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;; Scheduling description for z990 (cpu 2084).
;;   Copyright (C) 2003, 2004, 2005, 2006, 2007 Free Software Foundation, Inc.
;;   Contributed by Hartmut Penner (hpenner@de.ibm.com) and
;;                  Ulrich Weigand (uweigand@de.ibm.com).
 
;; This file is part of GCC.
 
;; GCC is free software; you can redistribute it and/or modify it under
;; the terms of the GNU General Public License as published by the Free
;; Software Foundation; either version 3, or (at your option) any later
;; version.
 
;; GCC 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 General Public License
;; for more details.
 
;; You should have received a copy of the GNU General Public License
;; along with GCC; see the file COPYING3.  If not see
;; .
 
(define_automaton "x_ipu")
 
(define_cpu_unit "x_e1_r,x_e1_s,x_e1_t"  "x_ipu")
(define_cpu_unit "x_wr_r,x_wr_s,x_wr_t,x_wr_fp" "x_ipu")
(define_cpu_unit "x_s1,x_s2,x_s3,x_s4"   "x_ipu")
(define_cpu_unit "x_t1,x_t2,x_t3,x_t4"   "x_ipu")
(define_cpu_unit "x_f1,x_f2,x_f3,x_f4,x_f5,x_f6"   "x_ipu")
(define_cpu_unit "x_store_tok"   "x_ipu")
(define_cpu_unit "x_ms,x_mt"   "x_ipu")
 
(define_reservation "x-e1-st" "(x_e1_s | x_e1_t)")
 
(define_reservation "x-e1-np" "(x_e1_r + x_e1_s + x_e1_t)")
 
(absence_set "x_e1_r" "x_e1_s,x_e1_t")
(absence_set "x_e1_s" "x_e1_t")
 
;; Try to avoid int <-> fp transitions.
 
(define_reservation "x-x" "x_s1|x_t1,x_s2|x_t2,x_s3|x_t3,x_s4|x_t4")
(define_reservation "x-f" "x_f1,x_f2,x_f3,x_f4,x_f5,x_f6")
(define_reservation "x-wr-st" "((x_wr_s | x_wr_t),x-x)")
(define_reservation "x-wr-np" "((x_wr_r + x_wr_s + x_wr_t),x-x)")
(define_reservation "x-wr-fp" "x_wr_fp,x-f")
(define_reservation "x-mem"   "x_ms|x_mt")
 
(absence_set "x_wr_fp"
             "x_s1,x_s2,x_s3,x_s4,x_t1,x_t2,x_t3,x_t4,x_wr_s,x_wr_t")
 
(absence_set "x_e1_r,x_wr_r,x_wr_s,x_wr_t"
             "x_f1,x_f2,x_f3,x_f4,x_f5,x_f6,x_wr_fp")
 
;; Don't have any load type insn in same group as store
 
(absence_set "x_ms,x_mt" "x_store_tok")
 
 
;;
;; Simple insns
;;
 
(define_insn_reservation "x_int" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (and (eq_attr "type" "integer")
            (eq_attr "atype" "reg")))
  "x-e1-st,x-wr-st")
 
(define_insn_reservation "x_agen" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (and (eq_attr "type" "integer")
            (eq_attr "atype" "agen")))
  "x-e1-st,x-wr-st")
 
(define_insn_reservation "x_lr" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "lr"))
  "x-e1-st,x-wr-st")
 
(define_insn_reservation "x_la" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "la"))
  "x-e1-st,x-wr-st")
 
(define_insn_reservation "x_larl" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "larl"))
  "x-e1-st,x-wr-st")
 
(define_insn_reservation "x_load" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "load"))
  "x-e1-st+x-mem,x-wr-st")
 
(define_insn_reservation "x_store" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "store"))
  "x-e1-st+x_store_tok,x-wr-st")
 
(define_insn_reservation "x_branch" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "branch"))
  "x_e1_r,x_wr_r")
 
