d317091d5e
The fields in the TaskState heap_base, heap_limit and stack_base are all guest addresses (representing the locations of the heap and stack for the guest binary), so they should be abi_ulong rather than uint32_t. (This only in practice affects ARM AArch64 since all the other semihosting implementations are 32-bit.) Signed-off-by: Peter Maydell <peter.maydell@linaro.org> Reviewed-by: Laurent Desnogues <laurent.desnogues@gmail.com> Message-id: 1466783381-29506-2-git-send-email-peter.maydell@linaro.org
614 lines
23 KiB
C
614 lines
23 KiB
C
#ifndef QEMU_H
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#define QEMU_H
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#include "hostdep.h"
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#include "cpu.h"
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#include "exec/exec-all.h"
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#include "exec/cpu_ldst.h"
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#undef DEBUG_REMAP
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#ifdef DEBUG_REMAP
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#endif /* DEBUG_REMAP */
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#include "exec/user/abitypes.h"
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#include "exec/user/thunk.h"
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#include "syscall_defs.h"
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#include "target_syscall.h"
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#include "exec/gdbstub.h"
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#include "qemu/queue.h"
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#define THREAD __thread
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/* This is the size of the host kernel's sigset_t, needed where we make
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* direct system calls that take a sigset_t pointer and a size.
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*/
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#define SIGSET_T_SIZE (_NSIG / 8)
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/* This struct is used to hold certain information about the image.
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* Basically, it replicates in user space what would be certain
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* task_struct fields in the kernel
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*/
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struct image_info {
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abi_ulong load_bias;
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abi_ulong load_addr;
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abi_ulong start_code;
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abi_ulong end_code;
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abi_ulong start_data;
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abi_ulong end_data;
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abi_ulong start_brk;
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abi_ulong brk;
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abi_ulong start_mmap;
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abi_ulong start_stack;
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abi_ulong stack_limit;
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abi_ulong entry;
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abi_ulong code_offset;
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abi_ulong data_offset;
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abi_ulong saved_auxv;
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abi_ulong auxv_len;
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abi_ulong arg_start;
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abi_ulong arg_end;
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uint32_t elf_flags;
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int personality;
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#ifdef CONFIG_USE_FDPIC
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abi_ulong loadmap_addr;
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uint16_t nsegs;
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void *loadsegs;
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abi_ulong pt_dynamic_addr;
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struct image_info *other_info;
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#endif
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};
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#ifdef TARGET_I386
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/* Information about the current linux thread */
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struct vm86_saved_state {
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uint32_t eax; /* return code */
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uint32_t ebx;
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uint32_t ecx;
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uint32_t edx;
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uint32_t esi;
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uint32_t edi;
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uint32_t ebp;
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uint32_t esp;
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uint32_t eflags;
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uint32_t eip;
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uint16_t cs, ss, ds, es, fs, gs;
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};
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#endif
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#if defined(TARGET_ARM) && defined(TARGET_ABI32)
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/* FPU emulator */
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#include "nwfpe/fpa11.h"
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#endif
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#define MAX_SIGQUEUE_SIZE 1024
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struct emulated_sigtable {
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int pending; /* true if signal is pending */
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target_siginfo_t info;
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};
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/* NOTE: we force a big alignment so that the stack stored after is
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aligned too */
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typedef struct TaskState {
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pid_t ts_tid; /* tid (or pid) of this task */
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#ifdef TARGET_ARM
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# ifdef TARGET_ABI32
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/* FPA state */
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FPA11 fpa;
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# endif
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int swi_errno;
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#endif
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#ifdef TARGET_UNICORE32
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int swi_errno;
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#endif
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#if defined(TARGET_I386) && !defined(TARGET_X86_64)
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abi_ulong target_v86;
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struct vm86_saved_state vm86_saved_regs;
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struct target_vm86plus_struct vm86plus;
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uint32_t v86flags;
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uint32_t v86mask;
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#endif
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abi_ulong child_tidptr;
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#ifdef TARGET_M68K
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int sim_syscalls;
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abi_ulong tp_value;
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#endif
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#if defined(TARGET_ARM) || defined(TARGET_M68K) || defined(TARGET_UNICORE32)
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/* Extra fields for semihosted binaries. */
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abi_ulong heap_base;
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abi_ulong heap_limit;
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#endif
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abi_ulong stack_base;
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int used; /* non zero if used */
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struct image_info *info;
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struct linux_binprm *bprm;
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struct emulated_sigtable sync_signal;
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struct emulated_sigtable sigtab[TARGET_NSIG];
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/* This thread's signal mask, as requested by the guest program.
