/* * Copyright (C) 2009 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 "Dalvik.h" #include "Dataflow.h" #include "Loop.h" #include "libdex/DexOpcodes.h" /* * Main table containing data flow attributes for each bytecode. The * first kNumPackedOpcodes entries are for Dalvik bytecode * instructions, where extended opcode at the MIR level are appended * afterwards. * * TODO - many optimization flags are incomplete - they will only limit the * scope of optimizations but will not cause mis-optimizations. */ int dvmCompilerDataFlowAttributes[kMirOpLast] = { // 00 OP_NOP DF_NOP, // 01 OP_MOVE vA, vB DF_DA | DF_UB | DF_IS_MOVE, // 02 OP_MOVE_FROM16 vAA, vBBBB DF_DA | DF_UB | DF_IS_MOVE, // 03 OP_MOVE_16 vAAAA, vBBBB DF_DA | DF_UB | DF_IS_MOVE, // 04 OP_MOVE_WIDE vA, vB DF_DA_WIDE | DF_UB_WIDE | DF_IS_MOVE, // 05 OP_MOVE_WIDE_FROM16 vAA, vBBBB DF_DA_WIDE | DF_UB_WIDE | DF_IS_MOVE, // 06 OP_MOVE_WIDE_16 vAAAA, vBBBB DF_DA_WIDE | DF_UB_WIDE | DF_IS_MOVE, // 07 OP_MOVE_OBJECT vA, vB DF_DA | DF_UB | DF_IS_MOVE, // 08 OP_MOVE_OBJECT_FROM16 vAA, vBBBB DF_DA | DF_UB | DF_IS_MOVE, // 09 OP_MOVE_OBJECT_16 vAAAA, vBBBB DF_DA | DF_UB | DF_IS_MOVE, // 0A OP_MOVE_RESULT vAA DF_DA, // 0B OP_MOVE_RESULT_WIDE vAA DF_DA_WIDE, // 0C OP_MOVE_RESULT_OBJECT vAA DF_DA, // 0D OP_MOVE_EXCEPTION vAA DF_DA, // 0E OP_RETURN_VOID DF_NOP, // 0F OP_RETURN vAA DF_UA, // 10 OP_RETURN_WIDE vAA DF_UA_WIDE, // 11 OP_RETURN_OBJECT vAA DF_UA, // 12 OP_CONST_4 vA, #+B DF_DA | DF_SETS_CONST, // 13 OP_CONST_16 vAA, #+BBBB DF_DA | DF_SETS_CONST, // 14 OP_CONST vAA, #+BBBBBBBB DF_DA | DF_SETS_CONST, // 15 OP_CONST_HIGH16 VAA, #+BBBB0000 DF_DA | DF_SETS_CONST, // 16 OP_CONST_WIDE_16 vAA, #+BBBB DF_DA_WIDE | DF_SETS_CONST, // 17 OP_CONST_WIDE_32 vAA, #+BBBBBBBB DF_DA_WIDE | DF_SETS_CONST, // 18 OP_CONST_WIDE vAA, #+BBBBBBBBBBBBBBBB DF_DA_WIDE | DF_SETS_CONST, // 19 OP_CONST_WIDE_HIGH16 vAA, #+BBBB000000000000 DF_DA_WIDE | DF_SETS_CONST, // 1A OP_CONST_STRING vAA, string@BBBB DF_DA, // 1B OP_CONST_STRING_JUMBO vAA, string@BBBBBBBB DF_DA, // 1C OP_CONST_CLASS vAA, type@BBBB DF_DA, // 1D OP_MONITOR_ENTER vAA DF_UA, // 1E OP_MONITOR_EXIT vAA DF_UA, // 1F OP_CHECK_CAST vAA, type@BBBB DF_UA, // 20 OP_INSTANCE_OF vA, vB, type@CCCC DF_DA | DF_UB, // 21 OP_ARRAY_LENGTH vA, vB DF_DA | DF_UB, // 22 OP_NEW_INSTANCE vAA, type@BBBB DF_DA, // 23 OP_NEW_ARRAY vA, vB, type@CCCC DF_DA | DF_UB, // 24 OP_FILLED_NEW_ARRAY {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 25 OP_FILLED_NEW_ARRAY_RANGE {vCCCC .. vNNNN}, type@BBBB DF_FORMAT_3RC, // 26 OP_FILL_ARRAY_DATA vAA, +BBBBBBBB DF_UA, // 27 OP_THROW vAA DF_UA, // 28 OP_GOTO DF_NOP, // 29 OP_GOTO_16 DF_NOP, // 2A OP_GOTO_32 DF_NOP, // 2B OP_PACKED_SWITCH vAA, +BBBBBBBB DF_UA, // 2C OP_SPARSE_SWITCH vAA, +BBBBBBBB DF_UA, // 2D OP_CMPL_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_B | DF_FP_C, // 2E OP_CMPG_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_B | DF_FP_C, // 2F OP_CMPL_DOUBLE vAA, vBB, vCC DF_DA | DF_UB_WIDE | DF_UC_WIDE | DF_FP_B | DF_FP_C, // 30 OP_CMPG_DOUBLE vAA, vBB, vCC DF_DA | DF_UB_WIDE | DF_UC_WIDE | DF_FP_B | DF_FP_C, // 31 OP_CMP_LONG vAA, vBB, vCC DF_DA | DF_UB_WIDE | DF_UC_WIDE, // 32 OP_IF_EQ vA, vB, +CCCC DF_UA | DF_UB, // 33 OP_IF_NE vA, vB, +CCCC DF_UA | DF_UB, // 34 OP_IF_LT vA, vB, +CCCC DF_UA | DF_UB, // 35 OP_IF_GE vA, vB, +CCCC DF_UA | DF_UB, // 36 OP_IF_GT vA, vB, +CCCC DF_UA | DF_UB, // 37 OP_IF_LE vA, vB, +CCCC DF_UA | DF_UB, // 38 OP_IF_EQZ vAA, +BBBB DF_UA, // 39 OP_IF_NEZ vAA, +BBBB DF_UA, // 3A OP_IF_LTZ vAA, +BBBB DF_UA, // 3B OP_IF_GEZ vAA, +BBBB DF_UA, // 3C OP_IF_GTZ vAA, +BBBB DF_UA, // 3D OP_IF_LEZ vAA, +BBBB DF_UA, // 3E OP_UNUSED_3E DF_NOP, // 3F OP_UNUSED_3F DF_NOP, // 40 OP_UNUSED_40 DF_NOP, // 41 OP_UNUSED_41 DF_NOP, // 42 OP_UNUSED_42 DF_NOP, // 43 OP_UNUSED_43 DF_NOP, // 44 OP_AGET vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 45 OP_AGET_WIDE vAA, vBB, vCC DF_DA_WIDE | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 46 OP_AGET_OBJECT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 47 OP_AGET_BOOLEAN vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 48 OP_AGET_BYTE vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 49 OP_AGET_CHAR vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 4A OP_AGET_SHORT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_0 | DF_IS_GETTER, // 4B OP_APUT vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 4C OP_APUT_WIDE vAA, vBB, vCC DF_UA_WIDE | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_2 | DF_IS_SETTER, // 4D OP_APUT_OBJECT vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 4E OP_APUT_BOOLEAN vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 4F OP_APUT_BYTE vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 50 OP_APUT_CHAR vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 51 OP_APUT_SHORT vAA, vBB, vCC DF_UA | DF_UB | DF_UC | DF_NULL_N_RANGE_CHECK_1 | DF_IS_SETTER, // 52 OP_IGET vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 53 OP_IGET_WIDE vA, vB, field@CCCC DF_DA_WIDE | DF_UB | DF_IS_GETTER, // 54 OP_IGET_OBJECT vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 55 OP_IGET_BOOLEAN vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 