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ucb_flow_2buf.v @ 6

Revision 6, 17.6 KB checked in by pntsvt00, 14 years ago (diff)
versione iniziale opensparc

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1	// ========== Copyright Header Begin ==========================================
2	//
3	// OpenSPARC T1 Processor File: ucb_flow_2buf.v
4	// Copyright (c) 2006 Sun Microsystems, Inc. All Rights Reserved.
5	// DO NOT ALTER OR REMOVE COPYRIGHT NOTICES.
6	//
7	// The above named program is free software; you can redistribute it and/or
8	// modify it under the terms of the GNU General Public
9	// License version 2 as published by the Free Software Foundation.
10	//
11	// The above named program is distributed in the hope that it will be
12	// useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
13	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14	// General Public License for more details.
15	//
16	// You should have received a copy of the GNU General Public
17	// License along with this work; if not, write to the Free Software
18	// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA.
19	//
20	// ========== Copyright Header End ============================================
21	////////////////////////////////////////////////////////////////////////
22	/*
23	// Module Name: ucb_flow_2buf
24	// Description: Unit Control Block
25	// - supports 64-bit or 128-bit read with flow control
26	// - supports 64-bit write with flow control
27	// - automactically drops non-64-bit writes
28	// - supports interrupt return to IO Bridge
29	// - provides 1+2 deep buffer for incoming requests
30	// from the IO Bridge
31	// - provides single buffer for returns going back
32	// to the IO Bridge
33	//
34	// This module is intended for units that have
35	// 64-bit (no 128-bit) registers.
36	//
37	// Data bus width to and from the IO Bridge is
38	// configured through parameters UCB_IOB_WIDTH and
39	// IOB_UCB_WIDTH. Supported widths are:
40	//
41	// IOB_UCB_WIDTH UCB_IOB_WIDTH
42	// ----------------------------
43	// 32 8
44	// 16 8
45	// 8 8
46	// 4 4
47	*/
48	////////////////////////////////////////////////////////////////////////
49	// Global header file includes
50	////////////////////////////////////////////////////////////////////////
51	`include "sys.h" // system level definition file which
52	// contains the time scale definition
53
54	`include "iop.h"
55
56	////////////////////////////////////////////////////////////////////////
57	// Local header file includes / local defines
58	////////////////////////////////////////////////////////////////////////
59	`define UCB_BUF_DEPTH 2
60	`define UCB_BUF_WIDTH 64+(`UCB_ADDR_HI-`UCB_ADDR_LO+1)+(`UCB_SIZE_HI-`UCB_SIZE_LO+1)+(`UCB_BUF_HI-`UCB_BUF_LO+1)+(`UCB_THR_HI-`UCB_THR_LO+1)+1+1
61
62	module ucb_flow_2buf (/AUTOARG/
63	// Outputs
64	ucb_iob_stall, rd_req_vld, wr_req_vld, thr_id_in, buf_id_in,
65	size_in, addr_in, data_in, ack_busy, int_busy, ucb_iob_vld,
66	ucb_iob_data,
67	// Inputs
68	clk, rst_l, iob_ucb_vld, iob_ucb_data, req_acpted, rd_ack_vld,
69	rd_nack_vld, thr_id_out, buf_id_out, data128, data_out, int_vld,
70	int_typ, int_thr_id, dev_id, int_stat, int_vec, iob_ucb_stall
71	);
72	// synopsys template
73
74	parameter IOB_UCB_WIDTH = 32; // data bus width from IOB to UCB
75	parameter UCB_IOB_WIDTH = 8; // data bus width from UCB to IOB
76	parameter REG_WIDTH = 64; // please do not change this parameter