(define_insn_reservation "x_call" 5
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "jsr"))
  "x-e1-np*5,x-wr-np")
 
(define_insn_reservation "x_mul_hi" 2
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "imulhi"))
  "x-e1-np*2,x-wr-np")
 
(define_insn_reservation "x_mul_sidi" 4
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "imulsi,imuldi"))
  "x-e1-np*4,x-wr-np")
 
(define_insn_reservation "x_div" 10
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "idiv"))
  "x-e1-np*10,x-wr-np")
 
(define_insn_reservation "x_sem" 17
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "sem"))
  "x-e1-np+x-mem,x-e1-np*16,x-wr-st")
 
;;
;; Multicycle insns
;;
 
(define_insn_reservation "x_cs" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "cs"))
  "x-e1-np,x-wr-np")
 
(define_insn_reservation "x_vs" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "vs"))
  "x-e1-np*10,x-wr-np")
 
(define_insn_reservation "x_stm" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "stm"))
  "(x-e1-np+x_store_tok)*10,x-wr-np")
 
(define_insn_reservation "x_lm" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "lm"))
  "x-e1-np*10,x-wr-np")
 
(define_insn_reservation "x_other" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "other"))
  "x-e1-np,x-wr-np")
 
;;
;; Floating point insns
;;
 
(define_insn_reservation "x_fsimptf" 7
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fsimptf"))
  "x_e1_t*2,x-wr-fp")
 
(define_insn_reservation "x_fsimpdf" 6
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fsimpdf,fmuldf"))
  "x_e1_t,x-wr-fp")
 
(define_insn_reservation "x_fsimpsf" 6
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fsimpsf,fmulsf"))
  "x_e1_t,x-wr-fp")
 
 
(define_insn_reservation "x_fmultf" 33
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fmultf"))
  "x_e1_t*27,x-wr-fp")
 
 
(define_insn_reservation "x_fdivtf" 82
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fdivtf,fsqrttf"))
  "x_e1_t*76,x-wr-fp")
 
(define_insn_reservation "x_fdivdf" 36
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fdivdf,fsqrtdf"))
  "x_e1_t*30,x-wr-fp")
 
(define_insn_reservation "x_fdivsf" 36
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fdivsf,fsqrtsf"))
  "x_e1_t*30,x-wr-fp")
 
 
(define_insn_reservation "x_floadtf" 6
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "floadtf"))
  "x_e1_t,x-wr-fp")
 
(define_insn_reservation "x_floaddf" 6
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "floaddf"))
  "x_e1_t,x-wr-fp")
 
(define_insn_reservation "x_floadsf" 6
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "floadsf"))
  "x_e1_t,x-wr-fp")
 
 
(define_insn_reservation "x_fstoredf" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fstoredf"))
  "x_e1_t,x-wr-fp")
 
(define_insn_reservation "x_fstoresf" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "fstoresf"))
  "x_e1_t,x-wr-fp")
 
 
(define_insn_reservation "x_ftrunctf" 16
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "ftrunctf"))
  "x_e1_t*10,x-wr-fp")
 
(define_insn_reservation "x_ftruncdf" 11
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "ftruncdf"))
  "x_e1_t*5,x-wr-fp")
 
 
(define_insn_reservation "x_ftoi" 1
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "ftoi"))
  "x_e1_t*3,x-wr-fp")
 
(define_insn_reservation "x_itof" 7
  (and (eq_attr "cpu" "z990,z9_109")
       (eq_attr "type" "itof"))
  "x_e1_t*3,x-wr-fp")
 
(define_bypass 1 "x_fsimpdf" "x_fstoredf")
 
(define_bypass 1 "x_fsimpsf" "x_fstoresf")
 
(define_bypass 1 "x_floaddf" "x_fsimpdf,x_fstoredf,x_floaddf")
 
(define_bypass 1 "x_floadsf" "x_fsimpsf,x_fstoresf,x_floadsf")
 
;;
;; s390_agen_dep_p returns 1, if a register is set in the
;; first insn and used in the dependent insn to form a address.
;;
 
