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sparc_exu_ecl_mdqctl.v @ 6

Revision 6, 12.4 KB checked in by pntsvt00, 14 years ago (diff)
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1	// ========== Copyright Header Begin ==========================================
2	//
3	// OpenSPARC T1 Processor File: sparc_exu_ecl_mdqctl.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: sparc_exu_ecl_mdqctl
24	// Description: This block is the control logic for the multiply/divide
25	// input buffer. It generates the select lines for both the output
26	// to mul and div, as well as for moving the data within the buffer.
27	// There are 4 slots in the buffer, which is a modified FIFO.
28	// It will output 1 MUL and 1 DIV every cycle, as well as whether those
29	// outputs are valid. If none of the slots contain a valid entry, it
30	// will pass through the input to the output. If a kill comes through
31	// and invalidates an entry, it will show up on the valid bit coming out
32	// of the mdq, but may cause a lost cycle as the kill won't affect the logic
33	// which chooses the output until the next cycle. The block also
34	// stores the thr, rd, setcc and other control bits for each entry.
35	*/
36
37	`define MULS 10
38	`define IS64 9
39	`define SIGNED 8
40	`define SET_CC 7
41
42	module sparc_exu_ecl_mdqctl (/AUTOARG/
43	// Outputs
44	mdqctl_divcntl_input_vld, mdqctl_divcntl_reset_div,
45	mdqctl_divcntl_muldone, ecl_div_div64, ecl_div_signed_div,
46	ecl_div_muls, mdqctl_wb_divthr_g, mdqctl_wb_divrd_g,
47	mdqctl_wb_multhr_g, mdqctl_wb_mulrd_g, mdqctl_wb_divsetcc_g,
48	mdqctl_wb_mulsetcc_g, mdqctl_wb_yreg_shift_g, exu_mul_input_vld,
49	mdqctl_wb_yreg_wen_g, ecl_div_mul_sext_rs1_e,
50	ecl_div_mul_sext_rs2_e, ecl_div_mul_get_new_data,
51	ecl_div_mul_keep_data, ecl_div_mul_get_32bit_data,
52	ecl_div_mul_wen, div_zero_m,
53	// Inputs
54	clk, se, reset, ifu_exu_muldivop_d, tid_d, ifu_exu_rd_d, tid_w1,
55	flush_w1, ifu_exu_inst_vld_w, wb_divcntl_ack_g, divcntl_wb_req_g,
56	byp_alu_rs1_data_31_e, byp_alu_rs2_data_31_e, mul_exu_ack,
57	ecl_div_sel_div, ifu_exu_muls_d, div_ecl_detect_zero_high,
58	div_ecl_detect_zero_low, ifu_tlu_flush_w, early_flush_w
59	) ;
60	input clk;
61	input se;
62	input reset;
63	input [4:0] ifu_exu_muldivop_d;
64	input [1:0] tid_d;
65	input [4:0] ifu_exu_rd_d;
66	input [1:0] tid_w1;
67	input flush_w1;
68	input ifu_exu_inst_vld_w;
69	input wb_divcntl_ack_g;
70	input divcntl_wb_req_g;
71	input byp_alu_rs1_data_31_e;
72	input byp_alu_rs2_data_31_e;
73	input mul_exu_ack;
74	input ecl_div_sel_div;
75	input ifu_exu_muls_d;
76	input div_ecl_detect_zero_high;
77	input div_ecl_detect_zero_low;
78	input ifu_tlu_flush_w;
79	input early_flush_w;
80
81
82	output mdqctl_divcntl_input_vld;
83	output mdqctl_divcntl_reset_div;
84	output mdqctl_divcntl_muldone;
85	output ecl_div_div64;
86	output ecl_div_signed_div;
87	output ecl_div_muls;
88	output [1:0] mdqctl_wb_divthr_g;
89	output [4:0] mdqctl_wb_divrd_g;
90	output [1:0] mdqctl_wb_multhr_g;
91	output [4:0] mdqctl_wb_mulrd_g;
92	output mdqctl_wb_divsetcc_g;
93	output mdqctl_wb_mulsetcc_g;
94	output mdqctl_wb_yreg_shift_g;
95
96
97	output exu_mul_input_vld;
98	output mdqctl_wb_yreg_wen_g;
99	output ecl_div_mul_sext_rs1_e;
100	output ecl_div_mul_sext_rs2_e;
101	output ecl_div_mul_get_new_data;
102	output ecl_div_mul_keep_data;
103	output ecl_div_mul_get_32bit_data;
104	output ecl_div_mul_wen;
105	output div_zero_m;
106
107	wire [11:0] div_data_next;
108	wire [11:0] div_data;
109	wire new_div_vld;
110	wire curr_div_vld;
111	wire [11:0] div_input_data_d;
112	wire [9:0] mul_input_data_d;
113	wire [9:0] mul_data;
114	wire [9:0] mul_data_next;
