	23	//// ////
	24	//// This source file is free software; you can redistribute it ////
	25	//// and/or modify it under the terms of the GNU Lesser General ////
	26	//// Public License as published by the Free Software Foundation; ////
	27	//// either version 2.1 of the License, or (at your option) any ////
	28	//// later version. ////
	29	//// ////
	30	//// This source is distributed in the hope that it will be ////
	31	//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
	32	//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
	33	//// PURPOSE. See the GNU Lesser General Public License for more ////
	34	//// details. ////
	35	//// ////
	36	//// You should have received a copy of the GNU Lesser General ////
	37	//// Public License along with this source; if not, download it ////
	38	//// from http://www.opencores.org/lgpl.shtml ////
	39	//// ////
	40	//////////////////////////////////////////////////////////////////////
	41	//
	42	// CVS Revision History
	43	//
	44	// $Log: pci_pciw_fifo_control.v,v $
	45	// Revision 1.1 2007-03-20 17:50:56 sithglan
	46	// add shit
	47	//
	48	// Revision 1.5 2003/08/14 13:06:03 simons
	49	// synchronizer_flop replaced with pci_synchronizer_flop, artisan ram instance updated.
	50	//
	51	// Revision 1.4 2003/08/08 16:36:33 tadejm
	52	// Added 'three_left_out' to pci_pciw_fifo signaling three locations before full. Added comparison between current registered cbe and next unregistered cbe to signal wb_master whether it is allowed to performe burst or not. Due to this, I needed 'three_left_out' so that writing to pci_pciw_fifo can be registered, otherwise timing problems would occure.
	53	//
	54	// Revision 1.3 2003/07/29 08:20:11 mihad
	55	// Found and simulated the problem in the synchronization logic.
	56	// Repaired the synchronization logic in the FIFOs.
	57	//
	58	//
	59
	60	/* FIFO_CONTROL module provides read/write address and status generation for
	61	FIFOs implemented with standard dual port SRAM cells in ASIC or FPGA designs */
	62	`include "pci_constants.v"
	63	// synopsys translate_off
	64	`include "timescale.v"
65	// synopsys translate_on
66
67	module pci_pciw_fifo_control
68	(
69	rclock_in,
70	wclock_in,
71	renable_in,
72	wenable_in,
73	reset_in,
74	almost_full_out,
75	full_out,
76	almost_empty_out,
77	empty_out,
78	waddr_out,
79	raddr_out,
80	rallow_out,
81	wallow_out,
82	three_left_out,
83	two_left_out
84	);
85
86	parameter ADDR_LENGTH = 7 ;
87
88	// independent clock inputs - rclock_in = read clock, wclock_in = write clock
89	input rclock_in, wclock_in;
90
91	// enable inputs - read address changes on rising edge of rclock_in when reads are allowed
92	// write address changes on rising edge of wclock_in when writes are allowed
93	input renable_in, wenable_in;
94
95	// reset input
96	input reset_in;
97
98	// almost full and empy status outputs
99	output almost_full_out, almost_empty_out;
100
101	// full and empty status outputs
102	output full_out, empty_out;
103
104	// read and write addresses outputs
105	output [(ADDR_LENGTH - 1):0] waddr_out, raddr_out;
106
107	// read and write allow outputs
108	output rallow_out, wallow_out ;
109
110	// three and two locations left output indicator
111	output three_left_out ;
112	output two_left_out ;
113
114	// read address register
115	reg [(ADDR_LENGTH - 1):0] raddr ;
116
117	// write address register
118	reg [(ADDR_LENGTH - 1):0] waddr;
119	reg [(ADDR_LENGTH - 1):0] waddr_plus1;
120	assign waddr_out = waddr ;
121
122	// grey code registers
123	// grey code pipeline for write address
124	reg [(ADDR_LENGTH - 1):0] wgrey_minus1 ; // previous
125	reg [(ADDR_LENGTH - 1):0] wgrey_addr ; // current
126	reg [(ADDR_LENGTH - 1):0] wgrey_next ; // next
127
128	reg [(ADDR_LENGTH - 1):0] wgrey_next_plus1 ; // next plus 1
129
130
