URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [gnu-old/] [gcc-4.2.2/] [gcc/] [config/] [i386/] [k6.md] - Blame information for rev 820

Go to most recent revision | Details | Compare with Previous | View Log


;; AMD K6/K6-2 Scheduling
;; Copyright (C) 2002, 2004, 2007
;; Free Software Foundation, Inc.
;;
;; 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
;; .
;;
;; The K6 architecture is quite similar to PPro.  Important difference is
;; that there are only two decoders and they seems to be much slower than
;; any of the execution units.  So we have to pay much more attention to
;; proper scheduling for the decoders.
;; FIXME: We don't do that right now.  A good start would be to sort the
;;        instructions based on length.
;;
;; This description is based on data from the following documents:
;;
;;    "AMD-K6 Processor Data Sheet (Preliminary information)"
;;    Advanced Micro Devices, Inc., 1998.
;;
;;    "AMD-K6 Processor Code Optimization Application Note"
;;    Advanced Micro Devices, Inc., 2000.
;;
;; CPU execution units of the K6:
;;
;; store        describes the Store unit.  This unit is not modelled
;;              completely and it is only used to model lea operation.
;;              Otherwise it lies outside of any critical path.
;; load         describes the Load unit
;; alux         describes the Integer X unit
;; mm           describes the Multimedia unit, which shares a pipe
;;              with the Integer X unit.  This unit is used for MMX,
;;              which is not implemented for K6.
;; aluy         describes the Integer Y unit
;; fpu          describes the FPU unit
;; branch       describes the Branch unit
;;
;; The fp unit is not pipelined, and it can only do one operation per two
;; cycles, including fxcg.
;;
;; Generally this is a very poor description, but at least no worse than
;; the old description, and a lot easier to extend to something more
;; reasonable if anyone still cares enough about this architecture in 2004.
;;
;; ??? fxch isn't handled; not an issue until sched3 after reg-stack is real.
 
(define_automaton "k6_decoder,k6_load_unit,k6_store_unit,k6_integer_units,k6_fpu_unit,k6_branch_unit")
 
;; The K6 instruction decoding begins before the on-chip instruction cache is
;; filled.  Depending on the length of the instruction, two simple instructions
;; can be decoded in two parallel short decoders, or one complex instruction can
;; be decoded in either the long or the vector decoder.  For all practical
;; purposes, the long and vector decoder can be modelled as one decoder.
(define_cpu_unit "k6_decode_short0" "k6_decoder")
(define_cpu_unit "k6_decode_short1" "k6_decoder")
(define_cpu_unit "k6_decode_long" "k6_decoder")
(exclusion_set "k6_decode_long" "k6_decode_short0,k6_decode_short1")
(define_reservation "k6_decode_short" "k6_decode_short0|k6_decode_short1")
(define_reservation "k6_decode_vector" "k6_decode_long")
 
(define_cpu_unit "k6_store" "k6_store_unit")
(define_cpu_unit "k6_load" "k6_load_unit")
(define_cpu_unit "k6_alux,k6_aluy" "k6_integer_units")
(define_cpu_unit "k6_fpu" "k6_fpu_unit")
(define_cpu_unit "k6_branch" "k6_branch_unit")
 
;; Shift instructions and certain arithmetic are issued only on Integer X.
(define_insn_reservation "k6_alux_only" 1
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")
                                   (eq_attr "memory" "none")))
                         "k6_decode_short,k6_alux")
 
(define_insn_reservation "k6_alux_only_load" 3
                         (and (eq_attr "cpu" "k6")
                               (and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")
                                    (eq_attr "memory" "load")))
                         "k6_decode_short,k6_load,k6_alux")
 
(define_insn_reservation "k6_alux_only_store" 3
                         (and (eq_attr "cpu" "k6")
                               (and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")
                                    (eq_attr "memory" "store,both,unknown")))
                         "k6_decode_long,k6_load,k6_alux,k6_store")
 