115	wire new_mul_d;
116	wire kill_thr_mul;
117	wire mul_kill;
118	wire invalid_mul_w;
119	wire div_kill;
120	wire kill_thr_div;
121
122	wire mul_ready_next;
123	wire mul_ready;
124	wire mul_done_valid_c0;
125	wire mul_done_valid_c1;
126	wire mul_done_ack;
127	wire mul_done_c0;
128	wire mul_done_c1;
129	wire mul_done_c2;
130	wire mul_done_c3;
131
132	wire isdiv_e_valid;
133	wire isdiv_m_valid;
134	wire ismul_e_valid;
135	wire ismul_m_valid;
136	wire isdiv_e;
137	wire isdiv_m;
138	wire isdiv_w;
139	wire ismul_e;
140	wire ismul_m;
141	wire ismul_w;
142
143	wire div_used;
144	wire invalid_div_w;
145	wire div_zero_e;
146
147	// Mul result state wires
148	wire go_mul_done;
149	wire stay_mul_done;
150	wire mul_done;
151	wire next_mul_done;
152
153
154	////////////////////////
155	// Divide output DATAPATH
156	////////////////////////
157	// store control signals
158	assign div_used = divcntl_wb_req_g & wb_divcntl_ack_g & ecl_div_sel_div;
159
160	assign new_div_vld = ifu_exu_muls_d \| ifu_exu_muldivop_d[3];
161
162	assign div_input_data_d[11:0] = {1'b1, // isdiv
163	ifu_exu_muls_d,
164	ifu_exu_muldivop_d[2], // 64bit
165	ifu_exu_muldivop_d[1], // signed
166	ifu_exu_muldivop_d[0], // setcc
167	ifu_exu_rd_d[4:0],
168	tid_d[1:0]};
169	mux2ds #(12) div_data_mux(.dout(div_data_next[11:0]),
170	.in0({curr_div_vld, div_data[10:0]}),
171	.in1(div_input_data_d[11:0]),
172	.sel0(~new_div_vld),
173	.sel1(new_div_vld));
174
175	dffr_s #(12) div_data_dff(.din(div_data_next[11:0]), .clk(clk), .q(div_data[11:0]),
176	.se(se), .si(), .so(), .rst(reset));
177
178	//div kill logic (kills on div by zero exception or if there isn't an outstanding div)
179	assign div_zero_e = isdiv_e & div_ecl_detect_zero_high & div_ecl_detect_zero_low & ~div_data[`MULS];
180	assign invalid_div_w = isdiv_w & (~ifu_exu_inst_vld_w \| ifu_tlu_flush_w \| early_flush_w);
181	assign kill_thr_div = ~(div_data[1] ^ tid_w1[1]) & ~(div_data[0] ^ tid_w1[0]);
182	assign div_kill = (flush_w1 & kill_thr_div) \| invalid_div_w \| new_div_vld;
183	assign curr_div_vld = div_data[11] & ~div_zero_m & ~div_kill & ~div_used;
184
185	wire div_zero_unqual_m;
186	assign div_zero_m = div_zero_unqual_m & isdiv_m;
187	dff_s div_zero_e2m(.din(div_zero_e), .clk(clk), .q(div_zero_unqual_m), .se(se), .si(), .so());
188
189	// pipeling for divide valid signal (for inst_vld checking)
190	dff_s isdiv_d2e(.din(new_div_vld), .clk(clk), .q(isdiv_e),
191	.se(se), .si(), .so());
192	dff_s isdiv_e2m(.din(isdiv_e_valid), .clk(clk), .q(isdiv_m),
193	.se(se), .si(), .so());
194	dff_s isdiv_m2w(.din(isdiv_m_valid), .clk(clk), .q(isdiv_w),
195	.se(se), .si(), .so());
196	assign isdiv_e_valid = isdiv_e & ~div_kill;
197	assign isdiv_m_valid = isdiv_m & ~div_kill;
198
199	// control for div state machine
200	assign mdqctl_divcntl_reset_div = (~div_data[11] \| div_kill);
201	assign mdqctl_divcntl_input_vld = isdiv_e;
202
203	// control signals for div
204	assign ecl_div_div64 = div_data[`IS64];
205	assign ecl_div_signed_div = div_data[`SIGNED];
206	assign ecl_div_muls = div_data[`MULS];
207
208	// control for writeback on completion
209	assign mdqctl_wb_divrd_g[4:0] = div_data[6:2];
210	assign mdqctl_wb_divthr_g[1:0] = div_data[1:0];
211	assign mdqctl_wb_divsetcc_g = div_data[`SET_CC] \| div_data[`MULS];
212	assign mdqctl_wb_yreg_shift_g = div_used & div_data[`MULS];
213
214
215	////////////////////////////////////////////////////////////////////////////
216	// Multiply control
217	//----------------------
218	// The multiply will drop the current operation if a new request is issued.
219	// This requires addition checking to make sure that the kills are for the
220	// proper operation.