131	// next write gray address calculation - bitwise xor between address and shifted address
132	wire [(ADDR_LENGTH - 2):0] calc_wgrey_next = waddr[(ADDR_LENGTH - 1):1] ^ waddr[(ADDR_LENGTH - 2):0] ;
133	wire [(ADDR_LENGTH - 2):0] calc_wgrey_next_plus1 = waddr_plus1[(ADDR_LENGTH - 1):1] ^ waddr_plus1[(ADDR_LENGTH - 2):0] ;
134
135	// grey code pipeline for read address
136	reg [(ADDR_LENGTH - 1):0] rgrey_minus2 ; // two before current
137	reg [(ADDR_LENGTH - 1):0] rgrey_minus1 ; // one before current
138	reg [(ADDR_LENGTH - 1):0] rgrey_addr ; // current
139	reg [(ADDR_LENGTH - 1):0] rgrey_next ; // next
140
141	// next read gray address calculation - bitwise xor between address and shifted address
142	wire [(ADDR_LENGTH - 2):0] calc_rgrey_next = raddr[(ADDR_LENGTH - 1):1] ^ raddr[(ADDR_LENGTH - 2):0] ;
143
144	// write allow - writes are allowed when fifo is not full
145	assign wallow_out = wenable_in & ~full_out ;
146
147	// clear generation for FFs and registers
148	wire clear = reset_in ;
149
150	//rallow generation
151	assign rallow_out = renable_in & ~empty_out ; // reads allowed if read enable is high and FIFO is not empty
152
153	// at any clock edge that rallow is high, this register provides next read address, so wait cycles are not necessary
154	// when FIFO is empty, this register provides actual read address, so first location can be read
155	reg [(ADDR_LENGTH - 1):0] raddr_plus_one ;
156
157
158	// read address mux - when read is performed, next address is driven, so next data is available immediately after read
159	// this is convenient for zero wait stait bursts
160	assign raddr_out = rallow_out ? raddr_plus_one : raddr ;
161
162	always@(posedge rclock_in or posedge clear)
163	begin
164	if (clear)
165	begin
166	// initial values seem a bit odd - they are this way to allow easier grey pipeline implementation and to allow min fifo size of 8
167	raddr_plus_one <= #`FF_DELAY 5 ;
168	raddr <= #`FF_DELAY 4 ;
169	// raddr_plus_one <= #`FF_DELAY 6 ;
170	// raddr <= #`FF_DELAY 5 ;
171	end
172	else if (rallow_out)
173	begin
174	raddr_plus_one <= #`FF_DELAY raddr_plus_one + 1'b1 ;
175	raddr <= #`FF_DELAY raddr_plus_one ;
176	end
177	end
178
179	/*-----------------------------------------------------------------------------------------------
180	Read address control consists of Read address counter and Grey Address pipeline
181	There are 4 Grey addresses:
182	- rgrey_minus2 is Grey Code of address two before current address
183	- rgrey_minus1 is Grey Code of address one before current address
184	- rgrey_addr is Grey Code of current read address
185	- rgrey_next is Grey Code of next read address
186	--------------------------------------------------------------------------------------------------*/
187	// grey coded address pipeline for status generation in read clock domain
188	always@(posedge rclock_in or posedge clear)
189	begin
190	if (clear)
191	begin
192	rgrey_minus2 <= #1 0 ;
193	rgrey_minus1 <= #`FF_DELAY 1 ;
194	rgrey_addr <= #1 3 ;
195	rgrey_next <= #`FF_DELAY 2 ;
196	end
197	else
198	if (rallow_out)
199	begin
200	rgrey_minus2 <= #1 rgrey_minus1 ;
201	rgrey_minus1 <= #`FF_DELAY rgrey_addr ;
202	rgrey_addr <= #1 rgrey_next ;
203	rgrey_next <= #`FF_DELAY {raddr[ADDR_LENGTH - 1], calc_rgrey_next} ;
204	end
205	end
206
207	/*--------------------------------------------------------------------------------------------
208	Write address control consists of write address counter and 3 Grey Code Registers:
209	- wgrey_minus1 represents previous Grey coded write address
210	- wgrey_addr represents current Grey Coded write address
211	- wgrey_next represents next Grey Coded write address
212
213	- wgrey_next_plus1 represents second next Grey Coded write address
214
215	----------------------------------------------------------------------------------------------*/
