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gerrit-public.fairphone.software / platform / art / e45fb9e7976c8462b94a58ad60b006b0eacec49f / . / compiler / dex / quick / arm64 / utility_arm64.cc
blob: e46e2015650542a59cce059b823747205df7db00 [file] [log] [blame]
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1/*
2 * Copyright (C) 2011 The Android Open Source Project
3 *
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at
7 *
8 * http://www.apache.org/licenses/LICENSE-2.0
9 *
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
15 */
16
17#include "arm64_lir.h"
18#include "codegen_arm64.h"
19#include "dex/quick/mir_to_lir-inl.h"
20
21namespace art {
22
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]23/* This file contains codegen for the A64 ISA. */
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]24
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]25static int32_t EncodeImmSingle(uint32_t bits) {
26 /*
27 * Valid values will have the form:
28 *
29 * aBbb.bbbc.defg.h000.0000.0000.0000.0000
30 *
31 * where B = not(b). In other words, if b == 1, then B == 0 and viceversa.
32 */
33
34 // bits[19..0] are cleared.
35 if ((bits & 0x0007ffff) != 0)
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]36 return -1;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]37
38 // bits[29..25] are all set or all cleared.
39 uint32_t b_pattern = (bits >> 16) & 0x3e00;
40 if (b_pattern != 0 && b_pattern != 0x3e00)
41 return -1;
42
43 // bit[30] and bit[29] are opposite.
44 if (((bits ^ (bits << 1)) & 0x40000000) == 0)
45 return -1;
46
47 // bits: aBbb.bbbc.defg.h000.0000.0000.0000.0000
48 // bit7: a000.0000
49 uint32_t bit7 = ((bits >> 31) & 0x1) << 7;
50 // bit6: 0b00.0000
51 uint32_t bit6 = ((bits >> 29) & 0x1) << 6;
52 // bit5_to_0: 00cd.efgh
53 uint32_t bit5_to_0 = (bits >> 19) & 0x3f;
54 return (bit7 | bit6 | bit5_to_0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]55}
56
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]57static int32_t EncodeImmDouble(uint64_t bits) {
58 /*
59 * Valid values will have the form:
60 *
61 * aBbb.bbbb.bbcd.efgh.0000.0000.0000.0000
62 * 0000.0000.0000.0000.0000.0000.0000.0000
63 *
64 * where B = not(b).
65 */
66
67 // bits[47..0] are cleared.
68 if ((bits & UINT64_C(0xffffffffffff)) != 0)
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]69 return -1;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]70
71 // bits[61..54] are all set or all cleared.
72 uint32_t b_pattern = (bits >> 48) & 0x3fc0;
73 if (b_pattern != 0 && b_pattern != 0x3fc0)
74 return -1;
75
76 // bit[62] and bit[61] are opposite.
77 if (((bits ^ (bits << 1)) & UINT64_C(0x4000000000000000)) == 0)
78 return -1;
79
80 // bit7: a000.0000
81 uint32_t bit7 = ((bits >> 63) & 0x1) << 7;
82 // bit6: 0b00.0000
83 uint32_t bit6 = ((bits >> 61) & 0x1) << 6;
84 // bit5_to_0: 00cd.efgh
85 uint32_t bit5_to_0 = (bits >> 48) & 0x3f;
86 return (bit7 | bit6 | bit5_to_0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]87}
88
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]89LIR* Arm64Mir2Lir::LoadFPConstantValue(int r_dest, int32_t value) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]90 DCHECK(RegStorage::IsSingle(r_dest));
91 if (value == 0) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]92 return NewLIR2(kA64Fmov2sw, r_dest, rwzr);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]93 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]94 int32_t encoded_imm = EncodeImmSingle((uint32_t)value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]95 if (encoded_imm >= 0) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]96 return NewLIR2(kA64Fmov2fI, r_dest, encoded_imm);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]97 }
98 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]99
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]100 LIR* data_target = ScanLiteralPool(literal_list_, value, 0);
101 if (data_target == NULL) {
102 data_target = AddWordData(&literal_list_, value);
103 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]104
105 LIR* load_pc_rel = RawLIR(current_dalvik_offset_, kA64Ldr2fp,
106 r_dest, 0, 0, 0, 0, data_target);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]107 SetMemRefType(load_pc_rel, true, kLiteral);
108 AppendLIR(load_pc_rel);
109 return load_pc_rel;
110}
111
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]112LIR* Arm64Mir2Lir::LoadFPConstantValueWide(int r_dest, int64_t value) {
113 DCHECK(RegStorage::IsDouble(r_dest));
114 if (value == 0) {
115 return NewLIR2(kA64Fmov2Sx, r_dest, rwzr);
116 } else {
117 int32_t encoded_imm = EncodeImmDouble(value);
118 if (encoded_imm >= 0) {
119 return NewLIR2(FWIDE(kA64Fmov2fI), r_dest, encoded_imm);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]120 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]121 }
122
123 // No short form - load from the literal pool.
124 int32_t val_lo = Low32Bits(value);
125 int32_t val_hi = High32Bits(value);
126 LIR* data_target = ScanLiteralPoolWide(literal_list_, val_lo, val_hi);
127 if (data_target == NULL) {
128 data_target = AddWideData(&literal_list_, val_lo, val_hi);
129 }
130
131 DCHECK(RegStorage::IsFloat(r_dest));
132 LIR* load_pc_rel = RawLIR(current_dalvik_offset_, FWIDE(kA64Ldr2fp),
133 r_dest, 0, 0, 0, 0, data_target);
134 SetMemRefType(load_pc_rel, true, kLiteral);
135 AppendLIR(load_pc_rel);
136 return load_pc_rel;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]137}
138
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]139static int CountLeadingZeros(bool is_wide, uint64_t value) {
140 return (is_wide) ? __builtin_clzl(value) : __builtin_clz((uint32_t)value);
141}
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]142
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]143static int CountTrailingZeros(bool is_wide, uint64_t value) {
144 return (is_wide) ? __builtin_ctzl(value) : __builtin_ctz((uint32_t)value);
145}
146
147static int CountSetBits(bool is_wide, uint64_t value) {
148 return ((is_wide) ?
