2 # Copyright (C) 2014 Intel Corporation
4 # Permission is hereby granted, free of charge, to any person obtaining a
5 # copy of this software and associated documentation files (the "Software"),
6 # to deal in the Software without restriction, including without limitation
7 # the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 # and/or sell copies of the Software, and to permit persons to whom the
9 # Software is furnished to do so, subject to the following conditions:
11 # The above copyright notice and this permission notice (including the next
12 # paragraph) shall be included in all copies or substantial portions of the
15 # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 # THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 # FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
24 # Jason Ekstrand (jason@jlekstrand.net)
26 from __future__
import print_function
28 from collections
import OrderedDict
30 from nir_opcodes
import type_sizes
35 # Convenience variables
42 # Written in the form (<search>, <replace>) where <search> is an expression
43 # and <replace> is either an expression or a value. An expression is
44 # defined as a tuple of the form ([~]<op>, <src0>, <src1>, <src2>, <src3>)
45 # where each source is either an expression or a value. A value can be
46 # either a numeric constant or a string representing a variable name.
48 # If the opcode in a search expression is prefixed by a '~' character, this
49 # indicates that the operation is inexact. Such operations will only get
50 # applied to SSA values that do not have the exact bit set. This should be
51 # used by by any optimizations that are not bit-for-bit exact. It should not,
52 # however, be used for backend-requested lowering operations as those need to
53 # happen regardless of precision.
55 # Variable names are specified as "[#]name[@type][(cond)][.swiz]" where:
56 # "#" indicates that the given variable will only match constants,
57 # type indicates that the given variable will only match values from ALU
58 # instructions with the given output type,
59 # (cond) specifies an additional condition function (see nir_search_helpers.h),
60 # swiz is a swizzle applied to the variable (only in the <replace> expression)
62 # For constants, you have to be careful to make sure that it is the right
63 # type because python is unaware of the source and destination types of the
66 # All expression types can have a bit-size specified. For opcodes, this
67 # looks like "op@32", for variables it is "a@32" or "a@uint32" to specify a
68 # type and size. In the search half of the expression this indicates that it
69 # should only match that particular bit-size. In the replace half of the
70 # expression this indicates that the constructed value should have that
73 # If the opcode in a replacement expression is prefixed by a '!' character,
74 # this indicated that the new expression will be marked exact.
76 # A special condition "many-comm-expr" can be used with expressions to note
77 # that the expression and its subexpressions have more commutative expressions
78 # than nir_replace_instr can handle. If this special condition is needed with
79 # another condition, the two can be separated by a comma (e.g.,
80 # "(many-comm-expr,is_used_once)").
82 # based on https://web.archive.org/web/20180105155939/http://forum.devmaster.net/t/fast-and-accurate-sine-cosine/9648
83 def lowered_sincos(c
):
84 x
= ('fsub', ('fmul', 2.0, ('ffract', ('fadd', ('fmul', 0.5 / pi
, a
), c
))), 1.0)
85 x
= ('fmul', ('fsub', x
, ('fmul', x
, ('fabs', x
))), 4.0)
86 return ('ffma', ('ffma', x
, ('fabs', x
), ('fneg', x
)), 0.225, x
)
88 def intBitsToFloat(i
):
89 return struct
.unpack('!f', struct
.pack('!I', i
))[0]
93 (('imul', a
, '#b@32(is_pos_power_of_two)'), ('ishl', a
, ('find_lsb', b
)), '!options->lower_bitops'),
94 (('imul', a
, '#b@32(is_neg_power_of_two)'), ('ineg', ('ishl', a
, ('find_lsb', ('iabs', b
)))), '!options->lower_bitops'),
95 (('ishl', a
, '#b@32'), ('imul', a
, ('ishl', 1, b
)), 'options->lower_bitops'),
97 (('unpack_64_2x32_split_x', ('imul_2x32_64(is_used_once)', a
, b
)), ('imul', a
, b
)),
98 (('unpack_64_2x32_split_x', ('umul_2x32_64(is_used_once)', a
, b
)), ('imul', a
, b
)),
99 (('imul_2x32_64', a
, b
), ('pack_64_2x32_split', ('imul', a
, b
), ('imul_high', a
, b
)), 'options->lower_mul_2x32_64'),
100 (('umul_2x32_64', a
, b
), ('pack_64_2x32_split', ('imul', a
, b
), ('umul_high', a
, b
)), 'options->lower_mul_2x32_64'),
105 (('udiv', a
, '#b@32(is_pos_power_of_two)'), ('ushr', a
, ('find_lsb', b
)), '!options->lower_bitops'),
106 (('idiv', a
, '#b@32(is_pos_power_of_two)'), ('imul', ('isign', a
), ('ushr', ('iabs', a
), ('find_lsb', b
))), 'options->lower_idiv'),
107 (('idiv', a
, '#b@32(is_neg_power_of_two)'), ('ineg', ('imul', ('isign', a
), ('ushr', ('iabs', a
), ('find_lsb', ('iabs', b
))))), 'options->lower_idiv'),
108 (('umod', a
, '#b(is_pos_power_of_two)'), ('iand', a
, ('isub', b
, 1))),
110 (('~fneg', ('fneg', a
)), a
),
111 (('ineg', ('ineg', a
)), a
),
112 (('fabs', ('fneg', a
)), ('fabs', a
)),
113 (('fabs', ('u2f', a
)), ('u2f', a
)),
114 (('iabs', ('iabs', a
)), ('iabs', a
)),
115 (('iabs', ('ineg', a
)), ('iabs', a
)),
116 (('f2b', ('fneg', a
)), ('f2b', a
)),
117 (('i2b', ('ineg', a
)), ('i2b', a
)),
118 (('~fadd', a
, 0.0), a
),
120 (('usadd_4x8', a
, 0), a
),
121 (('usadd_4x8', a
, ~
0), ~
0),
122 (('~fadd', ('fmul', a
, b
), ('fmul', a
, c
)), ('fmul', a
, ('fadd', b
, c
))),
123 (('iadd', ('imul', a
, b
), ('imul', a
, c
)), ('imul', a
, ('iadd', b
, c
))),
124 (('~fadd', ('fneg', a
), a
), 0.0),
125 (('iadd', ('ineg', a
), a
), 0),
126 (('iadd', ('ineg', a
), ('iadd', a
, b
)), b
),
127 (('iadd', a
, ('iadd', ('ineg', a
), b
)), b
),
128 (('~fadd', ('fneg', a
), ('fadd', a
, b
)), b
),
129 (('~fadd', a
, ('fadd', ('fneg', a
), b
)), b
),
130 (('fadd', ('fsat', a
), ('fsat', ('fneg', a
))), ('fsat', ('fabs', a
))),
131 (('~fmul', a
, 0.0), 0.0),
133 (('umul_unorm_4x8', a
, 0), 0),
134 (('umul_unorm_4x8', a
, ~
0), a
),
135 (('~fmul', a
, 1.0), a
),
137 (('fmul', a
, -1.0), ('fneg', a
)),
138 (('imul', a
, -1), ('ineg', a
)),
139 # If a < 0: fsign(a)*a*a => -1*a*a => -a*a => abs(a)*a
140 # If a > 0: fsign(a)*a*a => 1*a*a => a*a => abs(a)*a
141 # If a == 0: fsign(a)*a*a => 0*0*0 => abs(0)*0
142 (('fmul', ('fsign', a
), ('fmul', a
, a
)), ('fmul', ('fabs', a
), a
)),
143 (('fmul', ('fmul', ('fsign', a
), a
), a
), ('fmul', ('fabs', a
), a
)),
144 (('~ffma', 0.0, a
, b
), b
),
145 (('~ffma', a
, b
, 0.0), ('fmul', a
, b
)),
146 (('ffma', 1.0, a
, b
), ('fadd', a
, b
)),
147 (('ffma', -1.0, a
, b
), ('fadd', ('fneg', a
), b
)),
148 (('~flrp', a
, b
, 0.0), a
),
149 (('~flrp', a
, b
, 1.0), b
),
150 (('~flrp', a
, a
, b
), a
),
151 (('~flrp', 0.0, a
, b
), ('fmul', a
, b
)),
153 # flrp(a, a + b, c) => a + flrp(0, b, c) => a + (b * c)
154 (('~flrp', a
, ('fadd(is_used_once)', a
, b
), c
), ('fadd', ('fmul', b
, c
), a
)),
155 (('~flrp@32', a
, ('fadd', a
, b
), c
), ('fadd', ('fmul', b
, c
), a
), 'options->lower_flrp32'),
156 (('~flrp@64', a
, ('fadd', a
, b
), c
), ('fadd', ('fmul', b
, c
), a
), 'options->lower_flrp64'),
158 (('~flrp@32', ('fadd', a
, b
), ('fadd', a
, c
), d
), ('fadd', ('flrp', b
, c
, d
), a
), 'options->lower_flrp32'),
159 (('~flrp@64', ('fadd', a
, b
), ('fadd', a
, c
), d
), ('fadd', ('flrp', b
, c
, d
), a
), 'options->lower_flrp64'),
161 (('~flrp@32', a
, ('fmul(is_used_once)', a
, b
), c
), ('fmul', ('flrp', 1.0, b
, c
), a
), 'options->lower_flrp32'),
162 (('~flrp@64', a
, ('fmul(is_used_once)', a
, b
), c
), ('fmul', ('flrp', 1.0, b
, c
), a
), 'options->lower_flrp64'),
164 (('~flrp', ('fmul(is_used_once)', a
, b
), ('fmul(is_used_once)', a
, c
), d
), ('fmul', ('flrp', b
, c
, d
), a
)),
166 (('~flrp', a
, b
, ('b2f', 'c@1')), ('bcsel', c
, b
, a
), 'options->lower_flrp32'),
167 (('~flrp', a
, 0.0, c
), ('fadd', ('fmul', ('fneg', a
), c
), a
)),
168 (('ftrunc', a
), ('bcsel', ('flt', a
, 0.0), ('fneg', ('ffloor', ('fabs', a
))), ('ffloor', ('fabs', a
))), 'options->lower_ftrunc'),
169 (('ffloor', a
), ('fsub', a
, ('ffract', a
)), 'options->lower_ffloor'),
170 (('fadd', a
, ('fneg', ('ffract', a
))), ('ffloor', a
), '!options->lower_ffloor'),
171 (('ffract', a
), ('fsub', a
, ('ffloor', a
)), 'options->lower_ffract'),
172 (('fceil', a
), ('fneg', ('ffloor', ('fneg', a
))), 'options->lower_fceil'),
173 (('~fadd', ('fmul', a
, ('fadd', 1.0, ('fneg', ('b2f', 'c@1')))), ('fmul', b
, ('b2f', c
))), ('bcsel', c
, b
, a
), 'options->lower_flrp32'),
174 (('~fadd@32', ('fmul', a
, ('fadd', 1.0, ('fneg', c
) )), ('fmul', b
, c
)), ('flrp', a
, b
, c
), '!options->lower_flrp32'),
175 (('~fadd@64', ('fmul', a
, ('fadd', 1.0, ('fneg', c
) )), ('fmul', b
, c
)), ('flrp', a
, b
, c
), '!options->lower_flrp64'),
176 # These are the same as the previous three rules, but it depends on
177 # 1-fsat(x) <=> fsat(1-x). See below.
178 (('~fadd@32', ('fmul', a
, ('fsat', ('fadd', 1.0, ('fneg', c
)))), ('fmul', b
, ('fsat', c
))), ('flrp', a
, b
, ('fsat', c
)), '!options->lower_flrp32'),
179 (('~fadd@64', ('fmul', a
, ('fsat', ('fadd', 1.0, ('fneg', c
)))), ('fmul', b
, ('fsat', c
))), ('flrp', a
, b
, ('fsat', c
)), '!options->lower_flrp64'),
181 (('~fadd', a
, ('fmul', ('b2f', 'c@1'), ('fadd', b
, ('fneg', a
)))), ('bcsel', c
, b
, a
), 'options->lower_flrp32'),
182 (('~fadd@32', a
, ('fmul', c
, ('fadd', b
, ('fneg', a
)))), ('flrp', a
, b
, c
), '!options->lower_flrp32'),
183 (('~fadd@64', a
, ('fmul', c
, ('fadd', b
, ('fneg', a
)))), ('flrp', a
, b
, c
), '!options->lower_flrp64'),
184 (('ffma', a
, b
, c
), ('fadd', ('fmul', a
, b
), c
), 'options->lower_ffma'),
185 (('~fadd', ('fmul', a
, b
), c
), ('ffma', a
, b
, c
), 'options->fuse_ffma'),
187 (('~fmul', ('fadd', ('iand', ('ineg', ('b2i32', 'a@bool')), ('fmul', b
, c
)), '#d'), '#e'),
188 ('bcsel', a
, ('fmul', ('fadd', ('fmul', b
, c
), d
), e
), ('fmul', d
, e
))),
190 (('fdph', a
, b
), ('fdot4', ('vec4', 'a.x', 'a.y', 'a.z', 1.0), b
), 'options->lower_fdph'),
192 (('fdot4', ('vec4', a
, b
, c
, 1.0), d
), ('fdph', ('vec3', a
, b
, c
), d
), '!options->lower_fdph'),
193 (('fdot4', ('vec4', a
, 0.0, 0.0, 0.0), b
), ('fmul', a
, b
)),
194 (('fdot4', ('vec4', a
, b
, 0.0, 0.0), c
), ('fdot2', ('vec2', a
, b
), c
)),
195 (('fdot4', ('vec4', a
, b
, c
, 0.0), d
), ('fdot3', ('vec3', a
, b
, c
), d
)),
197 (('fdot3', ('vec3', a
, 0.0, 0.0), b
), ('fmul', a
, b
)),
198 (('fdot3', ('vec3', a
, b
, 0.0), c
), ('fdot2', ('vec2', a
, b
), c
)),
200 (('fdot2', ('vec2', a
, 0.0), b
), ('fmul', a
, b
)),
201 (('fdot2', a
, 1.0), ('fadd', 'a.x', 'a.y')),
203 # Lower fdot to fsum when it is available
204 (('fdot2', a
, b
), ('fsum2', ('fmul', a
, b
)), 'options->lower_fdot'),
205 (('fdot3', a
, b
), ('fsum3', ('fmul', a
, b
)), 'options->lower_fdot'),
206 (('fdot4', a
, b
), ('fsum4', ('fmul', a
, b
)), 'options->lower_fdot'),
207 (('fsum2', a
), ('fadd', 'a.x', 'a.y'), 'options->lower_fdot'),
209 # If x >= 0 and x <= 1: fsat(1 - x) == 1 - fsat(x) trivially
210 # If x < 0: 1 - fsat(x) => 1 - 0 => 1 and fsat(1 - x) => fsat(> 1) => 1
211 # If x > 1: 1 - fsat(x) => 1 - 1 => 0 and fsat(1 - x) => fsat(< 0) => 0
212 (('~fadd', ('fneg(is_used_once)', ('fsat(is_used_once)', 'a(is_not_fmul)')), 1.0), ('fsat', ('fadd', 1.0, ('fneg', a
)))),
214 # 1 - ((1 - a) * (1 - b))
215 # 1 - (1 - a - b + a*b)
216 # 1 - 1 + a + b - a*b
221 (('~fadd@32', 1.0, ('fneg', ('fmul', ('fadd', 1.0, ('fneg', a
)), ('fadd', 1.0, ('fneg', b
))))),
222 ('flrp', b
, 1.0, a
), '!options->lower_flrp32'),
224 # (a * #b + #c) << #d
225 # ((a * #b) << #d) + (#c << #d)
226 # (a * (#b << #d)) + (#c << #d)
227 (('ishl', ('iadd', ('imul', a
, '#b'), '#c'), '#d'),
228 ('iadd', ('imul', a
, ('ishl', b
, d
)), ('ishl', c
, d
))),
232 (('ishl', ('imul', a
, '#b'), '#c'), ('imul', a
, ('ishl', b
, c
))),
235 # Care must be taken here. Shifts in NIR uses only the lower log2(bitsize)
236 # bits of the second source. These replacements must correctly handle the
237 # case where (b % bitsize) + (c % bitsize) >= bitsize.
238 for s
in [8, 16, 32, 64]:
241 ishl
= "ishl@{}".format(s
)
242 ishr
= "ishr@{}".format(s
)
243 ushr
= "ushr@{}".format(s
)
245 in_bounds
= ('ult', ('iadd', ('iand', b
, mask
), ('iand', c
, mask
)), s
)
247 optimizations
.extend([
248 ((ishl
, (ishl
, a
, '#b'), '#c'), ('bcsel', in_bounds
, (ishl
, a
, ('iadd', b
, c
)), 0)),
249 ((ushr
, (ushr
, a
, '#b'), '#c'), ('bcsel', in_bounds
, (ushr
, a
, ('iadd', b
, c
)), 0)),
251 # To get get -1 for large shifts of negative values, ishr must instead
252 # clamp the shift count to the maximum value.
253 ((ishr
, (ishr
, a
, '#b'), '#c'),
254 (ishr
, a
, ('imin', ('iadd', ('iand', b
, mask
), ('iand', c
, mask
)), s
- 1))),
257 # Optimize a pattern of address calculation created by DXVK where the offset is
258 # divided by 4 and then multipled by 4. This can be turned into an iand and the
259 # additions before can be reassociated to CSE the iand instruction.
260 for log2
in range(1, 7): # powers of two from 2 to 64
262 mask
= 0xffffffff & ~
(v
- 1)
263 b_is_multiple
= '#b(is_unsigned_multiple_of_{})'.format(v
)
265 optimizations
.extend([
266 # 'a >> #b << #b' -> 'a & ~((1 << #b) - 1)'
267 (('ishl@32', ('ushr@32', a
, log2
), log2
), ('iand', a
, mask
)),
269 # Reassociate for improved CSE
270 (('iand@32', ('iadd@32', a
, b_is_multiple
), mask
), ('iadd', ('iand', a
, mask
), b
)),
273 # To save space in the state tables, reduce to the set that is known to help.
274 # Previously, this was range(1, 32). In addition, a couple rules inside the
275 # loop are commented out. Revisit someday, probably after mesa/#2635 has some
277 for i
in [1, 2, 16, 24]:
278 lo_mask
= 0xffffffff >> i
279 hi_mask
= (0xffffffff << i
) & 0xffffffff
281 optimizations
.extend([
282 # This pattern seems to only help in the soft-fp64 code.