;; Integer divide and multiply can only be issued on Integer X, too.
(define_insn_reservation "k6_alu_imul" 2
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "imul"))
                         "k6_decode_vector,k6_alux*3")
 
(define_insn_reservation "k6_alu_imul_load" 4
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imul")
                                   (eq_attr "memory" "load")))
                         "k6_decode_vector,k6_load,k6_alux*3")
 
(define_insn_reservation "k6_alu_imul_store" 4
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imul")
                                   (eq_attr "memory" "store,both,unknown")))
                         "k6_decode_vector,k6_load,k6_alux*3,k6_store")
 
;; ??? Guessed latencies based on the old pipeline description.
(define_insn_reservation "k6_alu_idiv" 17
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "idiv")
                                   (eq_attr "memory" "none")))
                         "k6_decode_vector,k6_alux*17")
 
(define_insn_reservation "k6_alu_idiv_mem" 19
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "idiv")
                                   (eq_attr "memory" "!none")))
                         "k6_decode_vector,k6_load,k6_alux*17")
 
;; Basic word and doubleword ALU ops can be issued on both Integer units.
(define_insn_reservation "k6_alu" 1
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")
                                   (eq_attr "memory" "none")))
                         "k6_decode_short,k6_alux|k6_aluy")
 
(define_insn_reservation "k6_alu_load" 3
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")
                                   (eq_attr "memory" "load")))
                         "k6_decode_short,k6_load,k6_alux|k6_aluy")
 
(define_insn_reservation "k6_alu_store" 3
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")
                                   (eq_attr "memory" "store,both,unknown")))
                         "k6_decode_long,k6_load,k6_alux|k6_aluy,k6_store")
 
;; A "load immediate" operation does not require execution at all,
;; it is available immediately after decoding.  Special-case this.
(define_insn_reservation "k6_alu_imov" 1
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imov")
                                   (and (eq_attr "memory" "none")
                                        (match_operand 1 "nonimmediate_operand"))))
                         "k6_decode_short,k6_alux|k6_aluy")
 
(define_insn_reservation "k6_alu_imov_imm" 0
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imov")
                                   (and (eq_attr "memory" "none")
                                        (match_operand 1 "immediate_operand"))))
                         "k6_decode_short")
 
(define_insn_reservation "k6_alu_imov_load" 2
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imov")
                                   (eq_attr "memory" "load")))
                         "k6_decode_short,k6_load")
 
(define_insn_reservation "k6_alu_imov_store" 1
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imov")
                                   (eq_attr "memory" "store")))
                         "k6_decode_short,k6_store")
 
(define_insn_reservation "k6_alu_imov_both" 2
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "imov")
                                   (eq_attr "memory" "both,unknown")))
                         "k6_decode_long,k6_load,k6_alux|k6_aluy")
 
;; The branch unit.
(define_insn_reservation "k6_branch_call" 1
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "call,callv"))
                         "k6_decode_vector,k6_branch")
 
(define_insn_reservation "k6_branch_branch" 1
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "ibr"))
                         "k6_decode_short,k6_branch")
 
;; The load and units have two pipeline stages.  The load latency is
;; two cycles.
(define_insn_reservation "k6_load_pop" 3
                         (and (eq_attr "cpu" "k6")
                              (ior (eq_attr "type" "pop")
                                   (eq_attr "memory" "load,both")))
                         "k6_decode_short,k6_load")
 
(define_insn_reservation "k6_load_leave" 5
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "leave"))
                         "k6_decode_long,k6_load,(k6_alux|k6_aluy)*2")
 
;; ??? From the old pipeline description.  Egad!
;; ??? Apparently we take care of this reservation in adjust_cost.
(define_insn_reservation "k6_load_str" 10
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "str")
                                   (eq_attr "memory" "load,both")))
                         "k6_decode_vector,k6_load*10")
 
;; The store unit handles lea and push.  It is otherwise unmodelled.
(define_insn_reservation "k6_store_lea" 2
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "lea"))
                         "k6_decode_short,k6_store,k6_alux|k6_aluy")
 