149 __builtin_popcountl(value) : __builtin_popcount((uint32_t)value));
150}
151
152/**
153 * @brief Try encoding an immediate in the form required by logical instructions.
154 *
155 * @param is_wide Whether @p value is a 64-bit (as opposed to 32-bit) value.
156 * @param value An integer to be encoded. This is interpreted as 64-bit if @p is_wide is true and as
157 * 32-bit if @p is_wide is false.
158 * @return A non-negative integer containing the encoded immediate or -1 if the encoding failed.
159 * @note This is the inverse of Arm64Mir2Lir::DecodeLogicalImmediate().
160 */
161int Arm64Mir2Lir::EncodeLogicalImmediate(bool is_wide, uint64_t value) {
162 unsigned n, imm_s, imm_r;
163
164 // Logical immediates are encoded using parameters n, imm_s and imm_r using
165 // the following table:
166 //
167 // N imms immr size S R
168 // 1 ssssss rrrrrr 64 UInt(ssssss) UInt(rrrrrr)
169 // 0 0sssss xrrrrr 32 UInt(sssss) UInt(rrrrr)
170 // 0 10ssss xxrrrr 16 UInt(ssss) UInt(rrrr)
171 // 0 110sss xxxrrr 8 UInt(sss) UInt(rrr)
172 // 0 1110ss xxxxrr 4 UInt(ss) UInt(rr)
173 // 0 11110s xxxxxr 2 UInt(s) UInt(r)
174 // (s bits must not be all set)
175 //
176 // A pattern is constructed of size bits, where the least significant S+1
177 // bits are set. The pattern is rotated right by R, and repeated across a
178 // 32 or 64-bit value, depending on destination register width.
179 //
180 // To test if an arbitary immediate can be encoded using this scheme, an
181 // iterative algorithm is used.
182 //
183
184 // 1. If the value has all set or all clear bits, it can't be encoded.
185 if (value == 0 || value == ~UINT64_C(0) ||
186 (!is_wide && (uint32_t)value == ~UINT32_C(0))) {
187 return -1;
188 }
189
190 unsigned lead_zero = CountLeadingZeros(is_wide, value);
191 unsigned lead_one = CountLeadingZeros(is_wide, ~value);
192 unsigned trail_zero = CountTrailingZeros(is_wide, value);
193 unsigned trail_one = CountTrailingZeros(is_wide, ~value);
194 unsigned set_bits = CountSetBits(is_wide, value);
195
196 // The fixed bits in the immediate s field.
197 // If width == 64 (X reg), start at 0xFFFFFF80.
198 // If width == 32 (W reg), start at 0xFFFFFFC0, as the iteration for 64-bit
199 // widths won't be executed.
200 unsigned width = (is_wide) ? 64 : 32;
201 int imm_s_fixed = (is_wide) ? -128 : -64;
202 int imm_s_mask = 0x3f;
203
204 for (;;) {
205 // 2. If the value is two bits wide, it can be encoded.
206 if (width == 2) {
207 n = 0;
208 imm_s = 0x3C;
209 imm_r = (value & 3) - 1;
210 break;
211 }
212
213 n = (width == 64) ? 1 : 0;
214 imm_s = ((imm_s_fixed | (set_bits - 1)) & imm_s_mask);
215 if ((lead_zero + set_bits) == width) {
216 imm_r = 0;
217 } else {
218 imm_r = (lead_zero > 0) ? (width - trail_zero) : lead_one;
219 }
220
221 // 3. If the sum of leading zeros, trailing zeros and set bits is
222 // equal to the bit width of the value, it can be encoded.
223 if (lead_zero + trail_zero + set_bits == width) {
224 break;
225 }
226
227 // 4. If the sum of leading ones, trailing ones and unset bits in the
228 // value is equal to the bit width of the value, it can be encoded.
229 if (lead_one + trail_one + (width - set_bits) == width) {
230 break;
231 }
232
233 // 5. If the most-significant half of the bitwise value is equal to
234 // the least-significant half, return to step 2 using the
235 // least-significant half of the value.
236 uint64_t mask = (UINT64_C(1) << (width >> 1)) - 1;
237 if ((value & mask) == ((value >> (width >> 1)) & mask)) {
238 width >>= 1;
239 set_bits >>= 1;
240 imm_s_fixed >>= 1;
241 continue;
242 }
243
244 // 6. Otherwise, the value can't be encoded.
245 return -1;
246 }
247
248 return (n << 12 | imm_r << 6 | imm_s);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]249}
250
251bool Arm64Mir2Lir::InexpensiveConstantInt(int32_t value) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]252 return false; // (ModifiedImmediate(value) >= 0) || (ModifiedImmediate(~value) >= 0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]253}
254
255bool Arm64Mir2Lir::InexpensiveConstantFloat(int32_t value) {
256 return EncodeImmSingle(value) >= 0;
257}
258
259bool Arm64Mir2Lir::InexpensiveConstantLong(int64_t value) {
260 return InexpensiveConstantInt(High32Bits(value)) && InexpensiveConstantInt(Low32Bits(value));
261}
262
263bool Arm64Mir2Lir::InexpensiveConstantDouble(int64_t value) {
264 return EncodeImmDouble(value) >= 0;
265}
266
267/*
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]268 * Load a immediate using one single instruction when possible; otherwise
269 * use a pair of movz and movk instructions.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]270 *
271 * No additional register clobbering operation performed. Use this version when
272 * 1) r_dest is freshly returned from AllocTemp or
273 * 2) The codegen is under fixed register usage
274 */
275LIR* Arm64Mir2Lir::LoadConstantNoClobber(RegStorage r_dest, int value) {
276 LIR* res;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]277
278 if (r_dest.IsFloat()) {
279 return LoadFPConstantValue(r_dest.GetReg(), value);
280 }
281
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]282 // Loading SP/ZR with an immediate is not supported.