;;
;; If an instruction uses a register to address memory, it needs
;; to be set 5 cycles in advance.
;;
 
(define_bypass 5 "x_int,x_agen,x_lr"
                 "x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"
                 "s390_agen_dep_p")
 
(define_bypass 9 "x_int,x_agen,x_lr"
                 "x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\
                  x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"
                 "s390_agen_dep_p")
;;
;; A load type instruction uses a bypass to feed the result back
;; to the address generation pipeline stage.
;;
 
(define_bypass 4 "x_load"
                 "x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"
                 "s390_agen_dep_p")
 
(define_bypass 5 "x_load"
                 "x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\
                  x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"
                 "s390_agen_dep_p")
 
;;
;; A load address type instruction uses a bypass to feed the
;; result back to the address generation pipeline stage.
;;
 
(define_bypass 3 "x_larl,x_la"
                 "x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"
                 "s390_agen_dep_p")
 
(define_bypass 5 "x_larl, x_la"
                 "x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\
                  x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"
                 "s390_agen_dep_p")
 
;;
;; Operand forwarding
;;
 
(define_bypass 0 "x_lr,x_la,x_load" "x_int,x_lr")
 
 

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[/] [openrisc/] [trunk/] [gnu-old/] [gcc-4.2.2/] [gcc/] [config/] [s390/] [2084.md] - Blame information for rev 832

