1 /* 2 * Generic intermediate code generation. 3 * 4 * Copyright (C) 2016-2017 Lluís Vilanova <vilanova@ac.upc.edu> 5 * 6 * This work is licensed under the terms of the GNU GPL, version 2 or later. 7 * See the COPYING file in the top-level directory. 8 */ 9 10 #ifndef EXEC__TRANSLATOR_H 11 #define EXEC__TRANSLATOR_H 12 13 /* 14 * Include this header from a target-specific file, and add a 15 * 16 * DisasContextBase base; 17 * 18 * member in your target-specific DisasContext. 19 */ 20 21 #include "qemu/bswap.h" 22 #include "exec/cpu_ldst.h" /* for abi_ptr */ 23 24 /** 25 * gen_intermediate_code 26 * @cpu: cpu context 27 * @tb: translation block 28 * @max_insns: max number of instructions to translate 29 * @pc: guest virtual program counter address 30 * @host_pc: host physical program counter address 31 * 32 * This function must be provided by the target, which should create 33 * the target-specific DisasContext, and then invoke translator_loop. 34 */ 35 void gen_intermediate_code(CPUState *cpu, TranslationBlock *tb, int *max_insns, 36 target_ulong pc, void *host_pc); 37 38 /** 39 * DisasJumpType: 40 * @DISAS_NEXT: Next instruction in program order. 41 * @DISAS_TOO_MANY: Too many instructions translated. 42 * @DISAS_NORETURN: Following code is dead. 43 * @DISAS_TARGET_*: Start of target-specific conditions. 44 * 45 * What instruction to disassemble next. 46 */ 47 typedef enum DisasJumpType { 48 DISAS_NEXT, 49 DISAS_TOO_MANY, 50 DISAS_NORETURN, 51 DISAS_TARGET_0, 52 DISAS_TARGET_1, 53 DISAS_TARGET_2, 54 DISAS_TARGET_3, 55 DISAS_TARGET_4, 56 DISAS_TARGET_5, 57 DISAS_TARGET_6, 58 DISAS_TARGET_7, 59 DISAS_TARGET_8, 60 DISAS_TARGET_9, 61 DISAS_TARGET_10, 62 DISAS_TARGET_11, 63 } DisasJumpType; 64 65 /** 66 * DisasContextBase: 67 * @tb: Translation block for this disassembly. 68 * @pc_first: Address of first guest instruction in this TB. 69 * @pc_next: Address of next guest instruction in this TB (current during 70 * disassembly). 71 * @is_jmp: What instruction to disassemble next. 72 * @num_insns: Number of translated instructions (including current). 73 * @max_insns: Maximum number of instructions to be translated in this TB. 74 * @singlestep_enabled: "Hardware" single stepping enabled. 75 * @saved_can_do_io: Known value of cpu->neg.can_do_io, or -1 for unknown. 76 * @plugin_enabled: TCG plugin enabled in this TB. 77 * 78 * Architecture-agnostic disassembly context. 79 */ 80 typedef struct DisasContextBase { 81 TranslationBlock *tb; 82 target_ulong pc_first; 83 target_ulong pc_next; 84 DisasJumpType is_jmp; 85 int num_insns; 86 int max_insns; 87 bool singlestep_enabled; 88 int8_t saved_can_do_io; 89 bool plugin_enabled; 90 void *host_addr[2]; 91 } DisasContextBase; 92 93 /** 94 * TranslatorOps: 95 * @init_disas_context: 96 * Initialize the target-specific portions of DisasContext struct. 97 * The generic DisasContextBase has already been initialized. 98 * 99 * @tb_start: 100 * Emit any code required before the start of the main loop, 101 * after the generic gen_tb_start(). 102 * 103 * @insn_start: 104 * Emit the tcg_gen_insn_start opcode. 105 * 106 * @translate_insn: 107 * Disassemble one instruction and set db->pc_next for the start 108 * of the following instruction. Set db->is_jmp as necessary to 109 * terminate the main loop. 110 * 111 * @tb_stop: 112 * Emit any opcodes required to exit the TB, based on db->is_jmp. 113 * 114 * @disas_log: 115 * Print instruction disassembly to log. 116 */ 117 typedef struct TranslatorOps { 118 void (*init_disas_context)(DisasContextBase *db, CPUState *cpu); 119 void (*tb_start)(DisasContextBase *db, CPUState *cpu); 120 void (*insn_start)(DisasContextBase *db, CPUState *cpu); 121 void (*translate_insn)(DisasContextBase *db, CPUState *cpu); 122 void (*tb_stop)(DisasContextBase *db, CPUState *cpu); 123 void (*disas_log)(const DisasContextBase *db, CPUState *cpu, FILE *f); 124 } TranslatorOps; 125 126 /** 127 * translator_loop: 128 * @cpu: Target vCPU. 129 * @tb: Translation block. 130 * @max_insns: Maximum number of insns to translate. 