/* * Copyright (C) 2011 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "arm64_lir.h" #include "codegen_arm64.h" #include "dex/quick/mir_to_lir-inl.h" namespace art { // The macros below are exclusively used in the encoding map. // Most generic way of providing two variants for one instructions. #define CUSTOM_VARIANTS(variant1, variant2) variant1, variant2 // Used for instructions which do not have a wide variant. #define NO_VARIANTS(variant) \ CUSTOM_VARIANTS(variant, 0) // Used for instructions which have a wide variant with the sf bit set to 1. #define SF_VARIANTS(sf0_skeleton) \ CUSTOM_VARIANTS(sf0_skeleton, (sf0_skeleton | 0x80000000)) // Used for instructions which have a wide variant with the size bits set to either x0 or x1. #define SIZE_VARIANTS(sizex0_skeleton) \ CUSTOM_VARIANTS(sizex0_skeleton, (sizex0_skeleton | 0x40000000)) // Used for instructions which have a wide variant with the sf and n bits set to 1. #define SF_N_VARIANTS(sf0_n0_skeleton) \ CUSTOM_VARIANTS(sf0_n0_skeleton, (sf0_n0_skeleton | 0x80400000)) // Used for FP instructions which have a single and double precision variants, with he type bits set // to either 00 or 01. #define FLOAT_VARIANTS(type00_skeleton) \ CUSTOM_VARIANTS(type00_skeleton, (type00_skeleton | 0x00400000)) /* * opcode: A64Opcode enum * variants: instruction skeletons supplied via CUSTOM_VARIANTS or derived macros. * a{n}k: key to applying argument {n} \ * a{n}s: argument {n} start bit position | n = 0, 1, 2, 3 * a{n}e: argument {n} end bit position / * flags: instruction attributes (used in optimization) * name: mnemonic name * fmt: for pretty-printing * fixup: used for second-pass fixes (e.g. adresses fixups in branch instructions). */ #define ENCODING_MAP(opcode, variants, a0k, a0s, a0e, a1k, a1s, a1e, a2k, a2s, a2e, \ a3k, a3s, a3e, flags, name, fmt, fixup) \ {variants, {{a0k, a0s, a0e}, {a1k, a1s, a1e}, {a2k, a2s, a2e}, \ {a3k, a3s, a3e}}, opcode, flags, name, fmt, 4, fixup} /* Instruction dump string format keys: !pf, where "!" is the start * of the key, "p" is which numeric operand to use and "f" is the * print format. * * [p]ositions: * 0 -> operands[0] (dest) * 1 -> operands[1] (src1) * 2 -> operands[2] (src2) * 3 -> operands[3] (extra) * * [f]ormats: * d -> decimal * D -> decimal*4 or decimal*8 depending on the instruction width * E -> decimal*4 * F -> decimal*2 * G -> ", lsl #2" or ", lsl #3" depending on the instruction width * c -> branch condition (eq, ne, etc.) * t -> pc-relative target * p -> pc-relative address * s -> single precision floating point register * S -> double precision floating point register * f -> single or double precision register (depending on instruction width) * I -> 8-bit immediate floating point number * l -> logical immediate * M -> 16-bit shift expression ("" or ", lsl #16" or ", lsl #32"...) * B -> dmb option string (sy, st, ish, ishst, nsh, hshst) * H -> operand shift * h -> 6-bit shift immediate * T -> register shift (either ", lsl #0" or ", lsl #12") * e -> register extend (e.g. uxtb #1) * o -> register shift (e.g. lsl #1) for Word registers * w -> word (32-bit) register wn, or wzr * W -> word (32-bit) register wn, or wsp * x -> extended (64-bit) register xn, or xzr * X -> extended (64-bit) register xn, or sp * r -> register with same width as instruction, r31 -> wzr, xzr * R -> register with same width as instruction, r31 -> wsp, sp * * [!] escape. To insert "!", use "!!" */ /* NOTE: must be kept in sync with enum A64Opcode from arm64_lir.h */ const A64EncodingMap Arm64Mir2Lir::EncodingMap[kA64Last] = { ENCODING_MAP(WIDE(kA64Adc3rrr), SF_VARIANTS(0x1a000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "adc", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Add4RRdT), SF_VARIANTS(0x11000000), kFmtRegROrSp, 4, 0, kFmtRegROrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtBitBlt, 23, 22, IS_QUAD_OP | REG_DEF0_USE1, "add", "!0R, !1R, #!2d!3T", kFixupNone), ENCODING_MAP(WIDE(kA64Add4rrro), SF_VARIANTS(0x0b000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "add", "!0r, !1r, !2r!3o", kFixupNone), ENCODING_MAP(WIDE(kA64Add4RRre), SF_VARIANTS(0x0b200000), kFmtRegROrSp, 4, 0, kFmtRegROrSp, 9, 5, kFmtRegR, 20, 16, kFmtExtend, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "add", "!0r, !1r, !2r!3e", kFixupNone), // Note: adr is binary, but declared as tertiary. The third argument is used while doing the // fixups and contains information to identify the adr label. ENCODING_MAP(kA64Adr2xd, NO_VARIANTS(0x10000000), kFmtRegX, 4, 0, kFmtImm21, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0 | NEEDS_FIXUP, "adr", "!0x, #!1d", kFixupAdr), ENCODING_MAP(WIDE(kA64And3Rrl), SF_VARIANTS(0x12000000), kFmtRegROrSp, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 22, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "and", "!0R, !1r, #!2l", kFixupNone), ENCODING_MAP(WIDE(kA64And4rrro), SF_VARIANTS(0x0a000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "and", "!0r, !1r, !2r!3o", kFixupNone), ENCODING_MAP(WIDE(kA64Asr3rrd), CUSTOM_VARIANTS(0x13007c00, 0x9340fc00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 21, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "asr", "!0r, !1r, #!2d", kFixupNone), ENCODING_MAP(WIDE(kA64Asr3rrr), SF_VARIANTS(0x1ac02800), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "asr", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(kA64B2ct, NO_VARIANTS(0x54000000), kFmtBitBlt, 3, 0, kFmtBitBlt, 23, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | IS_BRANCH | USES_CCODES | NEEDS_FIXUP, "b.!0c", "!1t", kFixupCondBranch), ENCODING_MAP(kA64Blr1x, NO_VARIANTS(0xd63f0000), kFmtRegX, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | REG_USE0 | IS_BRANCH | REG_DEF_LR, "blr", "!0x", kFixupNone), ENCODING_MAP(kA64Br1x, NO_VARIANTS(0xd61f0000), kFmtRegX, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | REG_USE0 | IS_BRANCH, "br", "!0x", kFixupNone), ENCODING_MAP(kA64Bl1t, NO_VARIANTS(0x94000000), kFmtBitBlt, 25, 0, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | IS_BRANCH | REG_DEF_LR | NEEDS_FIXUP, "bl", "!0T", kFixupLabel), ENCODING_MAP(kA64Brk1d, NO_VARIANTS(0xd4200000), kFmtBitBlt, 20, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | IS_BRANCH, "brk", "!0d", kFixupNone), ENCODING_MAP(kA64B1t, NO_VARIANTS(0x14000000), kFmtBitBlt, 25, 0, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | IS_BRANCH | NEEDS_FIXUP, "b", "!0t", kFixupT1Branch), ENCODING_MAP(WIDE(kA64Cbnz2rt), SF_VARIANTS(0x35000000), kFmtRegR, 4, 0, kFmtBitBlt, 23, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_USE0 | IS_BRANCH | NEEDS_FIXUP, "cbnz", "!0r, !1t", kFixupCBxZ), ENCODING_MAP(WIDE(kA64Cbz2rt), SF_VARIANTS(0x34000000), kFmtRegR, 4, 0, kFmtBitBlt, 23, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_USE0 | IS_BRANCH | NEEDS_FIXUP, "cbz", "!0r, !1t", kFixupCBxZ), ENCODING_MAP(WIDE(kA64Cmn3rro), SF_VARIANTS(0x2b00001f), kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | SETS_CCODES, "cmn", "!0r, !1r!2o", kFixupNone), ENCODING_MAP(WIDE(kA64Cmn3Rre), SF_VARIANTS(0x2b20001f), kFmtRegROrSp, 9, 5, kFmtRegR, 20, 16, kFmtExtend, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | SETS_CCODES, "cmn", "!0R, !1r!2e", kFixupNone), ENCODING_MAP(WIDE(kA64Cmn3RdT), SF_VARIANTS(0x3100001f), kFmtRegROrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtBitBlt, 23, 22, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE0 | SETS_CCODES, "cmn", "!0R, #!1d!2T", kFixupNone), ENCODING_MAP(WIDE(kA64Cmp3rro), SF_VARIANTS(0x6b00001f), kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | SETS_CCODES, "cmp", "!0r, !1r!2o", kFixupNone), ENCODING_MAP(WIDE(kA64Cmp3Rre), SF_VARIANTS(0x6b20001f), kFmtRegROrSp, 9, 5, kFmtRegR, 20, 16, kFmtExtend, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | SETS_CCODES, "cmp", "!0R, !1r!2e", kFixupNone), ENCODING_MAP(WIDE(kA64Cmp3RdT), SF_VARIANTS(0x7100001f), kFmtRegROrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtBitBlt, 23, 22, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE0 | SETS_CCODES, "cmp", "!0R, #!1d!2T", kFixupNone), ENCODING_MAP(WIDE(kA64Csel4rrrc), SF_VARIANTS(0x1a800000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtBitBlt, 15, 12, IS_QUAD_OP | REG_DEF0_USE12 | USES_CCODES, "csel", "!0r, !1r, !2r, !3c", kFixupNone), ENCODING_MAP(WIDE(kA64Csinc4rrrc), SF_VARIANTS(0x1a800400), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtBitBlt, 15, 12, IS_QUAD_OP | REG_DEF0_USE12 | USES_CCODES, "csinc", "!0r, !1r, !2r, !3c", kFixupNone), ENCODING_MAP(WIDE(kA64Csinv4rrrc), SF_VARIANTS(0x5a800000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtBitBlt, 15, 12, IS_QUAD_OP | REG_DEF0_USE12 | USES_CCODES, "csinv", "!0r, !1r, !2r, !3c", kFixupNone), ENCODING_MAP(WIDE(kA64Csneg4rrrc), SF_VARIANTS(0x5a800400), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtBitBlt, 15, 12, IS_QUAD_OP | REG_DEF0_USE12 | USES_CCODES, "csneg", "!0r, !1r, !2r, !3c", kFixupNone), ENCODING_MAP(kA64Dmb1B, NO_VARIANTS(0xd50330bf), kFmtBitBlt, 11, 8, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | IS_VOLATILE, "dmb", "#!0B", kFixupNone), ENCODING_MAP(WIDE(kA64Eor3Rrl), SF_VARIANTS(0x52000000), kFmtRegROrSp, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 22, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "eor", "!0R, !1r, #!2l", kFixupNone), ENCODING_MAP(WIDE(kA64Eor4rrro), SF_VARIANTS(0x4a000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "eor", "!0r, !1r, !2r!3o", kFixupNone), ENCODING_MAP(WIDE(kA64Extr4rrrd), SF_N_VARIANTS(0x13800000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtBitBlt, 15, 10, IS_QUAD_OP | REG_DEF0_USE12, "extr", "!0r, !1r, !2r, #!3d", kFixupNone), ENCODING_MAP(WIDE(kA64Fabs2ff), FLOAT_VARIANTS(0x1e20c000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP| REG_DEF0_USE1, "fabs", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fadd3fff), FLOAT_VARIANTS(0x1e202800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fadd", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(WIDE(kA64Fcmp1f), FLOAT_VARIANTS(0x1e202008), kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_UNARY_OP | REG_USE0 | SETS_CCODES, "fcmp", "!0f, #0", kFixupNone), ENCODING_MAP(WIDE(kA64Fcmp2ff), FLOAT_VARIANTS(0x1e202000), kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_USE01 | SETS_CCODES, "fcmp", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fcvtzs2wf), FLOAT_VARIANTS(0x1e380000), kFmtRegW, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvtzs", "!0w, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fcvtzs2xf), FLOAT_VARIANTS(0x9e380000), kFmtRegX, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvtzs", "!0x, !1f", kFixupNone), ENCODING_MAP(kA64Fcvt2Ss, NO_VARIANTS(0x1e22C000), kFmtRegD, 4, 0, kFmtRegS, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvt", "!0S, !1s", kFixupNone), ENCODING_MAP(kA64Fcvt2sS, NO_VARIANTS(0x1e624000), kFmtRegS, 4, 0, kFmtRegD, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvt", "!0s, !1S", kFixupNone), ENCODING_MAP(kA64Fcvtms2ws, NO_VARIANTS(0x1e300000), kFmtRegW, 4, 0, kFmtRegS, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvtms", "!0w, !1s", kFixupNone), ENCODING_MAP(kA64Fcvtms2xS, NO_VARIANTS(0x9e700000), kFmtRegX, 4, 0, kFmtRegD, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fcvtms", "!0x, !1S", kFixupNone), ENCODING_MAP(WIDE(kA64Fdiv3fff), FLOAT_VARIANTS(0x1e201800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fdiv", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(WIDE(kA64Fmax3fff), FLOAT_VARIANTS(0x1e204800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fmax", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(WIDE(kA64Fmin3fff), FLOAT_VARIANTS(0x1e205800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fmin", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(WIDE(kA64Fmov2ff), FLOAT_VARIANTS(0x1e204000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1 | IS_MOVE, "fmov", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fmov2fI), FLOAT_VARIANTS(0x1e201000), kFmtRegF, 4, 0, kFmtBitBlt, 20, 13, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0, "fmov", "!0f, #!1I", kFixupNone), ENCODING_MAP(kA64Fmov2sw, NO_VARIANTS(0x1e270000), kFmtRegS, 4, 0, kFmtRegW, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fmov", "!0s, !1w", kFixupNone), ENCODING_MAP(kA64Fmov2Sx, NO_VARIANTS(0x9e670000), kFmtRegD, 4, 0, kFmtRegX, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fmov", "!0S, !1x", kFixupNone), ENCODING_MAP(kA64Fmov2ws, NO_VARIANTS(0x1e260000), kFmtRegW, 4, 0, kFmtRegS, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fmov", "!0w, !1s", kFixupNone), ENCODING_MAP(kA64Fmov2xS, NO_VARIANTS(0x9e660000), kFmtRegX, 4, 0, kFmtRegD, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fmov", "!0x, !1S", kFixupNone), ENCODING_MAP(WIDE(kA64Fmul3fff), FLOAT_VARIANTS(0x1e200800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fmul", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(WIDE(kA64Fneg2ff), FLOAT_VARIANTS(0x1e214000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fneg", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Frintp2ff), FLOAT_VARIANTS(0x1e24c000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "frintp", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Frintm2ff), FLOAT_VARIANTS(0x1e254000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "frintm", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Frintn2ff), FLOAT_VARIANTS(0x1e244000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "frintn", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Frintz2ff), FLOAT_VARIANTS(0x1e25c000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "frintz", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fsqrt2ff), FLOAT_VARIANTS(0x1e61c000), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "fsqrt", "!0f, !1f", kFixupNone), ENCODING_MAP(WIDE(kA64Fsub3fff), FLOAT_VARIANTS(0x1e203800), kFmtRegF, 4, 0, kFmtRegF, 9, 5, kFmtRegF, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "fsub", "!0f, !1f, !2f", kFixupNone), ENCODING_MAP(kA64Ldrb3wXd, NO_VARIANTS(0x39400000), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldrb", "!0w, [!1X, #!2d]", kFixupNone), ENCODING_MAP(kA64Ldrb3wXx, NO_VARIANTS(0x38606800), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12 | IS_LOAD, "ldrb", "!0w, [!1X, !2x]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldrsb3rXd), CUSTOM_VARIANTS(0x39c00000, 0x39800000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldrsb", "!0r, [!1X, #!2d]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldrsb3rXx), CUSTOM_VARIANTS(0x38e06800, 0x38a06800), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12 | IS_LOAD, "ldrsb", "!0r, [!1X, !2x]", kFixupNone), ENCODING_MAP(kA64Ldrh3wXF, NO_VARIANTS(0x79400000), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldrh", "!0w, [!1X, #!2F]", kFixupNone), ENCODING_MAP(kA64Ldrh4wXxd, NO_VARIANTS(0x78606800), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_DEF0_USE12 | IS_LOAD_OFF, "ldrh", "!0w, [!1X, !2x, lsl #!3d]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldrsh3rXF), CUSTOM_VARIANTS(0x79c00000, 0x79800000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldrsh", "!0r, [!1X, #!2F]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldrsh4rXxd), CUSTOM_VARIANTS(0x78e06800, 0x78906800), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_DEF0_USE12 | IS_LOAD_OFF, "ldrsh", "!0r, [!1X, !2x, lsl #!3d]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldr2fp), SIZE_VARIANTS(0x1c000000), kFmtRegF, 4, 0, kFmtBitBlt, 23, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0 | REG_USE_PC | IS_LOAD | NEEDS_FIXUP, "ldr", "!0f, !1p", kFixupLoad), ENCODING_MAP(WIDE(kA64Ldr2rp), SIZE_VARIANTS(0x18000000), kFmtRegR, 4, 0, kFmtBitBlt, 23, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0 | REG_USE_PC | IS_LOAD | NEEDS_FIXUP, "ldr", "!0r, !1p", kFixupLoad), ENCODING_MAP(WIDE(kA64Ldr3fXD), SIZE_VARIANTS(0xbd400000), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldr", "!0f, [!1X, #!2D]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldr3rXD), SIZE_VARIANTS(0xb9400000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD_OFF, "ldr", "!0r, [!1X, #!2D]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldr4fXxG), SIZE_VARIANTS(0xbc606800), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_DEF0_USE12 | IS_LOAD, "ldr", "!0f, [!1X, !2x!3G]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldr4rXxG), SIZE_VARIANTS(0xb8606800), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_DEF0_USE12 | IS_LOAD, "ldr", "!0r, [!1X, !2x!3G]", kFixupNone), ENCODING_MAP(WIDE(kA64LdrPost3rXd), SIZE_VARIANTS(0xb8400400), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF01 | REG_USE1 | IS_LOAD, "ldr", "!0r, [!1X], #!2d", kFixupNone), ENCODING_MAP(WIDE(kA64Ldp4ffXD), CUSTOM_VARIANTS(0x2d400000, 0x6d400000), kFmtRegF, 4, 0, kFmtRegF, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_USE2 | REG_DEF01 | IS_LOAD_OFF, "ldp", "!0f, !1f, [!2X, #!3D]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldp4rrXD), SF_VARIANTS(0x29400000), kFmtRegR, 4, 0, kFmtRegR, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_USE2 | REG_DEF01 | IS_LOAD_OFF, "ldp", "!0r, !1r, [!2X, #!3D]", kFixupNone), ENCODING_MAP(WIDE(kA64LdpPost4rrXD), CUSTOM_VARIANTS(0x28c00000, 0xa8c00000), kFmtRegR, 4, 0, kFmtRegR, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_USE2 | REG_DEF012 | IS_LOAD, "ldp", "!0r, !1r, [!2X], #!3D", kFixupNone), ENCODING_MAP(WIDE(kA64Ldur3fXd), CUSTOM_VARIANTS(0xbc400000, 0xfc400000), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD, "ldur", "!0f, [!1X, #!2d]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldur3rXd), SIZE_VARIANTS(0xb8400000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | IS_LOAD, "ldur", "!0r, [!1X, #!2d]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldxr2rX), SIZE_VARIANTS(0x885f7c00), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1 | IS_LOADX, "ldxr", "!0r, [!1X]", kFixupNone), ENCODING_MAP(WIDE(kA64Ldaxr2rX), SIZE_VARIANTS(0x885ffc00), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1 | IS_LOADX, "ldaxr", "!0r, [!1X]", kFixupNone), ENCODING_MAP(WIDE(kA64Lsl3rrr), SF_VARIANTS(0x1ac02000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "lsl", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Lsr3rrd), CUSTOM_VARIANTS(0x53007c00, 0xd340fc00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 21, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "lsr", "!0r, !1r, #!2d", kFixupNone), ENCODING_MAP(WIDE(kA64Lsr3rrr), SF_VARIANTS(0x1ac02400), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "lsr", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Movk3rdM), SF_VARIANTS(0x72800000), kFmtRegR, 4, 0, kFmtBitBlt, 20, 5, kFmtBitBlt, 22, 21, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE0, "movk", "!0r, #!1d!2M", kFixupNone), ENCODING_MAP(WIDE(kA64Movn3rdM), SF_VARIANTS(0x12800000), kFmtRegR, 4, 0, kFmtBitBlt, 20, 5, kFmtBitBlt, 22, 21, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0, "movn", "!0r, #!1d!2M", kFixupNone), ENCODING_MAP(WIDE(kA64Movz3rdM), SF_VARIANTS(0x52800000), kFmtRegR, 4, 0, kFmtBitBlt, 20, 5, kFmtBitBlt, 22, 21, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0, "movz", "!0r, #!1d!2M", kFixupNone), ENCODING_MAP(WIDE(kA64Mov2rr), SF_VARIANTS(0x2a0003e0), kFmtRegR, 4, 0, kFmtRegR, 20, 16, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1 | IS_MOVE, "mov", "!0r, !1r", kFixupNone), ENCODING_MAP(WIDE(kA64Mvn2rr), SF_VARIANTS(0x2a2003e0), kFmtRegR, 4, 0, kFmtRegR, 20, 16, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "mvn", "!0r, !1r", kFixupNone), ENCODING_MAP(WIDE(kA64Mul3rrr), SF_VARIANTS(0x1b007c00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "mul", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Msub4rrrr), SF_VARIANTS(0x1b008000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 14, 10, kFmtRegR, 20, 16, IS_QUAD_OP | REG_DEF0_USE123, "msub", "!0r, !1r, !3r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Neg3rro), SF_VARIANTS(0x4b0003e0), kFmtRegR, 4, 0, kFmtRegR, 20, 16, kFmtShift, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "neg", "!0r, !1r!2o", kFixupNone), ENCODING_MAP(WIDE(kA64Orr3Rrl), SF_VARIANTS(0x32000000), kFmtRegROrSp, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 22, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1, "orr", "!0R, !1r, #!2l", kFixupNone), ENCODING_MAP(WIDE(kA64Orr4rrro), SF_VARIANTS(0x2a000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "orr", "!0r, !1r, !2r!3o", kFixupNone), ENCODING_MAP(kA64Ret, NO_VARIANTS(0xd65f03c0), kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, kFmtUnused, -1, -1, NO_OPERAND | IS_BRANCH, "ret", "", kFixupNone), ENCODING_MAP(WIDE(kA64Rbit2rr), SF_VARIANTS(0x5ac00000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "rbit", "!0r, !1r", kFixupNone), ENCODING_MAP(WIDE(kA64Rev2rr), CUSTOM_VARIANTS(0x5ac00800, 0xdac00c00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "rev", "!0r, !1r", kFixupNone), ENCODING_MAP(WIDE(kA64Rev162rr), SF_VARIANTS(0x5ac00400), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "rev16", "!0r, !1r", kFixupNone), ENCODING_MAP(WIDE(kA64Ror3rrr), SF_VARIANTS(0x1ac02c00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "ror", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Sbc3rrr), SF_VARIANTS(0x5a000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "sbc", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Sbfm4rrdd), SF_N_VARIANTS(0x13000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 21, 16, kFmtBitBlt, 15, 10, IS_QUAD_OP | REG_DEF0_USE1, "sbfm", "!0r, !1r, #!2d, #!3d", kFixupNone), ENCODING_MAP(WIDE(kA64Scvtf2fw), FLOAT_VARIANTS(0x1e220000), kFmtRegF, 4, 0, kFmtRegW, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "scvtf", "!0f, !1w", kFixupNone), ENCODING_MAP(WIDE(kA64Scvtf2fx), FLOAT_VARIANTS(0x9e220000), kFmtRegF, 4, 0, kFmtRegX, 9, 5, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_BINARY_OP | REG_DEF0_USE1, "scvtf", "!0f, !1x", kFixupNone), ENCODING_MAP(WIDE(kA64Sdiv3rrr), SF_VARIANTS(0x1ac00c00), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "sdiv", "!0r, !1r, !2r", kFixupNone), ENCODING_MAP(WIDE(kA64Smaddl4xwwx), NO_VARIANTS(0x9b200000), kFmtRegX, 4, 0, kFmtRegW, 9, 5, kFmtRegW, 20, 16, kFmtRegX, 14, 10, IS_QUAD_OP | REG_DEF0_USE123, "smaddl", "!0x, !1w, !2w, !3x", kFixupNone), ENCODING_MAP(kA64Smulh3xxx, NO_VARIANTS(0x9b407c00), kFmtRegX, 4, 0, kFmtRegX, 9, 5, kFmtRegX, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12, "smulh", "!0x, !1x, !2x", kFixupNone), ENCODING_MAP(WIDE(kA64Stp4ffXD), CUSTOM_VARIANTS(0x2d000000, 0x6d000000), kFmtRegF, 4, 0, kFmtRegF, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_USE012 | IS_STORE_OFF, "stp", "!0f, !1f, [!2X, #!3D]", kFixupNone), ENCODING_MAP(WIDE(kA64Stp4rrXD), SF_VARIANTS(0x29000000), kFmtRegR, 4, 0, kFmtRegR, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_USE012 | IS_STORE_OFF, "stp", "!0r, !1r, [!2X, #!3D]", kFixupNone), ENCODING_MAP(WIDE(kA64StpPost4rrXD), CUSTOM_VARIANTS(0x28800000, 0xa8800000), kFmtRegR, 4, 0, kFmtRegR, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_DEF2 | REG_USE012 | IS_STORE, "stp", "!0r, !1r, [!2X], #!3D", kFixupNone), ENCODING_MAP(WIDE(kA64StpPre4ffXD), CUSTOM_VARIANTS(0x2d800000, 0x6d800000), kFmtRegF, 4, 0, kFmtRegF, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_DEF2 | REG_USE012 | IS_STORE, "stp", "!0f, !1f, [!2X, #!3D]!!", kFixupNone), ENCODING_MAP(WIDE(kA64StpPre4rrXD), CUSTOM_VARIANTS(0x29800000, 0xa9800000), kFmtRegR, 4, 0, kFmtRegR, 14, 10, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 15, IS_QUAD_OP | REG_DEF2 | REG_USE012 | IS_STORE, "stp", "!0r, !1r, [!2X, #!3D]!!", kFixupNone), ENCODING_MAP(WIDE(kA64Str3fXD), CUSTOM_VARIANTS(0xbd000000, 0xfd000000), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE_OFF, "str", "!0f, [!1X, #!2D]", kFixupNone), ENCODING_MAP(WIDE(kA64Str4fXxG), CUSTOM_VARIANTS(0xbc206800, 0xfc206800), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_USE012 | IS_STORE, "str", "!0f, [!1X, !2x!3G]", kFixupNone), ENCODING_MAP(WIDE(kA64Str3rXD), SIZE_VARIANTS(0xb9000000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE_OFF, "str", "!0r, [!1X, #!2D]", kFixupNone), ENCODING_MAP(WIDE(kA64Str4rXxG), SIZE_VARIANTS(0xb8206800), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_USE012 | IS_STORE, "str", "!0r, [!1X, !2x!3G]", kFixupNone), ENCODING_MAP(kA64Strb3wXd, NO_VARIANTS(0x39000000), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE_OFF, "strb", "!0w, [!1X, #!2d]", kFixupNone), ENCODING_MAP(kA64Strb3wXx, NO_VARIANTS(0x38206800), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE012 | IS_STORE, "strb", "!0w, [!1X, !2x]", kFixupNone), ENCODING_MAP(kA64Strh3wXF, NO_VARIANTS(0x79000000), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE_OFF, "strh", "!0w, [!1X, #!2F]", kFixupNone), ENCODING_MAP(kA64Strh4wXxd, NO_VARIANTS(0x78206800), kFmtRegW, 4, 0, kFmtRegXOrSp, 9, 5, kFmtRegX, 20, 16, kFmtBitBlt, 12, 12, IS_QUAD_OP | REG_USE012 | IS_STORE, "strh", "!0w, [!1X, !2x, lsl #!3d]", kFixupNone), ENCODING_MAP(WIDE(kA64StrPost3rXd), SIZE_VARIANTS(0xb8000400), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | REG_DEF1 | IS_STORE, "str", "!0r, [!1X], #!2d", kFixupNone), ENCODING_MAP(WIDE(kA64Stur3fXd), CUSTOM_VARIANTS(0xbc000000, 0xfc000000), kFmtRegF, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE, "stur", "!0f, [!1X, #!2d]", kFixupNone), ENCODING_MAP(WIDE(kA64Stur3rXd), SIZE_VARIANTS(0xb8000000), kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtBitBlt, 20, 12, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | IS_STORE, "stur", "!0r, [!1X, #!2d]", kFixupNone), ENCODING_MAP(WIDE(kA64Stxr3wrX), SIZE_VARIANTS(0x88007c00), kFmtRegW, 20, 16, kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12 | IS_STOREX, "stxr", "!0w, !1r, [!2X]", kFixupNone), ENCODING_MAP(WIDE(kA64Stlxr3wrX), SIZE_VARIANTS(0x8800fc00), kFmtRegW, 