283 (('ishl@32', ('iand', 'a@32', lo_mask
), i
), ('ishl', a
, i
)),
284 # (('ushr@32', ('iand', 'a@32', hi_mask), i), ('ushr', a, i)),
285 # (('ishr@32', ('iand', 'a@32', hi_mask), i), ('ishr', a, i)),
287 (('iand', ('ishl', 'a@32', i
), hi_mask
), ('ishl', a
, i
)),
288 (('iand', ('ushr', 'a@32', i
), lo_mask
), ('ushr', a
, i
)),
289 # (('iand', ('ishr', 'a@32', i), lo_mask), ('ushr', a, i)), # Yes, ushr is correct
292 optimizations
.extend([
293 # This is common for address calculations. Reassociating may enable the
294 # 'a<<c' to be CSE'd. It also helps architectures that have an ISHLADD
295 # instruction or a constant offset field for in load / store instructions.
296 (('ishl', ('iadd', a
, '#b'), '#c'), ('iadd', ('ishl', a
, c
), ('ishl', b
, c
))),
298 # Comparison simplifications
299 (('~inot', ('flt', a
, b
)), ('fge', a
, b
)),
300 (('~inot', ('fge', a
, b
)), ('flt', a
, b
)),
301 (('inot', ('feq', a
, b
)), ('fne', a
, b
)),
302 (('inot', ('fne', a
, b
)), ('feq', a
, b
)),
303 (('inot', ('ilt', a
, b
)), ('ige', a
, b
)),
304 (('inot', ('ult', a
, b
)), ('uge', a
, b
)),
305 (('inot', ('ige', a
, b
)), ('ilt', a
, b
)),
306 (('inot', ('uge', a
, b
)), ('ult', a
, b
)),
307 (('inot', ('ieq', a
, b
)), ('ine', a
, b
)),
308 (('inot', ('ine', a
, b
)), ('ieq', a
, b
)),
310 (('iand', ('feq', a
, b
), ('fne', a
, b
)), False),
311 (('iand', ('flt', a
, b
), ('flt', b
, a
)), False),
312 (('iand', ('ieq', a
, b
), ('ine', a
, b
)), False),
313 (('iand', ('ilt', a
, b
), ('ilt', b
, a
)), False),
314 (('iand', ('ult', a
, b
), ('ult', b
, a
)), False),
316 # This helps some shaders because, after some optimizations, they end up
317 # with patterns like (-a < -b) || (b < a). In an ideal world, this sort of
318 # matching would be handled by CSE.
319 (('flt', ('fneg', a
), ('fneg', b
)), ('flt', b
, a
)),
320 (('fge', ('fneg', a
), ('fneg', b
)), ('fge', b
, a
)),
321 (('feq', ('fneg', a
), ('fneg', b
)), ('feq', b
, a
)),
322 (('fne', ('fneg', a
), ('fneg', b
)), ('fne', b
, a
)),
323 (('flt', ('fneg', a
), -1.0), ('flt', 1.0, a
)),
324 (('flt', -1.0, ('fneg', a
)), ('flt', a
, 1.0)),
325 (('fge', ('fneg', a
), -1.0), ('fge', 1.0, a
)),
326 (('fge', -1.0, ('fneg', a
)), ('fge', a
, 1.0)),
327 (('fne', ('fneg', a
), -1.0), ('fne', 1.0, a
)),
328 (('feq', -1.0, ('fneg', a
)), ('feq', a
, 1.0)),
330 (('flt', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('flt', a
, b
)),
331 (('flt', '#b(is_gt_0_and_lt_1)', ('fsat(is_used_once)', a
)), ('flt', b
, a
)),
332 (('fge', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('fge', a
, b
)),
333 (('fge', '#b(is_gt_0_and_lt_1)', ('fsat(is_used_once)', a
)), ('fge', b
, a
)),
334 (('feq', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('feq', a
, b
)),
335 (('fne', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('fne', a
, b
)),
337 (('fge', ('fsat(is_used_once)', a
), 1.0), ('fge', a
, 1.0)),
338 (('flt', ('fsat(is_used_once)', a
), 1.0), ('flt', a
, 1.0)),
339 (('fge', 0.0, ('fsat(is_used_once)', a
)), ('fge', 0.0, a
)),
340 (('flt', 0.0, ('fsat(is_used_once)', a
)), ('flt', 0.0, a
)),
344 # b2f(a) == 0.0 because b2f(a) can only be 0 or 1
346 (('fge', 0.0, ('b2f', 'a@1')), ('inot', a
)),
348 (('fge', ('fneg', ('b2f', 'a@1')), 0.0), ('inot', a
)),
350 (('fne', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('ior', a
, b
)),
351 (('fne', ('fmax', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('ior', a
, b
)),
352 (('fne', ('bcsel', a
, 1.0, ('b2f', 'b@1')) , 0.0), ('ior', a
, b
)),
353 (('fne', ('b2f', 'a@1'), ('fneg', ('b2f', 'b@1'))), ('ior', a
, b
)),
354 (('fne', ('fmul', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('iand', a
, b
)),
355 (('fne', ('fmin', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('iand', a
, b
)),
356 (('fne', ('bcsel', a
, ('b2f', 'b@1'), 0.0) , 0.0), ('iand', a
, b
)),
357 (('fne', ('fadd', ('b2f', 'a@1'), ('fneg', ('b2f', 'b@1'))), 0.0), ('ixor', a
, b
)),
358 (('fne', ('b2f', 'a@1') , ('b2f', 'b@1') ), ('ixor', a
, b
)),
359 (('fne', ('fneg', ('b2f', 'a@1')), ('fneg', ('b2f', 'b@1'))), ('ixor', a
, b
)),
360 (('feq', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('inot', ('ior', a
, b
))),
361 (('feq', ('fmax', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('inot', ('ior', a
, b
))),
362 (('feq', ('bcsel', a
, 1.0, ('b2f', 'b@1')) , 0.0), ('inot', ('ior', a
, b
))),
363 (('feq', ('b2f', 'a@1'), ('fneg', ('b2f', 'b@1'))), ('inot', ('ior', a
, b
))),
364 (('feq', ('fmul', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('inot', ('iand', a
, b
))),
365 (('feq', ('fmin', ('b2f', 'a@1'), ('b2f', 'b@1')), 0.0), ('inot', ('iand', a
, b
))),
366 (('feq', ('bcsel', a
, ('b2f', 'b@1'), 0.0) , 0.0), ('inot', ('iand', a
, b
))),
367 (('feq', ('fadd', ('b2f', 'a@1'), ('fneg', ('b2f', 'b@1'))), 0.0), ('ieq', a
, b
)),
368 (('feq', ('b2f', 'a@1') , ('b2f', 'b@1') ), ('ieq', a
, b
)),
369 (('feq', ('fneg', ('b2f', 'a@1')), ('fneg', ('b2f', 'b@1'))), ('ieq', a
, b
)),
371 # -(b2f(a) + b2f(b)) < 0
372 # 0 < b2f(a) + b2f(b)
373 # 0 != b2f(a) + b2f(b) b2f must be 0 or 1, so the sum is non-negative
375 (('flt', ('fneg', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1'))), 0.0), ('ior', a
, b
)),
376 (('flt', 0.0, ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1'))), ('ior', a
, b
)),
378 # -(b2f(a) + b2f(b)) >= 0
379 # 0 >= b2f(a) + b2f(b)
380 # 0 == b2f(a) + b2f(b) b2f must be 0 or 1, so the sum is non-negative
382 (('fge', ('fneg', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1'))), 0.0), ('inot', ('ior', a
, b
))),
383 (('fge', 0.0, ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1'))), ('inot', ('ior', a
, b
))),
385 (('flt', a
, ('fneg', a
)), ('flt', a
, 0.0)),
386 (('fge', a
, ('fneg', a
)), ('fge', a
, 0.0)),
388 # Some optimizations (below) convert things like (a < b || c < b) into
389 # (min(a, c) < b). However, this interfers with the previous optimizations
390 # that try to remove comparisons with negated sums of b2f. This just
392 (('flt', ('fmin', c
, ('fneg', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1')))), 0.0),
393 ('ior', ('flt', c
, 0.0), ('ior', a
, b
))),
395 (('~flt', ('fadd', a
, b
), a
), ('flt', b
, 0.0)),
396 (('~fge', ('fadd', a
, b
), a
), ('fge', b
, 0.0)),
397 (('~feq', ('fadd', a
, b
), a
), ('feq', b
, 0.0)),
398 (('~fne', ('fadd', a
, b
), a
), ('fne', b
, 0.0)),
399 (('~flt', ('fadd(is_used_once)', a
, '#b'), '#c'), ('flt', a
, ('fadd', c
, ('fneg', b
)))),
400 (('~flt', ('fneg(is_used_once)', ('fadd(is_used_once)', a
, '#b')), '#c'), ('flt', ('fneg', ('fadd', c
, b
)), a
)),
401 (('~fge', ('fadd(is_used_once)', a
, '#b'), '#c'), ('fge', a
, ('fadd', c
, ('fneg', b
)))),
402 (('~fge', ('fneg(is_used_once)', ('fadd(is_used_once)', a
, '#b')), '#c'), ('fge', ('fneg', ('fadd', c
, b
)), a
)),
403 (('~feq', ('fadd(is_used_once)', a
, '#b'), '#c'), ('feq', a
, ('fadd', c
, ('fneg', b
)))),
404 (('~feq', ('fneg(is_used_once)', ('fadd(is_used_once)', a
, '#b')), '#c'), ('feq', ('fneg', ('fadd', c
, b
)), a
)),
405 (('~fne', ('fadd(is_used_once)', a
, '#b'), '#c'), ('fne', a
, ('fadd', c
, ('fneg', b
)))),
406 (('~fne', ('fneg(is_used_once)', ('fadd(is_used_once)', a
, '#b')), '#c'), ('fne', ('fneg', ('fadd', c
, b
)), a
)),
408 # Cannot remove the addition from ilt or ige due to overflow.
409 (('ieq', ('iadd', a
, b
), a
), ('ieq', b
, 0)),
410 (('ine', ('iadd', a
, b
), a
), ('ine', b
, 0)),
412 # fmin(-b2f(a), b) >= 0.0
413 # -b2f(a) >= 0.0 && b >= 0.0
414 # -b2f(a) == 0.0 && b >= 0.0 -b2f can only be 0 or -1, never >0
415 # b2f(a) == 0.0 && b >= 0.0
416 # a == False && b >= 0.0
419 # The fge in the second replacement is not a typo. I leave the proof that
420 # "fmin(-b2f(a), b) >= 0 <=> fmin(-b2f(a), b) == 0" as an exercise for the
422 (('fge', ('fmin', ('fneg', ('b2f', 'a@1')), 'b@1'), 0.0), ('iand', ('inot', a
), ('fge', b
, 0.0))),
423 (('feq', ('fmin', ('fneg', ('b2f', 'a@1')), 'b@1'), 0.0), ('iand', ('inot', a
), ('fge', b
, 0.0))),
425 (('feq', ('b2f', 'a@1'), 0.0), ('inot', a
)),
426 (('~fne', ('b2f', 'a@1'), 0.0), a
),
427 (('ieq', ('b2i', 'a@1'), 0), ('inot', a
)),
428 (('ine', ('b2i', 'a@1'), 0), a
),
430 (('fne', ('u2f', a
), 0.0), ('ine', a
, 0)),
431 (('feq', ('u2f', a
), 0.0), ('ieq', a
, 0)),
432 (('fge', ('u2f', a
), 0.0), True),
433 (('fge', 0.0, ('u2f', a
)), ('uge', 0, a
)), # ieq instead?
434 (('flt', ('u2f', a
), 0.0), False),
435 (('flt', 0.0, ('u2f', a
)), ('ult', 0, a
)), # ine instead?
436 (('fne', ('i2f', a
), 0.0), ('ine', a
, 0)),
437 (('feq', ('i2f', a
), 0.0), ('ieq', a
, 0)),
438 (('fge', ('i2f', a
), 0.0), ('ige', a
, 0)),
439 (('fge', 0.0, ('i2f', a
)), ('ige', 0, a
)),
440 (('flt', ('i2f', a
), 0.0), ('ilt', a
, 0)),
441 (('flt', 0.0, ('i2f', a
)), ('ilt', 0, a
)),
445 # fabs(a) != 0.0 because fabs(a) must be >= 0
447 (('~flt', 0.0, ('fabs', a
)), ('fne', a
, 0.0)),
451 (('~flt', ('fneg', ('fabs', a
)), 0.0), ('fne', a
, 0.0)),
454 # 0.0 == fabs(a) because fabs(a) must be >= 0
456 (('fge', 0.0, ('fabs', a
)), ('feq', a
, 0.0)),
460 (('fge', ('fneg', ('fabs', a
)), 0.0), ('feq', a
, 0.0)),
462 # (a >= 0.0) && (a <= 1.0) -> fsat(a) == a
463 (('iand', ('fge', a
, 0.0), ('fge', 1.0, a
)), ('feq', a
, ('fsat', a
)), '!options->lower_fsat'),
465 # (a < 0.0) || (a > 1.0)
466 # !(!(a < 0.0) && !(a > 1.0))
467 # !((a >= 0.0) && (a <= 1.0))
470 (('ior', ('flt', a
, 0.0), ('flt', 1.0, a
)), ('fne', a
, ('fsat', a
)), '!options->lower_fsat'),
472 (('fmax', ('b2f(is_used_once)', 'a@1'), ('b2f', 'b@1')), ('b2f', ('ior', a
, b
))),
473 (('fmax', ('fneg(is_used_once)', ('b2f(is_used_once)', 'a@1')), ('fneg', ('b2f', 'b@1'))), ('fneg', ('b2f', ('ior', a
, b
)))),
474 (('fmin', ('b2f(is_used_once)', 'a@1'), ('b2f', 'b@1')), ('b2f', ('iand', a
, b
))),
475 (('fmin', ('fneg(is_used_once)', ('b2f(is_used_once)', 'a@1')), ('fneg', ('b2f', 'b@1'))), ('fneg', ('b2f', ('iand', a
, b
)))),
478 # bcsel(a, fmin(b2f(a), b), fmin(b2f(a), b))
479 # bcsel(a, fmin(b2f(True), b), fmin(b2f(False), b))
480 # bcsel(a, fmin(1.0, b), fmin(0.0, b))
482 # Since b is a constant, constant folding will eliminate the fmin and the
483 # fmax. If b is > 1.0, the bcsel will be replaced with a b2f.
484 (('fmin', ('b2f', 'a@1'), '#b'), ('bcsel', a
, ('fmin', b
, 1.0), ('fmin', b
, 0.0))),
486 (('flt', ('fadd(is_used_once)', a
, ('fneg', b
)), 0.0), ('flt', a
, b
)),
488 (('fge', ('fneg', ('fabs', a
)), 0.0), ('feq', a
, 0.0)),
489 (('~bcsel', ('flt', b
, a
), b
, a
), ('fmin', a
, b
)),
490 (('~bcsel', ('flt', a
, b
), b
, a
), ('fmax', a
, b
)),
491 (('~bcsel', ('fge', a
, b
), b
, a
), ('fmin', a
, b
)),
492 (('~bcsel', ('fge', b
, a
), b
, a
), ('fmax', a
, b
)),
493 (('bcsel', ('i2b', a
), b
, c
), ('bcsel', ('ine', a
, 0), b
, c
)),
494 (('bcsel', ('inot', a
), b
, c
), ('bcsel', a
, c
, b
)),
495 (('bcsel', a
, ('bcsel', a
, b
, c
), d
), ('bcsel', a
, b
, d
)),
496 (('bcsel', a
, b
, ('bcsel', a
, c
, d
)), ('bcsel', a
, b
, d
)),
497 (('bcsel', a
, ('bcsel', b
, c
, d
), ('bcsel(is_used_once)', b
, c
, 'e')), ('bcsel', b
, c
, ('bcsel', a
, d
, 'e'))),
498 (('bcsel', a
, ('bcsel(is_used_once)', b
, c
, d
), ('bcsel', b
, c
, 'e')), ('bcsel', b
, c
, ('bcsel', a
, d
, 'e'))),
499 (('bcsel', a
, ('bcsel', b
, c
, d
), ('bcsel(is_used_once)', b
, 'e', d
)), ('bcsel', b
, ('bcsel', a
, c
, 'e'), d
)),
500 (('bcsel', a
, ('bcsel(is_used_once)', b
, c
, d
), ('bcsel', b
, 'e', d
)), ('bcsel', b
, ('bcsel', a
, c
, 'e'), d
)),
501 (('bcsel', a
, True, b
), ('ior', a
, b
)),
502 (('bcsel', a
, a
, b
), ('ior', a
, b
)),
503 (('bcsel', a
, b
, False), ('iand', a
, b
)),
504 (('bcsel', a
, b
, a
), ('iand', a
, b
)),
505 (('~fmin', a
, a
), a
),
506 (('~fmax', a
, a
), a
),
511 (('fmax', ('fmax', a
, b
), b
), ('fmax', a
, b
)),
512 (('umax', ('umax', a
, b
), b
), ('umax', a
, b
)),
513 (('imax', ('imax', a
, b
), b
), ('imax', a
, b
)),
514 (('fmin', ('fmin', a
, b
), b
), ('fmin', a
, b
)),
515 (('umin', ('umin', a
, b
), b
), ('umin', a
, b
)),
516 (('imin', ('imin', a
, b
), b
), ('imin', a
, b
)),
517 (('iand@32', a
, ('inot', ('ishr', a
, 31))), ('imax', a
, 0)),
519 # Simplify logic to detect sign of an integer.
520 (('ieq', ('iand', 'a@32', 0x80000000), 0x00000000), ('ige', a
, 0)),
521 (('ine', ('iand', 'a@32', 0x80000000), 0x80000000), ('ige', a
, 0)),
522 (('ine', ('iand', 'a@32', 0x80000000), 0x00000000), ('ilt', a
, 0)),
523 (('ieq', ('iand', 'a@32', 0x80000000), 0x80000000), ('ilt', a
, 0)),
524 (('ine', ('ushr', 'a@32', 31), 0), ('ilt', a
, 0)),
525 (('ieq', ('ushr', 'a@32', 31), 0), ('ige', a
, 0)),
526 (('ieq', ('ushr', 'a@32', 31), 1), ('ilt', a
, 0)),
527 (('ine', ('ushr', 'a@32', 31), 1), ('ige', a
, 0)),
528 (('ine', ('ishr', 'a@32', 31), 0), ('ilt', a
, 0)),
529 (('ieq', ('ishr', 'a@32', 31), 0), ('ige', a
, 0)),
530 (('ieq', ('ishr', 'a@32', 31), -1), ('ilt', a
, 0)),
531 (('ine', ('ishr', 'a@32', 31), -1), ('ige', a
, 0)),
533 (('fmin', a
, ('fneg', a
)), ('fneg', ('fabs', a
))),
534 (('imin', a
, ('ineg', a
)), ('ineg', ('iabs', a
))),
535 (('fmin', a
, ('fneg', ('fabs', a
))), ('fneg', ('fabs', a
))),
536 (('imin', a
, ('ineg', ('iabs', a
))), ('ineg', ('iabs', a
))),
537 (('~fmin', a
, ('fabs', a
)), a
),
538 (('imin', a
, ('iabs', a
)), a
),
539 (('~fmax', a
, ('fneg', ('fabs', a
))), a
),
540 (('imax', a
, ('ineg', ('iabs', a
))), a
),
541 (('fmax', a
, ('fabs', a
)), ('fabs', a
)),
542 (('imax', a
, ('iabs', a
)), ('iabs', a
)),
543 (('fmax', a
, ('fneg', a
)), ('fabs', a
)),
544 (('imax', a
, ('ineg', a
)), ('iabs', a
)),
545 (('~fmax', ('fabs', a
), 0.0), ('fabs', a
)),
546 (('fmin', ('fmax', a
, 0.0), 1.0), ('fsat', a
), '!options->lower_fsat'),
547 # fmax(fmin(a, 1.0), 0.0) is inexact because it returns 1.0 on NaN, while
548 # fsat(a) returns 0.0.