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* The actual signal mask of this thread may differ:
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* + we don't let SIGSEGV and SIGBUS be blocked while running guest code
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* + sometimes we block all signals to avoid races
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*/
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sigset_t signal_mask;
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/* The signal mask imposed by a guest sigsuspend syscall, if we are
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* currently in the middle of such a syscall
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*/
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sigset_t sigsuspend_mask;
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/* Nonzero if we're leaving a sigsuspend and sigsuspend_mask is valid. */
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int in_sigsuspend;
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/* Nonzero if process_pending_signals() needs to do something (either
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* handle a pending signal or unblock signals).
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* This flag is written from a signal handler so should be accessed via
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* the atomic_read() and atomic_write() functions. (It is not accessed
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* from multiple threads.)
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*/
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int signal_pending;
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} __attribute__((aligned(16))) TaskState;
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extern char *exec_path;
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void init_task_state(TaskState *ts);
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void task_settid(TaskState *);
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void stop_all_tasks(void);
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extern const char *qemu_uname_release;
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extern unsigned long mmap_min_addr;
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/* ??? See if we can avoid exposing so much of the loader internals. */
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/* Read a good amount of data initially, to hopefully get all the
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program headers loaded. */
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#define BPRM_BUF_SIZE 1024
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/*
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* This structure is used to hold the arguments that are
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* used when loading binaries.
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*/
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struct linux_binprm {
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char buf[BPRM_BUF_SIZE] __attribute__((aligned));
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abi_ulong p;
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int fd;
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int e_uid, e_gid;
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int argc, envc;
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char **argv;
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char **envp;
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char * filename; /* Name of binary */
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int (*core_dump)(int, const CPUArchState *); /* coredump routine */
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};
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void do_init_thread(struct target_pt_regs *regs, struct image_info *infop);
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abi_ulong loader_build_argptr(int envc, int argc, abi_ulong sp,
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abi_ulong stringp, int push_ptr);
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int loader_exec(int fdexec, const char *filename, char **argv, char **envp,
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struct target_pt_regs * regs, struct image_info *infop,
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struct linux_binprm *);
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int load_elf_binary(struct linux_binprm *bprm, struct image_info *info);
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int load_flt_binary(struct linux_binprm *bprm, struct image_info *info);
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abi_long memcpy_to_target(abi_ulong dest, const void *src,
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unsigned long len);
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void target_set_brk(abi_ulong new_brk);
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abi_long do_brk(abi_ulong new_brk);
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void syscall_init(void);
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abi_long do_syscall(void *cpu_env, int num, abi_long arg1,
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abi_long arg2, abi_long arg3, abi_long arg4,
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abi_long arg5, abi_long arg6, abi_long arg7,
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abi_long arg8);
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void gemu_log(const char *fmt, ...) GCC_FMT_ATTR(1, 2);
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extern THREAD CPUState *thread_cpu;
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void cpu_loop(CPUArchState *env);
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const char *target_strerror(int err);
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int get_osversion(void);
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void init_qemu_uname_release(void);
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void fork_start(void);
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void fork_end(int child);
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/* Creates the initial guest address space in the host memory space using
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* the given host start address hint and size. The guest_start parameter
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* specifies the start address of the guest space. guest_base will be the
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* difference between the host start address computed by this function and
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* guest_start. If fixed is specified, then the mapped address space must
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* start at host_start. The real start address of the mapped memory space is
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* returned or -1 if there was an error.
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*/
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unsigned long init_guest_space(unsigned long host_start,
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unsigned long host_size,
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unsigned long guest_start,
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bool fixed);
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#include "qemu/log.h"
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/* safe_syscall.S */
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/**
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* safe_syscall:
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* @int number: number of system call to make
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* ...: arguments to the system call
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*
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* Call a system call if guest signal not pending.
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* This has the same API as the libc syscall() function, except that it
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* may return -1 with errno == TARGET_ERESTARTSYS if a signal was pending.
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*
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* Returns: the system call result, or -1 with an error code in errno
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* (Errnos are host errnos; we rely on TARGET_ERESTARTSYS not clashing
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* with any of the host errno values.)