56 OP_IGET_BYTE vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 57 OP_IGET_CHAR vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 58 OP_IGET_SHORT vA, vB, field@CCCC DF_DA | DF_UB | DF_IS_GETTER, // 59 OP_IPUT vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 5A OP_IPUT_WIDE vA, vB, field@CCCC DF_UA_WIDE | DF_UB | DF_IS_SETTER, // 5B OP_IPUT_OBJECT vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 5C OP_IPUT_BOOLEAN vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 5D OP_IPUT_BYTE vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 5E OP_IPUT_CHAR vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 5F OP_IPUT_SHORT vA, vB, field@CCCC DF_UA | DF_UB | DF_IS_SETTER, // 60 OP_SGET vAA, field@BBBB DF_DA | DF_IS_GETTER, // 61 OP_SGET_WIDE vAA, field@BBBB DF_DA_WIDE | DF_IS_GETTER, // 62 OP_SGET_OBJECT vAA, field@BBBB DF_DA | DF_IS_GETTER, // 63 OP_SGET_BOOLEAN vAA, field@BBBB DF_DA | DF_IS_GETTER, // 64 OP_SGET_BYTE vAA, field@BBBB DF_DA | DF_IS_GETTER, // 65 OP_SGET_CHAR vAA, field@BBBB DF_DA | DF_IS_GETTER, // 66 OP_SGET_SHORT vAA, field@BBBB DF_DA | DF_IS_GETTER, // 67 OP_SPUT vAA, field@BBBB DF_UA | DF_IS_SETTER, // 68 OP_SPUT_WIDE vAA, field@BBBB DF_UA_WIDE | DF_IS_SETTER, // 69 OP_SPUT_OBJECT vAA, field@BBBB DF_UA | DF_IS_SETTER, // 6A OP_SPUT_BOOLEAN vAA, field@BBBB DF_UA | DF_IS_SETTER, // 6B OP_SPUT_BYTE vAA, field@BBBB DF_UA | DF_IS_SETTER, // 6C OP_SPUT_CHAR vAA, field@BBBB DF_UA | DF_IS_SETTER, // 6D OP_SPUT_SHORT vAA, field@BBBB DF_UA | DF_IS_SETTER, // 6E OP_INVOKE_VIRTUAL {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 6F OP_INVOKE_SUPER {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 70 OP_INVOKE_DIRECT {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 71 OP_INVOKE_STATIC {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 72 OP_INVOKE_INTERFACE {vD, vE, vF, vG, vA} DF_FORMAT_35C, // 73 OP_UNUSED_73 DF_NOP, // 74 OP_INVOKE_VIRTUAL_RANGE {vCCCC .. vNNNN} DF_FORMAT_3RC, // 75 OP_INVOKE_SUPER_RANGE {vCCCC .. vNNNN} DF_FORMAT_3RC, // 76 OP_INVOKE_DIRECT_RANGE {vCCCC .. vNNNN} DF_FORMAT_3RC, // 77 OP_INVOKE_STATIC_RANGE {vCCCC .. vNNNN} DF_FORMAT_3RC, // 78 OP_INVOKE_INTERFACE_RANGE {vCCCC .. vNNNN} DF_FORMAT_3RC, // 79 OP_UNUSED_79 DF_NOP, // 7A OP_UNUSED_7A DF_NOP, // 7B OP_NEG_INT vA, vB DF_DA | DF_UB, // 7C OP_NOT_INT vA, vB DF_DA | DF_UB, // 7D OP_NEG_LONG vA, vB DF_DA_WIDE | DF_UB_WIDE, // 7E OP_NOT_LONG vA, vB DF_DA_WIDE | DF_UB_WIDE, // 7F OP_NEG_FLOAT vA, vB DF_DA | DF_UB | DF_FP_A | DF_FP_B, // 80 OP_NEG_DOUBLE vA, vB DF_DA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // 81 OP_INT_TO_LONG vA, vB DF_DA_WIDE | DF_UB, // 82 OP_INT_TO_FLOAT vA, vB DF_DA | DF_UB | DF_FP_A, // 83 OP_INT_TO_DOUBLE vA, vB DF_DA_WIDE | DF_UB | DF_FP_A, // 84 OP_LONG_TO_INT vA, vB DF_DA | DF_UB_WIDE, // 85 OP_LONG_TO_FLOAT vA, vB DF_DA | DF_UB_WIDE | DF_FP_A, // 86 OP_LONG_TO_DOUBLE vA, vB DF_DA_WIDE | DF_UB_WIDE | DF_FP_A, // 87 OP_FLOAT_TO_INT vA, vB DF_DA | DF_UB | DF_FP_B, // 88 OP_FLOAT_TO_LONG vA, vB DF_DA_WIDE | DF_UB | DF_FP_B, // 89 OP_FLOAT_TO_DOUBLE vA, vB DF_DA_WIDE | DF_UB | DF_FP_A | DF_FP_B, // 8A OP_DOUBLE_TO_INT vA, vB DF_DA | DF_UB_WIDE | DF_FP_B, // 8B OP_DOUBLE_TO_LONG vA, vB DF_DA_WIDE | DF_UB_WIDE | DF_FP_B, // 8C OP_DOUBLE_TO_FLOAT vA, vB DF_DA | DF_UB_WIDE | DF_FP_A | DF_FP_B, // 8D OP_INT_TO_BYTE vA, vB DF_DA | DF_UB, // 8E OP_INT_TO_CHAR vA, vB DF_DA | DF_UB, // 8F OP_INT_TO_SHORT vA, vB DF_DA | DF_UB, // 90 OP_ADD_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_IS_LINEAR, // 91 OP_SUB_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_IS_LINEAR, // 92 OP_MUL_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 93 OP_DIV_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 94 OP_REM_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 95 OP_AND_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 96 OP_OR_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 97 OP_XOR_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 98 OP_SHL_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 99 OP_SHR_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 9A OP_USHR_INT vAA, vBB, vCC DF_DA | DF_UB | DF_UC, // 9B OP_ADD_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // 9C OP_SUB_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // 9D OP_MUL_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // 9E OP_DIV_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // 9F OP_REM_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // A0 OP_AND_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // A1 OP_OR_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // A2 OP_XOR_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE, // A3 OP_SHL_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC, // A4 OP_SHR_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC, // A5 OP_USHR_LONG vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC, // A6 OP_ADD_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_A | DF_FP_B | DF_FP_C, // A7 OP_SUB_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_A | DF_FP_B | DF_FP_C, // A8 OP_MUL_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_A | DF_FP_B | DF_FP_C, // A9 OP_DIV_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_A | DF_FP_B | DF_FP_C, // AA OP_REM_FLOAT vAA, vBB, vCC DF_DA | DF_UB | DF_UC | DF_FP_A | DF_FP_B | DF_FP_C, // AB OP_ADD_DOUBLE vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE | DF_FP_A | DF_FP_B | DF_FP_C, // AC OP_SUB_DOUBLE vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE | DF_FP_A | DF_FP_B | DF_FP_C, // AD OP_MUL_DOUBLE vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE | DF_FP_A | DF_FP_B | DF_FP_C, // AE OP_DIV_DOUBLE vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE | DF_FP_A | DF_FP_B | DF_FP_C, // AF OP_REM_DOUBLE vAA, vBB, vCC DF_DA_WIDE | DF_UB_WIDE | DF_UC_WIDE | DF_FP_A | DF_FP_B | DF_FP_C, // B0 OP_ADD_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B1 OP_SUB_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B2 OP_MUL_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B3 OP_DIV_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B4 OP_REM_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B5 OP_AND_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B6 OP_OR_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B7 OP_XOR_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B8 OP_SHL_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // B9 OP_SHR_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // BA OP_USHR_INT_2ADDR vA, vB DF_DA | DF_UA | DF_UB, // BB OP_ADD_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // BC OP_SUB_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // BD OP_MUL_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // BE OP_DIV_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // BF OP_REM_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // C0 OP_AND_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // C1 OP_OR_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // C2 OP_XOR_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE, // C3 OP_SHL_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB, // C4 OP_SHR_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB, // C5 OP_USHR_LONG_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB, // C6 OP_ADD_FLOAT_2ADDR vA, vB DF_DA | DF_UA | DF_UB | DF_FP_A | DF_FP_B, // C7 OP_SUB_FLOAT_2ADDR vA, vB DF_DA | DF_UA | DF_UB | DF_FP_A | DF_FP_B, // C8 OP_MUL_FLOAT_2ADDR vA, vB DF_DA | DF_UA | DF_UB | DF_FP_A | DF_FP_B, // C9 OP_DIV_FLOAT_2ADDR vA, vB DF_DA | DF_UA | DF_UB | DF_FP_A | DF_FP_B, // CA OP_REM_FLOAT_2ADDR vA, vB DF_DA | DF_UA | DF_UB | DF_FP_A | DF_FP_B, // CB OP_ADD_DOUBLE_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // CC OP_SUB_DOUBLE_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // CD OP_MUL_DOUBLE_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // CE OP_DIV_DOUBLE_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // CF OP_REM_DOUBLE_2ADDR vA, vB DF_DA_WIDE | DF_UA_WIDE | DF_UB_WIDE | DF_FP_A | DF_FP_B, // D0 OP_ADD_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D1 OP_RSUB_INT vA, vB, #+CCCC DF_DA | DF_UB, // D2 OP_MUL_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D3 OP_DIV_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D4 OP_REM_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D5 OP_AND_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D6 OP_OR_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D7 OP_XOR_INT_LIT16 vA, vB, #+CCCC DF_DA | DF_UB, // D8 OP_ADD_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB | DF_IS_LINEAR, // D9 OP_RSUB_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DA OP_MUL_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DB OP_DIV_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DC OP_REM_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DD OP_AND_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DE OP_OR_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // DF OP_XOR_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // E0 OP_SHL_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // E1 OP_SHR_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // E2 OP_USHR_INT_LIT8 vAA, vBB, #+CC DF_DA | DF_UB, // E3 OP_IGET_VOLATILE DF_DA | DF_UB, // E4 OP_IPUT_VOLATILE DF_UA | DF_UB, // E5 OP_SGET_VOLATILE DF_DA, // E6 OP_SPUT_VOLATILE DF_UA, // E7 OP_IGET_OBJECT_VOLATILE DF_DA | DF_UB, // E8 OP_IGET_WIDE_VOLATILE DF_DA_WIDE | DF_UB, // E9 OP_IPUT_WIDE_VOLATILE DF_UA_WIDE | DF_UB, // EA OP_SGET_WIDE_VOLATILE DF_DA_WIDE, // EB OP_SPUT_WIDE_VOLATILE DF_UA_WIDE, // EC OP_BREAKPOINT DF_NOP, // ED OP_THROW_VERIFICATION_ERROR DF_NOP, // EE OP_EXECUTE_INLINE DF_FORMAT_35C, // EF OP_EXECUTE_INLINE_RANGE DF_FORMAT_3RC, // F0 OP_INVOKE_OBJECT_INIT_RANGE DF_NOP, // F1 OP_RETURN_VOID_BARRIER DF_NOP, // F2 OP_IGET_QUICK DF_DA | DF_UB | DF_IS_GETTER, // F3 OP_IGET_WIDE_QUICK DF_DA_WIDE | DF_UB | DF_IS_GETTER, // F4 OP_IGET_OBJECT_QUICK DF_DA | DF_UB | DF_IS_GETTER, // F5 OP_IPUT_QUICK DF_UA | DF_UB | DF_IS_SETTER, // F6 OP_IPUT_WIDE_QUICK DF_UA_WIDE | DF_UB | DF_IS_SETTER, // F7 OP_IPUT_OBJECT_QUICK DF_UA | DF_UB | DF_IS_SETTER, // F8 OP_INVOKE_VIRTUAL_QUICK DF_FORMAT_35C, // F9 OP_INVOKE_VIRTUAL_QUICK_RANGE DF_FORMAT_3RC, // FA OP_INVOKE_SUPER_QUICK DF_FORMAT_35C, // FB OP_INVOKE_SUPER_QUICK_RANGE