549 (('~fmax', ('fmin', a
, 1.0), 0.0), ('fsat', a
), '!options->lower_fsat'),
550 # fmin(fmax(a, -1.0), 0.0) is inexact because it returns -1.0 on NaN, while
551 # fneg(fsat(fneg(a))) returns -0.0 on NaN.
552 (('~fmin', ('fmax', a
, -1.0), 0.0), ('fneg', ('fsat', ('fneg', a
))), '!options->lower_fsat'),
553 # fmax(fmin(a, 0.0), -1.0) is inexact because it returns 0.0 on NaN, while
554 # fneg(fsat(fneg(a))) returns -0.0 on NaN. This only matters if
555 # SignedZeroInfNanPreserve is set, but we don't currently have any way of
556 # representing this in the optimizations other than the usual ~.
557 (('~fmax', ('fmin', a
, 0.0), -1.0), ('fneg', ('fsat', ('fneg', a
))), '!options->lower_fsat'),
558 (('fsat', ('fsign', a
)), ('b2f', ('flt', 0.0, a
))),
559 (('fsat', ('b2f', a
)), ('b2f', a
)),
560 (('fsat', a
), ('fmin', ('fmax', a
, 0.0), 1.0), 'options->lower_fsat'),
561 (('fsat', ('fsat', a
)), ('fsat', a
)),
562 (('fsat', ('fneg(is_used_once)', ('fadd(is_used_once)', a
, b
))), ('fsat', ('fadd', ('fneg', a
), ('fneg', b
))), '!options->lower_fsat'),
563 (('fsat', ('fneg(is_used_once)', ('fmul(is_used_once)', a
, b
))), ('fsat', ('fmul', ('fneg', a
), b
)), '!options->lower_fsat'),
564 (('fsat', ('fabs(is_used_once)', ('fmul(is_used_once)', a
, b
))), ('fsat', ('fmul', ('fabs', a
), ('fabs', b
))), '!options->lower_fsat'),
565 (('fmin', ('fmax', ('fmin', ('fmax', a
, b
), c
), b
), c
), ('fmin', ('fmax', a
, b
), c
)),
566 (('imin', ('imax', ('imin', ('imax', a
, b
), c
), b
), c
), ('imin', ('imax', a
, b
), c
)),
567 (('umin', ('umax', ('umin', ('umax', a
, b
), c
), b
), c
), ('umin', ('umax', a
, b
), c
)),
568 # Both the left and right patterns are "b" when isnan(a), so this is exact.
569 (('fmax', ('fsat', a
), '#b@32(is_zero_to_one)'), ('fsat', ('fmax', a
, b
))),
570 # The left pattern is 0.0 when isnan(a) (because fmin(fsat(NaN), b) ->
571 # fmin(0.0, b)) while the right one is "b", so this optimization is inexact.
572 (('~fmin', ('fsat', a
), '#b@32(is_zero_to_one)'), ('fsat', ('fmin', a
, b
))),
574 # If a in [0,b] then b-a is also in [0,b]. Since b in [0,1], max(b-a, 0) =
577 # If a > b, then b-a < 0 and max(b-a, 0) = fsat(b-a) = 0
579 # This should be NaN safe since max(NaN, 0) = fsat(NaN) = 0.
580 (('fmax', ('fadd(is_used_once)', ('fneg', 'a(is_not_negative)'), '#b@32(is_zero_to_one)'), 0.0),
581 ('fsat', ('fadd', ('fneg', a
), b
)), '!options->lower_fsat'),
583 (('extract_u8', ('imin', ('imax', a
, 0), 0xff), 0), ('imin', ('imax', a
, 0), 0xff)),
584 (('~ior', ('flt(is_used_once)', a
, b
), ('flt', a
, c
)), ('flt', a
, ('fmax', b
, c
))),
585 (('~ior', ('flt(is_used_once)', a
, c
), ('flt', b
, c
)), ('flt', ('fmin', a
, b
), c
)),
586 (('~ior', ('fge(is_used_once)', a
, b
), ('fge', a
, c
)), ('fge', a
, ('fmin', b
, c
))),
587 (('~ior', ('fge(is_used_once)', a
, c
), ('fge', b
, c
)), ('fge', ('fmax', a
, b
), c
)),
588 (('~ior', ('flt', a
, '#b'), ('flt', a
, '#c')), ('flt', a
, ('fmax', b
, c
))),
589 (('~ior', ('flt', '#a', c
), ('flt', '#b', c
)), ('flt', ('fmin', a
, b
), c
)),
590 (('~ior', ('fge', a
, '#b'), ('fge', a
, '#c')), ('fge', a
, ('fmin', b
, c
))),
591 (('~ior', ('fge', '#a', c
), ('fge', '#b', c
)), ('fge', ('fmax', a
, b
), c
)),
592 (('~iand', ('flt(is_used_once)', a
, b
), ('flt', a
, c
)), ('flt', a
, ('fmin', b
, c
))),
593 (('~iand', ('flt(is_used_once)', a
, c
), ('flt', b
, c
)), ('flt', ('fmax', a
, b
), c
)),
594 (('~iand', ('fge(is_used_once)', a
, b
), ('fge', a
, c
)), ('fge', a
, ('fmax', b
, c
))),
595 (('~iand', ('fge(is_used_once)', a
, c
), ('fge', b
, c
)), ('fge', ('fmin', a
, b
), c
)),
596 (('~iand', ('flt', a
, '#b'), ('flt', a
, '#c')), ('flt', a
, ('fmin', b
, c
))),
597 (('~iand', ('flt', '#a', c
), ('flt', '#b', c
)), ('flt', ('fmax', a
, b
), c
)),
598 (('~iand', ('fge', a
, '#b'), ('fge', a
, '#c')), ('fge', a
, ('fmax', b
, c
))),
599 (('~iand', ('fge', '#a', c
), ('fge', '#b', c
)), ('fge', ('fmin', a
, b
), c
)),
601 (('ior', ('ilt(is_used_once)', a
, b
), ('ilt', a
, c
)), ('ilt', a
, ('imax', b
, c
))),
602 (('ior', ('ilt(is_used_once)', a
, c
), ('ilt', b
, c
)), ('ilt', ('imin', a
, b
), c
)),
603 (('ior', ('ige(is_used_once)', a
, b
), ('ige', a
, c
)), ('ige', a
, ('imin', b
, c
))),
604 (('ior', ('ige(is_used_once)', a
, c
), ('ige', b
, c
)), ('ige', ('imax', a
, b
), c
)),
605 (('ior', ('ult(is_used_once)', a
, b
), ('ult', a
, c
)), ('ult', a
, ('umax', b
, c
))),
606 (('ior', ('ult(is_used_once)', a
, c
), ('ult', b
, c
)), ('ult', ('umin', a
, b
), c
)),
607 (('ior', ('uge(is_used_once)', a
, b
), ('uge', a
, c
)), ('uge', a
, ('umin', b
, c
))),
608 (('ior', ('uge(is_used_once)', a
, c
), ('uge', b
, c
)), ('uge', ('umax', a
, b
), c
)),
609 (('iand', ('ilt(is_used_once)', a
, b
), ('ilt', a
, c
)), ('ilt', a
, ('imin', b
, c
))),
610 (('iand', ('ilt(is_used_once)', a
, c
), ('ilt', b
, c
)), ('ilt', ('imax', a
, b
), c
)),
611 (('iand', ('ige(is_used_once)', a
, b
), ('ige', a
, c
)), ('ige', a
, ('imax', b
, c
))),
612 (('iand', ('ige(is_used_once)', a
, c
), ('ige', b
, c
)), ('ige', ('imin', a
, b
), c
)),
613 (('iand', ('ult(is_used_once)', a
, b
), ('ult', a
, c
)), ('ult', a
, ('umin', b
, c
))),
614 (('iand', ('ult(is_used_once)', a
, c
), ('ult', b
, c
)), ('ult', ('umax', a
, b
), c
)),
615 (('iand', ('uge(is_used_once)', a
, b
), ('uge', a
, c
)), ('uge', a
, ('umax', b
, c
))),
616 (('iand', ('uge(is_used_once)', a
, c
), ('uge', b
, c
)), ('uge', ('umin', a
, b
), c
)),
618 # These derive from the previous patterns with the application of b < 0 <=>
619 # 0 < -b. The transformation should be applied if either comparison is
620 # used once as this ensures that the number of comparisons will not
621 # increase. The sources to the ior and iand are not symmetric, so the
622 # rules have to be duplicated to get this behavior.
623 (('~ior', ('flt(is_used_once)', 0.0, 'a@32'), ('flt', 'b@32', 0.0)), ('flt', 0.0, ('fmax', a
, ('fneg', b
)))),
624 (('~ior', ('flt', 0.0, 'a@32'), ('flt(is_used_once)', 'b@32', 0.0)), ('flt', 0.0, ('fmax', a
, ('fneg', b
)))),
625 (('~ior', ('fge(is_used_once)', 0.0, 'a@32'), ('fge', 'b@32', 0.0)), ('fge', 0.0, ('fmin', a
, ('fneg', b
)))),
626 (('~ior', ('fge', 0.0, 'a@32'), ('fge(is_used_once)', 'b@32', 0.0)), ('fge', 0.0, ('fmin', a
, ('fneg', b
)))),
627 (('~iand', ('flt(is_used_once)', 0.0, 'a@32'), ('flt', 'b@32', 0.0)), ('flt', 0.0, ('fmin', a
, ('fneg', b
)))),
628 (('~iand', ('flt', 0.0, 'a@32'), ('flt(is_used_once)', 'b@32', 0.0)), ('flt', 0.0, ('fmin', a
, ('fneg', b
)))),
629 (('~iand', ('fge(is_used_once)', 0.0, 'a@32'), ('fge', 'b@32', 0.0)), ('fge', 0.0, ('fmax', a
, ('fneg', b
)))),
630 (('~iand', ('fge', 0.0, 'a@32'), ('fge(is_used_once)', 'b@32', 0.0)), ('fge', 0.0, ('fmax', a
, ('fneg', b
)))),
632 # Common pattern like 'if (i == 0 || i == 1 || ...)'
633 (('ior', ('ieq', a
, 0), ('ieq', a
, 1)), ('uge', 1, a
)),
634 (('ior', ('uge', 1, a
), ('ieq', a
, 2)), ('uge', 2, a
)),
635 (('ior', ('uge', 2, a
), ('ieq', a
, 3)), ('uge', 3, a
)),
637 # The (i2f32, ...) part is an open-coded fsign. When that is combined with
638 # the bcsel, it's basically copysign(1.0, a). There is no copysign in NIR,
639 # so emit an open-coded version of that.
640 (('bcsel@32', ('feq', a
, 0.0), 1.0, ('i2f32', ('iadd', ('b2i32', ('flt', 0.0, 'a@32')), ('ineg', ('b2i32', ('flt', 'a@32', 0.0)))))),
641 ('ior', 0x3f800000, ('iand', a
, 0x80000000))),
643 (('ior', a
, ('ieq', a
, False)), True),
644 (('ior', a
, ('inot', a
)), -1),
646 (('ine', ('ineg', ('b2i32', 'a@1')), ('ineg', ('b2i32', 'b@1'))), ('ine', a
, b
)),
647 (('b2i32', ('ine', 'a@1', 'b@1')), ('b2i32', ('ixor', a
, b
))),
649 (('iand', ('ieq', 'a@32', 0), ('ieq', 'b@32', 0)), ('ieq', ('umax', a
, b
), 0)),
650 (('ior', ('ieq', 'a@32', 0), ('ieq', 'b@32', 0)), ('ieq', ('umin', a
, b
), 0)),
651 (('iand', ('ine', 'a@32', 0), ('ine', 'b@32', 0)), ('ine', ('umin', a
, b
), 0)),
652 (('ior', ('ine', 'a@32', 0), ('ine', 'b@32', 0)), ('ine', ('umax', a
, b
), 0)),
654 # This pattern occurs coutresy of __flt64_nonnan in the soft-fp64 code.
655 # The first part of the iand comes from the !__feq64_nonnan.
657 # The second pattern is a reformulation of the first based on the relation
658 # (a == 0 || y == 0) <=> umin(a, y) == 0, where b in the first equation
659 # happens to be y == 0.
660 (('iand', ('inot', ('iand', ('ior', ('ieq', a
, 0), b
), c
)), ('ilt', a
, 0)),
661 ('iand', ('inot', ('iand', b
, c
)), ('ilt', a
, 0))),
662 (('iand', ('inot', ('iand', ('ieq', ('umin', a
, b
), 0), c
)), ('ilt', a
, 0)),
663 ('iand', ('inot', ('iand', ('ieq', b
, 0), c
)), ('ilt', a
, 0))),
665 # These patterns can result when (a < b || a < c) => (a < min(b, c))
666 # transformations occur before constant propagation and loop-unrolling.
667 (('~flt', a
, ('fmax', b
, a
)), ('flt', a
, b
)),
668 (('~flt', ('fmin', a
, b
), a
), ('flt', b
, a
)),
669 (('~fge', a
, ('fmin', b
, a
)), True),
670 (('~fge', ('fmax', a
, b
), a
), True),
671 (('~flt', a
, ('fmin', b
, a
)), False),
672 (('~flt', ('fmax', a
, b
), a
), False),
673 (('~fge', a
, ('fmax', b
, a
)), ('fge', a
, b
)),
674 (('~fge', ('fmin', a
, b
), a
), ('fge', b
, a
)),
676 (('ilt', a
, ('imax', b
, a
)), ('ilt', a
, b
)),
677 (('ilt', ('imin', a
, b
), a
), ('ilt', b
, a
)),
678 (('ige', a
, ('imin', b
, a
)), True),
679 (('ige', ('imax', a
, b
), a
), True),
680 (('ult', a
, ('umax', b
, a
)), ('ult', a
, b
)),
681 (('ult', ('umin', a
, b
), a
), ('ult', b
, a
)),
682 (('uge', a
, ('umin', b
, a
)), True),
683 (('uge', ('umax', a
, b
), a
), True),
684 (('ilt', a
, ('imin', b
, a
)), False),
685 (('ilt', ('imax', a
, b
), a
), False),
686 (('ige', a
, ('imax', b
, a
)), ('ige', a
, b
)),
687 (('ige', ('imin', a
, b
), a
), ('ige', b
, a
)),
688 (('ult', a
, ('umin', b
, a
)), False),
689 (('ult', ('umax', a
, b
), a
), False),
690 (('uge', a
, ('umax', b
, a
)), ('uge', a
, b
)),
691 (('uge', ('umin', a
, b
), a
), ('uge', b
, a
)),
692 (('ult', a
, ('iand', b
, a
)), False),
693 (('ult', ('ior', a
, b
), a
), False),
694 (('uge', a
, ('iand', b
, a
)), True),
695 (('uge', ('ior', a
, b
), a
), True),
697 (('ilt', '#a', ('imax', '#b', c
)), ('ior', ('ilt', a
, b
), ('ilt', a
, c
))),
698 (('ilt', ('imin', '#a', b
), '#c'), ('ior', ('ilt', a
, c
), ('ilt', b
, c
))),
699 (('ige', '#a', ('imin', '#b', c
)), ('ior', ('ige', a
, b
), ('ige', a
, c
))),
700 (('ige', ('imax', '#a', b
), '#c'), ('ior', ('ige', a
, c
), ('ige', b
, c
))),
701 (('ult', '#a', ('umax', '#b', c
)), ('ior', ('ult', a
, b
), ('ult', a
, c
))),
702 (('ult', ('umin', '#a', b
), '#c'), ('ior', ('ult', a
, c
), ('ult', b
, c
))),
703 (('uge', '#a', ('umin', '#b', c
)), ('ior', ('uge', a
, b
), ('uge', a
, c
))),
704 (('uge', ('umax', '#a', b
), '#c'), ('ior', ('uge', a
, c
), ('uge', b
, c
))),
705 (('ilt', '#a', ('imin', '#b', c
)), ('iand', ('ilt', a
, b
), ('ilt', a
, c
))),
706 (('ilt', ('imax', '#a', b
), '#c'), ('iand', ('ilt', a
, c
), ('ilt', b
, c
))),
707 (('ige', '#a', ('imax', '#b', c
)), ('iand', ('ige', a
, b
), ('ige', a
, c
))),
708 (('ige', ('imin', '#a', b
), '#c'), ('iand', ('ige', a
, c
), ('ige', b
, c
))),
709 (('ult', '#a', ('umin', '#b', c
)), ('iand', ('ult', a
, b
), ('ult', a
, c
))),
710 (('ult', ('umax', '#a', b
), '#c'), ('iand', ('ult', a
, c
), ('ult', b
, c
))),
711 (('uge', '#a', ('umax', '#b', c
)), ('iand', ('uge', a
, b
), ('uge', a
, c
))),
712 (('uge', ('umin', '#a', b
), '#c'), ('iand', ('uge', a
, c
), ('uge', b
, c
))),
714 # Thanks to sign extension, the ishr(a, b) is negative if and only if a is
716 (('bcsel', ('ilt', a
, 0), ('ineg', ('ishr', a
, b
)), ('ishr', a
, b
)),
717 ('iabs', ('ishr', a
, b
))),
718 (('iabs', ('ishr', ('iabs', a
), b
)), ('ishr', ('iabs', a
), b
)),
720 (('fabs', ('slt', a
, b
)), ('slt', a
, b
)),
721 (('fabs', ('sge', a
, b
)), ('sge', a
, b
)),
722 (('fabs', ('seq', a
, b
)), ('seq', a
, b
)),
723 (('fabs', ('sne', a
, b
)), ('sne', a
, b
)),
724 (('slt', a
, b
), ('b2f', ('flt', a
, b
)), 'options->lower_scmp'),
725 (('sge', a
, b
), ('b2f', ('fge', a
, b
)), 'options->lower_scmp'),
726 (('seq', a
, b
), ('b2f', ('feq', a
, b
)), 'options->lower_scmp'),
727 (('sne', a
, b
), ('b2f', ('fne', a
, b
)), 'options->lower_scmp'),
728 (('seq', ('seq', a
, b
), 1.0), ('seq', a
, b
)),
729 (('seq', ('sne', a
, b
), 1.0), ('sne', a
, b
)),
730 (('seq', ('slt', a
, b
), 1.0), ('slt', a
, b
)),
731 (('seq', ('sge', a
, b
), 1.0), ('sge', a
, b
)),
732 (('sne', ('seq', a
, b
), 0.0), ('seq', a
, b
)),
733 (('sne', ('sne', a
, b
), 0.0), ('sne', a
, b
)),
734 (('sne', ('slt', a
, b
), 0.0), ('slt', a
, b
)),
735 (('sne', ('sge', a
, b
), 0.0), ('sge', a
, b
)),
736 (('seq', ('seq', a
, b
), 0.0), ('sne', a
, b
)),
737 (('seq', ('sne', a
, b
), 0.0), ('seq', a
, b
)),
738 (('seq', ('slt', a
, b
), 0.0), ('sge', a
, b
)),
739 (('seq', ('sge', a
, b
), 0.0), ('slt', a
, b
)),
740 (('sne', ('seq', a
, b
), 1.0), ('sne', a
, b
)),
741 (('sne', ('sne', a
, b
), 1.0), ('seq', a
, b
)),
742 (('sne', ('slt', a
, b
), 1.0), ('sge', a
, b
)),
743 (('sne', ('sge', a
, b
), 1.0), ('slt', a
, b
)),
744 (('fall_equal2', a
, b
), ('fmin', ('seq', 'a.x', 'b.x'), ('seq', 'a.y', 'b.y')), 'options->lower_vector_cmp'),
745 (('fall_equal3', a
, b
), ('seq', ('fany_nequal3', a
, b
), 0.0), 'options->lower_vector_cmp'),
746 (('fall_equal4', a
, b
), ('seq', ('fany_nequal4', a
, b
), 0.0), 'options->lower_vector_cmp'),
747 (('fany_nequal2', a
, b
), ('fmax', ('sne', 'a.x', 'b.x'), ('sne', 'a.y', 'b.y')), 'options->lower_vector_cmp'),
748 (('fany_nequal3', a
, b
), ('fsat', ('fdot3', ('sne', a
, b
), ('sne', a
, b
))), 'options->lower_vector_cmp'),
749 (('fany_nequal4', a
, b
), ('fsat', ('fdot4', ('sne', a
, b
), ('sne', a
, b
))), 'options->lower_vector_cmp'),
750 (('fne', ('fneg', a
), a
), ('fne', a
, 0.0)),
751 (('feq', ('fneg', a
), a
), ('feq', a
, 0.0)),
753 (('imul', ('b2i', 'a@1'), ('b2i', 'b@1')), ('b2i', ('iand', a
, b
))),
754 (('fmul', ('b2f', 'a@1'), ('b2f', 'b@1')), ('b2f', ('iand', a
, b
))),
755 (('fsat', ('fadd', ('b2f', 'a@1'), ('b2f', 'b@1'))), ('b2f', ('ior', a
, b
))),
756 (('iand', 'a@bool32', 1.0), ('b2f', a
)),
757 # True/False are ~0 and 0 in NIR. b2i of True is 1, and -1 is ~0 (True).
