/* Unicorn Emulator Engine */ /* By Nguyen Anh Quynh , 2015 */ #ifndef UC_PRIV_H #define UC_PRIV_H #include "unicorn/platform.h" #include #include "qemu.h" #include "unicorn/unicorn.h" #include "list.h" // These are masks of supported modes for each cpu/arch. // They should be updated when changes are made to the uc_mode enum typedef. #define UC_MODE_ARM_MASK (UC_MODE_ARM|UC_MODE_THUMB|UC_MODE_LITTLE_ENDIAN|UC_MODE_MCLASS|UC_MODE_BIG_ENDIAN) #define UC_MODE_MIPS_MASK (UC_MODE_MIPS32|UC_MODE_MIPS64|UC_MODE_LITTLE_ENDIAN|UC_MODE_BIG_ENDIAN) #define UC_MODE_X86_MASK (UC_MODE_16|UC_MODE_32|UC_MODE_64|UC_MODE_LITTLE_ENDIAN) #define UC_MODE_PPC_MASK (UC_MODE_PPC64|UC_MODE_BIG_ENDIAN) #define UC_MODE_SPARC_MASK (UC_MODE_SPARC32|UC_MODE_SPARC64|UC_MODE_BIG_ENDIAN) #define UC_MODE_M68K_MASK (UC_MODE_BIG_ENDIAN) #define ARR_SIZE(a) (sizeof(a)/sizeof(a[0])) #define READ_QWORD(x) ((uint64)x) #define READ_DWORD(x) (x & 0xffffffff) #define READ_WORD(x) (x & 0xffff) #define READ_BYTE_H(x) ((x & 0xffff) >> 8) #define READ_BYTE_L(x) (x & 0xff) #define WRITE_DWORD(x, w) (x = (x & ~0xffffffffLL) | (w & 0xffffffff)) #define WRITE_WORD(x, w) (x = (x & ~0xffff) | (w & 0xffff)) #define WRITE_BYTE_H(x, b) (x = (x & ~0xff00) | ((b & 0xff) << 8)) #define WRITE_BYTE_L(x, b) (x = (x & ~0xff) | (b & 0xff)) typedef struct ModuleEntry { void (*init)(void); QTAILQ_ENTRY(ModuleEntry) node; module_init_type type; } ModuleEntry; typedef QTAILQ_HEAD(, ModuleEntry) ModuleTypeList; typedef uc_err (*query_t)(struct uc_struct *uc, uc_query_type type, size_t *result); // return 0 on success, -1 on failure typedef int (*reg_read_t)(struct uc_struct *uc, unsigned int *regs, void **vals, int count); typedef int (*reg_write_t)(struct uc_struct *uc, unsigned int *regs, void *const *vals, int count); typedef void (*reg_reset_t)(struct uc_struct *uc); typedef bool (*uc_write_mem_t)(AddressSpace *as, hwaddr addr, const uint8_t *buf, int len); typedef bool (*uc_read_mem_t)(AddressSpace *as, hwaddr addr, uint8_t *buf, int len); typedef void (*uc_args_void_t)(void*); typedef void (*uc_args_uc_t)(struct uc_struct*); typedef int (*uc_args_int_uc_t)(struct uc_struct*); typedef bool (*uc_args_tcg_enable_t)(struct uc_struct*); typedef void (*uc_args_uc_long_t)(struct uc_struct*, unsigned long); typedef void (*uc_args_uc_u64_t)(struct uc_struct *, uint64_t addr); typedef MemoryRegion* (*uc_args_uc_ram_size_t)(struct uc_struct*, hwaddr begin, size_t size, uint32_t perms); typedef MemoryRegion* (*uc_args_uc_ram_size_ptr_t)(struct uc_struct*, hwaddr begin, size_t size, uint32_t perms, void *ptr); typedef void (*uc_mem_unmap_t)(struct uc_struct*, MemoryRegion *mr); typedef void (*uc_readonly_mem_t)(MemoryRegion *mr, bool readonly); // which interrupt should make emulation stop? typedef bool (*uc_args_int_t)(int intno); // some architecture redirect virtual memory to physical memory like Mips typedef uint64_t (*uc_mem_redirect_t)(uint64_t address); // validate if Unicorn supports hooking a given instruction typedef bool(*uc_insn_hook_validate)(uint32_t insn_enum); struct hook { int type; // UC_HOOK_* int insn; // instruction for HOOK_INSN int refs; // reference count to free hook stored in multiple lists uint64_t begin, end; // only trigger if PC or memory access is in this address (depends on hook type) void *callback; // a uc_cb_* type void *user_data; }; // hook list offsets // mirrors the order of uc_hook_type from include/unicorn/unicorn.h enum uc_hook_idx { UC_HOOK_INTR_IDX, UC_HOOK_INSN_IDX, UC_HOOK_CODE_IDX, UC_HOOK_BLOCK_IDX, UC_HOOK_MEM_READ_UNMAPPED_IDX, UC_HOOK_MEM_WRITE_UNMAPPED_IDX, UC_HOOK_MEM_FETCH_UNMAPPED_IDX, UC_HOOK_MEM_READ_PROT_IDX, UC_HOOK_MEM_WRITE_PROT_IDX, UC_HOOK_MEM_FETCH_PROT_IDX, UC_HOOK_MEM_READ_IDX, UC_HOOK_MEM_WRITE_IDX, UC_HOOK_MEM_FETCH_IDX, UC_HOOK_MEM_READ_AFTER_IDX, UC_HOOK_MAX, }; #define HOOK_FOREACH_VAR_DECLARE \ struct list_item *cur // for loop macro to loop over hook lists #define HOOK_FOREACH(uc, hh, idx) \ for ( \ cur = (uc)->hook[idx##_IDX].head; \ cur != NULL && ((hh) = (struct hook *)cur->data) \ /* stop excuting callbacks on stop request */ \ && !uc->stop_request; \ cur = cur->next) // if statement to check hook bounds #define HOOK_BOUND_CHECK(hh, addr) \ ((((addr) >= (hh)->begin && (addr) <= (hh)->end) \ || (hh)->begin > (hh)->end)) #define HOOK_EXISTS(uc, idx) ((uc)->hook[idx##_IDX].head != NULL) #define HOOK_EXISTS_BOUNDED(uc, idx, addr) _hook_exists_bounded((uc)->hook[idx##_IDX].head, addr) static inline bool _hook_exists_bounded(struct list_item *cur, uint64_t addr) { while (cur != NULL) { if (HOOK_BOUND_CHECK((struct hook *)cur->data, addr)) return true; cur = cur->next; } return false; } //relloc increment, KEEP THIS A POWER OF 2! #define MEM_BLOCK_INCR 32 struct uc_struct { uc_arch arch; uc_mode mode; uc_err errnum; // qemu/cpu-exec.c AddressSpace as; query_t query; reg_read_t reg_read; reg_write_t reg_write; reg_reset_t reg_reset; uc_write_mem_t write_mem; uc_read_mem_t read_mem; uc_args_void_t release; // release resource when uc_close() uc_args_uc_u64_t set_pc; // set PC for tracecode uc_args_int_t stop_interrupt; // check if the interrupt should stop emulation uc_args_uc_t init_arch, cpu_exec_init_all; uc_args_int_uc_t vm_start; uc_args_tcg_enable_t tcg_enabled; uc_args_uc_long_t tcg_exec_init; uc_args_uc_ram_size_t memory_map; uc_args_uc_ram_size_ptr_t memory_map_ptr; uc_mem_unmap_t memory_unmap; uc_readonly_mem_t readonly_mem; uc_mem_redirect_t mem_redirect; // TODO: remove current_cpu, as it's a flag for something else ("cpu running"?) CPUState *cpu, *current_cpu; uc_insn_hook_validate insn_hook_validate; MemoryRegion *system_memory; // qemu/exec.c MemoryRegion io_mem_rom; // qemu/exec.c MemoryRegion io_mem_notdirty; // qemu/exec.c MemoryRegion io_mem_unassigned; // qemu/exec.c MemoryRegion io_mem_watch; // qemu/exec.c RAMList ram_list; // qemu/exec.c BounceBuffer bounce; // qemu/cpu-exec.c volatile sig_atomic_t exit_request; // qemu/cpu-exec.c bool global_dirty_log; // qemu/memory.c /* This is a multi-level map on the virtual address space. The bottom level has pointers to PageDesc. */ void **l1_map; // qemu/translate-all.c size_t l1_map_size; /* code generation context */ void *tcg_ctx; // for "TCGContext tcg_ctx" in qemu/translate-all.c /* memory.c */ unsigned memory_region_transaction_depth; bool memory_region_update_pending; bool ioeventfd_update_pending; QTAILQ_HEAD(memory_listeners, MemoryListener) memory_listeners; QTAILQ_HEAD(, AddressSpace) address_spaces; MachineState *machine_state; // qom/object.c GHashTable *type_table; Type type_interface; Object *root; Object *owner; bool enumerating_types; // util/module.c ModuleTypeList init_type_list[MODULE_INIT_MAX]; // hw/intc/apic_common.c DeviceState *vapic; int apic_no; bool mmio_registered; bool apic_report_tpr_access; // linked lists containing hooks per type struct list hook[UC_HOOK_MAX]; // hook to count number of instructions for uc_emu_start() uc_hook count_hook; size_t emu_counter; // current counter of uc_emu_start() size_t emu_count; // save counter of uc_emu_start() uint64_t block_addr; // save the last block address we hooked bool init_tcg; // already initialized local TCGv variables? bool stop_request; // request to immediately stop emulation - for uc_emu_stop() bool quit_request; // request to quit the current TB, but continue to emulate - for uc_mem_protect() bool emulation_done; // emulation is done by uc_emu_start() QemuThread timer; // timer for emulation timeout uint64_t timeout; // timeout for uc_emu_start() uint64_t invalid_addr; // invalid address to be accessed int invalid_error; // invalid memory code: 1 = READ, 2 = WRITE, 3 = CODE uint64_t addr_end; // address where emulation stops (@end param of uc_emu_start()) int thumb; // thumb mode for ARM // full TCG cache leads to middle-block break in the last translation? bool block_full; int size_arg; // what tcg arg slot do we need to update with the size of the block? MemoryRegion **mapped_blocks; uint32_t mapped_block_count; uint32_t mapped_block_cache_index; void *qemu_thread_data; // to support cross compile to Windows (qemu-thread-win32.c) uint32_t target_page_size; uint32_t target_page_align; uint64_t next_pc; // save next PC for some special cases }; // Metadata stub for the variable-size cpu context used with uc_context_*() struct uc_context { size_t size; char data[0]; }; // check if this address is mapped in (via uc_mem_map()) MemoryRegion *memory_mapping(struct uc_struct* uc, uint64_t address); #endif /* vim: set ts=4 noet: */