Line No.	Rev	Author	Line
1	38	julius	`;; Scheduling description for z990 (cpu 2084).`
2			`;; Copyright (C) 2003, 2004, 2005, 2006, 2007 Free Software Foundation, Inc.`
3			`;; Contributed by Hartmut Penner (hpenner@de.ibm.com) and`
4			`;; Ulrich Weigand (uweigand@de.ibm.com).`
5
6			`;; This file is part of GCC.`
7
8			`;; GCC is free software; you can redistribute it and/or modify it under`
9			`;; the terms of the GNU General Public License as published by the Free`
10			`;; Software Foundation; either version 3, or (at your option) any later`
11			`;; version.`
12
13			`;; GCC is distributed in the hope that it will be useful, but WITHOUT ANY`
14			`;; WARRANTY; without even the implied warranty of MERCHANTABILITY or`
15			`;; FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License`
16			`;; for more details.`
17
18			`;; You should have received a copy of the GNU General Public License`
19			`;; along with GCC; see the file COPYING3. If not see`
20			`;; .`
21
22			`(define_automaton "x_ipu")`
23
24			`(define_cpu_unit "x_e1_r,x_e1_s,x_e1_t" "x_ipu")`
25			`(define_cpu_unit "x_wr_r,x_wr_s,x_wr_t,x_wr_fp" "x_ipu")`
26			`(define_cpu_unit "x_s1,x_s2,x_s3,x_s4" "x_ipu")`
27			`(define_cpu_unit "x_t1,x_t2,x_t3,x_t4" "x_ipu")`
28			`(define_cpu_unit "x_f1,x_f2,x_f3,x_f4,x_f5,x_f6" "x_ipu")`
29			`(define_cpu_unit "x_store_tok" "x_ipu")`
30			`(define_cpu_unit "x_ms,x_mt" "x_ipu")`
31
32			`(define_reservation "x-e1-st" "(x_e1_s \| x_e1_t)")`
33
34			`(define_reservation "x-e1-np" "(x_e1_r + x_e1_s + x_e1_t)")`
35
36			`(absence_set "x_e1_r" "x_e1_s,x_e1_t")`
37			`(absence_set "x_e1_s" "x_e1_t")`
38
39			`;; Try to avoid int <-> fp transitions.`
40
41			`(define_reservation "x-x" "x_s1\|x_t1,x_s2\|x_t2,x_s3\|x_t3,x_s4\|x_t4")`
42			`(define_reservation "x-f" "x_f1,x_f2,x_f3,x_f4,x_f5,x_f6")`
43			`(define_reservation "x-wr-st" "((x_wr_s \| x_wr_t),x-x)")`
44			`(define_reservation "x-wr-np" "((x_wr_r + x_wr_s + x_wr_t),x-x)")`
45			`(define_reservation "x-wr-fp" "x_wr_fp,x-f")`
46			`(define_reservation "x-mem" "x_ms\|x_mt")`
47
48			`(absence_set "x_wr_fp"`
49			`"x_s1,x_s2,x_s3,x_s4,x_t1,x_t2,x_t3,x_t4,x_wr_s,x_wr_t")`
50
51			`(absence_set "x_e1_r,x_wr_r,x_wr_s,x_wr_t"`
52			`"x_f1,x_f2,x_f3,x_f4,x_f5,x_f6,x_wr_fp")`
53
54			`;; Don't have any load type insn in same group as store`
55
56			`(absence_set "x_ms,x_mt" "x_store_tok")`
57
58
59			`;;`
60			`;; Simple insns`
61			`;;`
62
63			`(define_insn_reservation "x_int" 1`
64			`(and (eq_attr "cpu" "z990,z9_109")`
65			`(and (eq_attr "type" "integer")`
66			`(eq_attr "atype" "reg")))`
67			`"x-e1-st,x-wr-st")`
68
69			`(define_insn_reservation "x_agen" 1`
70			`(and (eq_attr "cpu" "z990,z9_109")`
71			`(and (eq_attr "type" "integer")`
72			`(eq_attr "atype" "agen")))`
73			`"x-e1-st,x-wr-st")`
74
75			`(define_insn_reservation "x_lr" 1`
76			`(and (eq_attr "cpu" "z990,z9_109")`
77			`(eq_attr "type" "lr"))`
78			`"x-e1-st,x-wr-st")`
79
80			`(define_insn_reservation "x_la" 1`
81			`(and (eq_attr "cpu" "z990,z9_109")`
82			`(eq_attr "type" "la"))`
83			`"x-e1-st,x-wr-st")`
84
85			`(define_insn_reservation "x_larl" 1`
86			`(and (eq_attr "cpu" "z990,z9_109")`
87			`(eq_attr "type" "larl"))`
88			`"x-e1-st,x-wr-st")`
89
90			`(define_insn_reservation "x_load" 1`
91			`(and (eq_attr "cpu" "z990,z9_109")`