DF_FORMAT_3RC, // FC OP_IPUT_OBJECT_VOLATILE DF_UA | DF_UB, // FD OP_SGET_OBJECT_VOLATILE DF_DA, // FE OP_SPUT_OBJECT_VOLATILE DF_UA, // FF OP_UNUSED_FF DF_NOP, // Beginning of extended MIR opcodes // 100 OP_MIR_PHI DF_PHI | DF_DA, /* * For extended MIR inserted at the MIR2LIR stage, it is okay to have * undefined values here. */ }; /* Return the Dalvik register/subscript pair of a given SSA register */ int dvmConvertSSARegToDalvik(const CompilationUnit *cUnit, int ssaReg) { return GET_ELEM_N(cUnit->ssaToDalvikMap, int, ssaReg); } /* * Utility function to convert encoded SSA register value into Dalvik register * and subscript pair. Each SSA register can be used to index the * ssaToDalvikMap list to get the subscript[31..16]/dalvik_reg[15..0] mapping. */ char *dvmCompilerGetDalvikDisassembly(const DecodedInstruction *insn, const char *note) { char buffer[256]; Opcode opcode = insn->opcode; int dfAttributes = dvmCompilerDataFlowAttributes[opcode]; int flags; char *ret; buffer[0] = 0; if ((int)opcode >= (int)kMirOpFirst) { if ((int)opcode == (int)kMirOpPhi) { strcpy(buffer, "PHI"); } else { sprintf(buffer, "Opcode %#x", opcode); } flags = 0; } else { strcpy(buffer, dexGetOpcodeName(opcode)); flags = dexGetFlagsFromOpcode(insn->opcode); } if (note) strcat(buffer, note); /* For branches, decode the instructions to print out the branch targets */ if (flags & kInstrCanBranch) { InstructionFormat dalvikFormat = dexGetFormatFromOpcode(insn->opcode); int offset = 0; switch (dalvikFormat) { case kFmt21t: snprintf(buffer + strlen(buffer), 256, " v%d,", insn->vA); offset = (int) insn->vB; break; case kFmt22t: snprintf(buffer + strlen(buffer), 256, " v%d, v%d,", insn->vA, insn->vB); offset = (int) insn->vC; break; case kFmt10t: case kFmt20t: case kFmt30t: offset = (int) insn->vA; break; default: ALOGE("Unexpected branch format %d / opcode %#x", dalvikFormat, opcode); dvmAbort(); break; } snprintf(buffer + strlen(buffer), 256, " (%c%x)", offset > 0 ? '+' : '-', offset > 0 ? offset : -offset); } else if (dfAttributes & DF_FORMAT_35C) { unsigned int i; for (i = 0; i < insn->vA; i++) { if (i != 0) strcat(buffer, ","); snprintf(buffer + strlen(buffer), 256, " v%d", insn->arg[i]); } } else if (dfAttributes & DF_FORMAT_3RC) { snprintf(buffer + strlen(buffer), 256, " v%d..v%d", insn->vC, insn->vC + insn->vA - 1); } else { if (dfAttributes & DF_A_IS_REG) { snprintf(buffer + strlen(buffer), 256, " v%d", insn->vA); } if (dfAttributes & DF_B_IS_REG) { snprintf(buffer + strlen(buffer), 256, ", v%d", insn->vB); } else if ((int)opcode < (int)kMirOpFirst) { snprintf(buffer + strlen(buffer), 256, ", (#%d)", insn->vB); } if (dfAttributes & DF_C_IS_REG) { snprintf(buffer + strlen(buffer), 256, ", v%d", insn->vC); } else if ((int)opcode < (int)kMirOpFirst) { snprintf(buffer + strlen(buffer), 256, ", (#%d)", insn->vC); } } int length = strlen(buffer) + 1; ret = (char *)dvmCompilerNew(length, false); memcpy(ret, buffer, length); return ret; } char *getSSAName(const CompilationUnit *cUnit, int ssaReg, char *name) { int ssa2DalvikValue = dvmConvertSSARegToDalvik(cUnit, ssaReg); sprintf(name, "v%d_%d", DECODE_REG(ssa2DalvikValue), DECODE_SUB(ssa2DalvikValue)); return name; } /* * Dalvik instruction disassembler with optional SSA printing. */ char *dvmCompilerFullDisassembler(const CompilationUnit *cUnit, const MIR *mir) { char buffer[256]; char operand0[256], operand1[256]; const DecodedInstruction *insn = &mir->dalvikInsn; int opcode = insn->opcode; int dfAttributes = dvmCompilerDataFlowAttributes[opcode]; char *ret; int length; OpcodeFlags flags; buffer[0] = 0; if (opcode >= kMirOpFirst) { if (opcode == kMirOpPhi) { snprintf(buffer, 256, "PHI %s = (%s", getSSAName(cUnit, mir->ssaRep->defs[0], operand0), getSSAName(cUnit, mir->ssaRep->uses[0], operand1)); int i; for (i = 1; i < mir->ssaRep->numUses; i++) { snprintf(buffer + strlen(buffer), 256, ", %s", getSSAName(cUnit, mir->ssaRep->uses[i], operand0)); } snprintf(buffer + strlen(buffer), 256, ")"); } else { sprintf(buffer, "Opcode %#x", opcode); } goto done; } else { strcpy(buffer, dexGetOpcodeName((Opcode)opcode)); } flags = dexGetFlagsFromOpcode((Opcode)opcode); /* For branches, decode the instructions to print out the branch targets */ if (flags & kInstrCanBranch) { InstructionFormat dalvikFormat = dexGetFormatFromOpcode(insn->opcode); int delta = 0; switch (dalvikFormat) { case kFmt21t: snprintf(buffer + strlen(buffer), 256, " %s, ", getSSAName(cUnit, mir->ssaRep->uses[0], operand0)); delta = (int) insn->vB; break; case kFmt22t: snprintf(buffer + strlen(buffer), 256, " %s, %s, ", getSSAName(cUnit, mir->ssaRep->uses[0], operand0), getSSAName(cUnit, mir->ssaRep->uses[1], operand1)); delta = (int) insn->vC; break; case kFmt10t: case kFmt20t: case kFmt30t: delta = (int) insn->vA; break; default: ALOGE("Unexpected branch format: %d", dalvikFormat); dvmAbort(); break; } snprintf(buffer + strlen(buffer), 256, " %04x", mir->offset + delta); } else if (dfAttributes & (DF_FORMAT_35C | DF_FORMAT_3RC)) { unsigned int i; for (i = 0; i < insn->vA; i++) { if (i != 0) strcat(buffer, ","); snprintf(buffer + strlen(buffer), 256, " %s", getSSAName(cUnit, mir->ssaRep->uses[i], operand0)); } } else { int udIdx; if (mir->ssaRep->numDefs) { for (udIdx = 0; udIdx < mir->ssaRep->numDefs; udIdx++) { snprintf(buffer + strlen(buffer), 256, " %s", getSSAName(cUnit, mir->ssaRep->defs[udIdx], operand0)); } strcat(buffer, ","); } if (mir->ssaRep->numUses) { /* No leading ',' for the first use */ snprintf(buffer + strlen(buffer), 256, " %s", getSSAName(cUnit, mir->ssaRep->uses[0], operand0)); for (udIdx = 1; udIdx < mir->ssaRep->numUses; udIdx++) { snprintf(buffer + strlen(buffer), 256, ", %s", getSSAName(cUnit, mir->ssaRep->uses[udIdx], operand0)); } } if (opcode < kMirOpFirst) { InstructionFormat dalvikFormat = dexGetFormatFromOpcode((Opcode)opcode); switch (dalvikFormat) { case kFmt11n: // op vA, #+B case kFmt21s: // op vAA, #+BBBB case kFmt21h: // op vAA, #+BBBB00000[00000000] case kFmt31i: // op vAA, #+BBBBBBBB case kFmt51l: // op vAA, #+BBBBBBBBBBBBBBBB snprintf(buffer + strlen(buffer), 256, " #%#x", insn->vB); break; case kFmt21c: // op vAA, thing@BBBB case kFmt31c: // op vAA, thing@BBBBBBBB snprintf(buffer + strlen(buffer), 256, " @%#x", insn->vB); break; case kFmt22b: // op vAA, vBB, #+CC case kFmt22s: // op vA, vB, #+CCCC snprintf(buffer + strlen(buffer), 256, " #%#x", insn->vC); break; case kFmt22c: // op vA, vB, thing@CCCC case kFmt22cs: // [opt] op vA, vB, field offset CCCC snprintf(buffer + strlen(buffer), 256, " @%#x", insn->vC); break; /* No need for special printing */ default: break; } } } done: length = strlen(buffer) + 1; ret = (char *) dvmCompilerNew(length, false); memcpy(ret, buffer, length); return ret; } /* * Utility function to convert encoded SSA register value into Dalvik register * and subscript pair. Each SSA register can be used to index the * ssaToDalvikMap list to get the subscript[31..16]/dalvik_reg[15..0] mapping. */ char *dvmCompilerGetSSAString(CompilationUnit *cUnit, SSARepresentation *ssaRep) { char buffer[256]; char *ret; int i; buffer[0] = 0; for (i = 0; i < ssaRep->numDefs; i++) { int ssa2DalvikValue = dvmConvertSSARegToDalvik(cUnit, ssaRep->defs[i]); sprintf(buffer + strlen(buffer), "s%d(v%d_%d) ", ssaRep->defs[i], DECODE_REG(ssa2DalvikValue), DECODE_SUB(ssa2DalvikValue)); } if (ssaRep->numDefs) { strcat(buffer, "<- "); } for (i = 0; i < ssaRep->numUses; i++) { int ssa2DalvikValue = dvmConvertSSARegToDalvik(cUnit, ssaRep->uses[i]); int len = strlen(buffer); if (snprintf(buffer + len, 250 - len, "s%d(v%d_%d) ", ssaRep->uses[i], DECODE_REG(ssa2DalvikValue), DECODE_SUB(ssa2DalvikValue)) >= (250 - len)) { strcat(buffer, "..."); break; } } int length = strlen(buffer) + 1; ret = (char *)dvmCompilerNew(length, false); memcpy(ret, buffer, length); return ret; } /* Any register that is used before being defined is considered live-in */ static inline void handleLiveInUse(BitVector *useV, BitVector *defV, BitVector *liveInV, int dalvikRegId) { dvmCompilerSetBit(useV, dalvikRegId); if (!dvmIsBitSet(defV, dalvikRegId)) { dvmCompilerSetBit(liveInV, dalvikRegId); } } /* Mark a reg as being defined */ static inline void handleDef(BitVector *defV, int dalvikRegId) { dvmCompilerSetBit(defV, dalvikRegId); } /* * Find out live-in variables for natural loops. Variables that are live-in in * the main loop body are considered to be defined in the entry block. */ bool dvmCompilerFindLocalLiveIn(CompilationUnit *cUnit, BasicBlock *bb) { MIR *mir; BitVector *useV, *defV, *liveInV; if (bb->dataFlowInfo == NULL) return false; useV = bb->dataFlowInfo->useV = dvmCompilerAllocBitVector(cUnit->numDalvikRegisters, false); defV = bb->dataFlowInfo->defV = dvmCompilerAllocBitVector(cUnit->numDalvikRegisters, false); liveInV = bb->dataFlowInfo->liveInV = dvmCompilerAllocBitVector(cUnit->numDalvikRegisters, false); for (mir = bb->firstMIRInsn; mir; mir = mir->next) { int dfAttributes = dvmCompilerDataFlowAttributes[mir->dalvikInsn.opcode]; DecodedInstruction *dInsn = &mir->dalvikInsn; if (dfAttributes & DF_HAS_USES) { if (dfAttributes & DF_UA) { handleLiveInUse(useV, defV, liveInV, dInsn->vA); } else if (dfAttributes & DF_UA_WIDE) { handleLiveInUse(useV, defV, liveInV, dInsn->vA); handleLiveInUse(useV, defV, liveInV, dInsn->vA+1); } if (dfAttributes & DF_UB) { handleLiveInUse(useV, defV, liveInV, dInsn->vB); } else if (dfAttributes & DF_UB_WIDE) { handleLiveInUse(useV, defV, liveInV, dInsn->vB); handleLiveInUse(useV, defV, liveInV, dInsn->vB+1); } if (dfAttributes & DF_UC) { handleLiveInUse(useV, defV, liveInV, dInsn->vC); } else if (dfAttributes & DF_UC_WIDE) { handleLiveInUse(useV, defV, liveInV, dInsn->vC); handleLiveInUse(useV, defV, liveInV, dInsn->vC+1); } } if (dfAttributes & DF_HAS_DEFS) { handleDef(defV, dInsn->vA); if (dfAttributes & DF_DA_WIDE) { handleDef(defV, dInsn->vA+1); } } } return true; } /* Find out the latest SSA register for a given Dalvik register */ static void handleSSAUse(CompilationUnit *cUnit, int *uses, int dalvikReg, int regIndex) { int encodedValue = cUnit->dalvikToSSAMap[dalvikReg]; int ssaReg = DECODE_REG(encodedValue); uses[regIndex] = ssaReg; } /* Setup a new SSA register for a given Dalvik register */ static void handleSSADef(CompilationUnit *cUnit, int *defs, int dalvikReg, int regIndex) { int encodedValue = cUnit->dalvikToSSAMap[dalvikReg]; int