758 (('ineg', ('b2i32', 'a@32')), a
),
759 (('flt', ('fneg', ('b2f', 'a@1')), 0), a
), # Generated by TGSI KILL_IF.
760 # Comparison with the same args. Note that these are not done for
761 # the float versions because NaN always returns false on float
763 (('ilt', a
, a
), False),
764 (('ige', a
, a
), True),
765 (('ieq', a
, a
), True),
766 (('ine', a
, a
), False),
767 (('ult', a
, a
), False),
768 (('uge', a
, a
), True),
769 # Logical and bit operations
771 (('iand', a
, ~
0), a
),
775 (('ior', a
, True), True),
778 (('inot', ('inot', a
)), a
),
779 (('ior', ('iand', a
, b
), b
), b
),
780 (('ior', ('ior', a
, b
), b
), ('ior', a
, b
)),
781 (('iand', ('ior', a
, b
), b
), b
),
782 (('iand', ('iand', a
, b
), b
), ('iand', a
, b
)),
784 (('iand', ('inot', a
), ('inot', b
)), ('inot', ('ior', a
, b
))),
785 (('ior', ('inot', a
), ('inot', b
)), ('inot', ('iand', a
, b
))),
786 # Shift optimizations
793 (('ior', ('ishl@16', a
, b
), ('ushr@16', a
, ('iadd', 16, ('ineg', b
)))), ('urol', a
, b
), '!options->lower_rotate'),
794 (('ior', ('ishl@16', a
, b
), ('ushr@16', a
, ('isub', 16, b
))), ('urol', a
, b
), '!options->lower_rotate'),
795 (('ior', ('ishl@32', a
, b
), ('ushr@32', a
, ('iadd', 32, ('ineg', b
)))), ('urol', a
, b
), '!options->lower_rotate'),
796 (('ior', ('ishl@32', a
, b
), ('ushr@32', a
, ('isub', 32, b
))), ('urol', a
, b
), '!options->lower_rotate'),
797 (('ior', ('ushr@16', a
, b
), ('ishl@16', a
, ('iadd', 16, ('ineg', b
)))), ('uror', a
, b
), '!options->lower_rotate'),
798 (('ior', ('ushr@16', a
, b
), ('ishl@16', a
, ('isub', 16, b
))), ('uror', a
, b
), '!options->lower_rotate'),
799 (('ior', ('ushr@32', a
, b
), ('ishl@32', a
, ('iadd', 32, ('ineg', b
)))), ('uror', a
, b
), '!options->lower_rotate'),
800 (('ior', ('ushr@32', a
, b
), ('ishl@32', a
, ('isub', 32, b
))), ('uror', a
, b
), '!options->lower_rotate'),
801 (('urol@16', a
, b
), ('ior', ('ishl', a
, b
), ('ushr', a
, ('isub', 16, b
))), 'options->lower_rotate'),
802 (('urol@32', a
, b
), ('ior', ('ishl', a
, b
), ('ushr', a
, ('isub', 32, b
))), 'options->lower_rotate'),
803 (('uror@16', a
, b
), ('ior', ('ushr', a
, b
), ('ishl', a
, ('isub', 16, b
))), 'options->lower_rotate'),
804 (('uror@32', a
, b
), ('ior', ('ushr', a
, b
), ('ishl', a
, ('isub', 32, b
))), 'options->lower_rotate'),
805 # Exponential/logarithmic identities
806 (('~fexp2', ('flog2', a
)), a
), # 2^lg2(a) = a
807 (('~flog2', ('fexp2', a
)), a
), # lg2(2^a) = a
808 (('fpow', a
, b
), ('fexp2', ('fmul', ('flog2', a
), b
)), 'options->lower_fpow'), # a^b = 2^(lg2(a)*b)
809 (('~fexp2', ('fmul', ('flog2', a
), b
)), ('fpow', a
, b
), '!options->lower_fpow'), # 2^(lg2(a)*b) = a^b
810 (('~fexp2', ('fadd', ('fmul', ('flog2', a
), b
), ('fmul', ('flog2', c
), d
))),
811 ('~fmul', ('fpow', a
, b
), ('fpow', c
, d
)), '!options->lower_fpow'), # 2^(lg2(a) * b + lg2(c) + d) = a^b * c^d
812 (('~fexp2', ('fmul', ('flog2', a
), 0.5)), ('fsqrt', a
)),
813 (('~fexp2', ('fmul', ('flog2', a
), 2.0)), ('fmul', a
, a
)),
814 (('~fexp2', ('fmul', ('flog2', a
), 4.0)), ('fmul', ('fmul', a
, a
), ('fmul', a
, a
))),
815 (('~fpow', a
, 1.0), a
),
816 (('~fpow', a
, 2.0), ('fmul', a
, a
)),
817 (('~fpow', a
, 4.0), ('fmul', ('fmul', a
, a
), ('fmul', a
, a
))),
818 (('~fpow', 2.0, a
), ('fexp2', a
)),
819 (('~fpow', ('fpow', a
, 2.2), 0.454545), a
),
820 (('~fpow', ('fabs', ('fpow', a
, 2.2)), 0.454545), ('fabs', a
)),
821 (('~fsqrt', ('fexp2', a
)), ('fexp2', ('fmul', 0.5, a
))),
822 (('~frcp', ('fexp2', a
)), ('fexp2', ('fneg', a
))),
823 (('~frsq', ('fexp2', a
)), ('fexp2', ('fmul', -0.5, a
))),
824 (('~flog2', ('fsqrt', a
)), ('fmul', 0.5, ('flog2', a
))),
825 (('~flog2', ('frcp', a
)), ('fneg', ('flog2', a
))),
826 (('~flog2', ('frsq', a
)), ('fmul', -0.5, ('flog2', a
))),
827 (('~flog2', ('fpow', a
, b
)), ('fmul', b
, ('flog2', a
))),
828 (('~fmul', ('fexp2(is_used_once)', a
), ('fexp2(is_used_once)', b
)), ('fexp2', ('fadd', a
, b
))),
829 (('bcsel', ('flt', a
, 0.0), 0.0, ('fsqrt', a
)), ('fsqrt', ('fmax', a
, 0.0))),
830 (('~fmul', ('fsqrt', a
), ('fsqrt', a
)), ('fabs',a
)),
831 # Division and reciprocal
832 (('~fdiv', 1.0, a
), ('frcp', a
)),
833 (('fdiv', a
, b
), ('fmul', a
, ('frcp', b
)), 'options->lower_fdiv'),
834 (('~frcp', ('frcp', a
)), a
),
835 (('~frcp', ('fsqrt', a
)), ('frsq', a
)),
836 (('fsqrt', a
), ('frcp', ('frsq', a
)), 'options->lower_fsqrt'),
837 (('~frcp', ('frsq', a
)), ('fsqrt', a
), '!options->lower_fsqrt'),
839 (('fsin', a
), lowered_sincos(0.5), 'options->lower_sincos'),
840 (('fcos', a
), lowered_sincos(0.75), 'options->lower_sincos'),
841 # Boolean simplifications
842 (('i2b32(is_used_by_if)', a
), ('ine32', a
, 0)),
843 (('i2b1(is_used_by_if)', a
), ('ine', a
, 0)),
844 (('ieq', a
, True), a
),
845 (('ine(is_not_used_by_if)', a
, True), ('inot', a
)),
846 (('ine', a
, False), a
),
847 (('ieq(is_not_used_by_if)', a
, False), ('inot', 'a')),
848 (('bcsel', a
, True, False), a
),
849 (('bcsel', a
, False, True), ('inot', a
)),
850 (('bcsel@32', a
, 1.0, 0.0), ('b2f', a
)),
851 (('bcsel@32', a
, 0.0, 1.0), ('b2f', ('inot', a
))),
852 (('bcsel@32', a
, -1.0, -0.0), ('fneg', ('b2f', a
))),
853 (('bcsel@32', a
, -0.0, -1.0), ('fneg', ('b2f', ('inot', a
)))),
854 (('bcsel', True, b
, c
), b
),
855 (('bcsel', False, b
, c
), c
),
856 (('bcsel', a
, ('b2f(is_used_once)', 'b@32'), ('b2f', 'c@32')), ('b2f', ('bcsel', a
, b
, c
))),
858 (('bcsel', a
, b
, b
), b
),
859 (('~fcsel', a
, b
, b
), b
),
861 # D3D Boolean emulation
862 (('bcsel', a
, -1, 0), ('ineg', ('b2i', 'a@1'))),
863 (('bcsel', a
, 0, -1), ('ineg', ('b2i', ('inot', a
)))),
864 (('bcsel', a
, 1, 0), ('b2i', 'a@1')),
865 (('bcsel', a
, 0, 1), ('b2i', ('inot', a
))),
866 (('iand', ('ineg', ('b2i', 'a@1')), ('ineg', ('b2i', 'b@1'))),
867 ('ineg', ('b2i', ('iand', a
, b
)))),
868 (('ior', ('ineg', ('b2i','a@1')), ('ineg', ('b2i', 'b@1'))),
869 ('ineg', ('b2i', ('ior', a
, b
)))),
870 (('ieq', ('ineg', ('b2i', 'a@1')), 0), ('inot', a
)),
871 (('ieq', ('ineg', ('b2i', 'a@1')), -1), a
),
872 (('ine', ('ineg', ('b2i', 'a@1')), 0), a
),
873 (('ine', ('ineg', ('b2i', 'a@1')), -1), ('inot', a
)),
874 (('iand', ('ineg', ('b2i', a
)), 1.0), ('b2f', a
)),
875 (('iand', ('ineg', ('b2i', a
)), 1), ('b2i', a
)),
877 # SM5 32-bit shifts are defined to use the 5 least significant bits
878 (('ishl', 'a@32', ('iand', 31, b
)), ('ishl', a
, b
)),
879 (('ishr', 'a@32', ('iand', 31, b
)), ('ishr', a
, b
)),
880 (('ushr', 'a@32', ('iand', 31, b
)), ('ushr', a
, b
)),
883 (('i2b32', ('b2i', 'a@32')), a
),
884 (('f2i', ('ftrunc', a
)), ('f2i', a
)),
885 (('f2u', ('ftrunc', a
)), ('f2u', a
)),
886 (('i2b', ('ineg', a
)), ('i2b', a
)),
887 (('i2b', ('iabs', a
)), ('i2b', a
)),
888 (('inot', ('f2b1', a
)), ('feq', a
, 0.0)),
890 # The C spec says, "If the value of the integral part cannot be represented
891 # by the integer type, the behavior is undefined." "Undefined" can mean
892 # "the conversion doesn't happen at all."
893 (('~i2f32', ('f2i32', 'a@32')), ('ftrunc', a
)),
895 # Ironically, mark these as imprecise because removing the conversions may
896 # preserve more precision than doing the conversions (e.g.,
897 # uint(float(0x81818181u)) == 0x81818200).
898 (('~f2i32', ('i2f', 'a@32')), a
),
899 (('~f2i32', ('u2f', 'a@32')), a
),
900 (('~f2u32', ('i2f', 'a@32')), a
),
901 (('~f2u32', ('u2f', 'a@32')), a
),
903 # Conversions from 16 bits to 32 bits and back can always be removed
904 (('f2f16', ('f2f32', 'a@16')), a
),
905 (('f2fmp', ('f2f32', 'a@16')), a
),
906 (('i2i16', ('i2i32', 'a@16')), a
),
907 (('i2imp', ('i2i32', 'a@16')), a
),
908 (('u2u16', ('u2u32', 'a@16')), a
),
909 (('u2ump', ('u2u32', 'a@16')), a
),
910 (('f2f16', ('b2f32', 'a@1')), ('b2f16', a
)),
911 (('f2fmp', ('b2f32', 'a@1')), ('b2f16', a
)),
912 (('i2i16', ('b2i32', 'a@1')), ('b2i16', a
)),
913 (('i2imp', ('b2i32', 'a@1')), ('b2i16', a
)),
914 (('u2u16', ('b2i32', 'a@1')), ('b2i16', a
)),
915 (('u2ump', ('b2i32', 'a@1')), ('b2i16', a
)),
916 # Conversions to 16 bits would be lossy so they should only be removed if
917 # the instruction was generated by the precision lowering pass.
918 (('f2f32', ('f2fmp', 'a@32')), a
),
919 (('i2i32', ('i2imp', 'a@32')), a
),
920 (('u2u32', ('u2ump', 'a@32')), a
),
922 (('ffloor', 'a(is_integral)'), a
),
923 (('fceil', 'a(is_integral)'), a
),
924 (('ftrunc', 'a(is_integral)'), a
),
925 # fract(x) = x - floor(x), so fract(NaN) = NaN
926 (('~ffract', 'a(is_integral)'), 0.0),
927 (('fabs', 'a(is_not_negative)'), a
),
928 (('iabs', 'a(is_not_negative)'), a
),
929 (('fsat', 'a(is_not_positive)'), 0.0),
931 # Section 5.4.1 (Conversion and Scalar Constructors) of the GLSL 4.60 spec
934 # It is undefined to convert a negative floating-point value to an
937 # Assuming that (uint)some_float behaves like (uint)(int)some_float allows
938 # some optimizations in the i965 backend to proceed.
939 (('ige', ('f2u', a
), b
), ('ige', ('f2i', a
), b
)),
940 (('ige', b
, ('f2u', a
)), ('ige', b
, ('f2i', a
))),
941 (('ilt', ('f2u', a
), b
), ('ilt', ('f2i', a
), b
)),
942 (('ilt', b
, ('f2u', a
)), ('ilt', b
, ('f2i', a
))),
944 (('~fmin', 'a(is_not_negative)', 1.0), ('fsat', a
), '!options->lower_fsat'),
946 # The result of the multiply must be in [-1, 0], so the result of the ffma
948 (('flt', ('fadd', ('fmul', ('fsat', a
), ('fneg', ('fsat', a
))), 1.0), 0.0), False),
949 (('flt', ('fadd', ('fneg', ('fmul', ('fsat', a
), ('fsat', a
))), 1.0), 0.0), False),
950 (('fmax', ('fadd', ('fmul', ('fsat', a
), ('fneg', ('fsat', a
))), 1.0), 0.0), ('fadd', ('fmul', ('fsat', a
), ('fneg', ('fsat', a
))), 1.0)),
951 (('fmax', ('fadd', ('fneg', ('fmul', ('fsat', a
), ('fsat', a
))), 1.0), 0.0), ('fadd', ('fneg', ('fmul', ('fsat', a
), ('fsat', a
))), 1.0)),
953 (('fne', 'a(is_not_zero)', 0.0), True),
954 (('feq', 'a(is_not_zero)', 0.0), False),
956 # In this chart, + means value > 0 and - means value < 0.
958 # + >= + -> unknown 0 >= + -> false - >= + -> false
959 # + >= 0 -> true 0 >= 0 -> true - >= 0 -> false
960 # + >= - -> true 0 >= - -> true - >= - -> unknown
962 # Using grouping conceptually similar to a Karnaugh map...
964 # (+ >= 0, + >= -, 0 >= 0, 0 >= -) == (is_not_negative >= is_not_positive) -> true
965 # (0 >= +, - >= +) == (is_not_positive >= gt_zero) -> false
966 # (- >= +, - >= 0) == (lt_zero >= is_not_negative) -> false
968 # The flt / ilt cases just invert the expected result.
970 # The results expecting true, must be marked imprecise. The results
971 # expecting false are fine because NaN compared >= or < anything is false.