131 * @pc: guest virtual program counter address 132 * @host_pc: host physical program counter address 133 * @ops: Target-specific operations. 134 * @db: Disassembly context. 135 * 136 * Generic translator loop. 137 * 138 * Translation will stop in the following cases (in order): 139 * - When is_jmp set by #TranslatorOps::breakpoint_check. 140 * - set to DISAS_TOO_MANY exits after translating one more insn 141 * - set to any other value than DISAS_NEXT exits immediately. 142 * - When is_jmp set by #TranslatorOps::translate_insn. 143 * - set to any value other than DISAS_NEXT exits immediately. 144 * - When the TCG operation buffer is full. 145 * - When single-stepping is enabled (system-wide or on the current vCPU). 146 * - When too many instructions have been translated. 147 */ 148 void translator_loop(CPUState *cpu, TranslationBlock *tb, int *max_insns, 149 vaddr pc, void *host_pc, const TranslatorOps *ops, 150 DisasContextBase *db); 151 152 /** 153 * translator_use_goto_tb 154 * @db: Disassembly context 155 * @dest: target pc of the goto 156 * 157 * Return true if goto_tb is allowed between the current TB 158 * and the destination PC. 159 */ 160 bool translator_use_goto_tb(DisasContextBase *db, vaddr dest); 161 162 /** 163 * translator_io_start 164 * @db: Disassembly context 165 * 166 * If icount is enabled, set cpu->can_do_io, adjust db->is_jmp to 167 * DISAS_TOO_MANY if it is still DISAS_NEXT, and return true. 168 * Otherwise return false. 169 */ 170 bool translator_io_start(DisasContextBase *db); 171 172 /* 173 * Translator Load Functions 174 * 175 * These are intended to replace the direct usage of the cpu_ld*_code 176 * functions and are mandatory for front-ends that have been migrated 177 * to the common translator_loop. These functions are only intended 178 * to be called from the translation stage and should not be called 179 * from helper functions. Those functions should be converted to encode 180 * the relevant information at translation time. 181 */ 182 183 uint8_t translator_ldub(CPUArchState *env, DisasContextBase *db, abi_ptr pc); 184 uint16_t translator_lduw(CPUArchState *env, DisasContextBase *db, abi_ptr pc); 185 uint32_t translator_ldl(CPUArchState *env, DisasContextBase *db, abi_ptr pc); 186 uint64_t translator_ldq(CPUArchState *env, DisasContextBase *db, abi_ptr pc); 187 188 static inline uint16_t 189 translator_lduw_swap(CPUArchState *env, DisasContextBase *db, 190 abi_ptr pc, bool do_swap) 191 { 192 uint16_t ret = translator_lduw(env, db, pc); 193 if (do_swap) { 194 ret = bswap16(ret); 195 } 196 return ret; 197 } 198 199 static inline uint32_t 200 translator_ldl_swap(CPUArchState *env, DisasContextBase *db, 201 abi_ptr pc, bool do_swap) 202 { 203 uint32_t ret = translator_ldl(env, db, pc); 204 if (do_swap) { 205 ret = bswap32(ret); 206 } 207 return ret; 208 } 209 210 static inline uint64_t 211 translator_ldq_swap(CPUArchState *env, DisasContextBase *db, 212 abi_ptr pc, bool do_swap) 213 { 214 uint64_t ret = translator_ldq(env, db, pc); 215 if (do_swap) { 216 ret = bswap64(ret); 217 } 218 return ret; 219 } 220 221 /** 222 * translator_fake_ldb - fake instruction load 223 * @insn8: byte of instruction 224 * @pc: program counter of instruction 225 * 226 * This is a special case helper used where the instruction we are 227 * about to translate comes from somewhere else (e.g. being 228 * re-synthesised for s390x "ex"). It ensures we update other areas of 229 * the translator with details of the executed instruction. 230 */ 231 void translator_fake_ldb(uint8_t insn8, abi_ptr pc); 232 233 /* 234 * Return whether addr is on the same page as where disassembly started. 235 * Translators can use this to enforce the rule that only single-insn 236 * translation blocks are allowed to cross page boundaries. 237 */ 238 static inline bool is_same_page(const DisasContextBase *db, target_ulong addr) 239 { 240 return ((addr ^ db->pc_first) & TARGET_PAGE_MASK) == 0; 241 } 242 243 #endif /* EXEC__TRANSLATOR_H */ 244