77
78
79	// Globals
80	input clk;
81	input rst_l;
82
83	// Request from IO Bridge
84	input iob_ucb_vld;
85	input [IOB_UCB_WIDTH-1:0] iob_ucb_data;
86	output ucb_iob_stall;
87
88	// Request to local unit
89	output rd_req_vld;
90	output wr_req_vld;
91	output [`UCB_THR_HI-`UCB_THR_LO:0] thr_id_in;
92	output [`UCB_BUF_HI-`UCB_BUF_LO:0] buf_id_in;
93	output [`UCB_SIZE_HI-`UCB_SIZE_LO:0] size_in; // only pertinent to PCI
94	output [`UCB_ADDR_HI-`UCB_ADDR_LO:0] addr_in;
95	output [`UCB_DATA_HI-`UCB_DATA_LO:0] data_in;
96	input req_acpted;
97
98	// Ack/Nack from local unit
99	input rd_ack_vld;
100	input rd_nack_vld;
101	input [`UCB_THR_HI-`UCB_THR_LO:0] thr_id_out;
102	input [`UCB_BUF_HI-`UCB_BUF_LO:0] buf_id_out;
103	input data128; // set to 1 if data returned is 128 bit
104	input [REG_WIDTH-1:0] data_out;
105	output ack_busy;
106
107	// Interrupt from local unit
108	input int_vld;
109	input [`UCB_PKT_HI-`UCB_PKT_LO:0] int_typ; // interrupt type
110	input [`UCB_THR_HI-`UCB_THR_LO:0] int_thr_id; // interrupt thread ID
111	input [`UCB_INT_DEV_HI-`UCB_INT_DEV_LO:0] dev_id; // interrupt device ID
112	input [`UCB_INT_STAT_HI-`UCB_INT_STAT_LO:0] int_stat; // interrupt status
113	input [`UCB_INT_VEC_HI-`UCB_INT_VEC_LO:0] int_vec; // interrupt vector
114	output int_busy;
115
116	// Output to IO Bridge
117	output ucb_iob_vld;
118	output [UCB_IOB_WIDTH-1:0] ucb_iob_data;
119	input iob_ucb_stall;
120
121	// Local signals
122	wire indata_buf_vld;
123	wire [127:0] indata_buf;
124	wire ucb_iob_stall_a1;
125
126	wire read_pending;
127	wire write_pending;
128	wire illegal_write_size;
129
130	wire rd_buf;
131	wire [`UCB_BUF_DEPTH-1:0] buf_head_next;
132	wire [`UCB_BUF_DEPTH-1:0] buf_head;
133	wire wr_buf;
134	wire [`UCB_BUF_DEPTH-1:0] buf_tail_next;
135	wire [`UCB_BUF_DEPTH-1:0] buf_tail;
136	wire buf_full_next;
137	wire buf_full;
138	wire buf_empty_next;
139	wire buf_empty;
140	wire [`UCB_BUF_WIDTH-1:0] req_in;
141	wire buf0_en;
142	wire [`UCB_BUF_WIDTH-1:0] buf0;
143	wire buf1_en;
144	wire [`UCB_BUF_WIDTH-1:0] buf1;
145	wire [`UCB_BUF_WIDTH-1:0] req_out;
146	wire rd_req_vld_nq;
147	wire wr_req_vld_nq;
148
149	wire ack_buf_rd;
150	wire ack_buf_wr;
151	wire ack_buf_vld;
152	wire ack_buf_vld_next;
153	wire ack_buf_is_nack;
154	wire ack_buf_is_data128;
155	wire [`UCB_PKT_HI-`UCB_PKT_LO:0] ack_typ_out;
156	wire [REG_WIDTH+`UCB_BUF_HI-`UCB_PKT_LO:0] ack_buf_in;
157	wire [REG_WIDTH+`UCB_BUF_HI-`UCB_PKT_LO:0] ack_buf;
158	wire [(REG_WIDTH+64)/UCB_IOB_WIDTH-1:0] ack_buf_vec;
159
160	wire int_buf_rd;
161	wire int_buf_wr;
162	wire int_buf_vld;
163	wire int_buf_vld_next;
164	wire [`UCB_INT_VEC_HI-`UCB_PKT_LO:0] int_buf_in;
165	wire [`UCB_INT_VEC_HI-`UCB_PKT_LO:0] int_buf;
166	wire [(REG_WIDTH+64)/UCB_IOB_WIDTH-1:0] int_buf_vec;
167
168	wire int_last_rd;
169	wire outdata_buf_busy;
170	wire outdata_buf_wr;
171	wire [REG_WIDTH+63:0] outdata_buf_in;
172	wire [(REG_WIDTH+64)/UCB_IOB_WIDTH-1:0] outdata_vec_in;
173
174
175	////////////////////////////////////////////////////////////////////////
176	// Code starts here
177	////////////////////////////////////////////////////////////////////////
178	/************************************************************
179	* Inbound Data
180	************************************************************/
181	// Register size is hardcoded to 64 bits here because all
182	// units using the UCB module will only write to 64 bit registers.