283 DCHECK_NE(r_dest.GetReg(), rwsp);
284 DCHECK_NE(r_dest.GetReg(), rwzr);
285
286 // Compute how many movk, movz instructions are needed to load the value.
287 uint16_t high_bits = High16Bits(value);
288 uint16_t low_bits = Low16Bits(value);
289
290 bool low_fast = ((uint16_t)(low_bits + 1) <= 1);
291 bool high_fast = ((uint16_t)(high_bits + 1) <= 1);
292
293 if (LIKELY(low_fast || high_fast)) {
294 // 1 instruction is enough to load the immediate.
295 if (LIKELY(low_bits == high_bits)) {
296 // Value is either 0 or -1: we can just use wzr.
297 ArmOpcode opcode = LIKELY(low_bits == 0) ? kA64Mov2rr : kA64Mvn2rr;
298 res = NewLIR2(opcode, r_dest.GetReg(), rwzr);
299 } else {
300 uint16_t uniform_bits, useful_bits;
301 int shift;
302
303 if (LIKELY(high_fast)) {
304 shift = 0;
305 uniform_bits = high_bits;
306 useful_bits = low_bits;
307 } else {
308 shift = 1;
309 uniform_bits = low_bits;
310 useful_bits = high_bits;
311 }
312
313 if (UNLIKELY(uniform_bits != 0)) {
314 res = NewLIR3(kA64Movn3rdM, r_dest.GetReg(), ~useful_bits, shift);
315 } else {
316 res = NewLIR3(kA64Movz3rdM, r_dest.GetReg(), useful_bits, shift);
317 }
318 }
319 } else {
320 // movk, movz require 2 instructions. Try detecting logical immediates.
321 int log_imm = EncodeLogicalImmediate(/*is_wide=*/false, value);
322 if (log_imm >= 0) {
323 res = NewLIR3(kA64Orr3Rrl, r_dest.GetReg(), rwzr, log_imm);
324 } else {
325 // Use 2 instructions.
326 res = NewLIR3(kA64Movz3rdM, r_dest.GetReg(), low_bits, 0);
327 NewLIR3(kA64Movk3rdM, r_dest.GetReg(), high_bits, 1);
328 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]329 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]330
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]331 return res;
332}
333
334LIR* Arm64Mir2Lir::OpUnconditionalBranch(LIR* target) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]335 LIR* res = NewLIR1(kA64B1t, 0 /* offset to be patched during assembly */);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]336 res->target = target;
337 return res;
338}
339
340LIR* Arm64Mir2Lir::OpCondBranch(ConditionCode cc, LIR* target) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]341 LIR* branch = NewLIR2(kA64B2ct, ArmConditionEncoding(cc),
342 0 /* offset to be patched */);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]343 branch->target = target;
344 return branch;
345}
346
347LIR* Arm64Mir2Lir::OpReg(OpKind op, RegStorage r_dest_src) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]348 ArmOpcode opcode = kA64Brk1d;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]349 switch (op) {
350 case kOpBlx:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]351 opcode = kA64Blr1x;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]352 break;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]353 // TODO(Arm64): port kThumbBx.
354 // case kOpBx:
355 // opcode = kThumbBx;
356 // break;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]357 default:
358 LOG(FATAL) << "Bad opcode " << op;
359 }
360 return NewLIR1(opcode, r_dest_src.GetReg());
361}
362
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]363LIR* Arm64Mir2Lir::OpRegRegShift(OpKind op, int r_dest_src1, int r_src2,
364 int shift, bool is_wide) {
365 ArmOpcode wide = (is_wide) ? WIDE(0) : UNWIDE(0);
366 ArmOpcode opcode = kA64Brk1d;
367
368 switch (OP_KIND_UNWIDE(op)) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]369 case kOpCmn:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]370 opcode = kA64Cmn3Rro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]371 break;
372 case kOpCmp:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]373 // TODO(Arm64): check the instruction above: "cmp w0, w1" is rendered as "cmp w0, w1, uxtb".
374 opcode = kA64Cmp3Rro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]375 break;
376 case kOpMov:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]377 opcode = kA64Mov2rr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]378 break;
379 case kOpMvn:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]380 opcode = kA64Mvn2rr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]381 break;
382 case kOpNeg:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]383 opcode = kA64Neg3rro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]384 break;
385 case kOpTst:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]386 opcode = kA64Tst3rro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]387 break;
388 case kOpRev:
389 DCHECK_EQ(shift, 0);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]390 // Binary, but rm is encoded twice.
391 return NewLIR3(kA64Rev2rr | wide, r_dest_src1, r_src2, r_src2);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]392 break;
393 case kOpRevsh:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]394 // Binary, but rm is encoded twice.
395 return NewLIR3(kA64Rev162rr | wide, r_dest_src1, r_src2, r_src2);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]396 break;
397 case kOp2Byte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]398 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
399 // "sbfx r1, r2, #imm1, #imm2" is "sbfm r1, r2, #imm1, #(imm1 + imm2 - 1)".
400 // For now we use sbfm directly.
401 return NewLIR4(kA64Sbfm4rrdd | wide, r_dest_src1, r_src2, 0, 7);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]402 case kOp2Short:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]403 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
404 // For now we use sbfm rather than its alias, sbfx.
405 return NewLIR4(kA64Sbfm4rrdd | wide, r_dest_src1, r_src2, 0, 15);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]406 case kOp2Char:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]407 // "ubfx r1, r2, #imm1, #imm2" is "ubfm r1, r2, #imm1, #(imm1 + imm2 - 1)".
408 // For now we use ubfm directly.