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*/
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/* A guide to using safe_syscall() to handle interactions between guest
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* syscalls and guest signals:
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*
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* Guest syscalls come in two flavours:
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*
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* (1) Non-interruptible syscalls
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*
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* These are guest syscalls that never get interrupted by signals and
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* so never return EINTR. They can be implemented straightforwardly in
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* QEMU: just make sure that if the implementation code has to make any
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* blocking calls that those calls are retried if they return EINTR.
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* It's also OK to implement these with safe_syscall, though it will be
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* a little less efficient if a signal is delivered at the 'wrong' moment.
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*
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* Some non-interruptible syscalls need to be handled using block_signals()
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* to block signals for the duration of the syscall. This mainly applies
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* to code which needs to modify the data structures used by the
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* host_signal_handler() function and the functions it calls, including
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* all syscalls which change the thread's signal mask.
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*
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* (2) Interruptible syscalls
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*
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* These are guest syscalls that can be interrupted by signals and
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* for which we need to either return EINTR or arrange for the guest
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* syscall to be restarted. This category includes both syscalls which
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* always restart (and in the kernel return -ERESTARTNOINTR), ones
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* which only restart if there is no handler (kernel returns -ERESTARTNOHAND
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* or -ERESTART_RESTARTBLOCK), and the most common kind which restart
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* if the handler was registered with SA_RESTART (kernel returns
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* -ERESTARTSYS). System calls which are only interruptible in some
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* situations (like 'open') also need to be handled this way.
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*
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* Here it is important that the host syscall is made
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* via this safe_syscall() function, and *not* via the host libc.
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* If the host libc is used then the implementation will appear to work
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* most of the time, but there will be a race condition where a
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* signal could arrive just before we make the host syscall inside libc,
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* and then then guest syscall will not correctly be interrupted.
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* Instead the implementation of the guest syscall can use the safe_syscall
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* function but otherwise just return the result or errno in the usual
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* way; the main loop code will take care of restarting the syscall
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* if appropriate.
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*
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* (If the implementation needs to make multiple host syscalls this is
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* OK; any which might really block must be via safe_syscall(); for those
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* which are only technically blocking (ie which we know in practice won't
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* stay in the host kernel indefinitely) it's OK to use libc if necessary.
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* You must be able to cope with backing out correctly if some safe_syscall
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* you make in the implementation returns either -TARGET_ERESTARTSYS or
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* EINTR though.)
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*
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* block_signals() cannot be used for interruptible syscalls.
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*
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*
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* How and why the safe_syscall implementation works:
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*
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* The basic setup is that we make the host syscall via a known
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* section of host native assembly. If a signal occurs, our signal
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* handler checks the interrupted host PC against the addresse of that
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* known section. If the PC is before or at the address of the syscall
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* instruction then we change the PC to point at a "return
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* -TARGET_ERESTARTSYS" code path instead, and then exit the signal handler
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* (causing the safe_syscall() call to immediately return that value).
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* Then in the main.c loop if we see this magic return value we adjust
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* the guest PC to wind it back to before the system call, and invoke
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* the guest signal handler as usual.
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*
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* This winding-back will happen in two cases:
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* (1) signal came in just before we took the host syscall (a race);
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* in this case we'll take the guest signal and have another go
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* at the syscall afterwards, and this is indistinguishable for the
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* guest from the timing having been different such that the guest
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* signal really did win the race
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* (2) signal came in while the host syscall was blocking, and the
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* host kernel decided the syscall should be restarted;
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* in this case we want to restart the guest syscall also, and so
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* rewinding is the right thing. (Note that "restart" semantics mean
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* "first call the signal handler, then reattempt the syscall".)
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* The other situation to consider is when a signal came in while the
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* host syscall was blocking, and the host kernel decided that the syscall
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* should not be restarted; in this case QEMU's host signal handler will
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* be invoked with the PC pointing just after the syscall instruction,
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* with registers indicating an EINTR return; the special code in the
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* handler will not kick in, and we will return EINTR to the guest as
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* we should.
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*
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* Notice that we can leave the host kernel to make the decision for
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* us about whether to do a restart of the syscall or not; we do not
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* need to check SA_RESTART flags in QEMU or distinguish the various
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* kinds of restartability.