973 (('~fge', 'a(is_not_negative)', 'b(is_not_positive)'), True),
974 (('fge', 'a(is_not_positive)', 'b(is_gt_zero)'), False),
975 (('fge', 'a(is_lt_zero)', 'b(is_not_negative)'), False),
977 (('flt', 'a(is_not_negative)', 'b(is_not_positive)'), False),
978 (('~flt', 'a(is_not_positive)', 'b(is_gt_zero)'), True),
979 (('~flt', 'a(is_lt_zero)', 'b(is_not_negative)'), True),
981 (('ine', 'a(is_not_zero)', 0), True),
982 (('ieq', 'a(is_not_zero)', 0), False),
984 (('ige', 'a(is_not_negative)', 'b(is_not_positive)'), True),
985 (('ige', 'a(is_not_positive)', 'b(is_gt_zero)'), False),
986 (('ige', 'a(is_lt_zero)', 'b(is_not_negative)'), False),
988 (('ilt', 'a(is_not_negative)', 'b(is_not_positive)'), False),
989 (('ilt', 'a(is_not_positive)', 'b(is_gt_zero)'), True),
990 (('ilt', 'a(is_lt_zero)', 'b(is_not_negative)'), True),
992 (('ult', 0, 'a(is_gt_zero)'), True),
993 (('ult', a
, 0), False),
995 # Packing and then unpacking does nothing
996 (('unpack_64_2x32_split_x', ('pack_64_2x32_split', a
, b
)), a
),
997 (('unpack_64_2x32_split_y', ('pack_64_2x32_split', a
, b
)), b
),
998 (('unpack_64_2x32', ('pack_64_2x32_split', a
, b
)), ('vec2', a
, b
)),
999 (('unpack_64_2x32', ('pack_64_2x32', a
)), a
),
1000 (('pack_64_2x32_split', ('unpack_64_2x32_split_x', a
),
1001 ('unpack_64_2x32_split_y', a
)), a
),
1002 (('pack_64_2x32', ('vec2', ('unpack_64_2x32_split_x', a
),
1003 ('unpack_64_2x32_split_y', a
))), a
),
1004 (('pack_64_2x32', ('unpack_64_2x32', a
)), a
),
1006 # Comparing two halves of an unpack separately. While this optimization
1007 # should be correct for non-constant values, it's less obvious that it's
1008 # useful in that case. For constant values, the pack will fold and we're
1009 # guaranteed to reduce the whole tree to one instruction.
1010 (('iand', ('ieq', ('unpack_32_2x16_split_x', a
), '#b'),
1011 ('ieq', ('unpack_32_2x16_split_y', a
), '#c')),
1012 ('ieq', a
, ('pack_32_2x16_split', b
, c
))),
1015 (('ushr', 'a@16', 8), ('extract_u8', a
, 1), '!options->lower_extract_byte'),
1016 (('ushr', 'a@32', 24), ('extract_u8', a
, 3), '!options->lower_extract_byte'),
1017 (('ushr', 'a@64', 56), ('extract_u8', a
, 7), '!options->lower_extract_byte'),
1018 (('ishr', 'a@16', 8), ('extract_i8', a
, 1), '!options->lower_extract_byte'),
1019 (('ishr', 'a@32', 24), ('extract_i8', a
, 3), '!options->lower_extract_byte'),
1020 (('ishr', 'a@64', 56), ('extract_i8', a
, 7), '!options->lower_extract_byte'),
1021 (('iand', 0xff, a
), ('extract_u8', a
, 0), '!options->lower_extract_byte'),
1023 (('ubfe', a
, 0, 8), ('extract_u8', a
, 0), '!options->lower_extract_byte'),
1024 (('ubfe', a
, 8, 8), ('extract_u8', a
, 1), '!options->lower_extract_byte'),
1025 (('ubfe', a
, 16, 8), ('extract_u8', a
, 2), '!options->lower_extract_byte'),
1026 (('ubfe', a
, 24, 8), ('extract_u8', a
, 3), '!options->lower_extract_byte'),
1027 (('ibfe', a
, 0, 8), ('extract_i8', a
, 0), '!options->lower_extract_byte'),
1028 (('ibfe', a
, 8, 8), ('extract_i8', a
, 1), '!options->lower_extract_byte'),
1029 (('ibfe', a
, 16, 8), ('extract_i8', a
, 2), '!options->lower_extract_byte'),
1030 (('ibfe', a
, 24, 8), ('extract_i8', a
, 3), '!options->lower_extract_byte'),
1033 (('ushr', ('ishl', 'a@32', 16), 16), ('extract_u16', a
, 0), '!options->lower_extract_word'),
1034 (('ushr', 'a@32', 16), ('extract_u16', a
, 1), '!options->lower_extract_word'),
1035 (('ishr', ('ishl', 'a@32', 16), 16), ('extract_i16', a
, 0), '!options->lower_extract_word'),
1036 (('ishr', 'a@32', 16), ('extract_i16', a
, 1), '!options->lower_extract_word'),
1037 (('iand', 0xffff, a
), ('extract_u16', a
, 0), '!options->lower_extract_word'),
1039 (('ubfe', a
, 0, 16), ('extract_u16', a
, 0), '!options->lower_extract_word'),
1040 (('ubfe', a
, 16, 16), ('extract_u16', a
, 1), '!options->lower_extract_word'),
1041 (('ibfe', a
, 0, 16), ('extract_i16', a
, 0), '!options->lower_extract_word'),
1042 (('ibfe', a
, 16, 16), ('extract_i16', a
, 1), '!options->lower_extract_word'),
1044 # Useless masking before unpacking
1045 (('unpack_half_2x16_split_x', ('iand', a
, 0xffff)), ('unpack_half_2x16_split_x', a
)),
1046 (('unpack_32_2x16_split_x', ('iand', a
, 0xffff)), ('unpack_32_2x16_split_x', a
)),
1047 (('unpack_64_2x32_split_x', ('iand', a
, 0xffffffff)), ('unpack_64_2x32_split_x', a
)),
1048 (('unpack_half_2x16_split_y', ('iand', a
, 0xffff0000)), ('unpack_half_2x16_split_y', a
)),
1049 (('unpack_32_2x16_split_y', ('iand', a
, 0xffff0000)), ('unpack_32_2x16_split_y', a
)),
1050 (('unpack_64_2x32_split_y', ('iand', a
, 0xffffffff00000000)), ('unpack_64_2x32_split_y', a
)),
1052 (('unpack_half_2x16_split_x', ('extract_u16', a
, 0)), ('unpack_half_2x16_split_x', a
)),
1053 (('unpack_half_2x16_split_x', ('extract_u16', a
, 1)), ('unpack_half_2x16_split_y', a
)),
1054 (('unpack_32_2x16_split_x', ('extract_u16', a
, 0)), ('unpack_32_2x16_split_x', a
)),
1055 (('unpack_32_2x16_split_x', ('extract_u16', a
, 1)), ('unpack_32_2x16_split_y', a
)),
1057 # Optimize half packing
1058 (('ishl', ('pack_half_2x16', ('vec2', a
, 0)), 16), ('pack_half_2x16', ('vec2', 0, a
))),
1059 (('ushr', ('pack_half_2x16', ('vec2', 0, a
)), 16), ('pack_half_2x16', ('vec2', a
, 0))),
1061 (('iadd', ('pack_half_2x16', ('vec2', a
, 0)), ('pack_half_2x16', ('vec2', 0, b
))),
1062 ('pack_half_2x16', ('vec2', a
, b
))),
1063 (('ior', ('pack_half_2x16', ('vec2', a
, 0)), ('pack_half_2x16', ('vec2', 0, b
))),
1064 ('pack_half_2x16', ('vec2', a
, b
))),
1066 (('ishl', ('pack_half_2x16_split', a
, 0), 16), ('pack_half_2x16_split', 0, a
)),
1067 (('ushr', ('pack_half_2x16_split', 0, a
), 16), ('pack_half_2x16_split', a
, 0)),
1068 (('extract_u16', ('pack_half_2x16_split', 0, a
), 1), ('pack_half_2x16_split', a
, 0)),
1070 (('iadd', ('pack_half_2x16_split', a
, 0), ('pack_half_2x16_split', 0, b
)), ('pack_half_2x16_split', a
, b
)),
1071 (('ior', ('pack_half_2x16_split', a
, 0), ('pack_half_2x16_split', 0, b
)), ('pack_half_2x16_split', a
, b
)),
1074 # After the ('extract_u8', a, 0) pattern, above, triggers, there will be
1075 # patterns like those below.
1076 for op
in ('ushr', 'ishr'):
1077 optimizations
.extend([(('extract_u8', (op
, 'a@16', 8), 0), ('extract_u8', a
, 1))])
1078 optimizations
.extend([(('extract_u8', (op
, 'a@32', 8 * i
), 0), ('extract_u8', a
, i
)) for i
in range(1, 4)])
1079 optimizations
.extend([(('extract_u8', (op
, 'a@64', 8 * i
), 0), ('extract_u8', a
, i
)) for i
in range(1, 8)])
1081 optimizations
.extend([(('extract_u8', ('extract_u16', a
, 1), 0), ('extract_u8', a
, 2))])
1083 # After the ('extract_[iu]8', a, 3) patterns, above, trigger, there will be
1084 # patterns like those below.
1085 for op
in ('extract_u8', 'extract_i8'):
1086 optimizations
.extend([((op
, ('ishl', 'a@16', 8), 1), (op
, a
, 0))])
1087 optimizations
.extend([((op
, ('ishl', 'a@32', 24 - 8 * i
), 3), (op
, a
, i
)) for i
in range(2, -1, -1)])
1088 optimizations
.extend([((op
, ('ishl', 'a@64', 56 - 8 * i
), 7), (op
, a
, i
)) for i
in range(6, -1, -1)])
1090 optimizations
.extend([
1092 (('ussub_4x8', a
, 0), a
),
1093 (('ussub_4x8', a
, ~
0), 0),
1094 # Lower all Subtractions first - they can get recombined later
1095 (('fsub', a
, b
), ('fadd', a
, ('fneg', b
))),
1096 (('isub', a
, b
), ('iadd', a
, ('ineg', b
))),
1097 (('uabs_usub', a
, b
), ('bcsel', ('ult', a
, b
), ('ineg', ('isub', a
, b
)), ('isub', a
, b
))),
1098 # This is correct. We don't need isub_sat because the result type is unsigned, so it cannot overflow.
1099 (('uabs_isub', a
, b
), ('bcsel', ('ilt', a
, b
), ('ineg', ('isub', a
, b
)), ('isub', a
, b
))),
1101 # Propagate negation up multiplication chains
1102 (('fmul(is_used_by_non_fsat)', ('fneg', a
), b
), ('fneg', ('fmul', a
, b
))),
1103 (('imul', ('ineg', a
), b
), ('ineg', ('imul', a
, b
))),
1105 # Propagate constants up multiplication chains
1106 (('~fmul(is_used_once)', ('fmul(is_used_once)', 'a(is_not_const)', 'b(is_not_const)'), '#c'), ('fmul', ('fmul', a
, c
), b
)),
1107 (('imul(is_used_once)', ('imul(is_used_once)', 'a(is_not_const)', 'b(is_not_const)'), '#c'), ('imul', ('imul', a
, c
), b
)),
1108 (('~fadd(is_used_once)', ('fadd(is_used_once)', 'a(is_not_const)', 'b(is_not_const)'), '#c'), ('fadd', ('fadd', a
, c
), b
)),
1109 (('iadd(is_used_once)', ('iadd(is_used_once)', 'a(is_not_const)', 'b(is_not_const)'), '#c'), ('iadd', ('iadd', a
, c
), b
)),
1111 # Reassociate constants in add/mul chains so they can be folded together.
1112 # For now, we mostly only handle cases where the constants are separated by
1113 # a single non-constant. We could do better eventually.
1114 (('~fmul', '#a', ('fmul', 'b(is_not_const)', '#c')), ('fmul', ('fmul', a
, c
), b
)),
1115 (('imul', '#a', ('imul', 'b(is_not_const)', '#c')), ('imul', ('imul', a
, c
), b
)),
1116 (('~fadd', '#a', ('fadd', 'b(is_not_const)', '#c')), ('fadd', ('fadd', a
, c
), b
)),
1117 (('~fadd', '#a', ('fneg', ('fadd', 'b(is_not_const)', '#c'))), ('fadd', ('fadd', a
, ('fneg', c
)), ('fneg', b
))),
1118 (('iadd', '#a', ('iadd', 'b(is_not_const)', '#c')), ('iadd', ('iadd', a
, c
), b
)),
1119 (('iand', '#a', ('iand', 'b(is_not_const)', '#c')), ('iand', ('iand', a
, c
), b
)),
1120 (('ior', '#a', ('ior', 'b(is_not_const)', '#c')), ('ior', ('ior', a
, c
), b
)),
1121 (('ixor', '#a', ('ixor', 'b(is_not_const)', '#c')), ('ixor', ('ixor', a
, c
), b
)),
1123 # Drop mul-div by the same value when there's no wrapping.
1124 (('idiv', ('imul(no_signed_wrap)', a
, b
), b
), a
),
1127 (('bcsel', ('ige', ('find_lsb', a
), 0), ('find_lsb', a
), -1), ('find_lsb', a
)),
1128 (('bcsel', ('ige', ('ifind_msb', a
), 0), ('ifind_msb', a
), -1), ('ifind_msb', a
)),
1129 (('bcsel', ('ige', ('ufind_msb', a
), 0), ('ufind_msb', a
), -1), ('ufind_msb', a
)),
1131 (('bcsel', ('ine', a
, 0), ('find_lsb', a
), -1), ('find_lsb', a
)),
1132 (('bcsel', ('ine', a
, 0), ('ifind_msb', a
), -1), ('ifind_msb', a
)),
1133 (('bcsel', ('ine', a
, 0), ('ufind_msb', a
), -1), ('ufind_msb', a
)),
1135 (('bcsel', ('ine', a
, -1), ('ifind_msb', a
), -1), ('ifind_msb', a
)),
1137 (('~fmul', ('bcsel(is_used_once)', c
, -1.0, 1.0), b
), ('bcsel', c
, ('fneg', b
), b
)),
1138 (('~fmul', ('bcsel(is_used_once)', c
, 1.0, -1.0), b
), ('bcsel', c
, b
, ('fneg', b
))),
1140 (('fmin3@64', a
, b
, c
), ('fmin@64', a
, ('fmin@64', b
, c
))),
1141 (('fmax3@64', a
, b
, c
), ('fmax@64', a
, ('fmax@64', b
, c
))),
1142 (('fmed3@64', a
, b
, c
), ('fmax@64', ('fmin@64', ('fmax@64', a
, b
), c
), ('fmin@64', a
, b
))),
1145 (('fmod', a
, b
), ('fsub', a
, ('fmul', b
, ('ffloor', ('fdiv', a
, b
)))), 'options->lower_fmod'),
1146 (('frem', a
, b
), ('fsub', a
, ('fmul', b
, ('ftrunc', ('fdiv', a
, b
)))), 'options->lower_fmod'),
1147 (('uadd_carry@32', a
, b
), ('b2i', ('ult', ('iadd', a
, b
), a
)), 'options->lower_uadd_carry'),
1148 (('usub_borrow@32', a
, b
), ('b2i', ('ult', a
, b
)), 'options->lower_usub_borrow'),
1150 (('bitfield_insert', 'base', 'insert', 'offset', 'bits'),
1151 ('bcsel', ('ult', 31, 'bits'), 'insert',
1152 ('bfi', ('bfm', 'bits', 'offset'), 'insert', 'base')),
1153 'options->lower_bitfield_insert'),
1154 (('ihadd', a
, b
), ('iadd', ('iand', a
, b
), ('ishr', ('ixor', a
, b
), 1)), 'options->lower_hadd'),
1155 (('uhadd', a
, b
), ('iadd', ('iand', a
, b
), ('ushr', ('ixor', a
, b
), 1)), 'options->lower_hadd'),
1156 (('irhadd', a
, b
), ('isub', ('ior', a
, b
), ('ishr', ('ixor', a
, b
), 1)), 'options->lower_hadd'),
1157 (('urhadd', a
, b
), ('isub', ('ior', a
, b
), ('ushr', ('ixor', a
, b
), 1)), 'options->lower_hadd'),
1158 (('ihadd@64', a
, b
), ('iadd', ('iand', a
, b
), ('ishr', ('ixor', a
, b
), 1)), 'options->lower_hadd64 || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1159 (('uhadd@64', a
, b
), ('iadd', ('iand', a
, b
), ('ushr', ('ixor', a
, b
), 1)), 'options->lower_hadd64 || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1160 (('irhadd@64', a
, b
), ('isub', ('ior', a
, b
), ('ishr', ('ixor', a
, b
), 1)), 'options->lower_hadd64 || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1161 (('urhadd@64', a
, b
), ('isub', ('ior', a
, b
), ('ushr', ('ixor', a
, b
), 1)), 'options->lower_hadd64 || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1163 (('uadd_sat@64', a
, b
), ('bcsel', ('ult', ('iadd', a
, b
), a
), -1, ('iadd', a
, b
)), 'options->lower_add_sat || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1164 (('uadd_sat', a
, b
), ('bcsel', ('ult', ('iadd', a
, b
), a
), -1, ('iadd', a
, b
)), 'options->lower_add_sat'),
1165 (('usub_sat', a
, b
), ('bcsel', ('ult', a
, b
), 0, ('isub', a
, b
)), 'options->lower_add_sat'),
1166 (('usub_sat@64', a
, b
), ('bcsel', ('ult', a
, b
), 0, ('isub', a
, b
)), 'options->lower_usub_sat64 || (options->lower_int64_options & nir_lower_iadd64) != 0'),
1168 # int64_t sum = a + b;
1170 # if (a < 0 && b < 0 && a < sum)
1172 # } else if (a >= 0 && b >= 0 && sum < a)
1176 # A couple optimizations are applied.
1178 # 1. a < sum => sum >= 0. This replacement works because it is known that
1179 # a < 0 and b < 0, so sum should also be < 0 unless there was
1182 # 2. sum < a => sum < 0. This replacement works because it is known that
1183 # a >= 0 and b >= 0, so sum should also be >= 0 unless there was
1186 # 3. Invert the second if-condition and swap the order of parameters for
1187 # the bcsel. !(a >= 0 && b >= 0 && sum < 0) becomes !(a >= 0) || !(b >=
1188 # 0) || !(sum < 0), and that becomes (a < 0) || (b < 0) || (sum >= 0)
1190 # On Intel Gen11, this saves ~11 instructions.
1191 (('iadd_sat@64', a
, b
), ('bcsel',
1192 ('iand', ('iand', ('ilt', a
, 0), ('ilt', b
, 0)), ('ige', ('iadd', a
, b
), 0)),
1195 ('ior', ('ior', ('ilt', a
, 0), ('ilt', b
, 0)), ('ige', ('iadd', a
, b
), 0)),
1197 0x7fffffffffffffff)),
1198 '(options->lower_int64_options & nir_lower_iadd64) != 0'),
1200 # int64_t sum = a - b;
1202 # if (a < 0 && b >= 0 && a < sum)
1204 # } else if (a >= 0 && b < 0 && a >= sum)
1208 # Optimizations similar to the iadd_sat case are applied here.