409 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
410 return NewLIR4(kA64Ubfm4rrdd | wide, r_dest_src1, r_src2, 0, 15);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]411 default:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]412 return OpRegRegRegShift(op, r_dest_src1, r_dest_src1, r_src2, shift);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]413 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]414
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]415 DCHECK(!IsPseudoLirOp(opcode));
416 if (EncodingMap[opcode].flags & IS_BINARY_OP) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]417 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
418 return NewLIR2(opcode | wide, r_dest_src1, r_src2);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]419 } else if (EncodingMap[opcode].flags & IS_TERTIARY_OP) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]420 ArmEncodingKind kind = EncodingMap[opcode].field_loc[2].kind;
421 if (kind == kFmtExtend || kind == kFmtShift) {
422 DCHECK_EQ(kind == kFmtExtend, IsExtendEncoding(shift));
423 return NewLIR3(opcode | wide, r_dest_src1, r_src2, shift);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]424 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]425 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]426
427 LOG(FATAL) << "Unexpected encoding operand count";
428 return NULL;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]429}
430
431LIR* Arm64Mir2Lir::OpRegReg(OpKind op, RegStorage r_dest_src1, RegStorage r_src2) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]432 return OpRegRegShift(op, r_dest_src1.GetReg(), r_src2.GetReg(), ENCODE_NO_SHIFT,
433 r_dest_src1.Is64Bit());
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]434}
435
436LIR* Arm64Mir2Lir::OpMovRegMem(RegStorage r_dest, RegStorage r_base, int offset, MoveType move_type) {
437 UNIMPLEMENTED(FATAL);
438 return nullptr;
439}
440
441LIR* Arm64Mir2Lir::OpMovMemReg(RegStorage r_base, int offset, RegStorage r_src, MoveType move_type) {
442 UNIMPLEMENTED(FATAL);
443 return nullptr;
444}
445
446LIR* Arm64Mir2Lir::OpCondRegReg(OpKind op, ConditionCode cc, RegStorage r_dest, RegStorage r_src) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]447 LOG(FATAL) << "Unexpected use of OpCondRegReg for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]448 return NULL;
449}
450
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]451LIR* Arm64Mir2Lir::OpRegRegRegShift(OpKind op, int r_dest, int r_src1,
452 int r_src2, int shift, bool is_wide) {
453 ArmOpcode opcode = kA64Brk1d;
454
455 switch (OP_KIND_UNWIDE(op)) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]456 case kOpAdd:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]457 opcode = kA64Add4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]458 break;
459 case kOpSub:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]460 opcode = kA64Sub4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]461 break;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]462 // case kOpRsub:
463 // opcode = kA64RsubWWW;
464 // break;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]465 case kOpAdc:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]466 opcode = kA64Adc3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]467 break;
468 case kOpAnd:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]469 opcode = kA64And4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]470 break;
471 case kOpXor:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]472 opcode = kA64Eor4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]473 break;
474 case kOpMul:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]475 opcode = kA64Mul3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]476 break;
477 case kOpDiv:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]478 opcode = kA64Sdiv3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]479 break;
480 case kOpOr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]481 opcode = kA64Orr4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]482 break;
483 case kOpSbc:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]484 opcode = kA64Sbc3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]485 break;
486 case kOpLsl:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]487 opcode = kA64Lsl3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]488 break;
489 case kOpLsr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]490 opcode = kA64Lsr3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]491 break;
492 case kOpAsr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]493 opcode = kA64Asr3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]494 break;
495 case kOpRor:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]496 opcode = kA64Ror3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]497 break;
498 default:
499 LOG(FATAL) << "Bad opcode: " << op;
500 break;
501 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]502
503 // The instructions above belong to two kinds:
504 // - 4-operands instructions, where the last operand is a shift/extend immediate,
505 // - 3-operands instructions with no shift/extend.
506 ArmOpcode widened_opcode = (is_wide) ? WIDE(opcode) : opcode;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]507 if (EncodingMap[opcode].flags & IS_QUAD_OP) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]508 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
509 return NewLIR4(widened_opcode, r_dest, r_src1, r_src2, shift);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]510 } else {
511 DCHECK(EncodingMap[opcode].flags & IS_TERTIARY_OP);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]512 DCHECK_EQ(shift, ENCODE_NO_SHIFT);
513 return NewLIR3(widened_opcode, r_dest, r_src1, r_src2);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]514 }
515}
516
517LIR* Arm64Mir2Lir::OpRegRegReg(OpKind op, RegStorage r_dest, RegStorage r_src1, RegStorage r_src2) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]518 return OpRegRegRegShift(op, r_dest.GetReg(), r_src1.GetReg(), r_src2.GetReg(), ENCODE_NO_SHIFT);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]519}
520
521LIR* Arm64Mir2Lir::OpRegRegImm(OpKind op, RegStorage r_dest, RegStorage r_src1, int value) {
522 LIR* res;
523 bool neg = (value < 0);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]524 int64_t abs_value = (neg) ? -value : value;
525 ArmOpcode opcode = kA64Brk1d;
526 ArmOpcode alt_opcode = kA64Brk1d;
527 int32_t log_imm = -1;
528 bool is_wide = OP_KIND_IS_WIDE(op);
529 ArmOpcode wide = (is_wide) ? WIDE(0) : UNWIDE(0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]530
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]531 switch (OP_KIND_UNWIDE(op)) {
532 case kOpLsl: {
533 // "lsl w1, w2, #imm" is an alias of "ubfm w1, w2, #(-imm MOD 32), #(31-imm)"
534 // and "lsl x1, x2, #imm" of "ubfm x1, x2, #(-imm MOD 32), #(31-imm)".
535 // For now, we just use ubfm directly.