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*/
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#ifdef HAVE_SAFE_SYSCALL
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/* The core part of this function is implemented in assembly */
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extern long safe_syscall_base(int *pending, long number, ...);
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#define safe_syscall(...) \
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({ \
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long ret_; \
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int *psp_ = &((TaskState *)thread_cpu->opaque)->signal_pending; \
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ret_ = safe_syscall_base(psp_, __VA_ARGS__); \
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if (is_error(ret_)) { \
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errno = -ret_; \
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ret_ = -1; \
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} \
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ret_; \
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})
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#else
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/* Fallback for architectures which don't yet provide a safe-syscall assembly
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* fragment; note that this is racy!
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* This should go away when all host architectures have been updated.
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*/
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#define safe_syscall syscall
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#endif
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/* syscall.c */
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int host_to_target_waitstatus(int status);
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/* strace.c */
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void print_syscall(int num,
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abi_long arg1, abi_long arg2, abi_long arg3,
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abi_long arg4, abi_long arg5, abi_long arg6);
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void print_syscall_ret(int num, abi_long arg1);
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extern int do_strace;
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/* signal.c */
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void process_pending_signals(CPUArchState *cpu_env);
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void signal_init(void);
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int queue_signal(CPUArchState *env, int sig, target_siginfo_t *info);
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void host_to_target_siginfo(target_siginfo_t *tinfo, const siginfo_t *info);
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void target_to_host_siginfo(siginfo_t *info, const target_siginfo_t *tinfo);
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int target_to_host_signal(int sig);
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int host_to_target_signal(int sig);
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long do_sigreturn(CPUArchState *env);
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long do_rt_sigreturn(CPUArchState *env);
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abi_long do_sigaltstack(abi_ulong uss_addr, abi_ulong uoss_addr, abi_ulong sp);
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int do_sigprocmask(int how, const sigset_t *set, sigset_t *oldset);
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/**
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* block_signals: block all signals while handling this guest syscall
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*
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* Block all signals, and arrange that the signal mask is returned to
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* its correct value for the guest before we resume execution of guest code.
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* If this function returns non-zero, then the caller should immediately
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* return -TARGET_ERESTARTSYS to the main loop, which will take the pending
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* signal and restart execution of the syscall.
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* If block_signals() returns zero, then the caller can continue with
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* emulation of the system call knowing that no signals can be taken
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* (and therefore that no race conditions will result).
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* This should only be called once, because if it is called a second time
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* it will always return non-zero. (Think of it like a mutex that can't
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* be recursively locked.)
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* Signals will be unblocked again by process_pending_signals().
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*
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* Return value: non-zero if there was a pending signal, zero if not.
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*/
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int block_signals(void); /* Returns non zero if signal pending */
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#ifdef TARGET_I386
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/* vm86.c */
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void save_v86_state(CPUX86State *env);
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void handle_vm86_trap(CPUX86State *env, int trapno);
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void handle_vm86_fault(CPUX86State *env);
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int do_vm86(CPUX86State *env, long subfunction, abi_ulong v86_addr);
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#elif defined(TARGET_SPARC64)
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void sparc64_set_context(CPUSPARCState *env);
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void sparc64_get_context(CPUSPARCState *env);
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#endif
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/* mmap.c */
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int target_mprotect(abi_ulong start, abi_ulong len, int prot);
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abi_long target_mmap(abi_ulong start, abi_ulong len, int prot,
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int flags, int fd, abi_ulong offset);
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int target_munmap(abi_ulong start, abi_ulong len);
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abi_long target_mremap(abi_ulong old_addr, abi_ulong old_size,
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abi_ulong new_size, unsigned long flags,
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abi_ulong new_addr);
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int target_msync(abi_ulong start, abi_ulong len, int flags);
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extern unsigned long last_brk;
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extern abi_ulong mmap_next_start;
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abi_ulong mmap_find_vma(abi_ulong, abi_ulong);
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void cpu_list_lock(void);
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void cpu_list_unlock(void);
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void mmap_fork_start(void);
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void mmap_fork_end(int child);
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/* main.c */
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extern unsigned long guest_stack_size;
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/* user access */
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#define VERIFY_READ 0
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#define VERIFY_WRITE 1 /* implies read access */
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static inline int access_ok(int type, abi_ulong addr, abi_ulong size)
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{
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return page_check_range((target_ulong)addr, size,
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(type == VERIFY_READ) ? PAGE_READ : (PAGE_READ | PAGE_WRITE)) == 0;
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}
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/* NOTE __get_user and __put_user use host pointers and don't check access.