92			`(eq_attr "type" "load"))`
93			`"x-e1-st+x-mem,x-wr-st")`
94
95			`(define_insn_reservation "x_store" 1`
96			`(and (eq_attr "cpu" "z990,z9_109")`
97			`(eq_attr "type" "store"))`
98			`"x-e1-st+x_store_tok,x-wr-st")`
99
100			`(define_insn_reservation "x_branch" 1`
101			`(and (eq_attr "cpu" "z990,z9_109")`
102			`(eq_attr "type" "branch"))`
103			`"x_e1_r,x_wr_r")`
104
105			`(define_insn_reservation "x_call" 5`
106			`(and (eq_attr "cpu" "z990,z9_109")`
107			`(eq_attr "type" "jsr"))`
108			`"x-e1-np*5,x-wr-np")`
109
110			`(define_insn_reservation "x_mul_hi" 2`
111			`(and (eq_attr "cpu" "z990,z9_109")`
112			`(eq_attr "type" "imulhi"))`
113			`"x-e1-np*2,x-wr-np")`
114
115			`(define_insn_reservation "x_mul_sidi" 4`
116			`(and (eq_attr "cpu" "z990,z9_109")`
117			`(eq_attr "type" "imulsi,imuldi"))`
118			`"x-e1-np*4,x-wr-np")`
119
120			`(define_insn_reservation "x_div" 10`
121			`(and (eq_attr "cpu" "z990,z9_109")`
122			`(eq_attr "type" "idiv"))`
123			`"x-e1-np*10,x-wr-np")`
124
125			`(define_insn_reservation "x_sem" 17`
126			`(and (eq_attr "cpu" "z990,z9_109")`
127			`(eq_attr "type" "sem"))`
128			`"x-e1-np+x-mem,x-e1-np*16,x-wr-st")`
129
130			`;;`
131			`;; Multicycle insns`
132			`;;`
133
134			`(define_insn_reservation "x_cs" 1`
135			`(and (eq_attr "cpu" "z990,z9_109")`
136			`(eq_attr "type" "cs"))`
137			`"x-e1-np,x-wr-np")`
138
139			`(define_insn_reservation "x_vs" 1`
140			`(and (eq_attr "cpu" "z990,z9_109")`
141			`(eq_attr "type" "vs"))`
142			`"x-e1-np*10,x-wr-np")`
143
144			`(define_insn_reservation "x_stm" 1`
145			`(and (eq_attr "cpu" "z990,z9_109")`
146			`(eq_attr "type" "stm"))`
147			`"(x-e1-np+x_store_tok)*10,x-wr-np")`
148
149			`(define_insn_reservation "x_lm" 1`
150			`(and (eq_attr "cpu" "z990,z9_109")`
151			`(eq_attr "type" "lm"))`
152			`"x-e1-np*10,x-wr-np")`
153
154			`(define_insn_reservation "x_other" 1`
155			`(and (eq_attr "cpu" "z990,z9_109")`
156			`(eq_attr "type" "other"))`
157			`"x-e1-np,x-wr-np")`
158
159			`;;`
160			`;; Floating point insns`
161			`;;`
162
163			`(define_insn_reservation "x_fsimptf" 7`
164			`(and (eq_attr "cpu" "z990,z9_109")`
165			`(eq_attr "type" "fsimptf"))`
166			`"x_e1_t*2,x-wr-fp")`
167
168			`(define_insn_reservation "x_fsimpdf" 6`
169			`(and (eq_attr "cpu" "z990,z9_109")`
170			`(eq_attr "type" "fsimpdf,fmuldf"))`
171			`"x_e1_t,x-wr-fp")`
172
173			`(define_insn_reservation "x_fsimpsf" 6`
174			`(and (eq_attr "cpu" "z990,z9_109")`
175			`(eq_attr "type" "fsimpsf,fmulsf"))`
176			`"x_e1_t,x-wr-fp")`
177
178
179			`(define_insn_reservation "x_fmultf" 33`
180			`(and (eq_attr "cpu" "z990,z9_109")`
181			`(eq_attr "type" "fmultf"))`
182			`"x_e1_t*27,x-wr-fp")`
183
184
185			`(define_insn_reservation "x_fdivtf" 82`
186			`(and (eq_attr "cpu" "z990,z9_109")`
187			`(eq_attr "type" "fdivtf,fsqrttf"))`
188			`"x_e1_t*76,x-wr-fp")`
189
190			`(define_insn_reservation "x_fdivdf" 36`
191			`(and (eq_attr "cpu" "z990,z9_109")`
192			`(eq_attr "type" "fdivdf,fsqrtdf"))`
193			`"x_e1_t*30,x-wr-fp")`
194
195			`(define_insn_reservation "x_fdivsf" 36`
196			`(and (eq_attr "cpu" "z990,z9_109")`
197			`(eq_attr "type" "fdivsf,fsqrtsf"))`
198			`"x_e1_t*30,x-wr-fp")`
199
200
201			`(define_insn_reservation "x_floadtf" 6`
202			`(and (eq_attr "cpu" "z990,z9_109")`