536 int max_value = (is_wide) ? 64 : 32;
537 return NewLIR4(kA64Ubfm4rrdd | wide, r_dest.GetReg(), r_src1.GetReg(),
538 (-value) & (max_value - 1), max_value - value);
539 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]540 case kOpLsr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]541 return NewLIR3(kA64Lsr3rrd | wide, r_dest.GetReg(), r_src1.GetReg(), value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]542 case kOpAsr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]543 return NewLIR3(kA64Asr3rrd | wide, r_dest.GetReg(), r_src1.GetReg(), value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]544 case kOpRor:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]545 // "ror r1, r2, #imm" is an alias of "extr r1, r2, r2, #imm".
546 // For now, we just use extr directly.
547 return NewLIR4(kA64Extr4rrrd | wide, r_dest.GetReg(), r_src1.GetReg(), r_src1.GetReg(),
548 value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]549 case kOpAdd:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]550 neg = !neg;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]551 // Note: intentional fallthrough
552 case kOpSub:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]553 // Add and sub below read/write sp rather than xzr.
554 if (abs_value < 0x1000) {
555 opcode = (neg) ? kA64Add4RRdT : kA64Sub4RRdT;
556 return NewLIR4(opcode | wide, r_dest.GetReg(), r_src1.GetReg(), abs_value, 0);
557 } else if ((abs_value & UINT64_C(0xfff)) == 0 && ((abs_value >> 12) < 0x1000)) {
558 opcode = (neg) ? kA64Add4RRdT : kA64Sub4RRdT;
559 return NewLIR4(opcode | wide, r_dest.GetReg(), r_src1.GetReg(), abs_value >> 12, 1);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]560 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]561 log_imm = -1;
562 alt_opcode = (neg) ? kA64Add4rrro : kA64Sub4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]563 }
564 break;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]565 // case kOpRsub:
566 // opcode = kThumb2RsubRRI8M;
567 // alt_opcode = kThumb2RsubRRR;
568 // break;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]569 case kOpAdc:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]570 log_imm = -1;
571 alt_opcode = kA64Adc3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]572 break;
573 case kOpSbc:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]574 log_imm = -1;
575 alt_opcode = kA64Sbc3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]576 break;
577 case kOpOr:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]578 log_imm = EncodeLogicalImmediate(is_wide, value);
579 opcode = kA64Orr3Rrl;
580 alt_opcode = kA64Orr4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]581 break;
582 case kOpAnd:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]583 log_imm = EncodeLogicalImmediate(is_wide, value);
584 opcode = kA64And3Rrl;
585 alt_opcode = kA64And4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]586 break;
587 case kOpXor:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]588 log_imm = EncodeLogicalImmediate(is_wide, value);
589 opcode = kA64Eor3Rrl;
590 alt_opcode = kA64Eor4rrro;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]591 break;
592 case kOpMul:
593 // TUNING: power of 2, shift & add
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]594 log_imm = -1;
595 alt_opcode = kA64Mul3rrr;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]596 break;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]597 default:
598 LOG(FATAL) << "Bad opcode: " << op;
599 }
600
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]601 if (log_imm >= 0) {
602 return NewLIR3(opcode | wide, r_dest.GetReg(), r_src1.GetReg(), log_imm);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]603 } else {
604 RegStorage r_scratch = AllocTemp();
605 LoadConstant(r_scratch, value);
606 if (EncodingMap[alt_opcode].flags & IS_QUAD_OP)
607 res = NewLIR4(alt_opcode, r_dest.GetReg(), r_src1.GetReg(), r_scratch.GetReg(), 0);
608 else
609 res = NewLIR3(alt_opcode, r_dest.GetReg(), r_src1.GetReg(), r_scratch.GetReg());
610 FreeTemp(r_scratch);
611 return res;
612 }
613}
614
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]615LIR* Arm64Mir2Lir::OpRegImm(OpKind op, RegStorage r_dest_src1, int value) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]616 return OpRegImm64(op, r_dest_src1, static_cast<int64_t>(value), /*is_wide*/false);
617}
618
619LIR* Arm64Mir2Lir::OpRegImm64(OpKind op, RegStorage r_dest_src1, int64_t value, bool is_wide) {
620 ArmOpcode wide = (is_wide) ? WIDE(0) : UNWIDE(0);
621 ArmOpcode opcode = kA64Brk1d;
622 ArmOpcode neg_opcode = kA64Brk1d;
623 bool shift;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]624 bool neg = (value < 0);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]625 uint64_t abs_value = (neg) ? -value : value;
626
627 if (LIKELY(abs_value < 0x1000)) {
628 // abs_value is a 12-bit immediate.
629 shift = false;
630 } else if ((abs_value & UINT64_C(0xfff)) == 0 && ((abs_value >> 12) < 0x1000)) {
631 // abs_value is a shifted 12-bit immediate.
632 shift = true;
633 abs_value >>= 12;
634 } else {
635 RegStorage r_tmp = AllocTemp();
636 LIR* res = LoadConstant(r_tmp, value);
637 OpRegReg(op, r_dest_src1, r_tmp);
638 FreeTemp(r_tmp);
639 return res;
640 }
641
642 switch (OP_KIND_UNWIDE(op)) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]643 case kOpAdd:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]644 neg_opcode = kA64Sub4RRdT;
645 opcode = kA64Add4RRdT;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]646 break;
647 case kOpSub:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]648 neg_opcode = kA64Add4RRdT;
649 opcode = kA64Sub4RRdT;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]650 break;
651 case kOpCmp:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]652 neg_opcode = kA64Cmn3RdT;
653 opcode = kA64Cmp3RdT;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]654 break;
655 default:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]656 LOG(FATAL) << "Bad op-kind in OpRegImm: " << op;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]657 break;
658 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]659
660 if (UNLIKELY(neg))
661 opcode = neg_opcode;
662
663 if (EncodingMap[opcode].flags & IS_QUAD_OP)
664 return NewLIR4(opcode | wide, r_dest_src1.GetReg(), r_dest_src1.GetReg(), abs_value,
665 (shift) ? 1 : 0);
666 else
667 return NewLIR3(opcode | wide, r_dest_src1.GetReg(), abs_value, (shift) ? 1 : 0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]668}
669
670LIR* Arm64Mir2Lir::LoadConstantWide(RegStorage r_dest, int64_t value) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]671 if (r_dest.IsFloat()) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]672 return LoadFPConstantValueWide(r_dest.GetReg(), value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]673 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]674 // TODO(Arm64): check whether we can load the immediate with a short form.