ssaReg = cUnit->numSSARegs++; /* Bump up the subscript */ int dalvikSub = DECODE_SUB(encodedValue) + 1; int newD2SMapping = ENCODE_REG_SUB(ssaReg, dalvikSub); cUnit->dalvikToSSAMap[dalvikReg] = newD2SMapping; int newS2DMapping = ENCODE_REG_SUB(dalvikReg, dalvikSub); dvmInsertGrowableList(cUnit->ssaToDalvikMap, newS2DMapping); defs[regIndex] = ssaReg; } /* Loop up new SSA names for format_35c instructions */ static void dataFlowSSAFormat35C(CompilationUnit *cUnit, MIR *mir) { DecodedInstruction *dInsn = &mir->dalvikInsn; int numUses = dInsn->vA; int i; mir->ssaRep->numUses = numUses; mir->ssaRep->uses = (int *)dvmCompilerNew(sizeof(int) * numUses, false); for (i = 0; i < numUses; i++) { handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->arg[i], i); } } /* Loop up new SSA names for format_3rc instructions */ static void dataFlowSSAFormat3RC(CompilationUnit *cUnit, MIR *mir) { DecodedInstruction *dInsn = &mir->dalvikInsn; int numUses = dInsn->vA; int i; mir->ssaRep->numUses = numUses; mir->ssaRep->uses = (int *)dvmCompilerNew(sizeof(int) * numUses, false); for (i = 0; i < numUses; i++) { handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vC+i, i); } } /* Entry function to convert a block into SSA representation */ bool dvmCompilerDoSSAConversion(CompilationUnit *cUnit, BasicBlock *bb) { MIR *mir; if (bb->dataFlowInfo == NULL) return false; for (mir = bb->firstMIRInsn; mir; mir = mir->next) { mir->ssaRep = (struct SSARepresentation *) dvmCompilerNew(sizeof(SSARepresentation), true); int dfAttributes = dvmCompilerDataFlowAttributes[mir->dalvikInsn.opcode]; int numUses = 0; if (dfAttributes & DF_FORMAT_35C) { dataFlowSSAFormat35C(cUnit, mir); continue; } if (dfAttributes & DF_FORMAT_3RC) { dataFlowSSAFormat3RC(cUnit, mir); continue; } if (dfAttributes & DF_HAS_USES) { if (dfAttributes & DF_UA) { numUses++; } else if (dfAttributes & DF_UA_WIDE) { numUses += 2; } if (dfAttributes & DF_UB) { numUses++; } else if (dfAttributes & DF_UB_WIDE) { numUses += 2; } if (dfAttributes & DF_UC) { numUses++; } else if (dfAttributes & DF_UC_WIDE) { numUses += 2; } } if (numUses) { mir->ssaRep->numUses = numUses; mir->ssaRep->uses = (int *)dvmCompilerNew(sizeof(int) * numUses, false); mir->ssaRep->fpUse = (bool *)dvmCompilerNew(sizeof(bool) * numUses, false); } int numDefs = 0; if (dfAttributes & DF_HAS_DEFS) { numDefs++; if (dfAttributes & DF_DA_WIDE) { numDefs++; } } if (numDefs) { mir->ssaRep->numDefs = numDefs; mir->ssaRep->defs = (int *)dvmCompilerNew(sizeof(int) * numDefs, false); mir->ssaRep->fpDef = (bool *)dvmCompilerNew(sizeof(bool) * numDefs, false); } DecodedInstruction *dInsn = &mir->dalvikInsn; if (dfAttributes & DF_HAS_USES) { numUses = 0; if (dfAttributes & DF_UA) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_A; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vA, numUses++); } else if (dfAttributes & DF_UA_WIDE) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_A; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vA, numUses++); mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_A; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vA+1, numUses++); } if (dfAttributes & DF_UB) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_B; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vB, numUses++); } else if (dfAttributes & DF_UB_WIDE) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_B; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vB, numUses++); mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_B; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vB+1, numUses++); } if (dfAttributes & DF_UC) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_C; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vC, numUses++); } else if (dfAttributes & DF_UC_WIDE) { mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_C; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vC, numUses++); mir->ssaRep->fpUse[numUses] = dfAttributes & DF_FP_C; handleSSAUse(cUnit, mir->ssaRep->uses, dInsn->vC+1, numUses++); } } if (dfAttributes & DF_HAS_DEFS) { mir->ssaRep->fpDef[0] = dfAttributes & DF_FP_A; handleSSADef(cUnit, mir->ssaRep->defs, dInsn->vA, 0); if (dfAttributes & DF_DA_WIDE) { mir->ssaRep->fpDef[1] = dfAttributes & DF_FP_A; handleSSADef(cUnit, mir->ssaRep->defs, dInsn->vA+1, 1); } } } /* * Take a snapshot of Dalvik->SSA mapping at the end of each block. The * input to PHI nodes can be derived from the snapshot of all predecessor * blocks. */ bb->dataFlowInfo->dalvikToSSAMap = (int *)dvmCompilerNew(sizeof(int) * cUnit->method->registersSize, false); memcpy(bb->dataFlowInfo->dalvikToSSAMap, cUnit->dalvikToSSAMap, sizeof(int) * cUnit->method->registersSize); return true; } /* Setup a constant value for opcodes thare have the DF_SETS_CONST attribute */ static void setConstant(CompilationUnit *cUnit, int ssaReg, int value) { dvmSetBit(cUnit->isConstantV, ssaReg); cUnit->constantValues[ssaReg] = value; } bool dvmCompilerDoConstantPropagation(CompilationUnit *cUnit, BasicBlock *bb) { MIR *mir; BitVector *isConstantV = cUnit->isConstantV; for (mir = bb->firstMIRInsn; mir; mir = mir->next) { int dfAttributes = dvmCompilerDataFlowAttributes[mir->dalvikInsn.opcode]; DecodedInstruction *dInsn = &mir->dalvikInsn; if (!