(define_insn_reservation "k6_store_push" 2
                         (and (eq_attr "cpu" "k6")
                              (ior (eq_attr "type" "push")
                                   (eq_attr "memory" "store,both")))
                         "k6_decode_short,k6_store")
 
(define_insn_reservation "k6_store_str" 10
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "str"))
                         "k6_store*10")
 
;; Most FPU instructions have latency 2 and throughput 2.
(define_insn_reservation "k6_fpu" 2
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "fop,fmov,fcmp,fistp")
                                   (eq_attr "memory" "none")))
                         "k6_decode_vector,k6_fpu*2")
 
(define_insn_reservation "k6_fpu_load" 6
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "fop,fmov,fcmp,fistp")
                                   (eq_attr "memory" "load,both")))
                         "k6_decode_short,k6_load,k6_fpu*2")
 
(define_insn_reservation "k6_fpu_store" 6
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "fop,fmov,fcmp,fistp")
                                   (eq_attr "memory" "store")))
                         "k6_decode_short,k6_store,k6_fpu*2")
 
(define_insn_reservation "k6_fpu_fmul" 2
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "fmul")
                                   (eq_attr "memory" "none")))
                         "k6_decode_short,k6_fpu*2")
 
(define_insn_reservation "k6_fpu_fmul_load" 2
                         (and (eq_attr "cpu" "k6")
                              (and (eq_attr "type" "fmul")
                                   (eq_attr "memory" "load,both")))
                         "k6_decode_short,k6_load,k6_fpu*2")
 
;; ??? Guessed latencies from the old pipeline description.
(define_insn_reservation "k6_fpu_expensive" 56
                         (and (eq_attr "cpu" "k6")
                              (eq_attr "type" "fdiv,fpspc"))
                         "k6_decode_short,k6_fpu*56")
 

Browse

Tools

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [gnu-old/] [gcc-4.2.2/] [gcc/] [config/] [i386/] [k6.md] - Blame information for rev 820