221	////////////////////////////////////////////////////////////////////////////
222	dff_s ismul_d2e(.din(ifu_exu_muldivop_d[4]), .clk(clk), .q(ismul_e),
223	.se(se), .si(), .so());
224	dff_s ismul_e2m(.din(ismul_e_valid), .clk(clk), .q(ismul_m),
225	.se(se), .si(), .so());
226	dff_s ismul_m2w(.din(ismul_m_valid), .clk(clk), .q(ismul_w),
227	.se(se), .si(), .so());
228	assign ismul_e_valid = ismul_e & ~mul_kill;
229	assign ismul_m_valid = ismul_m & ~mul_kill & ~ismul_e;
230
231	// store control signals
232	// assign mul_used = divcntl_wb_req_g & wb_divcntl_ack_g & ~ecl_div_sel_div;
233	assign new_mul_d = ifu_exu_muldivop_d[4];
234
235	assign mul_input_data_d[9:0] = {ifu_exu_muldivop_d[2], // 64bit
236	ifu_exu_muldivop_d[1], // signed
237	ifu_exu_muldivop_d[0], // setcc
238	ifu_exu_rd_d[4:0],
239	tid_d[1:0]};
240	assign mul_data_next[9:0] = (new_mul_d)? mul_input_data_d[9:0]: mul_data[9:0];
241
242	dff_s #(10) mul_data_dff(.din(mul_data_next[9:0]), .clk(clk), .q(mul_data[9:0]),
243	.se(se), .si(), .so());
244
245	// mul kill logic
246	assign kill_thr_mul = ~(mul_data[1] ^ tid_w1[1]) & ~(mul_data[0] ^ tid_w1[0]);
247	assign mul_kill = (flush_w1 & kill_thr_mul) \| reset;
248	assign invalid_mul_w = ismul_w & ~ifu_exu_inst_vld_w;
249
250	// control signals for mul data in div unit
251	assign ecl_div_mul_keep_data = ~ismul_e;
252	assign ecl_div_mul_get_new_data = ismul_e & mul_data[`IS64];
253	assign ecl_div_mul_get_32bit_data = ismul_e & ~mul_data[`IS64];
254	assign ecl_div_mul_sext_rs1_e = byp_alu_rs1_data_31_e & mul_data[`SIGNED];
255	assign ecl_div_mul_sext_rs2_e = byp_alu_rs2_data_31_e & mul_data[`SIGNED];
256
257	// control for writeback on completion
258	assign mdqctl_wb_yreg_wen_g = ~mul_data[`IS64] & ecl_div_mul_wen;
259	assign mdqctl_wb_multhr_g[1:0] = mul_data[1:0];
260	assign mdqctl_wb_mulsetcc_g = mul_data[`SET_CC];
261	assign mdqctl_wb_mulrd_g[4:0] = mul_data[6:2];
262
263	// interface with mul and state of pending mul
264	assign mul_ready_next = ismul_e_valid \| (mul_ready & ~mul_exu_ack & ~mul_kill & ~ismul_e & ~invalid_mul_w);
265	dff_s mul_ready_dff(.din(mul_ready_next), .clk(clk), .q(mul_ready), .se(se), .si(), .so());
266
267	assign exu_mul_input_vld = mul_ready;
268
269	// If there was a valid request and an ack then start passing down pipe
270	assign mul_done_ack = mul_ready & ~mul_kill & ~ismul_e & mul_exu_ack & ~invalid_mul_w;
271	dff_s dff_done_ack2c0(.din(mul_done_ack), .clk(clk), .q(mul_done_c0),
272	.se(se), .si(), .so());
273	// need to check here cause this could be w
274	assign mul_done_valid_c0 = mul_done_c0 & ~mul_kill & ~invalid_mul_w & ~ismul_e;
275	dff_s dff_done_c02c1(.din(mul_done_valid_c0), .clk(clk), .q(mul_done_c1),
276	.se(se), .si(), .so());
277	// need to check here cause this could be w1
278	assign mul_done_valid_c1 = mul_done_c1 & ~mul_kill & ~ismul_e;
279	dff_s dff_done_c1c2(.din(mul_done_valid_c1), .clk(clk), .q(mul_done_c2),
280	.se(se), .si(), .so());
281	dff_s dff_done_c22c3(.din(mul_done_c2), .clk(clk), .q(mul_done_c3),
282	.se(se), .si(), .so());
283	dff_s dff_done_c32c4(.din(mul_done_c3), .clk(clk), .q(ecl_div_mul_wen),
284	.se(se), .si(), .so());
285
286	// Mul result state machine
287	assign go_mul_done = ~mul_done & ecl_div_mul_wen;
288	assign stay_mul_done = mul_done & (~wb_divcntl_ack_g \| ecl_div_sel_div);
289	assign next_mul_done = ~reset & (go_mul_done \| stay_mul_done);
290
291	assign mdqctl_divcntl_muldone = mul_done;
292
293	// mul state flop
294	dff_s mulstate_dff(.din(next_mul_done), .clk(clk), .q(mul_done), .se(se), .si(),
295	.so());
296
297	/////////////////////////////////////////
298	// Pipeline registers for control signals
299	/////////////////////////////////////////
300
301
302	endmodule // sparc_exu_ecl_mdqctl

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source: XOpenSparcT1/trunk/T1-CPU/exu/sparc_exu_ecl_mdqctl.v @ 6

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