675 // e.g. via movz, movk or via logical immediate.
676
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]677 // No short form - load from the literal pool.
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]678 int32_t val_lo = Low32Bits(value);
679 int32_t val_hi = High32Bits(value);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]680 LIR* data_target = ScanLiteralPoolWide(literal_list_, val_lo, val_hi);
681 if (data_target == NULL) {
682 data_target = AddWideData(&literal_list_, val_lo, val_hi);
683 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]684
685 LIR* res = RawLIR(current_dalvik_offset_, WIDE(kA64Ldr2rp),
686 r_dest.GetReg(), 0, 0, 0, 0, data_target);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]687 SetMemRefType(res, true, kLiteral);
688 AppendLIR(res);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]689 return res;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]690 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]691}
692
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]693int Arm64Mir2Lir::EncodeShift(int shift_type, int amount) {
694 return ((shift_type & 0x3) << 7) | (amount & 0x1f);
695}
696
697int Arm64Mir2Lir::EncodeExtend(int extend_type, int amount) {
698 return (1 << 6) | ((extend_type & 0x7) << 3) | (amount & 0x7);
699}
700
701bool Arm64Mir2Lir::IsExtendEncoding(int encoded_value) {
702 return ((1 << 6) & encoded_value) != 0;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]703}
704
705LIR* Arm64Mir2Lir::LoadBaseIndexed(RegStorage r_base, RegStorage r_index, RegStorage r_dest,
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]706 int scale, OpSize size) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]707 LIR* load;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]708 ArmOpcode opcode = kA64Brk1d;
709 ArmOpcode wide = kA64NotWide;
710
711 DCHECK(scale == 0 || scale == 1);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]712
713 if (r_dest.IsFloat()) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]714 bool is_double = r_dest.IsDouble();
715 bool is_single = !is_double;
716 DCHECK_EQ(is_single, r_dest.IsSingle());
717
718 // If r_dest is a single, then size must be either k32 or kSingle.
719 // If r_dest is a double, then size must be either k64 or kDouble.
720 DCHECK(!is_single || size == k32 || size == kSingle);
721 DCHECK(!is_double || size == k64 || size == kDouble);
722 return NewLIR4((is_double) ? FWIDE(kA64Ldr4fXxG) : kA64Ldr4fXxG,
723 r_dest.GetReg(), r_base.GetReg(), r_index.GetReg(), scale);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]724 }
725
726 switch (size) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]727 case kDouble:
728 case kWord:
729 case k64:
730 wide = kA64Wide;
731 // Intentional fall-trough.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]732 case kSingle:
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]733 case k32:
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]734 case kReference:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]735 opcode = kA64Ldr4rXxG;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]736 break;
737 case kUnsignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]738 opcode = kA64Ldrh4wXxd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]739 break;
740 case kSignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]741 opcode = kA64Ldrsh4rXxd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]742 break;
743 case kUnsignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]744 opcode = kA64Ldrb3wXx;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]745 break;
746 case kSignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]747 opcode = kA64Ldrsb3rXx;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]748 break;
749 default:
750 LOG(FATAL) << "Bad size: " << size;
751 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]752
753 if (UNLIKELY((EncodingMap[opcode].flags & IS_TERTIARY_OP) != 0)) {
754 // Tertiary ops (e.g. ldrb, ldrsb) do not support scale.
755 DCHECK_EQ(scale, 0);
756 load = NewLIR3(opcode | wide, r_dest.GetReg(), r_base.GetReg(), r_index.GetReg());
757 } else {
758 DCHECK(scale == 0 || scale == ((wide == kA64Wide) ? 3 : 2));
759 load = NewLIR4(opcode | wide, r_dest.GetReg(), r_base.GetReg(), r_index.GetReg(),
760 (scale != 0) ? 1 : 0);
761 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]762
763 return load;
764}
765
766LIR* Arm64Mir2Lir::StoreBaseIndexed(RegStorage r_base, RegStorage r_index, RegStorage r_src,
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]767 int scale, OpSize size) {
768 LIR* store;
769 ArmOpcode opcode = kA64Brk1d;
770 ArmOpcode wide = kA64NotWide;
771
772 DCHECK(scale == 0 || scale == 1);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]773
774 if (r_src.IsFloat()) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]775 bool is_double = r_src.IsDouble();
776 bool is_single = !is_double;
777 DCHECK_EQ(is_single, r_src.IsSingle());
778
779 // If r_src is a single, then size must be either k32 or kSingle.
780 // If r_src is a double, then size must be either k64 or kDouble.
781 DCHECK(!is_single || size == k32 || size == kSingle);
782 DCHECK(!is_double || size == k64 || size == kDouble);
783 return NewLIR4((is_double) ? FWIDE(kA64Str4fXxG) : kA64Str4fXxG,
784 r_src.GetReg(), r_base.GetReg(), r_index.GetReg(), scale);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]785 }
786
787 switch (size) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]788 case kDouble: // Intentional fall-trough.
789 case kWord: // Intentional fall-trough.
790 case k64:
791 opcode = kA64Str4rXxG;
792 wide = kA64Wide;
793 break;
794 case kSingle: // Intentional fall-trough.