203			`(eq_attr "type" "floadtf"))`
204			`"x_e1_t,x-wr-fp")`
205
206			`(define_insn_reservation "x_floaddf" 6`
207			`(and (eq_attr "cpu" "z990,z9_109")`
208			`(eq_attr "type" "floaddf"))`
209			`"x_e1_t,x-wr-fp")`
210
211			`(define_insn_reservation "x_floadsf" 6`
212			`(and (eq_attr "cpu" "z990,z9_109")`
213			`(eq_attr "type" "floadsf"))`
214			`"x_e1_t,x-wr-fp")`
215
216
217			`(define_insn_reservation "x_fstoredf" 1`
218			`(and (eq_attr "cpu" "z990,z9_109")`
219			`(eq_attr "type" "fstoredf"))`
220			`"x_e1_t,x-wr-fp")`
221
222			`(define_insn_reservation "x_fstoresf" 1`
223			`(and (eq_attr "cpu" "z990,z9_109")`
224			`(eq_attr "type" "fstoresf"))`
225			`"x_e1_t,x-wr-fp")`
226
227
228			`(define_insn_reservation "x_ftrunctf" 16`
229			`(and (eq_attr "cpu" "z990,z9_109")`
230			`(eq_attr "type" "ftrunctf"))`
231			`"x_e1_t*10,x-wr-fp")`
232
233			`(define_insn_reservation "x_ftruncdf" 11`
234			`(and (eq_attr "cpu" "z990,z9_109")`
235			`(eq_attr "type" "ftruncdf"))`
236			`"x_e1_t*5,x-wr-fp")`
237
238
239			`(define_insn_reservation "x_ftoi" 1`
240			`(and (eq_attr "cpu" "z990,z9_109")`
241			`(eq_attr "type" "ftoi"))`
242			`"x_e1_t*3,x-wr-fp")`
243
244			`(define_insn_reservation "x_itof" 7`
245			`(and (eq_attr "cpu" "z990,z9_109")`
246			`(eq_attr "type" "itof"))`
247			`"x_e1_t*3,x-wr-fp")`
248
249			`(define_bypass 1 "x_fsimpdf" "x_fstoredf")`
250
251			`(define_bypass 1 "x_fsimpsf" "x_fstoresf")`
252
253			`(define_bypass 1 "x_floaddf" "x_fsimpdf,x_fstoredf,x_floaddf")`
254
255			`(define_bypass 1 "x_floadsf" "x_fsimpsf,x_fstoresf,x_floadsf")`
256
257			`;;`
258			`;; s390_agen_dep_p returns 1, if a register is set in the`
259			`;; first insn and used in the dependent insn to form a address.`
260			`;;`
261
262			`;;`
263			`;; If an instruction uses a register to address memory, it needs`
264			`;; to be set 5 cycles in advance.`
265			`;;`
266
267			`(define_bypass 5 "x_int,x_agen,x_lr"`
268			`"x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"`
269			`"s390_agen_dep_p")`
270
271			`(define_bypass 9 "x_int,x_agen,x_lr"`
272			`"x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\`
273			`x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"`
274			`"s390_agen_dep_p")`
275			`;;`
276			`;; A load type instruction uses a bypass to feed the result back`
277			`;; to the address generation pipeline stage.`
278			`;;`
279
280			`(define_bypass 4 "x_load"`
281			`"x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"`
282			`"s390_agen_dep_p")`
283
284			`(define_bypass 5 "x_load"`
285			`"x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\`
286			`x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"`
287			`"s390_agen_dep_p")`
288
289			`;;`
290			`;; A load address type instruction uses a bypass to feed the`
291			`;; result back to the address generation pipeline stage.`
292			`;;`
293
294			`(define_bypass 3 "x_larl,x_la"`
295			`"x_agen,x_la,x_branch,x_call,x_load,x_store,x_cs,x_stm,x_lm,x_other"`
296			`"s390_agen_dep_p")`
297
298			`(define_bypass 5 "x_larl, x_la"`
299			`"x_floadtf, x_floaddf, x_floadsf, x_fstoredf, x_fstoresf,\`
300			`x_fsimpdf, x_fsimpsf, x_fdivdf, x_fdivsf"`
301			`"s390_agen_dep_p")`
302
303			`;;`
304			`;; Operand forwarding`
305			`;;`
306
307			`(define_bypass 0 "x_lr,x_la,x_load" "x_int,x_lr")`
308
309