Line No.	Rev	Author	Line
1	38	julius	`;; AMD K6/K6-2 Scheduling`
2			`;; Copyright (C) 2002, 2004, 2007`
3			`;; Free Software Foundation, Inc.`
4			`;;`
5			`;; This file is part of GCC.`
6			`;;`
7			`;; GCC is free software; you can redistribute it and/or modify`
8			`;; it under the terms of the GNU General Public License as published by`
9			`;; the Free Software Foundation; either version 3, or (at your option)`
10			`;; any later version.`
11			`;;`
12			`;; GCC is distributed in the hope that it will be useful,`
13			`;; but WITHOUT ANY WARRANTY; without even the implied warranty of`
14			`;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
15			`;; GNU General Public License for more details.`
16			`;;`
17			`;; You should have received a copy of the GNU General Public License`
18			`;; along with GCC; see the file COPYING3. If not see`
19			`;; .`
20			`;;`
21			`;; The K6 architecture is quite similar to PPro. Important difference is`
22			`;; that there are only two decoders and they seems to be much slower than`
23			`;; any of the execution units. So we have to pay much more attention to`
24			`;; proper scheduling for the decoders.`
25			`;; FIXME: We don't do that right now. A good start would be to sort the`
26			`;; instructions based on length.`
27			`;;`
28			`;; This description is based on data from the following documents:`
29			`;;`
30			`;; "AMD-K6 Processor Data Sheet (Preliminary information)"`
31			`;; Advanced Micro Devices, Inc., 1998.`
32			`;;`
33			`;; "AMD-K6 Processor Code Optimization Application Note"`
34			`;; Advanced Micro Devices, Inc., 2000.`
35			`;;`
36			`;; CPU execution units of the K6:`
37			`;;`
38			`;; store describes the Store unit. This unit is not modelled`
39			`;; completely and it is only used to model lea operation.`
40			`;; Otherwise it lies outside of any critical path.`
41			`;; load describes the Load unit`
42			`;; alux describes the Integer X unit`
43			`;; mm describes the Multimedia unit, which shares a pipe`
44			`;; with the Integer X unit. This unit is used for MMX,`
45			`;; which is not implemented for K6.`
46			`;; aluy describes the Integer Y unit`
47			`;; fpu describes the FPU unit`
48			`;; branch describes the Branch unit`
49			`;;`
50			`;; The fp unit is not pipelined, and it can only do one operation per two`
51			`;; cycles, including fxcg.`
52			`;;`
53			`;; Generally this is a very poor description, but at least no worse than`
54			`;; the old description, and a lot easier to extend to something more`
55			`;; reasonable if anyone still cares enough about this architecture in 2004.`
56			`;;`
57			`;; ??? fxch isn't handled; not an issue until sched3 after reg-stack is real.`
58
59			`(define_automaton "k6_decoder,k6_load_unit,k6_store_unit,k6_integer_units,k6_fpu_unit,k6_branch_unit")`
60
61			`;; The K6 instruction decoding begins before the on-chip instruction cache is`
62			`;; filled. Depending on the length of the instruction, two simple instructions`
63			`;; can be decoded in two parallel short decoders, or one complex instruction can`
64			`;; be decoded in either the long or the vector decoder. For all practical`
65			`;; purposes, the long and vector decoder can be modelled as one decoder.`
66			`(define_cpu_unit "k6_decode_short0" "k6_decoder")`
67			`(define_cpu_unit "k6_decode_short1" "k6_decoder")`
68			`(define_cpu_unit "k6_decode_long" "k6_decoder")`
69			`(exclusion_set "k6_decode_long" "k6_decode_short0,k6_decode_short1")`
70			`(define_reservation "k6_decode_short" "k6_decode_short0\|k6_decode_short1")`
71			`(define_reservation "k6_decode_vector" "k6_decode_long")`
72
73			`(define_cpu_unit "k6_store" "k6_store_unit")`