20, 16, kFmtRegR, 4, 0, kFmtRegXOrSp, 9, 5, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE12 | IS_STOREX, "stlxr", "!0w, !1r, [!2X]", kFixupNone), ENCODING_MAP(WIDE(kA64Sub4RRdT), SF_VARIANTS(0x51000000), kFmtRegROrSp, 4, 0, kFmtRegROrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtBitBlt, 23, 22, IS_QUAD_OP | REG_DEF0_USE1, "sub", "!0R, !1R, #!2d!3T", kFixupNone), ENCODING_MAP(WIDE(kA64Sub4rrro), SF_VARIANTS(0x4b000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "sub", "!0r, !1r, !2r!3o", kFixupNone), ENCODING_MAP(WIDE(kA64Sub4RRre), SF_VARIANTS(0x4b200000), kFmtRegROrSp, 4, 0, kFmtRegROrSp, 9, 5, kFmtRegR, 20, 16, kFmtExtend, -1, -1, IS_QUAD_OP | REG_DEF0_USE12, "sub", "!0r, !1r, !2r!3e", kFixupNone), ENCODING_MAP(WIDE(kA64Subs3rRd), SF_VARIANTS(0x71000000), kFmtRegR, 4, 0, kFmtRegROrSp, 9, 5, kFmtBitBlt, 21, 10, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_DEF0_USE1 | SETS_CCODES, "subs", "!0r, !1R, #!2d", kFixupNone), ENCODING_MAP(WIDE(kA64Tst2rl), SF_VARIANTS(0x7200001f), kFmtRegR, 9, 5, kFmtBitBlt, 22, 10, kFmtUnused, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE0 | SETS_CCODES, "tst", "!0r, !1l", kFixupNone), ENCODING_MAP(WIDE(kA64Tst3rro), SF_VARIANTS(0x6a00001f), kFmtRegR, 9, 5, kFmtRegR, 20, 16, kFmtShift, -1, -1, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE01 | SETS_CCODES, "tst", "!0r, !1r!2o", kFixupNone), // NOTE: Tbz/Tbnz does not require SETS_CCODES, but it may be replaced by some other LIRs // which require SETS_CCODES in the fix-up stage. ENCODING_MAP(WIDE(kA64Tbnz3rht), CUSTOM_VARIANTS(0x37000000, 0x37000000), kFmtRegR, 4, 0, kFmtImm6Shift, -1, -1, kFmtBitBlt, 18, 5, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE0 | IS_BRANCH | NEEDS_FIXUP | SETS_CCODES, "tbnz", "!0r, #!1h, !2t", kFixupTBxZ), ENCODING_MAP(WIDE(kA64Tbz3rht), CUSTOM_VARIANTS(0x36000000, 0x36000000), kFmtRegR, 4, 0, kFmtImm6Shift, -1, -1, kFmtBitBlt, 18, 5, kFmtUnused, -1, -1, IS_TERTIARY_OP | REG_USE0 | IS_BRANCH | NEEDS_FIXUP | SETS_CCODES, "tbz", "!0r, #!1h, !2t", kFixupTBxZ), ENCODING_MAP(WIDE(kA64Ubfm4rrdd), SF_N_VARIANTS(0x53000000), kFmtRegR, 4, 0, kFmtRegR, 9, 5, kFmtBitBlt, 21, 16, kFmtBitBlt, 15, 10, IS_QUAD_OP | REG_DEF0_USE1, "ubfm", "!0r, !1r, !2d, !3d", kFixupNone), }; // new_lir replaces orig_lir in the pcrel_fixup list. void Arm64Mir2Lir::ReplaceFixup(LIR* prev_lir, LIR* orig_lir, LIR* new_lir) { new_lir->u.a.pcrel_next = orig_lir->u.a.pcrel_next; if (UNLIKELY(prev_lir == NULL)) { first_fixup_ = new_lir; } else { prev_lir->u.a.pcrel_next = new_lir; } orig_lir->flags.fixup = kFixupNone; } // new_lir is inserted before orig_lir in the pcrel_fixup list. void Arm64Mir2Lir::InsertFixupBefore(LIR* prev_lir, LIR* orig_lir, LIR* new_lir) { new_lir->u.a.pcrel_next = orig_lir; if (UNLIKELY(prev_lir == NULL)) { first_fixup_ = new_lir; } else { DCHECK(prev_lir->u.a.pcrel_next == orig_lir); prev_lir->u.a.pcrel_next = new_lir; } } /* Nop, used for aligning code. Nop is an alias for hint #0. */ #define PADDING_NOP (UINT32_C(0xd503201f)) uint8_t* Arm64Mir2Lir::EncodeLIRs(uint8_t* write_pos, LIR* lir) { for (; lir != nullptr; lir = NEXT_LIR(lir)) { bool opcode_is_wide = IS_WIDE(lir->opcode); A64Opcode opcode = UNWIDE(lir->opcode); if (UNLIKELY(IsPseudoLirOp(opcode))) { continue; } if (LIKELY(!lir->flags.is_nop)) { const A64EncodingMap *encoder = &EncodingMap[opcode]; // Select the right variant of the skeleton. uint32_t bits = opcode_is_wide ? encoder->xskeleton : encoder->wskeleton; DCHECK(!opcode_is_wide || IS_WIDE(encoder->opcode)); for (int i = 0; i < 4; i++) { A64EncodingKind kind = encoder->field_loc[i].kind; uint32_t operand = lir->operands[i]; uint32_t value; if (LIKELY(static_cast(kind) <= kFmtBitBlt)) { // Note: this will handle kFmtReg* and kFmtBitBlt. if (static_cast(kind) < kFmtBitBlt) { bool is_zero = A64_REG_IS_ZR(operand); if (kIsDebugBuild && (kFailOnSizeError || kReportSizeError)) { // Register usage checks: First establish register usage requirements based on the // format in `kind'. bool want_float = false; // Want a float (rather than core) register. bool want_64_bit = false; // Want a 64-bit (rather than 32-bit) register. bool want_var_size = true; // Want register with variable size (kFmtReg{R,F}). bool want_zero = false; // Want the zero (rather than sp) register. switch (kind) { case kFmtRegX: want_64_bit = true; // Intentional fall-through. case kFmtRegW: want_var_size = false; // Intentional fall-through. case kFmtRegR: want_zero = true; break; case kFmtRegXOrSp: want_64_bit = true; // Intentional fall-through. case kFmtRegWOrSp: want_var_size = false; break; case kFmtRegROrSp: break; case kFmtRegD: want_64_bit = true; // Intentional fall-through. case kFmtRegS: want_var_size = false; // Intentional fall-through. case kFmtRegF: want_float = true; break; default: LOG(FATAL) << "Bad fmt for arg n. " << i << " of " << encoder->name << " (" << kind << ")"; break; } // want_var_size == true means kind == kFmtReg{R,F}. In these two cases, we want // the register size to be coherent with the instruction width. if (want_var_size) { want_64_bit = opcode_is_wide; } // Now check that the requirements are satisfied. RegStorage reg(operand | RegStorage::kValid); const char *expected = nullptr; if (want_float) { if (!reg.IsFloat()) { expected = "float register"; } else if (reg.IsDouble() != want_64_bit) { expected = (want_64_bit) ? "double register" : "single register"; } } else { if (reg.IsFloat()) { expected = "core register"; } else if (reg.Is64Bit() != want_64_bit) { expected = (want_64_bit) ? "x-register" : "w-register"; } else if (A64_REGSTORAGE_IS_SP_OR_ZR(reg) && is_zero != want_zero) { expected = (want_zero) ? "zero-register" : "sp-register"; } } // Fail, if `expected' contains an unsatisfied requirement. if (expected != nullptr) { LOG(WARNING) << "Method: " << PrettyMethod(cu_->method_idx, *cu_->dex_file) << " @ 0x" << std::hex << lir->dalvik_offset; if (kFailOnSizeError) { LOG(FATAL) << "Bad argument n. " << i << " of " << encoder->name << "(" << UNWIDE(encoder->opcode) << ", " << encoder->fmt << ")" << ". Expected " << expected << ", got 0x" << std::hex << operand; } else { LOG(WARNING) << "Bad argument n. " << i << " of " << encoder->name << ". Expected " << expected << ", got 0x" << std::hex << operand; } } } // In the lines below, we rely on (operand & 0x1f) == 31 to be true for register sp // and zr. This means that these two registers do not need any special treatment, as // their bottom 5 bits are correctly set to 31 == 0b11111, which is the right // value for encoding both sp and zr. COMPILE_ASSERT((rxzr & 0x1f) == 0x1f, rzr_register_number_must_be_31); COMPILE_ASSERT((rsp & 0x1f) == 0x1f, rsp_register_number_must_be_31); } value = (operand << encoder->field_loc[i].start) & ((1 << (encoder->field_loc[i].end + 1)) - 1); bits |= value; } else { switch (kind) { case kFmtSkip: break; // Nothing to do, but continue to next. case kFmtUnused: i = 4; // Done, break out of the enclosing loop. break; case kFmtShift: // Intentional fallthrough. case kFmtExtend: DCHECK_EQ((operand & (1 << 6)) == 0, kind == kFmtShift); value = (operand & 0x3f) << 10; value |= ((operand & 0x1c0) >> 6) << 21; bits |= value; break; case kFmtImm21: value = (operand & 0x3) << 29; value |= ((operand & 0x1ffffc) >> 2) << 5; bits |= value; break; case kFmtImm6Shift: value = (operand & 0x1f) << 19; value |= ((operand & 0x20) >> 5) << 31; bits |= value; break; default: LOG(FATAL) << "Bad fmt for arg. " << i << " in " << encoder->name << " (" << kind << ")"; } } } DCHECK_EQ(encoder->size, 4); write_pos[0] = (bits & 0xff); write_pos[1] = ((bits >> 8) & 0xff); write_pos[2] = ((bits >> 16) & 0xff); write_pos[3] = ((bits >> 24) & 0xff); write_pos += 4; } } return write_pos; } // Align data offset on 8 byte boundary: it will only contain double-word items, as word immediates // are better set directly from the code (they will require no more than 2 instructions). #define ALIGNED_DATA_OFFSET(offset) (((offset) + 0x7) & ~0x7) // Assemble the LIR into binary instruction format. void Arm64Mir2Lir::AssembleLIR() { LIR* lir; LIR* prev_lir; cu_->NewTimingSplit("Assemble"); int assembler_retries = 0; CodeOffset starting_offset = LinkFixupInsns(first_lir_insn_, last_lir_insn_, 0); data_offset_ = ALIGNED_DATA_OFFSET(starting_offset); int32_t offset_adjustment; AssignDataOffsets(); /* * Note: generation must be 1 on first pass (to distinguish from initialized state of 0 * for non-visited nodes). Start at zero here, and bit will be flipped to 1 on entry to the loop. */ int generation = 0; while (true) { offset_adjustment = 0; AssemblerStatus res = kSuccess; // Assume success generation ^= 1; // Note: nodes requiring possible fixup linked in ascending order. lir = first_fixup_; prev_lir = NULL; while (lir != NULL) { // NOTE: Any new non-pc_rel instructions inserted due to retry must be explicitly encoded at // the time of insertion. Note that inserted instructions don't need use/def flags, but do // need size and pc-rel status properly updated. lir->offset += offset_adjustment; // During pass, allows us to tell whether a node has been updated with offset_adjustment yet. lir->flags.generation = generation; switch (static_cast(lir->flags.fixup)) { case kFixupLabel: case kFixupNone: case kFixupVLoad: break; case kFixupT1Branch: { LIR *target_lir = lir->target; DCHECK(target_lir); CodeOffset pc = lir->offset; CodeOffset target = target_lir->offset + ((target_lir->flags.generation == lir->flags.generation) ? 0 : offset_adjustment); int32_t delta = target - pc; DCHECK_EQ(delta & 0x3, 0); if (!IS_SIGNED_IMM26(delta >> 2)) { LOG(FATAL) << "Invalid jump range in kFixupT1Branch"; } lir->operands[0] = delta >> 2; break; } case kFixupLoad: case kFixupCBxZ: case kFixupCondBranch: { LIR *target_lir = lir->target; DCHECK(target_lir); CodeOffset pc = lir->offset; CodeOffset target = target_lir->offset + ((target_lir->flags.generation == lir->flags.generation) ? 