183	ucb_bus_in #(IOB_UCB_WIDTH,64) ucb_bus_in (.rst_l(rst_l),
184	.clk(clk),
185	.vld(iob_ucb_vld),
186	.data(iob_ucb_data),
187	.stall(ucb_iob_stall),
188	.indata_buf_vld(indata_buf_vld),
189	.indata_buf(indata_buf),
190	.stall_a1(ucb_iob_stall_a1));
191
192
193	/************************************************************
194	* Decode inbound packet type
195	************************************************************/
196	assign read_pending = (indata_buf[`UCB_PKT_HI:`UCB_PKT_LO] ==
197	`UCB_READ_REQ) &
198	indata_buf_vld;
199
200	assign write_pending = (indata_buf[`UCB_PKT_HI:`UCB_PKT_LO] ==
201	`UCB_WRITE_REQ) &
202	indata_buf_vld;
203
204	// 3'b011 is the encoding for double word. All writes have to be
205	// 64 bits except writes going to PCI. PCI will instantiate a
206	// customized version of UCB.
207	assign illegal_write_size = (indata_buf[`UCB_SIZE_HI:`UCB_SIZE_LO] !=
208	3'b011);
209
210	assign ucb_iob_stall_a1 = (read_pending \| write_pending) & buf_full;
211
212
213	/************************************************************
214	* Inbound buffer
215	************************************************************/
216	// Head pointer
217	assign rd_buf = req_acpted;
218	assign buf_head_next = ~rst_l ? `UCB_BUF_DEPTH'b01 :
219	rd_buf ? {buf_head[`UCB_BUF_DEPTH-2:0],
220	buf_head[`UCB_BUF_DEPTH-1]} :
221	buf_head;
222	dff_ns #(`UCB_BUF_DEPTH) buf_head_ff (.din(buf_head_next),
223	.clk(clk),
224	.q(buf_head));
225
226	// Tail pointer
227	assign wr_buf = (read_pending \|
228	(write_pending & ~illegal_write_size)) &
229	~buf_full;
230	assign buf_tail_next = ~rst_l ? `UCB_BUF_DEPTH'b01 :
231	wr_buf ? {buf_tail[`UCB_BUF_DEPTH-2:0],
232	buf_tail[`UCB_BUF_DEPTH-1]} :
233	buf_tail;
234	dff_ns #(`UCB_BUF_DEPTH) buf_tail_ff (.din(buf_tail_next),
235	.clk(clk),
236	.q(buf_tail));
237
238	// Buffer full
239	assign buf_full_next = (buf_head_next == buf_tail_next) &
240	wr_buf;
241	dffrle_ns #(1) buf_full_ff (.din(buf_full_next),
242	.rst_l(rst_l),
243	.en(rd_buf\|wr_buf),
244	.clk(clk),
245	.q(buf_full));
246
247	// Buffer empty
248	assign buf_empty_next = ((buf_head_next == buf_tail_next) &
249	rd_buf) \| ~rst_l;
250	dffe_ns #(1) buf_empty_ff (.din(buf_empty_next),
251	.en(rd_buf\|wr_buf\|~rst_l),
252	.clk(clk),
253	.q(buf_empty));
254
255
256	assign req_in = {indata_buf[`UCB_DATA_HI:`UCB_DATA_LO],
257	indata_buf[`UCB_ADDR_HI:`UCB_ADDR_LO],
258	indata_buf[`UCB_SIZE_HI:`UCB_SIZE_LO],