1209 (('isub_sat@64', a
, b
), ('bcsel',
1210 ('iand', ('iand', ('ilt', a
, 0), ('ige', b
, 0)), ('ige', ('isub', a
, b
), 0)),
1213 ('ior', ('ior', ('ilt', a
, 0), ('ige', b
, 0)), ('ige', ('isub', a
, b
), 0)),
1215 0x7fffffffffffffff)),
1216 '(options->lower_int64_options & nir_lower_iadd64) != 0'),
1218 # These are done here instead of in the backend because the int64 lowering
1219 # pass will make a mess of the patterns. The first patterns are
1220 # conditioned on nir_lower_minmax64 because it was not clear that it was
1221 # always an improvement on platforms that have real int64 support. No
1222 # shaders in shader-db hit this, so it was hard to say one way or the
1224 (('ilt', ('imax(is_used_once)', 'a@64', 'b@64'), 0), ('ilt', ('imax', ('unpack_64_2x32_split_y', a
), ('unpack_64_2x32_split_y', b
)), 0), '(options->lower_int64_options & nir_lower_minmax64) != 0'),
1225 (('ilt', ('imin(is_used_once)', 'a@64', 'b@64'), 0), ('ilt', ('imin', ('unpack_64_2x32_split_y', a
), ('unpack_64_2x32_split_y', b
)), 0), '(options->lower_int64_options & nir_lower_minmax64) != 0'),
1226 (('ige', ('imax(is_used_once)', 'a@64', 'b@64'), 0), ('ige', ('imax', ('unpack_64_2x32_split_y', a
), ('unpack_64_2x32_split_y', b
)), 0), '(options->lower_int64_options & nir_lower_minmax64) != 0'),
1227 (('ige', ('imin(is_used_once)', 'a@64', 'b@64'), 0), ('ige', ('imin', ('unpack_64_2x32_split_y', a
), ('unpack_64_2x32_split_y', b
)), 0), '(options->lower_int64_options & nir_lower_minmax64) != 0'),
1228 (('ilt', 'a@64', 0), ('ilt', ('unpack_64_2x32_split_y', a
), 0), '(options->lower_int64_options & nir_lower_icmp64) != 0'),
1229 (('ige', 'a@64', 0), ('ige', ('unpack_64_2x32_split_y', a
), 0), '(options->lower_int64_options & nir_lower_icmp64) != 0'),
1231 (('ine', 'a@64', 0), ('ine', ('ior', ('unpack_64_2x32_split_x', a
), ('unpack_64_2x32_split_y', a
)), 0), '(options->lower_int64_options & nir_lower_icmp64) != 0'),
1232 (('ieq', 'a@64', 0), ('ieq', ('ior', ('unpack_64_2x32_split_x', a
), ('unpack_64_2x32_split_y', a
)), 0), '(options->lower_int64_options & nir_lower_icmp64) != 0'),
1233 # 0u < uint(a) <=> uint(a) != 0u
1234 (('ult', 0, 'a@64'), ('ine', ('ior', ('unpack_64_2x32_split_x', a
), ('unpack_64_2x32_split_y', a
)), 0), '(options->lower_int64_options & nir_lower_icmp64) != 0'),
1236 # Alternative lowering that doesn't rely on bfi.
1237 (('bitfield_insert', 'base', 'insert', 'offset', 'bits'),
1238 ('bcsel', ('ult', 31, 'bits'),
1241 ('iand', 'base', ('inot', ('ishl', ('isub', ('ishl', 1, 'bits'), 1), 'offset'))),
1242 ('iand', ('ishl', 'insert', 'offset'), ('ishl', ('isub', ('ishl', 1, 'bits'), 1), 'offset'))))),
1243 'options->lower_bitfield_insert_to_shifts'),
1245 # Alternative lowering that uses bitfield_select.
1246 (('bitfield_insert', 'base', 'insert', 'offset', 'bits'),
1247 ('bcsel', ('ult', 31, 'bits'), 'insert',
1248 ('bitfield_select', ('bfm', 'bits', 'offset'), ('ishl', 'insert', 'offset'), 'base')),
1249 'options->lower_bitfield_insert_to_bitfield_select'),
1251 (('ibitfield_extract', 'value', 'offset', 'bits'),
1252 ('bcsel', ('ult', 31, 'bits'), 'value',
1253 ('ibfe', 'value', 'offset', 'bits')),
1254 'options->lower_bitfield_extract'),
1256 (('ubitfield_extract', 'value', 'offset', 'bits'),
1257 ('bcsel', ('ult', 31, 'bits'), 'value',
1258 ('ubfe', 'value', 'offset', 'bits')),
1259 'options->lower_bitfield_extract'),
1261 # Note that these opcodes are defined to only use the five least significant bits of 'offset' and 'bits'
1262 (('ubfe', 'value', 'offset', ('iand', 31, 'bits')), ('ubfe', 'value', 'offset', 'bits')),
1263 (('ubfe', 'value', ('iand', 31, 'offset'), 'bits'), ('ubfe', 'value', 'offset', 'bits')),
1264 (('ibfe', 'value', 'offset', ('iand', 31, 'bits')), ('ibfe', 'value', 'offset', 'bits')),
1265 (('ibfe', 'value', ('iand', 31, 'offset'), 'bits'), ('ibfe', 'value', 'offset', 'bits')),
1266 (('bfm', 'bits', ('iand', 31, 'offset')), ('bfm', 'bits', 'offset')),
1267 (('bfm', ('iand', 31, 'bits'), 'offset'), ('bfm', 'bits', 'offset')),
1269 # Section 8.8 (Integer Functions) of the GLSL 4.60 spec says:
1271 # If bits is zero, the result will be zero.
1273 # These patterns prevent other patterns from generating invalid results
1274 # when count is zero.
1275 (('ubfe', a
, b
, 0), 0),
1276 (('ibfe', a
, b
, 0), 0),
1278 (('ubfe', a
, 0, '#b'), ('iand', a
, ('ushr', 0xffffffff, ('ineg', b
)))),
1280 (('b2i32', ('i2b', ('ubfe', a
, b
, 1))), ('ubfe', a
, b
, 1)),
1281 (('b2i32', ('i2b', ('ibfe', a
, b
, 1))), ('ubfe', a
, b
, 1)), # ubfe in the replacement is correct
1282 (('ine', ('ibfe(is_used_once)', a
, '#b', '#c'), 0), ('ine', ('iand', a
, ('ishl', ('ushr', 0xffffffff, ('ineg', c
)), b
)), 0)),
1283 (('ieq', ('ibfe(is_used_once)', a
, '#b', '#c'), 0), ('ieq', ('iand', a
, ('ishl', ('ushr', 0xffffffff, ('ineg', c
)), b
)), 0)),
1284 (('ine', ('ubfe(is_used_once)', a
, '#b', '#c'), 0), ('ine', ('iand', a
, ('ishl', ('ushr', 0xffffffff, ('ineg', c
)), b
)), 0)),
1285 (('ieq', ('ubfe(is_used_once)', a
, '#b', '#c'), 0), ('ieq', ('iand', a
, ('ishl', ('ushr', 0xffffffff, ('ineg', c
)), b
)), 0)),
1287 (('ibitfield_extract', 'value', 'offset', 'bits'),
1288 ('bcsel', ('ieq', 0, 'bits'),
1291 ('ishl', 'value', ('isub', ('isub', 32, 'bits'), 'offset')),
1292 ('isub', 32, 'bits'))),
1293 'options->lower_bitfield_extract_to_shifts'),
1295 (('ubitfield_extract', 'value', 'offset', 'bits'),
1297 ('ushr', 'value', 'offset'),
1298 ('bcsel', ('ieq', 'bits', 32),
1300 ('isub', ('ishl', 1, 'bits'), 1))),
1301 'options->lower_bitfield_extract_to_shifts'),
1303 (('ifind_msb', 'value'),
1304 ('ufind_msb', ('bcsel', ('ilt', 'value', 0), ('inot', 'value'), 'value')),
1305 'options->lower_ifind_msb'),
1307 (('find_lsb', 'value'),
1308 ('ufind_msb', ('iand', 'value', ('ineg', 'value'))),
1309 'options->lower_find_lsb'),
1311 (('extract_i8', a
, 'b@32'),
1312 ('ishr', ('ishl', a
, ('imul', ('isub', 3, b
), 8)), 24),
1313 'options->lower_extract_byte'),
1315 (('extract_u8', a
, 'b@32'),
1316 ('iand', ('ushr', a
, ('imul', b
, 8)), 0xff),
1317 'options->lower_extract_byte'),
1319 (('extract_i16', a
, 'b@32'),
1320 ('ishr', ('ishl', a
, ('imul', ('isub', 1, b
), 16)), 16),
1321 'options->lower_extract_word'),
1323 (('extract_u16', a
, 'b@32'),
1324 ('iand', ('ushr', a
, ('imul', b
, 16)), 0xffff),
1325 'options->lower_extract_word'),
1327 (('pack_unorm_2x16', 'v'),
1328 ('pack_uvec2_to_uint',
1329 ('f2u32', ('fround_even', ('fmul', ('fsat', 'v'), 65535.0)))),
1330 'options->lower_pack_unorm_2x16'),
1332 (('pack_unorm_4x8', 'v'),
1333 ('pack_uvec4_to_uint',
1334 ('f2u32', ('fround_even', ('fmul', ('fsat', 'v'), 255.0)))),
1335 'options->lower_pack_unorm_4x8'),
1337 (('pack_snorm_2x16', 'v'),
1338 ('pack_uvec2_to_uint',
1339 ('f2i32', ('fround_even', ('fmul', ('fmin', 1.0, ('fmax', -1.0, 'v')), 32767.0)))),
1340 'options->lower_pack_snorm_2x16'),
1342 (('pack_snorm_4x8', 'v'),
1343 ('pack_uvec4_to_uint',
1344 ('f2i32', ('fround_even', ('fmul', ('fmin', 1.0, ('fmax', -1.0, 'v')), 127.0)))),
1345 'options->lower_pack_snorm_4x8'),
1347 (('unpack_unorm_2x16', 'v'),
1348 ('fdiv', ('u2f32', ('vec2', ('extract_u16', 'v', 0),
1349 ('extract_u16', 'v', 1))),
1351 'options->lower_unpack_unorm_2x16'),
1353 (('unpack_unorm_4x8', 'v'),
1354 ('fdiv', ('u2f32', ('vec4', ('extract_u8', 'v', 0),
1355 ('extract_u8', 'v', 1),
1356 ('extract_u8', 'v', 2),
1357 ('extract_u8', 'v', 3))),
1359 'options->lower_unpack_unorm_4x8'),
1361 (('unpack_snorm_2x16', 'v'),
1362 ('fmin', 1.0, ('fmax', -1.0, ('fdiv', ('i2f', ('vec2', ('extract_i16', 'v', 0),
1363 ('extract_i16', 'v', 1))),
1365 'options->lower_unpack_snorm_2x16'),
1367 (('unpack_snorm_4x8', 'v'),
1368 ('fmin', 1.0, ('fmax', -1.0, ('fdiv', ('i2f', ('vec4', ('extract_i8', 'v', 0),
1369 ('extract_i8', 'v', 1),
1370 ('extract_i8', 'v', 2),
1371 ('extract_i8', 'v', 3))),
1373 'options->lower_unpack_snorm_4x8'),
1375 (('pack_half_2x16_split', 'a@32', 'b@32'),
1376 ('ior', ('ishl', ('u2u32', ('f2f16', b
)), 16), ('u2u32', ('f2f16', a
))),
1377 'options->lower_pack_split'),
1379 (('unpack_half_2x16_split_x', 'a@32'),
1380 ('f2f32', ('u2u16', a
)),
1381 'options->lower_pack_split'),
1383 (('unpack_half_2x16_split_y', 'a@32'),
1384 ('f2f32', ('u2u16', ('ushr', a
, 16))),
1385 'options->lower_pack_split'),
1387 (('pack_32_2x16_split', 'a@16', 'b@16'),
1388 ('ior', ('ishl', ('u2u32', b
), 16), ('u2u32', a
)),
1389 'options->lower_pack_split'),
1391 (('unpack_32_2x16_split_x', 'a@32'),
1393 'options->lower_pack_split'),
1395 (('unpack_32_2x16_split_y', 'a@32'),
1396 ('u2u16', ('ushr', 'a', 16)),
1397 'options->lower_pack_split'),
1399 (('isign', a
), ('imin', ('imax', a
, -1), 1), 'options->lower_isign'),
1400 (('imin', ('imax', a
, -1), 1), ('isign', a
), '!options->lower_isign'),
1401 (('imax', ('imin', a
, 1), -1), ('isign', a
), '!options->lower_isign'),
1402 (('fsign', a
), ('fsub', ('b2f', ('flt', 0.0, a
)), ('b2f', ('flt', a
, 0.0))), 'options->lower_fsign'),
1403 (('fadd', ('b2f32', ('flt', 0.0, 'a@32')), ('fneg', ('b2f32', ('flt', 'a@32', 0.0)))), ('fsign', a
), '!options->lower_fsign'),
1404 (('iadd', ('b2i32', ('flt', 0, 'a@32')), ('ineg', ('b2i32', ('flt', 'a@32', 0)))), ('f2i32', ('fsign', a
)), '!options->lower_fsign'),
1406 # Address/offset calculations:
1407 # Drivers supporting imul24 should use the nir_lower_amul() pass, this
1408 # rule converts everyone else to imul:
1409 (('amul', a
, b
), ('imul', a
, b
), '!options->has_imul24'),
1412 ('imul', ('iand', a
, 0xffffff), ('iand', b
, 0xffffff)),
1413 '!options->has_umul24'),
1414 (('umad24', a
, b
, c
),
1415 ('iadd', ('imul', ('iand', a
, 0xffffff), ('iand', b
, 0xffffff)), c
),
1416 '!options->has_umad24'),
1418 (('imad24_ir3', a
, b
, 0), ('imul24', a
, b
)),
1419 (('imad24_ir3', a
, 0, c
), (c
)),
1420 (('imad24_ir3', a
, 1, c
), ('iadd', a
, c
)),
1422 # if first two srcs are const, crack apart the imad so constant folding
1423 # can clean up the imul:
1424 # TODO ffma should probably get a similar rule:
1425 (('imad24_ir3', '#a', '#b', c
), ('iadd', ('imul', a
, b
), c
)),
1427 # These will turn 24b address/offset calc back into 32b shifts, but
1428 # it should be safe to get back some of the bits of precision that we
1429 # already decided were no necessary:
1430 (('imul24', a
, '#b@32(is_pos_power_of_two)'), ('ishl', a
, ('find_lsb', b
)), '!options->lower_bitops'),
1431 (('imul24', a
, '#b@32(is_neg_power_of_two)'), ('ineg', ('ishl', a
, ('find_lsb', ('iabs', b
)))), '!options->lower_bitops'),
1432 (('imul24', a
, 0), (0)),
1435 # bit_size dependent lowerings
1436 for bit_size
in [8, 16, 32, 64]:
1437 # convenience constants
1438 intmax
= (1 << (bit_size
- 1)) - 1
1439 intmin
= 1 << (bit_size
- 1)
1442 (('iadd_sat@' + str(bit_size
), a
, b
),
1443 ('bcsel', ('ige', b
, 1), ('bcsel', ('ilt', ('iadd', a
, b
), a
), intmax
, ('iadd', a
, b
)),
1444 ('bcsel', ('ilt', a
, ('iadd', a
, b
)), intmin
, ('iadd', a
, b
))), 'options->lower_add_sat'),
1445 (('isub_sat@' + str(bit_size
), a
, b
),
1446 ('bcsel', ('ilt', b
, 0), ('bcsel', ('ilt', ('isub', a
, b
), a
), intmax
, ('isub', a
, b
)),
1447 ('bcsel', ('ilt', a
, ('isub', a
, b
)), intmin
, ('isub', a
, b
))), 'options->lower_add_sat'),
1450 invert
= OrderedDict([('feq', 'fne'), ('fne', 'feq')])
1452 for left
, right
in itertools
.combinations_with_replacement(invert
.keys(), 2):
1453 optimizations
.append((('inot', ('ior(is_used_once)', (left
, a
, b
), (right
, c
, d
))),
1454 ('iand', (invert
[left
], a
, b
), (invert
[right
], c
, d
))))
1455 optimizations
.append((('inot', ('iand(is_used_once)', (left
, a
, b
), (right
, c
, d
))),
1456 ('ior', (invert
[left
], a
, b
), (invert
[right
], c
, d
))))
1458 # Optimize x2bN(b2x(x)) -> x
1459 for size
in type_sizes('bool'):
1460 aN
= 'a@' + str(size
)
1461 f2bN
= 'f2b' + str(size
)
1462 i2bN
= 'i2b' + str(size
)
1463 optimizations
.append(((f2bN
, ('b2f', aN
)), a
))
1464 optimizations
.append(((i2bN
, ('b2i', aN
)), a
))
1466 # Optimize x2yN(b2x(x)) -> b2y
1467 for x
, y
in itertools
.product(['f', 'u', 'i'], ['f', 'u', 'i']):
1468 if x
!= 'f' and y
!= 'f' and x
!= y
:
1471 b2x
= 'b2f' if x
== 'f' else 'b2i'
1472 b2y
= 'b2f' if y
== 'f' else 'b2i'
1473 x2yN
= '{}2{}'.format(x
, y
)
1474 optimizations
.append(((x2yN
, (b2x
, a
)), (b2y
, a
)))
1476 # Optimize away x2xN(a@N)
1477 for t
in ['int', 'uint', 'float', 'bool']:
1478 for N
in type_sizes(t
):
1479 x2xN
= '{0}2{0}{1}'.format(t
[0], N
)
1480 aN
= 'a@{0}'.format(N
)
1481 optimizations
.append(((x2xN
, aN
), a
))
1483 # Optimize x2xN(y2yM(a@P)) -> y2yN(a) for integers
1484 # In particular, we can optimize away everything except upcast of downcast and
1485 # upcasts where the type differs from the other cast
1486 for N
, M
in itertools
.product(type_sizes('uint'), type_sizes('uint')):
1488 # The outer cast is a down-cast. It doesn't matter what the size of the
1489 # argument of the inner cast is because we'll never been in the upcast
1490 # of downcast case. Regardless of types, we'll always end up with y2yN
1492 for x
, y
in itertools
.product(['i', 'u'], ['i', 'u']):
1493 x2xN
= '{0}2{0}{1}'.format(x
, N
)
1494 y2yM
= '{0}2{0}{1}'.format(y
, M
)
1495 y2yN
= '{0}2{0}{1}'.format(y
, N
)
1496 optimizations
.append(((x2xN
, (y2yM
, a
)), (y2yN
, a
)))
1498 # If the outer cast is an up-cast, we have to be more careful about the
1499 # size of the argument of the inner cast and with types. In this case,
1500 # the type is always the type of type up-cast which is given by the
1502 for P
in type_sizes('uint'):
1503 # We can't optimize away up-cast of down-cast.