74			`(define_cpu_unit "k6_load" "k6_load_unit")`
75			`(define_cpu_unit "k6_alux,k6_aluy" "k6_integer_units")`
76			`(define_cpu_unit "k6_fpu" "k6_fpu_unit")`
77			`(define_cpu_unit "k6_branch" "k6_branch_unit")`
78
79			`;; Shift instructions and certain arithmetic are issued only on Integer X.`
80			`(define_insn_reservation "k6_alux_only" 1`
81			`(and (eq_attr "cpu" "k6")`
82			`(and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")`
83			`(eq_attr "memory" "none")))`
84			`"k6_decode_short,k6_alux")`
85
86			`(define_insn_reservation "k6_alux_only_load" 3`
87			`(and (eq_attr "cpu" "k6")`
88			`(and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")`
89			`(eq_attr "memory" "load")))`
90			`"k6_decode_short,k6_load,k6_alux")`
91
92			`(define_insn_reservation "k6_alux_only_store" 3`
93			`(and (eq_attr "cpu" "k6")`
94			`(and (eq_attr "type" "ishift,ishift1,rotate,rotate1,alu1,negnot,cld")`
95			`(eq_attr "memory" "store,both,unknown")))`
96			`"k6_decode_long,k6_load,k6_alux,k6_store")`
97
98			`;; Integer divide and multiply can only be issued on Integer X, too.`
99			`(define_insn_reservation "k6_alu_imul" 2`
100			`(and (eq_attr "cpu" "k6")`
101			`(eq_attr "type" "imul"))`
102			`"k6_decode_vector,k6_alux*3")`
103
104			`(define_insn_reservation "k6_alu_imul_load" 4`
105			`(and (eq_attr "cpu" "k6")`
106			`(and (eq_attr "type" "imul")`
107			`(eq_attr "memory" "load")))`
108			`"k6_decode_vector,k6_load,k6_alux*3")`
109
110			`(define_insn_reservation "k6_alu_imul_store" 4`
111			`(and (eq_attr "cpu" "k6")`
112			`(and (eq_attr "type" "imul")`
113			`(eq_attr "memory" "store,both,unknown")))`
114			`"k6_decode_vector,k6_load,k6_alux*3,k6_store")`
115
116			`;; ??? Guessed latencies based on the old pipeline description.`
117			`(define_insn_reservation "k6_alu_idiv" 17`
118			`(and (eq_attr "cpu" "k6")`
119			`(and (eq_attr "type" "idiv")`
120			`(eq_attr "memory" "none")))`
121			`"k6_decode_vector,k6_alux*17")`
122
123			`(define_insn_reservation "k6_alu_idiv_mem" 19`
124			`(and (eq_attr "cpu" "k6")`
125			`(and (eq_attr "type" "idiv")`
126			`(eq_attr "memory" "!none")))`
127			`"k6_decode_vector,k6_load,k6_alux*17")`
128
129			`;; Basic word and doubleword ALU ops can be issued on both Integer units.`
130			`(define_insn_reservation "k6_alu" 1`
131			`(and (eq_attr "cpu" "k6")`
132			`(and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")`
133			`(eq_attr "memory" "none")))`
134			`"k6_decode_short,k6_alux\|k6_aluy")`
135
136			`(define_insn_reservation "k6_alu_load" 3`
137			`(and (eq_attr "cpu" "k6")`
138			`(and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")`
139			`(eq_attr "memory" "load")))`
140			`"k6_decode_short,k6_load,k6_alux\|k6_aluy")`
141
142			`(define_insn_reservation "k6_alu_store" 3`
143			`(and (eq_attr "cpu" "k6")`
144			`(and (eq_attr "type" "alu,alu1,negnot,icmp,test,imovx,incdec,setcc")`
145			`(eq_attr "memory" "store,both,unknown")))`
146			`"k6_decode_long,k6_load,k6_alux\|k6_aluy,k6_store")`
147
148			`;; A "load immediate" operation does not require execution at all,`
149			`;; it is available immediately after decoding. Special-case this.`
150			`(define_insn_reservation "k6_alu_imov" 1`
151			`(and (eq_attr "cpu" "k6")`
152			`(and (eq_attr "type" "imov")`
153			`(and (eq_attr "memory" "none")`
154			`(match_operand 1 "nonimmediate_operand"))))`
155			`"k6_decode_short,k6_alux\|k6_aluy")`
156
157			`(define_insn_reservation "k6_alu_imov_imm" 0`
158			`(and (eq_attr "cpu" "k6")`
159			`(and (eq_attr "type" "imov")`
160			`(and (eq_attr "memory" "none")`
161			`(match_operand 1 "immediate_operand"))))`
162			`"k6_decode_short")`
163
164			`(define_insn_reservation "k6_alu_imov_load" 2`