259	indata_buf[`UCB_BUF_HI:`UCB_BUF_LO],
260	indata_buf[`UCB_THR_HI:`UCB_THR_LO],
261	write_pending & ~illegal_write_size,
262	read_pending};
263
264	// Buffer 0
265	assign buf0_en = buf_tail[0] & wr_buf;
266	dffe_ns #(`UCB_BUF_WIDTH) buf0_ff (.din(req_in),
267	.en(buf0_en),
268	.clk(clk),
269	.q(buf0));
270	// Buffer 1
271	assign buf1_en = buf_tail[1] & wr_buf;
272	dffe_ns #(`UCB_BUF_WIDTH) buf1_ff (.din(req_in),
273	.en(buf1_en),
274	.clk(clk),
275	.q(buf1));
276
277	assign req_out = buf_head[0] ? buf0 :
278	buf_head[1] ? buf1 :
279	{`UCB_BUF_WIDTH{1'b0}};
280
281
282	/************************************************************
283	* Inbound interface to local unit
284	************************************************************/
285	assign {data_in,
286	addr_in,
287	size_in,
288	buf_id_in,
289	thr_id_in,
290	wr_req_vld_nq,
291	rd_req_vld_nq} = req_out;
292
293	assign rd_req_vld = rd_req_vld_nq & ~buf_empty;
294	assign wr_req_vld = wr_req_vld_nq & ~buf_empty;
295
296
297	/************************************************************
298	* Outbound Ack/Nack
299	************************************************************/
300	assign ack_buf_wr = rd_ack_vld \| rd_nack_vld;
301
302	assign ack_buf_vld_next = ack_buf_wr ? 1'b1 :
303	ack_buf_rd ? 1'b0 :
304	ack_buf_vld;
305
306	dffrl_ns #(1) ack_buf_vld_ff (.din(ack_buf_vld_next),
307	.clk(clk),
308	.rst_l(rst_l),
309	.q(ack_buf_vld));
310
311	dffe_ns #(1) ack_buf_is_nack_ff (.din(rd_nack_vld),
312	.en(ack_buf_wr),
313	.clk(clk),
314	.q(ack_buf_is_nack));
315
316	dffe_ns #(1) ack_buf_is_data128_ff (.din(data128),
317	.en(ack_buf_wr),
318	.clk(clk),
319	.q(ack_buf_is_data128));
320
321	assign ack_typ_out = rd_ack_vld ? `UCB_READ_ACK:
322	`UCB_READ_NACK;
323
324	assign ack_buf_in = {data_out,
325	buf_id_out,
326	thr_id_out,
327	ack_typ_out};
328
329	dffe_ns #(REG_WIDTH+`UCB_BUF_HI-`UCB_PKT_LO+1) ack_buf_ff (.din(ack_buf_in),
330	.en(ack_buf_wr),
331	.clk(clk),
332	.q(ack_buf));
333
334	assign ack_buf_vec = ack_buf_is_nack ? {{REG_WIDTH/UCB_IOB_WIDTH{1'b0}},
335	{64/UCB_IOB_WIDTH{1'b1}}} :
336	ack_buf_is_data128 ? {(REG_WIDTH+64)/UCB_IOB_WIDTH{1'b1}} :
337	{(64+64)/UCB_IOB_WIDTH{1'b1}};
338
339	assign ack_busy = ack_buf_vld;
340
341
342	/************************************************************
343	* Outbound Interrupt
344	************************************************************/
345	// Assertion: int_buf_wr shoudn't be asserted if int_buf_busy