1507 # Because we're doing down-cast of down-cast, the types always have
1508 # to match between the two casts
1509 for x
in ['i', 'u']:
1510 x2xN
= '{0}2{0}{1}'.format(x
, N
)
1511 x2xM
= '{0}2{0}{1}'.format(x
, M
)
1512 aP
= 'a@{0}'.format(P
)
1513 optimizations
.append(((x2xN
, (x2xM
, aP
)), (x2xN
, a
)))
1515 # The N == M case is handled by other optimizations
1518 # Downcast operations should be able to see through pack
1519 for t
in ['i', 'u']:
1520 for N
in [8, 16, 32]:
1521 x2xN
= '{0}2{0}{1}'.format(t
, N
)
1523 ((x2xN
, ('pack_64_2x32_split', a
, b
)), (x2xN
, a
)),
1524 ((x2xN
, ('pack_64_2x32_split', a
, b
)), (x2xN
, a
)),
1527 # Optimize comparisons with up-casts
1528 for t
in ['int', 'uint', 'float']:
1529 for N
, M
in itertools
.product(type_sizes(t
), repeat
=2):
1530 if N
== 1 or N
>= M
:
1535 cond
= 'options->support_8bit_alu'
1537 cond
= 'options->support_16bit_alu'
1538 x2xM
= '{0}2{0}{1}'.format(t
[0], M
)
1539 x2xN
= '{0}2{0}{1}'.format(t
[0], N
)
1542 xeq
= 'feq' if t
== 'float' else 'ieq'
1543 xne
= 'fne' if t
== 'float' else 'ine'
1544 xge
= '{0}ge'.format(t
[0])
1545 xlt
= '{0}lt'.format(t
[0])
1547 # Up-casts are lossless so for correctly signed comparisons of
1548 # up-casted values we can do the comparison at the largest of the two
1549 # original sizes and drop one or both of the casts. (We have
1550 # optimizations to drop the no-op casts which this may generate.)
1551 for P
in type_sizes(t
):
1557 ((xeq
, (x2xM
, aN
), (x2xM
, bP
)), (xeq
, a
, (x2xN
, b
)), cond
),
1558 ((xne
, (x2xM
, aN
), (x2xM
, bP
)), (xne
, a
, (x2xN
, b
)), cond
),
1559 ((xge
, (x2xM
, aN
), (x2xM
, bP
)), (xge
, a
, (x2xN
, b
)), cond
),
1560 ((xlt
, (x2xM
, aN
), (x2xM
, bP
)), (xlt
, a
, (x2xN
, b
)), cond
),
1561 ((xge
, (x2xM
, bP
), (x2xM
, aN
)), (xge
, (x2xN
, b
), a
), cond
),
1562 ((xlt
, (x2xM
, bP
), (x2xM
, aN
)), (xlt
, (x2xN
, b
), a
), cond
),
1565 # The next bit doesn't work on floats because the range checks would
1566 # get way too complicated.
1567 if t
in ['int', 'uint']:
1569 xN_min
= -(1 << (N
- 1))
1570 xN_max
= (1 << (N
- 1)) - 1
1573 xN_max
= (1 << N
) - 1
1577 # If we're up-casting and comparing to a constant, we can unfold
1578 # the comparison into a comparison with the shrunk down constant
1579 # and a check that the constant fits in the smaller bit size.
1581 ((xeq
, (x2xM
, aN
), '#b'),
1582 ('iand', (xeq
, a
, (x2xN
, b
)), (xeq
, (x2xM
, (x2xN
, b
)), b
)), cond
),
1583 ((xne
, (x2xM
, aN
), '#b'),
1584 ('ior', (xne
, a
, (x2xN
, b
)), (xne
, (x2xM
, (x2xN
, b
)), b
)), cond
),
1585 ((xlt
, (x2xM
, aN
), '#b'),
1586 ('iand', (xlt
, xN_min
, b
),
1587 ('ior', (xlt
, xN_max
, b
), (xlt
, a
, (x2xN
, b
)))), cond
),
1588 ((xlt
, '#a', (x2xM
, bN
)),
1589 ('iand', (xlt
, a
, xN_max
),
1590 ('ior', (xlt
, a
, xN_min
), (xlt
, (x2xN
, a
), b
))), cond
),
1591 ((xge
, (x2xM
, aN
), '#b'),
1592 ('iand', (xge
, xN_max
, b
),
1593 ('ior', (xge
, xN_min
, b
), (xge
, a
, (x2xN
, b
)))), cond
),
1594 ((xge
, '#a', (x2xM
, bN
)),
1595 ('iand', (xge
, a
, xN_min
),
1596 ('ior', (xge
, a
, xN_max
), (xge
, (x2xN
, a
), b
))), cond
),
1599 def fexp2i(exp
, bits
):
1600 # Generate an expression which constructs value 2.0^exp or 0.0.
1602 # We assume that exp is already in a valid range:
1604 # * [-15, 15] for 16-bit float
1605 # * [-127, 127] for 32-bit float
1606 # * [-1023, 1023] for 16-bit float
1608 # If exp is the lowest value in the valid range, a value of 0.0 is
1609 # constructed. Otherwise, the value 2.0^exp is constructed.
1611 return ('i2i16', ('ishl', ('iadd', exp
, 15), 10))
1613 return ('ishl', ('iadd', exp
, 127), 23)
1615 return ('pack_64_2x32_split', 0, ('ishl', ('iadd', exp
, 1023), 20))
1619 def ldexp(f
, exp
, bits
):
1620 # The maximum possible range for a normal exponent is [-126, 127] and,
1621 # throwing in denormals, you get a maximum range of [-149, 127]. This
1622 # means that we can potentially have a swing of +-276. If you start with
1623 # FLT_MAX, you actually have to do ldexp(FLT_MAX, -278) to get it to flush
1624 # all the way to zero. The GLSL spec only requires that we handle a subset
1625 # of this range. From version 4.60 of the spec:
1627 # "If exp is greater than +128 (single-precision) or +1024
1628 # (double-precision), the value returned is undefined. If exp is less
1629 # than -126 (single-precision) or -1022 (double-precision), the value
1630 # returned may be flushed to zero. Additionally, splitting the value
1631 # into a significand and exponent using frexp() and then reconstructing
1632 # a floating-point value using ldexp() should yield the original input
1633 # for zero and all finite non-denormalized values."
1635 # The SPIR-V spec has similar language.
1637 # In order to handle the maximum value +128 using the fexp2i() helper
1638 # above, we have to split the exponent in half and do two multiply
1641 # First, we clamp exp to a reasonable range. Specifically, we clamp to
1642 # twice the full range that is valid for the fexp2i() function above. If
1643 # exp/2 is the bottom value of that range, the fexp2i() expression will
1644 # yield 0.0f which, when multiplied by f, will flush it to zero which is
1645 # allowed by the GLSL and SPIR-V specs for low exponent values. If the
1646 # value is clamped from above, then it must have been above the supported
1647 # range of the GLSL built-in and therefore any return value is acceptable.
1649 exp
= ('imin', ('imax', exp
, -30), 30)
1651 exp
= ('imin', ('imax', exp
, -254), 254)
1653 exp
= ('imin', ('imax', exp
, -2046), 2046)
1657 # Now we compute two powers of 2, one for exp/2 and one for exp-exp/2.
1658 # (We use ishr which isn't the same for -1, but the -1 case still works
1659 # since we use exp-exp/2 as the second exponent.) While the spec
1660 # technically defines ldexp as f * 2.0^exp, simply multiplying once doesn't
1661 # work with denormals and doesn't allow for the full swing in exponents
1662 # that you can get with normalized values. Instead, we create two powers
1663 # of two and multiply by them each in turn. That way the effective range
1664 # of our exponent is doubled.
1665 pow2_1
= fexp2i(('ishr', exp
, 1), bits
)
1666 pow2_2
= fexp2i(('isub', exp
, ('ishr', exp
, 1)), bits
)
1667 return ('fmul', ('fmul', f
, pow2_1
), pow2_2
)
1670 (('ldexp@16', 'x', 'exp'), ldexp('x', 'exp', 16), 'options->lower_ldexp'),
1671 (('ldexp@32', 'x', 'exp'), ldexp('x', 'exp', 32), 'options->lower_ldexp'),
1672 (('ldexp@64', 'x', 'exp'), ldexp('x', 'exp', 64), 'options->lower_ldexp'),
1675 # Unreal Engine 4 demo applications open-codes bitfieldReverse()
1676 def bitfield_reverse(u
):
1677 step1
= ('ior', ('ishl', u
, 16), ('ushr', u
, 16))
1678 step2
= ('ior', ('ishl', ('iand', step1
, 0x00ff00ff), 8), ('ushr', ('iand', step1
, 0xff00ff00), 8))
1679 step3
= ('ior', ('ishl', ('iand', step2
, 0x0f0f0f0f), 4), ('ushr', ('iand', step2
, 0xf0f0f0f0), 4))
1680 step4
= ('ior', ('ishl', ('iand', step3
, 0x33333333), 2), ('ushr', ('iand', step3
, 0xcccccccc), 2))
1681 step5
= ('ior(many-comm-expr)', ('ishl', ('iand', step4
, 0x55555555), 1), ('ushr', ('iand', step4
, 0xaaaaaaaa), 1))
1685 optimizations
+= [(bitfield_reverse('x@32'), ('bitfield_reverse', 'x'), '!options->lower_bitfield_reverse')]
1687 # For any float comparison operation, "cmp", if you have "a == a && a cmp b"
1688 # then the "a == a" is redundant because it's equivalent to "a is not NaN"
1689 # and, if a is a NaN then the second comparison will fail anyway.
1690 for op
in ['flt', 'fge', 'feq']:
1692 (('iand', ('feq', a
, a
), (op
, a
, b
)), ('!' + op
, a
, b
)),
1693 (('iand', ('feq', a
, a
), (op
, b
, a
)), ('!' + op
, b
, a
)),
1696 # Add optimizations to handle the case where the result of a ternary is
1697 # compared to a constant. This way we can take things like
1703 # a ? (0 > 0) : (1 > 0)
1705 # which constant folding will eat for lunch. The resulting ternary will
1706 # further get cleaned up by the boolean reductions above and we will be
1707 # left with just the original variable "a".
1708 for op
in ['flt', 'fge', 'feq', 'fne',
1709 'ilt', 'ige', 'ieq', 'ine', 'ult', 'uge']:
1711 ((op
, ('bcsel', 'a', '#b', '#c'), '#d'),
1712 ('bcsel', 'a', (op
, 'b', 'd'), (op
, 'c', 'd'))),
1713 ((op
, '#d', ('bcsel', a
, '#b', '#c')),
1714 ('bcsel', 'a', (op
, 'd', 'b'), (op
, 'd', 'c'))),
1718 # For example, this converts things like
1720 # 1 + mix(0, a - 1, condition)
1724 # mix(1, (a-1)+1, condition)
1726 # Other optimizations will rearrange the constants.
1727 for op
in ['fadd', 'fmul', 'iadd', 'imul']:
1729 ((op
, ('bcsel(is_used_once)', a
, '#b', c
), '#d'), ('bcsel', a
, (op
, b
, d
), (op
, c
, d
)))
1732 # For derivatives in compute shaders, GLSL_NV_compute_shader_derivatives
1735 # If neither layout qualifier is specified, derivatives in compute shaders
1736 # return zero, which is consistent with the handling of built-in texture
1737 # functions like texture() in GLSL 4.50 compute shaders.
1738 for op
in ['fddx', 'fddx_fine', 'fddx_coarse',
1739 'fddy', 'fddy_fine', 'fddy_coarse']:
1741 ((op
, 'a'), 0.0, 'info->stage == MESA_SHADER_COMPUTE && info->cs.derivative_group == DERIVATIVE_GROUP_NONE')
1744 # Some optimizations for ir3-specific instructions.
1746 # 'al * bl': If either 'al' or 'bl' is zero, return zero.
1747 (('umul_low', '#a(is_lower_half_zero)', 'b'), (0)),
1748 # '(ah * bl) << 16 + c': If either 'ah' or 'bl' is zero, return 'c'.
1749 (('imadsh_mix16', '#a@32(is_lower_half_zero)', 'b@32', 'c@32'), ('c')),
1750 (('imadsh_mix16', 'a@32', '#b@32(is_upper_half_zero)', 'c@32'), ('c')),
1753 # These kinds of sequences can occur after nir_opt_peephole_select.
1755 # NOTE: fadd is not handled here because that gets in the way of ffma
1756 # generation in the i965 driver. Instead, fadd and ffma are handled in
1757 # late_optimizations.
1761 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
, d
), (op
, b
, c
, e
)), (op
, b
, c
, ('bcsel', a
, d
, e
))),
1762 (('bcsel', a
, (op
, b
, c
, d
), (op
+ '(is_used_once)', b
, c
, e
)), (op
, b
, c
, ('bcsel', a
, d
, e
))),
1763 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
, d
), (op
, b
, e
, d
)), (op
, b
, ('bcsel', a
, c
, e
), d
)),
1764 (('bcsel', a
, (op
, b
, c
, d
), (op
+ '(is_used_once)', b
, e
, d
)), (op
, b
, ('bcsel', a
, c
, e
), d
)),
1765 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
, d
), (op
, e
, c
, d
)), (op
, ('bcsel', a
, b
, e
), c
, d
)),
1766 (('bcsel', a
, (op
, b
, c
, d
), (op
+ '(is_used_once)', e
, c
, d
)), (op
, ('bcsel', a
, b
, e
), c
, d
)),
1769 for op
in ['fmul', 'iadd', 'imul', 'iand', 'ior', 'ixor', 'fmin', 'fmax', 'imin', 'imax', 'umin', 'umax']:
1771 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
), (op
, b
, 'd(is_not_const)')), (op
, b
, ('bcsel', a
, c
, d
))),
1772 (('bcsel', a
, (op
+ '(is_used_once)', b
, 'c(is_not_const)'), (op
, b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
1773 (('bcsel', a
, (op
, b
, 'c(is_not_const)'), (op
+ '(is_used_once)', b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
1774 (('bcsel', a
, (op
, b
, c
), (op
+ '(is_used_once)', b
, 'd(is_not_const)')), (op
, b
, ('bcsel', a
, c
, d
))),
1779 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
), (op
, b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
1780 (('bcsel', a
, (op
, b
, c
), (op
+ '(is_used_once)', b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
1781 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
), (op
, d
, c
)), (op
, ('bcsel', a
, b
, d
), c
)),
1782 (('bcsel', a
, (op
, b
, c
), (op
+ '(is_used_once)', d
, c
)), (op
, ('bcsel', a
, b
, d
), c
)),
1785 for op
in ['frcp', 'frsq', 'fsqrt', 'fexp2', 'flog2', 'fsign', 'fsin', 'fcos', 'fneg', 'fabs', 'fsign']:
1787 (('bcsel', c
, (op
+ '(is_used_once)', a
), (op
+ '(is_used_once)', b
)), (op
, ('bcsel', c
, a
, b
))),
1790 for op
in ['ineg', 'iabs', 'inot', 'isign']:
1792 ((op
, ('bcsel', c
, '#a', '#b')), ('bcsel', c
, (op
, a
), (op
, b
))),
1795 # This section contains optimizations to propagate downsizing conversions of
1796 # constructed vectors into vectors of downsized components. Whether this is
1797 # useful depends on the SIMD semantics of the backend. On a true SIMD machine,
1798 # this reduces the register pressure of the vector itself and often enables the
1799 # conversions to be eliminated via other algebraic rules or constant folding.
1800 # In the worst case on a SIMD architecture, the propagated conversions may be
1801 # revectorized via nir_opt_vectorize so instruction count is minimally
1804 # On a machine with SIMD-within-a-register only, this actually
1805 # counterintuitively hurts instruction count. These machines are the same that
1806 # require vectorize_vec2_16bit, so we predicate the optimizations on that flag
1809 # Finally for scalar architectures, there should be no difference in generated
1810 # code since it all ends up scalarized at the end, but it might minimally help
1813 for i
in range(2, 4 + 1):
1814 for T
in ('f', 'u', 'i'):
1815 vec_inst
= ('vec' + str(i
),)
1817 indices
= ['a', 'b', 'c', 'd']
1818 suffix_in
= tuple((indices
[j
] + '@32') for j
in range(i
))
1820 to_16
= '{}2{}16'.format(T
, T
)
1821 to_mp
= '{}2{}mp'.format(T
, T
)
1823 out_16
= tuple((to_16
, indices
[j
]) for j
in range(i
))
1824 out_mp
= tuple((to_mp
, indices
[j
]) for j
in range(i
))
1827 ((to_16
, vec_inst
+ suffix_in
), vec_inst
+ out_16
, '!options->vectorize_vec2_16bit'),
1828 ((to_mp
, vec_inst
+ suffix_in
), vec_inst
+ out_mp
, '!options->vectorize_vec2_16bit')
1831 # This section contains "late" optimizations that should be run before
1832 # creating ffmas and calling regular optimizations for the final time.
1833 # Optimizations should go here if they help code generation and conflict
1834 # with the regular optimizations.
1835 before_ffma_optimizations
= [
1836 # Propagate constants down multiplication chains
1837 (('~fmul(is_used_once)', ('fmul(is_used_once)', 'a(is_not_const)', '#b'), 'c(is_not_const)'), ('fmul', ('fmul', a
, c
), b
)),
1838 (('imul(is_used_once)', ('imul(is_used_once)', 'a(is_not_const)', '#b'), 'c(is_not_const)'), ('imul', ('imul', a
, c
), b
)),
1839 (('~fadd(is_used_once)', ('fadd(is_used_once)', 'a(is_not_const)', '#b'), 'c(is_not_const)'), ('fadd', ('fadd', a
, c
), b
)),
1840 (('iadd(is_used_once)', ('iadd(is_used_once)', 'a(is_not_const)', '#b'), 'c(is_not_const)'), ('iadd', ('iadd', a
, c
), b
)),
1842 (('~fadd', ('fmul', a
, b
), ('fmul', a
, c
)), ('fmul', a
, ('fadd', b
, c
))),
1843 (('iadd', ('imul', a
, b
), ('imul', a
, c
)), ('imul', a
, ('iadd', b
, c
))),
1844 (('~fadd', ('fneg', a
), a
), 0.0),
1845 (('iadd', ('ineg', a
), a
), 0),
1846 (('iadd', ('ineg', a
), ('iadd', a
, b
)), b
),
1847 (('iadd', a
, ('iadd', ('ineg', a
), b
)), b
),
1848 (('~fadd', ('fneg', a
), ('fadd', a
, b
)), b
),
1849 (('~fadd', a
, ('fadd', ('fneg', a
), b
)), b
),
1851 (('~flrp@32', ('fadd(is_used_once)', a
, -1.0), ('fadd(is_used_once)', a
, 1.0), d
), ('fadd', ('flrp', -1.0, 1.0, d
), a
)),
1852 (('~flrp@32', ('fadd(is_used_once)', a
, 1.0), ('fadd(is_used_once)', a
, -1.0), d
), ('fadd', ('flrp', 1.0, -1.0, d
), a
)),
1853 (('~flrp@32', ('fadd(is_used_once)', a
, '#b'), ('fadd(is_used_once)', a
, '#c'), d
), ('fadd', ('fmul', d
, ('fadd', c
, ('fneg', b
))), ('fadd', a
, b
))),
1856 # This section contains "late" optimizations that should be run after the
1857 # regular optimizations have finished. Optimizations should go here if
1858 # they help code generation but do not necessarily produce code that is
1859 # more easily optimizable.