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These are usually used to access struct data members once the struct has
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been locked - usually with lock_user_struct. */
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/* Tricky points:
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- Use __builtin_choose_expr to avoid type promotion from ?:,
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- Invalid sizes result in a compile time error stemming from
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the fact that abort has no parameters.
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- It's easier to use the endian-specific unaligned load/store
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functions than host-endian unaligned load/store plus tswapN. */
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#define __put_user_e(x, hptr, e) \
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(__builtin_choose_expr(sizeof(*(hptr)) == 1, stb_p, \
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__builtin_choose_expr(sizeof(*(hptr)) == 2, stw_##e##_p, \
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|
__builtin_choose_expr(sizeof(*(hptr)) == 4, stl_##e##_p, \
|
|
__builtin_choose_expr(sizeof(*(hptr)) == 8, stq_##e##_p, abort)))) \
|
|
((hptr), (x)), (void)0)
|
|
|
|
#define __get_user_e(x, hptr, e) \
|
|
((x) = (typeof(*hptr))( \
|
|
__builtin_choose_expr(sizeof(*(hptr)) == 1, ldub_p, \
|
|
__builtin_choose_expr(sizeof(*(hptr)) == 2, lduw_##e##_p, \
|
|
__builtin_choose_expr(sizeof(*(hptr)) == 4, ldl_##e##_p, \
|
|
__builtin_choose_expr(sizeof(*(hptr)) == 8, ldq_##e##_p, abort)))) \
|
|
(hptr)), (void)0)
|
|
|
|
#ifdef TARGET_WORDS_BIGENDIAN
|
|
# define __put_user(x, hptr) __put_user_e(x, hptr, be)
|
|
# define __get_user(x, hptr) __get_user_e(x, hptr, be)
|
|
#else
|
|
# define __put_user(x, hptr) __put_user_e(x, hptr, le)
|
|
# define __get_user(x, hptr) __get_user_e(x, hptr, le)
|
|
#endif
|
|
|
|
/* put_user()/get_user() take a guest address and check access */
|
|
/* These are usually used to access an atomic data type, such as an int,
|
|
* that has been passed by address. These internally perform locking
|
|
* and unlocking on the data type.
|
|
*/
|
|
#define put_user(x, gaddr, target_type) \
|
|
({ \
|
|
abi_ulong __gaddr = (gaddr); \
|
|
target_type *__hptr; \
|
|
abi_long __ret = 0; \
|
|
if ((__hptr = lock_user(VERIFY_WRITE, __gaddr, sizeof(target_type), 0))) { \
|
|
__put_user((x), __hptr); \
|
|
unlock_user(__hptr, __gaddr, sizeof(target_type)); \
|
|
} else \
|
|
__ret = -TARGET_EFAULT; \
|
|
__ret; \
|
|
})
|
|
|
|
#define get_user(x, gaddr, target_type) \
|
|
({ \
|
|
abi_ulong __gaddr = (gaddr); \
|
|
target_type *__hptr; \
|
|
abi_long __ret = 0; \
|
|
if ((__hptr = lock_user(VERIFY_READ, __gaddr, sizeof(target_type), 1))) { \
|
|
__get_user((x), __hptr); \
|
|
unlock_user(__hptr, __gaddr, 0); \
|
|
} else { \
|
|
/* avoid warning */ \
|
|
(x) = 0; \
|
|
__ret = -TARGET_EFAULT; \
|
|
} \
|
|
__ret; \
|
|
})
|
|
|
|
#define put_user_ual(x, gaddr) put_user((x), (gaddr), abi_ulong)
|
|
#define put_user_sal(x, gaddr) put_user((x), (gaddr), abi_long)
|
|
#define put_user_u64(x, gaddr) put_user((x), (gaddr), uint64_t)
|
|
#define put_user_s64(x, gaddr) put_user((x), (gaddr), int64_t)
|
|
#define put_user_u32(x, gaddr) put_user((x), (gaddr), uint32_t)
|
|
#define put_user_s32(x, gaddr) put_user((x), (gaddr), int32_t)
|
|
#define put_user_u16(x, gaddr) put_user((x), (gaddr), uint16_t)
|
|
#define put_user_s16(x, gaddr) put_user((x), (gaddr), int16_t)
|
|
#define put_user_u8(x, gaddr) put_user((x), (gaddr), uint8_t)
|
|
#define put_user_s8(x, gaddr) put_user((x), (gaddr), int8_t)
|
|
|
|
#define get_user_ual(x, gaddr) get_user((x), (gaddr), abi_ulong)
|
|
#define get_user_sal(x, gaddr) get_user((x), (gaddr), abi_long)
|
|
#define get_user_u64(x, gaddr) get_user((x), (gaddr), uint64_t)
|
|
#define get_user_s64(x, gaddr) get_user((x), (gaddr), int64_t)
|
|
#define get_user_u32(x, gaddr) get_user((x), (gaddr), uint32_t)
|
|
#define get_user_s32(x, gaddr) get_user((x), (gaddr), int32_t)
|
|
#define get_user_u16(x, gaddr) get_user((x), (gaddr), uint16_t)
|
|
#define get_user_s16(x, gaddr) get_user((x), (gaddr), int16_t)
|
|
#define get_user_u8(x, gaddr) get_user((x), (gaddr), uint8_t)
|
|
#define get_user_s8(x, gaddr) get_user((x), (gaddr), int8_t)
|
|
|
|
/* copy_from_user() and copy_to_user() are usually used to copy data
|
|
* buffers between the target and host. These internally perform
|
|
* locking/unlocking of the memory.