(dfAttributes & DF_HAS_DEFS)) continue; /* Handle instructions that set up constants directly */ if (dfAttributes & DF_SETS_CONST) { if (dfAttributes & DF_DA) { switch (dInsn->opcode) { case OP_CONST_4: case OP_CONST_16: case OP_CONST: setConstant(cUnit, mir->ssaRep->defs[0], dInsn->vB); break; case OP_CONST_HIGH16: setConstant(cUnit, mir->ssaRep->defs[0], dInsn->vB << 16); break; default: break; } } else if (dfAttributes & DF_DA_WIDE) { switch (dInsn->opcode) { case OP_CONST_WIDE_16: case OP_CONST_WIDE_32: setConstant(cUnit, mir->ssaRep->defs[0], dInsn->vB); setConstant(cUnit, mir->ssaRep->defs[1], 0); break; case OP_CONST_WIDE: setConstant(cUnit, mir->ssaRep->defs[0], (int) dInsn->vB_wide); setConstant(cUnit, mir->ssaRep->defs[1], (int) (dInsn->vB_wide >> 32)); break; case OP_CONST_WIDE_HIGH16: setConstant(cUnit, mir->ssaRep->defs[0], 0); setConstant(cUnit, mir->ssaRep->defs[1], dInsn->vB << 16); break; default: break; } } /* Handle instructions that set up constants directly */ } else if (dfAttributes & DF_IS_MOVE) { int i; for (i = 0; i < mir->ssaRep->numUses; i++) { if (!dvmIsBitSet(isConstantV, mir->ssaRep->uses[i])) break; } /* Move a register holding a constant to another register */ if (i == mir->ssaRep->numUses) { setConstant(cUnit, mir->ssaRep->defs[0], cUnit->constantValues[mir->ssaRep->uses[0]]); if (dfAttributes & DF_DA_WIDE) { setConstant(cUnit, mir->ssaRep->defs[1], cUnit->constantValues[mir->ssaRep->uses[1]]); } } } } /* TODO: implement code to handle arithmetic operations */ return true; } bool dvmCompilerFindInductionVariables(struct CompilationUnit *cUnit, struct BasicBlock *bb) { BitVector *isIndVarV = cUnit->loopAnalysis->isIndVarV; BitVector *isConstantV = cUnit->isConstantV; GrowableList *ivList = cUnit->loopAnalysis->ivList; MIR *mir; if (bb->blockType != kDalvikByteCode && bb->blockType != kEntryBlock) { return false; } /* If the bb doesn't have a phi it cannot contain an induction variable */ if (bb->firstMIRInsn == NULL || (int)bb->firstMIRInsn->dalvikInsn.opcode != (int)kMirOpPhi) { return false; } /* Find basic induction variable first */ for (mir = bb->firstMIRInsn; mir; mir = mir->next) { int dfAttributes = dvmCompilerDataFlowAttributes[mir->dalvikInsn.opcode]; if (!(dfAttributes & DF_IS_LINEAR)) continue; /* * For a basic induction variable: * 1) use[0] should belong to the output of a phi node * 2) def[0] should belong to the input of the same phi node * 3) the value added/subtracted is a constant */ MIR *phi; for (phi = bb->firstMIRInsn; phi; phi = phi->next) { if ((int)phi->dalvikInsn.opcode != (int)kMirOpPhi) break; if (phi->ssaRep->defs[0] == mir->ssaRep->uses[0] && phi->ssaRep->uses[1] == mir->ssaRep->defs[0]) { bool deltaIsConstant = false; int deltaValue; switch (mir->dalvikInsn.opcode) { case OP_ADD_INT: if (dvmIsBitSet(isConstantV, mir->ssaRep->uses[1])) { deltaValue = cUnit->constantValues[mir->ssaRep->uses[1]]; deltaIsConstant = true; } break; case OP_SUB_INT: if (dvmIsBitSet(isConstantV, mir->ssaRep->uses[1])) { deltaValue = -cUnit->constantValues[mir->ssaRep->uses[1]]; deltaIsConstant = true; } break; case OP_ADD_INT_LIT8: deltaValue = mir->dalvikInsn.vC; deltaIsConstant = true; break; default: break; } if (deltaIsConstant) { dvmSetBit(isIndVarV, mir->ssaRep->uses[0]); InductionVariableInfo *ivInfo = (InductionVariableInfo *) dvmCompilerNew(sizeof(InductionVariableInfo), false); ivInfo->ssaReg = mir->ssaRep->uses[0]; ivInfo->basicSSAReg = mir->ssaRep->uses[0]; ivInfo->m = 1; // always 1 to basic iv ivInfo->c = 0; // N/A to basic iv ivInfo->inc = deltaValue; dvmInsertGrowableList(ivList, (intptr_t) ivInfo); cUnit->loopAnalysis->numBasicIV++; break; } } } } /* Find dependent induction variable now */ for (mir = bb->firstMIRInsn; mir; mir = mir->next) { int dfAttributes = dvmCompilerDataFlowAttributes[mir->dalvikInsn.opcode]; if (!(dfAttributes & DF_IS_LINEAR)) continue; /* Skip already identified induction variables */ if (dvmIsBitSet(isIndVarV, mir->ssaRep->defs[0])) continue; /* * For a dependent induction variable: * 1) use[0] should be an induction variable (basic/dependent) * 2) operand2 should be a constant */ if (dvmIsBitSet(isIndVarV, mir->ssaRep->uses[0])) { int srcDalvikReg = dvmConvertSSARegToDalvik(cUnit, mir->ssaRep->uses[0]); int dstDalvikReg = dvmConvertSSARegToDalvik(cUnit, mir->ssaRep->defs[0]); bool cIsConstant = false; int c = 0; switch (mir->dalvikInsn.opcode) { case OP_ADD_INT: if (dvmIsBitSet(isConstantV, mir->ssaRep->uses[1])) { c = cUnit->constantValues[mir->ssaRep->uses[1]]; cIsConstant = true; } break; case OP_SUB_INT: if (dvmIsBitSet(isConstantV, mir->ssaRep->uses[1])) { c = -cUnit->constantValues[mir->ssaRep->uses[1]]; cIsConstant = true; } break; case OP_ADD_INT_LIT8: c = mir->dalvikInsn.vC; cIsConstant = true; break; default: break; } /* Ignore the update to the basic induction variable itself */ if (DECODE_REG(srcDalvikReg) == DECODE_REG(dstDalvikReg)) { cUnit->loopAnalysis->ssaBIV = mir->ssaRep->defs[0]; cIsConstant = false; } if (cIsConstant) { unsigned int i; dvmSetBit(isIndVarV, mir->ssaRep->defs[0]); InductionVariableInfo *ivInfo = (InductionVariableInfo *) dvmCompilerNew(sizeof(InductionVariableInfo), false); InductionVariableInfo *ivInfoOld = NULL ; for (i = 0; i < ivList->numUsed; i++) { ivInfoOld = (InductionVariableInfo *) ivList->elemList[i]; if (ivInfoOld->ssaReg == mir->ssaRep->uses[0]) break; } /* Guaranteed to find an element */ assert(i < ivList->numUsed); ivInfo->ssaReg = mir->ssaRep->defs[0]; ivInfo->basicSSAReg = ivInfoOld->basicSSAReg; ivInfo->m = ivInfoOld->m; ivInfo->c = c + ivInfoOld->c; ivInfo->inc = ivInfoOld->inc; dvmInsertGrowableList(ivList, (intptr_t) ivInfo); } } } return true; } /* Setup the basic data structures for SSA conversion */ void dvmInitializeSSAConversion(CompilationUnit *cUnit) { int i; int numDalvikReg = cUnit->method->registersSize; cUnit->ssaToDalvikMap = (GrowableList *)dvmCompilerNew(sizeof(GrowableList), false); dvmInitGrowableList(cUnit->ssaToDalvikMap, numDalvikReg); /* * Initial number of SSA registers is equal to the number of Dalvik * registers. */ cUnit->numSSARegs = numDalvikReg; /* * Initialize the SSA2Dalvik map list. For the first numDalvikReg elements, * the subscript is 0 so we use the ENCODE_REG_SUB macro to encode the value * into "(0 << 16) | i" */ for (i = 0; i < numDalvikReg; i++) { dvmInsertGrowableList(cUnit->ssaToDalvikMap, ENCODE_REG_SUB(i, 0)); } /* * Initialize the DalvikToSSAMap map. The low 16 bit is the SSA register id, * while the high 16 bit is the current subscript. The original Dalvik * register N is mapped to SSA register N with subscript 0. */ cUnit->dalvikToSSAMap = (int *)dvmCompilerNew(sizeof(int) * numDalvikReg, false); for (i = 0; i < numDalvikReg; i++) { cUnit->dalvikToSSAMap[i] = i; } /* * Allocate the BasicBlockDataFlow structure for the entry and code blocks */ GrowableListIterator iterator; dvmGrowableListIteratorInit(&cUnit->blockList, &iterator); while (true) { BasicBlock *bb = (BasicBlock *) dvmGrowableListIteratorNext(&iterator); if (bb == NULL) break; if (bb->hidden == true) continue; if (bb->blockType == kDalvikByteCode || bb->blockType == kEntryBlock || bb->blockType == kExitBlock) { bb->dataFlowInfo = (BasicBlockDataFlow *) dvmCompilerNew(sizeof(BasicBlockDataFlow), true); } } } /* Clear the visited flag for each BB */ bool dvmCompilerClearVisitedFlag(struct CompilationUnit *cUnit, struct BasicBlock *bb) { bb->visited = false; return true; } void dvmCompilerDataFlowAnalysisDispatcher(CompilationUnit *cUnit, bool (*func)(CompilationUnit *, BasicBlock *), DataFlowAnalysisMode dfaMode, bool isIterative) { bool change = true; while (change) { change = false; /* Scan all blocks and perform the operations specified in func */ if (dfaMode == kAllNodes) { GrowableListIterator iterator; dvmGrowableListIteratorInit(&cUnit->blockList, &iterator); while (true) { BasicBlock *bb = (BasicBlock *) dvmGrowableListIteratorNext(&iterator); if (bb == NULL) break; if (bb->hidden == true) continue; change |= (*func)(cUnit, bb); } } /* * Scan all reachable blocks and perform the operations specified in * func. */ else if (dfaMode == kReachableNodes) { int numReachableBlocks = cUnit->numReachableBlocks; int idx; const GrowableList *blockList = &cUnit->blockList; for (idx = 0; idx < numReachableBlocks; idx++) { int blockIdx = cUnit->dfsOrder.elemList[idx]; BasicBlock *bb = (BasicBlock *) dvmGrowableListGetElement(blockList, blockIdx); change |= (*func)(cUnit, bb); } } /* * Scan all reachable blocks by the pre-order in the depth-first-search * CFG and perform the operations specified in func. */ else if (dfaMode == kPreOrderDFSTraversal) { int numReachableBlocks = cUnit->numReachableBlocks; int idx; const GrowableList *blockList = &cUnit->blockList; for (idx = 0; idx < numReachableBlocks; idx++) { int dfsIdx = cUnit->dfsOrder.elemList[idx]; BasicBlock *bb = (BasicBlock *) dvmGrowableListGetElement(blockList, dfsIdx); change |= (*func)(cUnit, bb); } } /* * Scan all reachable blocks by the post-order in the depth-first-search * CFG and perform the operations specified in func. */ else if (dfaMode == kPostOrderDFSTraversal) { int numReachableBlocks = cUnit->numReachableBlocks; int idx; const GrowableList *blockList = &cUnit->blockList; for (idx = numReachableBlocks - 1; idx >= 0; idx--) { int dfsIdx = cUnit->dfsOrder.elemList[idx]; BasicBlock *bb = (BasicBlock *) dvmGrowableListGetElement(blockList, dfsIdx); change |= (*func)(cUnit, bb); } } /* * Scan all reachable blocks by the post-order in the dominator tree * and perform the operations specified in func. */ else if (dfaMode == kPostOrderDOMTraversal) { int numReachableBlocks = cUnit->numReachableBlocks; int idx; const GrowableList *blockList = &cUnit->blockList; for (idx = 0; idx < numReachableBlocks; idx++) { int domIdx = cUnit->domPostOrderTraversal.elemList[idx]; BasicBlock *bb = (BasicBlock *) dvmGrowableListGetElement(blockList, domIdx); change |= (*func)(cUnit, bb); } } /* If isIterative is false, exit the loop after the first iteration */ change &= isIterative; } } /* Main entry point to do SSA conversion for non-loop traces */ void dvmCompilerNonLoopAnalysis(CompilationUnit *cUnit) { dvmCompilerDataFlowAnalysisDispatcher(cUnit, dvmCompilerDoSSAConversion, kAllNodes, false /* isIterative */); }