795 case k32: // Intentional fall-trough.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]796 case kReference:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]797 opcode = kA64Str4rXxG;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]798 break;
799 case kUnsignedHalf:
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]800 case kSignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]801 opcode = kA64Strh4wXxd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]802 break;
803 case kUnsignedByte:
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]804 case kSignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]805 opcode = kA64Strb3wXx;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]806 break;
807 default:
808 LOG(FATAL) << "Bad size: " << size;
809 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]810
811 if (UNLIKELY((EncodingMap[opcode].flags & IS_TERTIARY_OP) != 0)) {
812 // Tertiary ops (e.g. strb) do not support scale.
813 DCHECK_EQ(scale, 0);
814 store = NewLIR3(opcode | wide, r_src.GetReg(), r_base.GetReg(), r_index.GetReg());
815 } else {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]816 store = NewLIR4(opcode, r_src.GetReg(), r_base.GetReg(), r_index.GetReg(), scale);
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]817 }
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]818
819 return store;
820}
821
822/*
823 * Load value from base + displacement. Optionally perform null check
824 * on base (which must have an associated s_reg and MIR). If not
825 * performing null check, incoming MIR can be null.
826 */
827LIR* Arm64Mir2Lir::LoadBaseDispBody(RegStorage r_base, int displacement, RegStorage r_dest,
Vladimir Marko3bf7c602014-05-07 14:55:43 +0100[diff] [blame]828 OpSize size) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]829 LIR* load = NULL;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]830 ArmOpcode opcode = kA64Brk1d;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]831 bool short_form = false;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]832 int encoded_disp = displacement;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]833 switch (size) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]834 case kDouble: // Intentional fall-through.
835 case kWord: // Intentional fall-through.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]836 case k64:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]837 DCHECK_EQ(encoded_disp & 0x3, 0);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]838 if (r_dest.IsFloat()) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]839 // Currently double values may be misaligned.
840 if ((displacement & 0x7) == 0 && displacement >= 0 && displacement <= 32760) {
841 // Can use scaled load.
842 opcode = FWIDE(kA64Ldr3fXD);
843 encoded_disp >>= 3;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]844 short_form = true;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]845 } else if (IS_SIGNED_IMM9(displacement)) {
846 // Can use unscaled load.
847 opcode = FWIDE(kA64Ldur3fXd);
848 short_form = true;
849 } else {
850 short_form = false;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]851 }
852 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]853 // Currently long values may be misaligned.
854 if ((displacement & 0x7) == 0 && displacement >= 0 && displacement <= 32760) {
855 // Can use scaled store.
856 opcode = FWIDE(kA64Ldr3rXD);
857 encoded_disp >>= 3;
858 short_form = true;
859 } else if (IS_SIGNED_IMM9(displacement)) {
860 // Can use unscaled store.
861 opcode = FWIDE(kA64Ldur3rXd);
862 short_form = true;
863 } // else: use long sequence (short_form = false).
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]864 }
865 break;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]866 case kSingle: // Intentional fall-through.
867 case k32: // Intentional fall-trough.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]868 case kReference:
869 if (r_dest.IsFloat()) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]870 opcode = kA64Ldr3fXD;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]871 if (displacement <= 1020) {
872 short_form = true;
873 encoded_disp >>= 2;
874 }
875 break;
876 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]877 if (displacement <= 16380 && displacement >= 0) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]878 DCHECK_EQ((displacement & 0x3), 0);
879 short_form = true;
880 encoded_disp >>= 2;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]881 opcode = kA64Ldr3rXD;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]882 }
883 break;
884 case kUnsignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]885 if (displacement < 64 && displacement >= 0) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]886 DCHECK_EQ((displacement & 0x1), 0);
887 short_form = true;
888 encoded_disp >>= 1;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]889 opcode = kA64Ldrh3wXF;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]890 } else if (displacement < 4092 && displacement >= 0) {
891 short_form = true;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]892 opcode = kA64Ldrh3wXF;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]893 }
894 break;
895 case kSignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]896 short_form = true;
897 opcode = kA64Ldrsh3rXF;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]898 break;
899 case kUnsignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]900 short_form = true;
901 opcode = kA64Ldrb3wXd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]902 break;
903 case kSignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]904 short_form = true;
905 opcode = kA64Ldrsb3rXd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]906 break;
907 default:
908 LOG(FATAL) << "Bad size: " << size;
909 }
910
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]911 if (short_form) {
912 load = NewLIR3(opcode, r_dest.GetReg(), r_base.GetReg(), encoded_disp);
913 } else {
914 RegStorage reg_offset = AllocTemp();
915 LoadConstant(reg_offset, encoded_disp);
916 if (r_dest.IsFloat()) {
917 // No index ops - must use a long sequence. Turn the offset into a direct pointer.
918 OpRegReg(kOpAdd, reg_offset, r_base);
919 load = LoadBaseDispBody(reg_offset, 0, r_dest, size);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]920 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]921 load = LoadBaseIndexed(r_base, reg_offset, r_dest, 0, size);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]922 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]923 FreeTemp(reg_offset);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]924 }
925
926 // TODO: in future may need to differentiate Dalvik accesses w/ spills
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]927 if (r_base == rs_rA64_SP) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]928 AnnotateDalvikRegAccess(load, displacement >> 2, true /* is_load */, r_dest.Is64Bit());
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]929 }
930 return load;
931}
932
Vladimir Marko3bf7c602014-05-07 14:55:43 +0100[diff] [blame]933LIR* Arm64Mir2Lir::LoadBaseDisp(RegStorage r_base, int displacement, RegStorage r_dest,
934 OpSize size) {
Vladimir Marko3bf7c602014-05-07 14:55:43 +0100[diff] [blame]935 return LoadBaseDispBody(r_base, displacement, r_dest, size);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]936}
937
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]938
939LIR* Arm64Mir2Lir::StoreBaseDispBody(RegStorage r_base, int displacement, RegStorage r_src,
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]940 OpSize size) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]941 LIR* store = NULL;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]942 ArmOpcode opcode = kA64Brk1d;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]943 bool short_form = false;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]944 int encoded_disp = displacement;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]945 switch (size) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]946 case kDouble: // Intentional fall-through.