|
|
*/
|
|
abi_long copy_from_user(void *hptr, abi_ulong gaddr, size_t len);
|
|
abi_long copy_to_user(abi_ulong gaddr, void *hptr, size_t len);
|
|
|
|
/* Functions for accessing guest memory. The tget and tput functions
|
|
read/write single values, byteswapping as necessary. The lock_user function
|
|
gets a pointer to a contiguous area of guest memory, but does not perform
|
|
any byteswapping. lock_user may return either a pointer to the guest
|
|
memory, or a temporary buffer. */
|
|
|
|
/* Lock an area of guest memory into the host. If copy is true then the
|
|
host area will have the same contents as the guest. */
|
|
static inline void *lock_user(int type, abi_ulong guest_addr, long len, int copy)
|
|
{
|
|
if (!access_ok(type, guest_addr, len))
|
|
return NULL;
|
|
#ifdef DEBUG_REMAP
|
|
{
|
|
void *addr;
|
|
addr = malloc(len);
|
|
if (copy)
|
|
memcpy(addr, g2h(guest_addr), len);
|
|
else
|
|
memset(addr, 0, len);
|
|
return addr;
|
|
}
|
|
#else
|
|
return g2h(guest_addr);
|
|
#endif
|
|
}
|
|
|
|
/* Unlock an area of guest memory. The first LEN bytes must be
|
|
flushed back to guest memory. host_ptr = NULL is explicitly
|
|
allowed and does nothing. */
|
|
static inline void unlock_user(void *host_ptr, abi_ulong guest_addr,
|
|
long len)
|
|
{
|
|
|
|
#ifdef DEBUG_REMAP
|
|
if (!host_ptr)
|
|
return;
|
|
if (host_ptr == g2h(guest_addr))
|
|
return;
|
|
if (len > 0)
|
|
memcpy(g2h(guest_addr), host_ptr, len);
|
|
free(host_ptr);
|
|
#endif
|
|
}
|
|
|
|
/* Return the length of a string in target memory or -TARGET_EFAULT if
|
|
access error. */
|
|
abi_long target_strlen(abi_ulong gaddr);
|
|
|
|
/* Like lock_user but for null terminated strings. */
|
|
static inline void *lock_user_string(abi_ulong guest_addr)
|
|
{
|
|
abi_long len;
|
|
len = target_strlen(guest_addr);
|
|
if (len < 0)
|
|
return NULL;
|
|
return lock_user(VERIFY_READ, guest_addr, (long)(len + 1), 1);
|
|
}
|
|
|
|
/* Helper macros for locking/unlocking a target struct. */
|
|
#define lock_user_struct(type, host_ptr, guest_addr, copy) \
|
|
(host_ptr = lock_user(type, guest_addr, sizeof(*host_ptr), copy))
|
|
#define unlock_user_struct(host_ptr, guest_addr, copy) \
|
|
unlock_user(host_ptr, guest_addr, (copy) ? sizeof(*host_ptr) : 0)
|
|
|
|
#include <pthread.h>
|
|
|
|
/* Include target-specific struct and function definitions;
|
|
* they may need access to the target-independent structures
|
|
* above, so include them last.
|
|
*/
|
|
#include "target_cpu.h"
|
|
#include "target_signal.h"
|
|
#include "target_structs.h"
|
|
|
|
#endif /* QEMU_H */
|