346	assign int_buf_wr = int_vld;
347
348	assign int_buf_vld_next = int_buf_wr ? 1'b1 :
349	int_buf_rd ? 1'b0 :
350	int_buf_vld;
351
352	dffrl_ns #(1) int_buf_vld_ff (.din(int_buf_vld_next),
353	.clk(clk),
354	.rst_l(rst_l),
355	.q(int_buf_vld));
356
357	assign int_buf_in = {int_vec,
358	int_stat,
359	dev_id,
360	int_thr_id,
361	int_typ};
362
363	dffe_ns #(`UCB_INT_VEC_HI-`UCB_PKT_LO+1) int_buf_ff (.din(int_buf_in),
364	.en(int_buf_wr),
365	.clk(clk),
366	.q(int_buf));
367
368	assign int_buf_vec = {{REG_WIDTH/UCB_IOB_WIDTH{1'b0}},
369	{64/UCB_IOB_WIDTH{1'b1}}};
370
371	assign int_busy = int_buf_vld;
372
373
374	/************************************************************
375	* Outbound ack/interrupt Arbitration
376	************************************************************/
377	dffrle_ns #(1) int_last_rd_ff (.din(int_buf_rd),
378	.en(ack_buf_rd\|int_buf_rd),
379	.rst_l(rst_l),
380	.clk(clk),
381	.q(int_last_rd));
382
383	assign ack_buf_rd = ~outdata_buf_busy & ack_buf_vld &
384	(~int_buf_vld \| int_last_rd);
385
386	assign int_buf_rd = ~outdata_buf_busy & int_buf_vld &
387	(~ack_buf_vld \| ~int_last_rd);
388
389	assign outdata_buf_wr = ack_buf_rd \| int_buf_rd;
390
391	assign outdata_buf_in = ack_buf_rd ? {ack_buf[REG_WIDTH+`UCB_BUF_HI:`UCB_BUF_HI+1],
392	{(`UCB_RSV_HI-`UCB_RSV_LO+1){1'b0}},
393	{(`UCB_ADDR_HI-`UCB_ADDR_LO+1){1'b0}},
394	{(`UCB_SIZE_HI-`UCB_SIZE_LO+1){1'b0}},
395	ack_buf[`UCB_BUF_HI:`UCB_BUF_LO],
396	ack_buf[`UCB_THR_HI:`UCB_THR_LO],
397	ack_buf[`UCB_PKT_HI:`UCB_PKT_LO]}:
398	{{REG_WIDTH{1'b0}},
399	{(`UCB_INT_RSV_HI-`UCB_INT_RSV_LO+1){1'b0}},
400	int_buf[`UCB_INT_VEC_HI:`UCB_INT_VEC_LO],
401	int_buf[`UCB_INT_STAT_HI:`UCB_INT_STAT_LO],
402	int_buf[`UCB_INT_DEV_HI:`UCB_INT_DEV_LO],
403	int_buf[`UCB_THR_HI:`UCB_THR_LO],
404	int_buf[`UCB_PKT_HI:`UCB_PKT_LO]};
405
406	assign outdata_vec_in = ack_buf_rd ? ack_buf_vec :
407	int_buf_vec;
408
409	ucb_bus_out #(UCB_IOB_WIDTH, REG_WIDTH) ucb_bus_out (.rst_l(rst_l),
410	.clk(clk),
411	.outdata_buf_wr(outdata_buf_wr),
412	.outdata_buf_in(outdata_buf_in),
413	.outdata_vec_in(outdata_vec_in),
414	.outdata_buf_busy(outdata_buf_busy),
415	.vld(ucb_iob_vld),
416	.data(ucb_iob_data),
417	.stall(iob_ucb_stall));
418
419
420	`undef UCB_BUF_WIDTH
421
422	endmodule // ucb_flow_2buf
423
424
425	// Local Variables:
426	// verilog-library-directories:(".")
427	// End:
428
429
430
431
432
433
434

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