947 case kWord: // Intentional fall-through.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]948 case k64:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]949 DCHECK_EQ(encoded_disp & 0x3, 0);
950 if (r_src.IsFloat()) {
951 // Currently double values may be misaligned.
952 if ((displacement & 0x7) == 0 && displacement >= 0 && displacement <= 32760) {
953 // Can use scaled store.
954 opcode = FWIDE(kA64Str3fXD);
955 encoded_disp >>= 3;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]956 short_form = true;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]957 } else if (IS_SIGNED_IMM9(displacement)) {
958 // Can use unscaled store.
959 opcode = FWIDE(kA64Stur3fXd);
960 short_form = true;
961 } // else: use long sequence (short_form = false).
962 } else {
963 // Currently long values may be misaligned.
964 if ((displacement & 0x7) == 0 && displacement >= 0 && displacement <= 32760) {
965 // Can use scaled store.
966 opcode = FWIDE(kA64Str3rXD);
967 encoded_disp >>= 3;
968 short_form = true;
969 } else if (IS_SIGNED_IMM9(displacement)) {
970 // Can use unscaled store.
971 opcode = FWIDE(kA64Stur3rXd);
972 short_form = true;
973 } // else: use long sequence (short_form = false).
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]974 }
975 break;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]976 case kSingle: // Intentional fall-through.
977 case k32: // Intentional fall-trough.
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]978 case kReference:
979 if (r_src.IsFloat()) {
980 DCHECK(r_src.IsSingle());
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]981 DCHECK_EQ(encoded_disp & 0x3, 0);
982 opcode = kA64Str3fXD;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]983 if (displacement <= 1020) {
984 short_form = true;
985 encoded_disp >>= 2;
986 }
987 break;
988 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]989
990 if (displacement <= 16380 && displacement >= 0) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]991 DCHECK_EQ((displacement & 0x3), 0);
992 short_form = true;
993 encoded_disp >>= 2;
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]994 opcode = kA64Str3rXD;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]995 }
996 break;
997 case kUnsignedHalf:
998 case kSignedHalf:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]999 DCHECK_EQ((displacement & 0x1), 0);
1000 short_form = true;
1001 encoded_disp >>= 1;
1002 opcode = kA64Strh3wXF;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1003 break;
1004 case kUnsignedByte:
1005 case kSignedByte:
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1006 short_form = true;
1007 opcode = kA64Strb3wXd;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1008 break;
1009 default:
1010 LOG(FATAL) << "Bad size: " << size;
1011 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1012
1013 if (short_form) {
1014 store = NewLIR3(opcode, r_src.GetReg(), r_base.GetReg(), encoded_disp);
1015 } else {
1016 RegStorage r_scratch = AllocTemp();
1017 LoadConstant(r_scratch, encoded_disp);
1018 if (r_src.IsFloat()) {
1019 // No index ops - must use a long sequence. Turn the offset into a direct pointer.
1020 OpRegReg(kOpAdd, r_scratch, r_base);
1021 store = StoreBaseDispBody(r_scratch, 0, r_src, size);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1022 } else {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1023 store = StoreBaseIndexed(r_base, r_scratch, r_src, 0, size);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1024 }
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1025 FreeTemp(r_scratch);
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1026 }
1027
1028 // TODO: In future, may need to differentiate Dalvik & spill accesses
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1029 if (r_base == rs_rA64_SP) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1030 AnnotateDalvikRegAccess(store, displacement >> 2, false /* is_load */, r_src.Is64Bit());
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1031 }
1032 return store;
1033}
1034
1035LIR* Arm64Mir2Lir::StoreBaseDisp(RegStorage r_base, int displacement, RegStorage r_src,
1036 OpSize size) {
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1037 return StoreBaseDispBody(r_base, displacement, r_src, size);
1038}
1039
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1040LIR* Arm64Mir2Lir::OpFpRegCopy(RegStorage r_dest, RegStorage r_src) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1041 LOG(FATAL) << "Unexpected use of OpFpRegCopy for Arm64";
1042 return NULL;
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1043}
1044
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1045LIR* Arm64Mir2Lir::OpThreadMem(OpKind op, A64ThreadOffset thread_offset) {
1046 LOG(FATAL) << "Unexpected use of OpThreadMem for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1047 return NULL;
1048}
1049
1050LIR* Arm64Mir2Lir::OpMem(OpKind op, RegStorage r_base, int disp) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1051 LOG(FATAL) << "Unexpected use of OpMem for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1052 return NULL;
1053}
1054
1055LIR* Arm64Mir2Lir::StoreBaseIndexedDisp(RegStorage r_base, RegStorage r_index, int scale,
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1056 int displacement, RegStorage r_src, OpSize size) {
1057 LOG(FATAL) << "Unexpected use of StoreBaseIndexedDisp for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1058 return NULL;
1059}
1060
1061LIR* Arm64Mir2Lir::OpRegMem(OpKind op, RegStorage r_dest, RegStorage r_base, int offset) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1062 LOG(FATAL) << "Unexpected use of OpRegMem for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1063 return NULL;
1064}
1065
1066LIR* Arm64Mir2Lir::LoadBaseIndexedDisp(RegStorage r_base, RegStorage r_index, int scale,
Vladimir Marko3bf7c602014-05-07 14:55:43 +0100[diff] [blame]1067 int displacement, RegStorage r_dest, OpSize size) {
Matteo Franchine45fb9e2014-05-06 10:10:30 +0100[diff] [blame^]1068 LOG(FATAL) << "Unexpected use of LoadBaseIndexedDisp for Arm64";
Matteo Franchin43ec8732014-03-31 15:00:14 +0100[diff] [blame]1069 return NULL;
1070}
1071
1072} // namespace art