0 : offset_adjustment); int32_t delta = target - pc; DCHECK_EQ(delta & 0x3, 0); if (!IS_SIGNED_IMM19(delta >> 2)) { LOG(FATAL) << "Invalid jump range in kFixupLoad"; } lir->operands[1] = delta >> 2; break; } case kFixupTBxZ: { int16_t opcode = lir->opcode; RegStorage reg(lir->operands[0] | RegStorage::kValid); int32_t imm = lir->operands[1]; DCHECK_EQ(IS_WIDE(opcode), reg.Is64Bit()); DCHECK_LT(imm, 64); if (imm >= 32) { DCHECK(IS_WIDE(opcode)); } else if (kIsDebugBuild && IS_WIDE(opcode)) { // "tbz/tbnz x0, #imm(<32)" is the same with "tbz/tbnz w0, #imm(<32)", but GCC/oatdump // will disassemble it as "tbz/tbnz w0, #imm(<32)". So unwide the LIR to make the // compiler log behave the same with those disassembler in debug build. // This will also affect tst instruction if it need to be replaced, but there is no // performance difference between "tst Xt" and "tst Wt". lir->opcode = UNWIDE(opcode); lir->operands[0] = As32BitReg(reg).GetReg(); } // Fix-up branch offset. LIR *target_lir = lir->target; DCHECK(target_lir); CodeOffset pc = lir->offset; CodeOffset target = target_lir->offset + ((target_lir->flags.generation == lir->flags.generation) ? 0 : offset_adjustment); int32_t delta = target - pc; DCHECK_EQ(delta & 0x3, 0); // Check if branch offset can be encoded in tbz/tbnz. if (!IS_SIGNED_IMM14(delta >> 2)) { DexOffset dalvik_offset = lir->dalvik_offset; int16_t opcode = lir->opcode; LIR* target = lir->target; // "tbz/tbnz Rt, #imm, label" -> "tst Rt, #(1<flags.size; int32_t imm = EncodeLogicalImmediate(IS_WIDE(opcode), 1 << lir->operands[1]); DCHECK_NE(imm, -1); lir->opcode = IS_WIDE(opcode) ? WIDE(kA64Tst2rl) : kA64Tst2rl; lir->operands[1] = imm; lir->target = nullptr; lir->flags.fixup = EncodingMap[kA64Tst2rl].fixup; lir->flags.size = EncodingMap[kA64Tst2rl].size; offset_adjustment += lir->flags.size; // Insert "beq/bneq label". opcode = UNWIDE(opcode); DCHECK(opcode == kA64Tbz3rht || opcode == kA64Tbnz3rht); LIR* new_lir = RawLIR(dalvik_offset, kA64B2ct, opcode == kA64Tbz3rht ? kArmCondEq : kArmCondNe, 0, 0, 0, 0, target); InsertLIRAfter(lir, new_lir); new_lir->offset = lir->offset + lir->flags.size; new_lir->flags.generation = generation; new_lir->flags.fixup = EncodingMap[kA64B2ct].fixup; new_lir->flags.size = EncodingMap[kA64B2ct].size; offset_adjustment += new_lir->flags.size; // lir no longer pcrel, unlink and link in new_lir. ReplaceFixup(prev_lir, lir, new_lir); prev_lir = new_lir; // Continue with the new instruction. lir = new_lir->u.a.pcrel_next; res = kRetryAll; continue; } lir->operands[2] = delta >> 2; break; } case kFixupAdr: { LIR* target_lir = lir->target; int32_t delta; if (target_lir) { CodeOffset target_offs = ((target_lir->flags.generation == lir->flags.generation) ? 0 : offset_adjustment) + target_lir->offset; delta = target_offs - lir->offset; } else if (lir->operands[2] >= 0) { EmbeddedData* tab = reinterpret_cast(UnwrapPointer(lir->operands[2])); delta = tab->offset + offset_adjustment - lir->offset; } else { // No fixup: this usage allows to retrieve the current PC. delta = lir->operands[1]; } if (!IS_SIGNED_IMM21(delta)) { LOG(FATAL) << "Jump range above 1MB in kFixupAdr"; } lir->operands[1] = delta; break; } default: LOG(FATAL) << "Unexpected case " << lir->flags.fixup; } prev_lir = lir; lir = lir->u.a.pcrel_next; } if (res == kSuccess) { DCHECK_EQ(offset_adjustment, 0); break; } else { assembler_retries++; if (assembler_retries > MAX_ASSEMBLER_RETRIES) { CodegenDump(); LOG(FATAL) << "Assembler error - too many retries"; } starting_offset += offset_adjustment; data_offset_ = ALIGNED_DATA_OFFSET(starting_offset); AssignDataOffsets(); } } // Build the CodeBuffer. DCHECK_LE(data_offset_, total_size_); code_buffer_.reserve(total_size_); code_buffer_.resize(starting_offset); uint8_t* write_pos = &code_buffer_[0]; write_pos = EncodeLIRs(write_pos, first_lir_insn_); DCHECK_EQ(static_cast(write_pos - &code_buffer_[0]), starting_offset); DCHECK_EQ(data_offset_, ALIGNED_DATA_OFFSET(code_buffer_.size())); // Install literals InstallLiteralPools(); // Install switch tables InstallSwitchTables(); // Install fill array data InstallFillArrayData(); // Create the mapping table and native offset to reference map. cu_->NewTimingSplit("PcMappingTable"); CreateMappingTables(); cu_->NewTimingSplit("GcMap"); CreateNativeGcMap(); } size_t Arm64Mir2Lir::GetInsnSize(LIR* lir) { A64Opcode opcode = UNWIDE(lir->opcode); DCHECK(!IsPseudoLirOp(opcode)); return EncodingMap[opcode].size; } // Encode instruction bit pattern and assign offsets. uint32_t Arm64Mir2Lir::LinkFixupInsns(LIR* head_lir, LIR* tail_lir, uint32_t offset) { LIR* end_lir = tail_lir->next; LIR* last_fixup = NULL; for (LIR* lir = head_lir; lir != end_lir; lir = NEXT_LIR(lir)) { A64Opcode opcode = UNWIDE(lir->opcode); if (!lir->flags.is_nop) { if (lir->flags.fixup != kFixupNone) { if (!IsPseudoLirOp(opcode)) { lir->flags.size = EncodingMap[opcode].size; lir->flags.fixup = EncodingMap[opcode].fixup; } else { DCHECK_NE(static_cast(opcode), kPseudoPseudoAlign4); lir->flags.size = 0; lir->flags.fixup = kFixupLabel; } // Link into the fixup chain. lir->flags.use_def_invalid = true; lir->u.a.pcrel_next = NULL; if (first_fixup_ == NULL) { first_fixup_ = lir; } else { last_fixup->u.a.pcrel_next = lir; } last_fixup = lir; lir->offset = offset; } offset += lir->flags.size; } } return offset; } void Arm64Mir2Lir::AssignDataOffsets() { /* Set up offsets for literals */ CodeOffset offset = data_offset_; offset = AssignLiteralOffset(offset); offset = AssignSwitchTablesOffset(offset); total_size_ = AssignFillArrayDataOffset(offset); } } // namespace art