165			`(and (eq_attr "cpu" "k6")`
166			`(and (eq_attr "type" "imov")`
167			`(eq_attr "memory" "load")))`
168			`"k6_decode_short,k6_load")`
169
170			`(define_insn_reservation "k6_alu_imov_store" 1`
171			`(and (eq_attr "cpu" "k6")`
172			`(and (eq_attr "type" "imov")`
173			`(eq_attr "memory" "store")))`
174			`"k6_decode_short,k6_store")`
175
176			`(define_insn_reservation "k6_alu_imov_both" 2`
177			`(and (eq_attr "cpu" "k6")`
178			`(and (eq_attr "type" "imov")`
179			`(eq_attr "memory" "both,unknown")))`
180			`"k6_decode_long,k6_load,k6_alux\|k6_aluy")`
181
182			`;; The branch unit.`
183			`(define_insn_reservation "k6_branch_call" 1`
184			`(and (eq_attr "cpu" "k6")`
185			`(eq_attr "type" "call,callv"))`
186			`"k6_decode_vector,k6_branch")`
187
188			`(define_insn_reservation "k6_branch_branch" 1`
189			`(and (eq_attr "cpu" "k6")`
190			`(eq_attr "type" "ibr"))`
191			`"k6_decode_short,k6_branch")`
192
193			`;; The load and units have two pipeline stages. The load latency is`
194			`;; two cycles.`
195			`(define_insn_reservation "k6_load_pop" 3`
196			`(and (eq_attr "cpu" "k6")`
197			`(ior (eq_attr "type" "pop")`
198			`(eq_attr "memory" "load,both")))`
199			`"k6_decode_short,k6_load")`
200
201			`(define_insn_reservation "k6_load_leave" 5`
202			`(and (eq_attr "cpu" "k6")`
203			`(eq_attr "type" "leave"))`
204			`"k6_decode_long,k6_load,(k6_alux\|k6_aluy)*2")`
205
206			`;; ??? From the old pipeline description. Egad!`
207			`;; ??? Apparently we take care of this reservation in adjust_cost.`
208			`(define_insn_reservation "k6_load_str" 10`
209			`(and (eq_attr "cpu" "k6")`
210			`(and (eq_attr "type" "str")`
211			`(eq_attr "memory" "load,both")))`
212			`"k6_decode_vector,k6_load*10")`
213
214			`;; The store unit handles lea and push. It is otherwise unmodelled.`
215			`(define_insn_reservation "k6_store_lea" 2`
216			`(and (eq_attr "cpu" "k6")`
217			`(eq_attr "type" "lea"))`
218			`"k6_decode_short,k6_store,k6_alux\|k6_aluy")`
219
220			`(define_insn_reservation "k6_store_push" 2`
221			`(and (eq_attr "cpu" "k6")`
222			`(ior (eq_attr "type" "push")`
223			`(eq_attr "memory" "store,both")))`
224			`"k6_decode_short,k6_store")`
225
226			`(define_insn_reservation "k6_store_str" 10`
227			`(and (eq_attr "cpu" "k6")`
228			`(eq_attr "type" "str"))`
229			`"k6_store*10")`
230
231			`;; Most FPU instructions have latency 2 and throughput 2.`
232			`(define_insn_reservation "k6_fpu" 2`
233			`(and (eq_attr "cpu" "k6")`
234			`(and (eq_attr "type" "fop,fmov,fcmp,fistp")`
235			`(eq_attr "memory" "none")))`
236			`"k6_decode_vector,k6_fpu*2")`
237
238			`(define_insn_reservation "k6_fpu_load" 6`
239			`(and (eq_attr "cpu" "k6")`
240			`(and (eq_attr "type" "fop,fmov,fcmp,fistp")`
241			`(eq_attr "memory" "load,both")))`
242			`"k6_decode_short,k6_load,k6_fpu*2")`
243
244			`(define_insn_reservation "k6_fpu_store" 6`
245			`(and (eq_attr "cpu" "k6")`
246			`(and (eq_attr "type" "fop,fmov,fcmp,fistp")`
247			`(eq_attr "memory" "store")))`
248			`"k6_decode_short,k6_store,k6_fpu*2")`
249
250			`(define_insn_reservation "k6_fpu_fmul" 2`
251			`(and (eq_attr "cpu" "k6")`
252			`(and (eq_attr "type" "fmul")`
253			`(eq_attr "memory" "none")))`
254			`"k6_decode_short,k6_fpu*2")`
255
256			`(define_insn_reservation "k6_fpu_fmul_load" 2`
257			`(and (eq_attr "cpu" "k6")`
258			`(and (eq_attr "type" "fmul")`
259			`(eq_attr "memory" "load,both")))`
260			`"k6_decode_short,k6_load,k6_fpu*2")`
261
262			`;; ??? Guessed latencies from the old pipeline description.`
263			`(define_insn_reservation "k6_fpu_expensive" 56`
264			`(and (eq_attr "cpu" "k6")`
265			`(eq_attr "type" "fdiv,fpspc"))`
266			`"k6_decode_short,k6_fpu*56")`
267