216	// grey coded address pipeline for status generation in write clock domain
217	always@(posedge wclock_in or posedge clear)
218	begin
219	if (clear)
220	begin
221	wgrey_minus1 <= #`FF_DELAY 1 ;
222	wgrey_addr <= #`FF_DELAY 3 ;
223	wgrey_next <= #`FF_DELAY 2 ;
224
225	wgrey_next_plus1 <= #`FF_DELAY 6;
226
227	end
228	else
229	if (wallow_out)
230	begin
231	wgrey_minus1 <= #`FF_DELAY wgrey_addr ;
232	wgrey_addr <= #`FF_DELAY wgrey_next ;
233
234	wgrey_next <= #`FF_DELAY {waddr[(ADDR_LENGTH - 1)], calc_wgrey_next} ;
235	// wgrey_next <= #`FF_DELAY wgrey_next_plus1 ;
236	wgrey_next_plus1 <= #`FF_DELAY {waddr_plus1[(ADDR_LENGTH - 1)], calc_wgrey_next_plus1} ;
237
238	end
239	end
240
241	// write address counter - nothing special except initial value
242	always@(posedge wclock_in or posedge clear)
243	begin
244	if (clear)
245	begin
246	// initial value 5
247
248	waddr <= #`FF_DELAY 4 ;
249	waddr_plus1 <= #`FF_DELAY 5 ;
250	end
251	else
252	if (wallow_out)
253	begin
254	waddr <= #`FF_DELAY waddr + 1'b1 ;
255	waddr_plus1 <= #`FF_DELAY waddr_plus1 + 1'b1 ;
256	end
257	end
258
259	/*------------------------------------------------------------------------------------------------------------------------------
260	Gray coded address of read address decremented by two is synchronized to write clock domain and compared to:
261	- previous grey coded write address - if they are equal, the fifo is full
262
263	- gray coded write address. If they are equal, fifo is almost full.
264
265	- grey coded next write address. If they are equal, the fifo has two free locations left.
266	--------------------------------------------------------------------------------------------------------------------------------*/
267	wire [(ADDR_LENGTH - 1):0] wclk_sync_rgrey_minus2 ;
268	reg [(ADDR_LENGTH - 1):0] wclk_rgrey_minus2 ;
269
270	pci_synchronizer_flop #(ADDR_LENGTH, 0) i_synchronizer_reg_rgrey_minus2
271	(
272	.data_in (rgrey_minus2),
273	.clk_out (wclock_in),
274	.sync_data_out (wclk_sync_rgrey_minus2),
275	.async_reset (clear)
276	) ;
277
278	always@(posedge wclock_in or posedge clear)
279	begin
280	if (clear)
281	begin
282	wclk_rgrey_minus2 <= #`FF_DELAY 0 ;
283	end
284	else
285	begin
286	wclk_rgrey_minus2 <= #`FF_DELAY wclk_sync_rgrey_minus2 ;
287	end
288	end
289
290	assign full_out = (wgrey_minus1 == wclk_rgrey_minus2) ;
291	assign almost_full_out = (wgrey_addr == wclk_rgrey_minus2) ;
292	assign two_left_out = (wgrey_next == wclk_rgrey_minus2) ;
293
294	assign three_left_out = (wgrey_next_plus1 == wclk_rgrey_minus2) ;
295
296
297	/*------------------------------------------------------------------------------------------------------------------------------
298	Empty control:
299	Gray coded write address pointer is synchronized to read clock domain and compared to Gray coded read address pointer.
300	If they are equal, fifo is empty.
301
302	Almost empty control:
303	Synchronized write pointer is also compared to Gray coded next read address. If these two are
304	equal, fifo is almost empty.
305	--------------------------------------------------------------------------------------------------------------------------------*/
306	wire [(ADDR_LENGTH - 1):0] rclk_sync_wgrey_addr ;
307	reg [(ADDR_LENGTH - 1):0] rclk_wgrey_addr ;
308	pci_synchronizer_flop #(ADDR_LENGTH, 3) i_synchronizer_reg_wgrey_addr
309	(
310	.data_in (wgrey_addr),
311	.clk_out (rclock_in),
312	.sync_data_out (rclk_sync_wgrey_addr),
313	.async_reset (clear)
314	) ;
315
316	always@(posedge rclock_in or posedge clear)
317	begin
318	if (clear)
319	rclk_wgrey_addr <= #`FF_DELAY 3 ;
320	else
321	rclk_wgrey_addr <= #`FF_DELAY rclk_sync_wgrey_addr ;
322	end
323
324	assign almost_empty_out = (rgrey_next == rclk_wgrey_addr) ;
325	assign empty_out = (rgrey_addr == rclk_wgrey_addr) ;
326	endmodule