1860 late_optimizations
= [
1861 # Most of these optimizations aren't quite safe when you get infinity or
1862 # Nan involved but the first one should be fine.
1863 (('flt', ('fadd', a
, b
), 0.0), ('flt', a
, ('fneg', b
))),
1864 (('flt', ('fneg', ('fadd', a
, b
)), 0.0), ('flt', ('fneg', a
), b
)),
1865 (('~fge', ('fadd', a
, b
), 0.0), ('fge', a
, ('fneg', b
))),
1866 (('~fge', ('fneg', ('fadd', a
, b
)), 0.0), ('fge', ('fneg', a
), b
)),
1867 (('~feq', ('fadd', a
, b
), 0.0), ('feq', a
, ('fneg', b
))),
1868 (('~fne', ('fadd', a
, b
), 0.0), ('fne', a
, ('fneg', b
))),
1870 # nir_lower_to_source_mods will collapse this, but its existence during the
1871 # optimization loop can prevent other optimizations.
1872 (('fneg', ('fneg', a
)), a
),
1874 # Subtractions get lowered during optimization, so we need to recombine them
1875 (('fadd', 'a', ('fneg', 'b')), ('fsub', 'a', 'b'), '!options->lower_sub'),
1876 (('iadd', 'a', ('ineg', 'b')), ('isub', 'a', 'b'), '!options->lower_sub'),
1877 (('fneg', a
), ('fsub', 0.0, a
), 'options->lower_negate'),
1878 (('ineg', a
), ('isub', 0, a
), 'options->lower_negate'),
1880 # These are duplicated from the main optimizations table. The late
1881 # patterns that rearrange expressions like x - .5 < 0 to x < .5 can create
1882 # new patterns like these. The patterns that compare with zero are removed
1883 # because they are unlikely to be created in by anything in
1884 # late_optimizations.
1885 (('flt', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('flt', a
, b
)),
1886 (('flt', '#b(is_gt_0_and_lt_1)', ('fsat(is_used_once)', a
)), ('flt', b
, a
)),
1887 (('fge', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('fge', a
, b
)),
1888 (('fge', '#b(is_gt_0_and_lt_1)', ('fsat(is_used_once)', a
)), ('fge', b
, a
)),
1889 (('feq', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('feq', a
, b
)),
1890 (('fne', ('fsat(is_used_once)', a
), '#b(is_gt_0_and_lt_1)'), ('fne', a
, b
)),
1892 (('fge', ('fsat(is_used_once)', a
), 1.0), ('fge', a
, 1.0)),
1893 (('flt', ('fsat(is_used_once)', a
), 1.0), ('flt', a
, 1.0)),
1895 (('~fge', ('fmin(is_used_once)', ('fadd(is_used_once)', a
, b
), ('fadd', c
, d
)), 0.0), ('iand', ('fge', a
, ('fneg', b
)), ('fge', c
, ('fneg', d
)))),
1897 (('flt', ('fneg', a
), ('fneg', b
)), ('flt', b
, a
)),
1898 (('fge', ('fneg', a
), ('fneg', b
)), ('fge', b
, a
)),
1899 (('feq', ('fneg', a
), ('fneg', b
)), ('feq', b
, a
)),
1900 (('fne', ('fneg', a
), ('fneg', b
)), ('fne', b
, a
)),
1901 (('flt', ('fneg', a
), -1.0), ('flt', 1.0, a
)),
1902 (('flt', -1.0, ('fneg', a
)), ('flt', a
, 1.0)),
1903 (('fge', ('fneg', a
), -1.0), ('fge', 1.0, a
)),
1904 (('fge', -1.0, ('fneg', a
)), ('fge', a
, 1.0)),
1905 (('fne', ('fneg', a
), -1.0), ('fne', 1.0, a
)),
1906 (('feq', -1.0, ('fneg', a
)), ('feq', a
, 1.0)),
1909 (('iand', a
, a
), a
),
1911 (('iand', ('ine(is_used_once)', 'a@32', 0), ('ine', 'b@32', 0)), ('ine', ('umin', a
, b
), 0)),
1912 (('ior', ('ieq(is_used_once)', 'a@32', 0), ('ieq', 'b@32', 0)), ('ieq', ('umin', a
, b
), 0)),
1914 (('~fadd', ('fneg(is_used_once)', ('fsat(is_used_once)', 'a(is_not_fmul)')), 1.0), ('fsat', ('fadd', 1.0, ('fneg', a
)))),
1916 (('fdot2', a
, b
), ('fdot_replicated2', a
, b
), 'options->fdot_replicates'),
1917 (('fdot3', a
, b
), ('fdot_replicated3', a
, b
), 'options->fdot_replicates'),
1918 (('fdot4', a
, b
), ('fdot_replicated4', a
, b
), 'options->fdot_replicates'),
1919 (('fdph', a
, b
), ('fdph_replicated', a
, b
), 'options->fdot_replicates'),
1921 (('~flrp@32', ('fadd(is_used_once)', a
, b
), ('fadd(is_used_once)', a
, c
), d
), ('fadd', ('flrp', b
, c
, d
), a
)),
1922 (('~flrp@64', ('fadd(is_used_once)', a
, b
), ('fadd(is_used_once)', a
, c
), d
), ('fadd', ('flrp', b
, c
, d
), a
)),
1924 (('~fadd@32', 1.0, ('fmul(is_used_once)', c
, ('fadd', b
, -1.0 ))), ('fadd', ('fadd', 1.0, ('fneg', c
)), ('fmul', b
, c
)), 'options->lower_flrp32'),
1925 (('~fadd@64', 1.0, ('fmul(is_used_once)', c
, ('fadd', b
, -1.0 ))), ('fadd', ('fadd', 1.0, ('fneg', c
)), ('fmul', b
, c
)), 'options->lower_flrp64'),
1927 # A similar operation could apply to any ffma(#a, b, #(-a/2)), but this
1928 # particular operation is common for expanding values stored in a texture
1929 # from [0,1] to [-1,1].
1930 (('~ffma@32', a
, 2.0, -1.0), ('flrp', -1.0, 1.0, a
), '!options->lower_flrp32'),
1931 (('~ffma@32', a
, -2.0, -1.0), ('flrp', -1.0, 1.0, ('fneg', a
)), '!options->lower_flrp32'),
1932 (('~ffma@32', a
, -2.0, 1.0), ('flrp', 1.0, -1.0, a
), '!options->lower_flrp32'),
1933 (('~ffma@32', a
, 2.0, 1.0), ('flrp', 1.0, -1.0, ('fneg', a
)), '!options->lower_flrp32'),
1934 (('~fadd@32', ('fmul(is_used_once)', 2.0, a
), -1.0), ('flrp', -1.0, 1.0, a
), '!options->lower_flrp32'),
1935 (('~fadd@32', ('fmul(is_used_once)', -2.0, a
), -1.0), ('flrp', -1.0, 1.0, ('fneg', a
)), '!options->lower_flrp32'),
1936 (('~fadd@32', ('fmul(is_used_once)', -2.0, a
), 1.0), ('flrp', 1.0, -1.0, a
), '!options->lower_flrp32'),
1937 (('~fadd@32', ('fmul(is_used_once)', 2.0, a
), 1.0), ('flrp', 1.0, -1.0, ('fneg', a
)), '!options->lower_flrp32'),
1941 # a + -a*a + a*b (1)
1943 # Option 1: ffma(a, (b-a), a)
1945 # Alternately, after (1):
1951 # Option 2: ffma(a, 2, -(a*a))
1952 # Option 3: ffma(a, 2, (-a)*a)
1953 # Option 4: ffma(a, -a, (2*a)
1954 # Option 5: a * (2 - a)
1956 # There are a lot of other possible combinations.
1957 (('~ffma@32', ('fadd', b
, ('fneg', a
)), a
, a
), ('flrp', a
, b
, a
), '!options->lower_flrp32'),
1958 (('~ffma@32', a
, 2.0, ('fneg', ('fmul', a
, a
))), ('flrp', a
, 1.0, a
), '!options->lower_flrp32'),
1959 (('~ffma@32', a
, 2.0, ('fmul', ('fneg', a
), a
)), ('flrp', a
, 1.0, a
), '!options->lower_flrp32'),
1960 (('~ffma@32', a
, ('fneg', a
), ('fmul', 2.0, a
)), ('flrp', a
, 1.0, a
), '!options->lower_flrp32'),
1961 (('~fmul@32', a
, ('fadd', 2.0, ('fneg', a
))), ('flrp', a
, 1.0, a
), '!options->lower_flrp32'),
1963 # we do these late so that we don't get in the way of creating ffmas
1964 (('fmin', ('fadd(is_used_once)', '#c', a
), ('fadd(is_used_once)', '#c', b
)), ('fadd', c
, ('fmin', a
, b
))),
1965 (('fmax', ('fadd(is_used_once)', '#c', a
), ('fadd(is_used_once)', '#c', b
)), ('fadd', c
, ('fmax', a
, b
))),
1967 (('bcsel', a
, 0, ('b2f32', ('inot', 'b@bool'))), ('b2f32', ('inot', ('ior', a
, b
)))),
1969 # Putting this in 'optimizations' interferes with the bcsel(a, op(b, c),
1970 # op(b, d)) => op(b, bcsel(a, c, d)) transformations. I do not know why.
1971 (('bcsel', ('feq', ('fsqrt', 'a(is_not_negative)'), 0.0), intBitsToFloat(0x7f7fffff), ('frsq', a
)),
1972 ('fmin', ('frsq', a
), intBitsToFloat(0x7f7fffff))),
1974 # Things that look like DPH in the source shader may get expanded to
1975 # something that looks like dot(v1.xyz, v2.xyz) + v1.w by the time it gets
1976 # to NIR. After FFMA is generated, this can look like:
1978 # fadd(ffma(v1.z, v2.z, ffma(v1.y, v2.y, fmul(v1.x, v2.x))), v1.w)
1980 # Reassociate the last addition into the first multiplication.
1982 # Some shaders do not use 'invariant' in vertex and (possibly) geometry
1983 # shader stages on some outputs that are intended to be invariant. For
1984 # various reasons, this optimization may not be fully applied in all
1985 # shaders used for different rendering passes of the same geometry. This
1986 # can result in Z-fighting artifacts (at best). For now, disable this
1987 # optimization in these stages. See bugzilla #111490. In tessellation
1988 # stages applications seem to use 'precise' when necessary, so allow the
1989 # optimization in those stages.
1990 (('~fadd', ('ffma(is_used_once)', a
, b
, ('ffma', c
, d
, ('fmul', 'e(is_not_const_and_not_fsign)', 'f(is_not_const_and_not_fsign)'))), 'g(is_not_const)'),
1991 ('ffma', a
, b
, ('ffma', c
, d
, ('ffma', e
, 'f', 'g'))), '(info->stage != MESA_SHADER_VERTEX && info->stage != MESA_SHADER_GEOMETRY) && !options->intel_vec4'),
1992 (('~fadd', ('ffma(is_used_once)', a
, b
, ('fmul', 'c(is_not_const_and_not_fsign)', 'd(is_not_const_and_not_fsign)') ), 'e(is_not_const)'),
1993 ('ffma', a
, b
, ('ffma', c
, d
, e
)), '(info->stage != MESA_SHADER_VERTEX && info->stage != MESA_SHADER_GEOMETRY) && !options->intel_vec4'),
1995 # Convert *2*mp instructions to concrete *2*16 instructions. At this point
1996 # any conversions that could have been removed will have been removed in
1997 # nir_opt_algebraic so any remaining ones are required.
1998 (('f2fmp', a
), ('f2f16', a
)),
1999 (('i2imp', a
), ('i2i16', a
)),
2000 (('u2ump', a
), ('u2u16', a
)),
2002 # Section 8.8 (Integer Functions) of the GLSL 4.60 spec says:
2004 # If bits is zero, the result will be zero.
2006 # These prevent the next two lowerings generating incorrect results when
2008 (('ubfe', a
, b
, 0), 0),
2009 (('ibfe', a
, b
, 0), 0),
2011 # On Intel GPUs, BFE is a 3-source instruction. Like all 3-source
2012 # instructions on Intel GPUs, it cannot have an immediate values as
2013 # sources. There are also limitations on source register strides. As a
2014 # result, it is very easy for 3-source instruction combined with either
2015 # loads of immediate values or copies from weird register strides to be
2016 # more expensive than the primitive instructions it represents.
2017 (('ubfe', a
, '#b', '#c'), ('iand', ('ushr', 0xffffffff, ('ineg', c
)), ('ushr', a
, b
)), 'options->lower_bfe_with_two_constants'),
2019 # b is the lowest order bit to be extracted and c is the number of bits to
2020 # extract. The inner shift removes the bits above b + c by shifting left
2021 # 32 - (b + c). ishl only sees the low 5 bits of the shift count, which is
2022 # -(b + c). The outer shift moves the bit that was at b to bit zero.
2023 # After the first shift, that bit is now at b + (32 - (b + c)) or 32 - c.
2024 # This means that it must be shifted right by 32 - c or -c bits.
2025 (('ibfe', a
, '#b', '#c'), ('ishr', ('ishl', a
, ('ineg', ('iadd', b
, c
))), ('ineg', c
)), 'options->lower_bfe_with_two_constants'),
2027 # Clean up no-op shifts that may result from the bfe lowerings.
2028 (('ishl', a
, 0), a
),
2029 (('ishl', a
, -32), a
),
2030 (('ishr', a
, 0), a
),
2031 (('ishr', a
, -32), a
),
2032 (('ushr', a
, 0), a
),
2036 late_optimizations
+= [
2037 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
), (op
, b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
2038 (('bcsel', a
, (op
, b
, c
), (op
+ '(is_used_once)', b
, d
)), (op
, b
, ('bcsel', a
, c
, d
))),
2042 late_optimizations
+= [
2043 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
, d
), (op
, b
, c
, e
)), (op
, b
, c
, ('bcsel', a
, d
, e
))),
2044 (('bcsel', a
, (op
, b
, c
, d
), (op
+ '(is_used_once)', b
, c
, e
)), (op
, b
, c
, ('bcsel', a
, d
, e
))),
2046 (('bcsel', a
, (op
+ '(is_used_once)', b
, c
, d
), (op
, b
, e
, d
)), (op
, b
, ('bcsel', a
, c
, e
), d
)),
2047 (('bcsel', a
, (op
, b
, c
, d
), (op
+ '(is_used_once)', b
, e
, d
)), (op
, b
, ('bcsel', a
, c
, e
), d
)),
2050 distribute_src_mods
= [
2051 # Try to remove some spurious negations rather than pushing them down.
2052 (('fmul', ('fneg', a
), ('fneg', b
)), ('fmul', a
, b
)),
2053 (('ffma', ('fneg', a
), ('fneg', b
), c
), ('ffma', a
, b
, c
)),
2054 (('fdot_replicated2', ('fneg', a
), ('fneg', b
)), ('fdot_replicated2', a
, b
)),
2055 (('fdot_replicated3', ('fneg', a
), ('fneg', b
)), ('fdot_replicated3', a
, b
)),
2056 (('fdot_replicated4', ('fneg', a
), ('fneg', b
)), ('fdot_replicated4', a
, b
)),
2057 (('fneg', ('fneg', a
)), a
),
2059 (('fneg', ('fmul(is_used_once)', a
, b
)), ('fmul', ('fneg', a
), b
)),
2060 (('fabs', ('fmul(is_used_once)', a
, b
)), ('fmul', ('fabs', a
), ('fabs', b
))),
2062 (('fneg', ('ffma(is_used_once)', a
, b
, c
)), ('ffma', ('fneg', a
), b
, ('fneg', c
))),
2063 (('fneg', ('flrp(is_used_once)', a
, b
, c
)), ('flrp', ('fneg', a
), ('fneg', b
), c
)),
2064 (('fneg', ('fadd(is_used_once)', a
, b
)), ('fadd', ('fneg', a
), ('fneg', b
))),
2066 # Note that fmin <-> fmax. I don't think there is a way to distribute
2067 # fabs() into fmin or fmax.
2068 (('fneg', ('fmin(is_used_once)', a
, b
)), ('fmax', ('fneg', a
), ('fneg', b
))),
2069 (('fneg', ('fmax(is_used_once)', a
, b
)), ('fmin', ('fneg', a
), ('fneg', b
))),
2071 (('fneg', ('fdot_replicated2(is_used_once)', a
, b
)), ('fdot_replicated2', ('fneg', a
), b
)),
2072 (('fneg', ('fdot_replicated3(is_used_once)', a
, b
)), ('fdot_replicated3', ('fneg', a
), b
)),
2073 (('fneg', ('fdot_replicated4(is_used_once)', a
, b
)), ('fdot_replicated4', ('fneg', a
), b
)),
2075 # fdph works mostly like fdot, but to get the correct result, the negation
2076 # must be applied to the second source.
2077 (('fneg', ('fdph_replicated(is_used_once)', a
, b
)), ('fdph_replicated', a
, ('fneg', b
))),
2079 (('fneg', ('fsign(is_used_once)', a
)), ('fsign', ('fneg', a
))),
2080 (('fabs', ('fsign(is_used_once)', a
)), ('fsign', ('fabs', a
))),
2083 print(nir_algebraic
.AlgebraicPass("nir_opt_algebraic", optimizations
).render())
2084 print(nir_algebraic
.AlgebraicPass("nir_opt_algebraic_before_ffma",
2085 before_ffma_optimizations
).render())
2086 print(nir_algebraic
.AlgebraicPass("nir_opt_algebraic_late",
2087 late_optimizations
).render())
2088 print(nir_algebraic
.AlgebraicPass("nir_opt_algebraic_distribute_src_mods",
2089 distribute_src_mods
).render())