//! The fault module contains the implementation for handling breakpoints, traps, and signals
//! for wasm code.

pub mod raw {
    //! The raw module contains required externed function interfaces for the fault module.
    use std::ffi::c_void;

    #[cfg(target_arch = "x86_64")]
    extern "C" {
        /// Load registers and return on the stack [stack_end..stack_begin].
        pub fn run_on_alternative_stack(stack_end: *mut u64, stack_begin: *mut u64) -> u64;
        /// Internal routine for switching into a backend without information about where registers are preserved.
        pub fn register_preservation_trampoline(); // NOT safe to call directly
    }

    /// Internal routine for switching into a backend without information about where registers are preserved.
    #[cfg(not(target_arch = "x86_64"))]
    pub extern "C" fn register_preservation_trampoline() {
        unimplemented!("register_preservation_trampoline");
    }

    extern "C" {
        /// libc setjmp
        pub fn setjmp(env: *mut c_void) -> i32;
        /// libc longjmp
        pub fn longjmp(env: *mut c_void, val: i32) -> !;
    }
}

use crate::codegen::{BreakpointInfo, BreakpointMap};
use crate::error::{InvokeError, RuntimeError};
use crate::state::x64::{build_instance_image, read_stack, X64Register, GPR};
use crate::state::{CodeVersion, ExecutionStateImage};
use crate::vm;
use libc::{mmap, mprotect, siginfo_t, MAP_ANON, MAP_PRIVATE, PROT_NONE, PROT_READ, PROT_WRITE};
use nix::sys::signal::{
    sigaction, SaFlags, SigAction, SigHandler, SigSet, Signal, SIGBUS, SIGFPE, SIGILL, SIGINT,
    SIGSEGV, SIGTRAP,
};
use std::cell::{Cell, RefCell, UnsafeCell};
use std::ffi::c_void;
use std::process;
use std::sync::atomic::{AtomicBool, Ordering};
use std::sync::Once;

#[cfg(target_arch = "x86_64")]
pub(crate) unsafe fn run_on_alternative_stack(stack_end: *mut u64, stack_begin: *mut u64) -> u64 {
    raw::run_on_alternative_stack(stack_end, stack_begin)
}

#[cfg(not(target_arch = "x86_64"))]
pub(crate) unsafe fn run_on_alternative_stack(_stack_end: *mut u64, _stack_begin: *mut u64) -> u64 {
    unimplemented!("run_on_alternative_stack");
}

const TRAP_STACK_SIZE: usize = 1048576; // 1MB

const SETJMP_BUFFER_LEN: usize = 128;
type SetJmpBuffer = [i32; SETJMP_BUFFER_LEN];

struct UnwindInfo {
    jmpbuf: SetJmpBuffer, // in
    breakpoints: Option<BreakpointMap>,
    payload: Option<Box<RuntimeError>>, // out
}

/// A store for boundary register preservation.
#[repr(packed)]
#[derive(Default, Copy, Clone)]
pub struct BoundaryRegisterPreservation {
    /// R15.
    pub r15: u64,
    /// R14.
    pub r14: u64,
    /// R13.
    pub r13: u64,
    /// R12.
    pub r12: u64,
    /// RBX.
    pub rbx: u64,
}

thread_local! {
    static UNWIND: UnsafeCell<Option<UnwindInfo>> = UnsafeCell::new(None);
    static CURRENT_CTX: UnsafeCell<*mut vm::Ctx> = UnsafeCell::new(::std::ptr::null_mut());
    static CURRENT_CODE_VERSIONS: RefCell<Vec<CodeVersion>> = RefCell::new(vec![]);
    static WAS_SIGINT_TRIGGERED: Cell<bool> = Cell::new(false);
    static BOUNDARY_REGISTER_PRESERVATION: UnsafeCell<BoundaryRegisterPreservation> = UnsafeCell::new(BoundaryRegisterPreservation::default());
}

/// Gets a mutable pointer to the `BoundaryRegisterPreservation`.
#[no_mangle]
pub unsafe extern "C" fn get_boundary_register_preservation() -> *mut BoundaryRegisterPreservation {
    BOUNDARY_REGISTER_PRESERVATION.with(|x| x.get())
}

struct InterruptSignalMem(*mut u8);
unsafe impl Send for InterruptSignalMem {}
unsafe impl Sync for InterruptSignalMem {}

const INTERRUPT_SIGNAL_MEM_SIZE: usize = 4096;

lazy_static! {
    static ref INTERRUPT_SIGNAL_MEM: InterruptSignalMem = {
        let ptr = unsafe {
            mmap(
                ::std::ptr::null_mut(),
                INTERRUPT_SIGNAL_MEM_SIZE,
                PROT_READ | PROT_WRITE,
                MAP_PRIVATE | MAP_ANON,
                -1,
                0,
            )
        };
        if ptr as isize == -1 {
            panic!("cannot allocate code memory");
        }
        InterruptSignalMem(ptr as _)
    };
}
static INTERRUPT_SIGNAL_DELIVERED: AtomicBool = AtomicBool::new(false);

/// Returns a boolean indicating if SIGINT triggered the fault.
pub fn was_sigint_triggered_fault() -> bool {
    WAS_SIGINT_TRIGGERED.with(|x| x.get())
}

/// Runs a callback function with the given `Ctx`.
pub unsafe fn with_ctx<R, F: FnOnce() -> R>(ctx: *mut vm::Ctx, cb: F) -> R {
    let addr = CURRENT_CTX.with(|x| x.get());
    let old = *addr;
    *addr = ctx;
    let ret = cb();
    *addr = old;
    ret
}

/// Pushes a new `CodeVersion` to the current code versions.
pub fn push_code_version(version: CodeVersion) {
    CURRENT_CODE_VERSIONS.with(|x| x.borrow_mut().push(version));
}

/// Pops a `CodeVersion` from the current code versions.
pub fn pop_code_version() -> Option<CodeVersion> {
    CURRENT_CODE_VERSIONS.with(|x| x.borrow_mut().pop())
}

/// Gets the wasm interrupt signal mem.
pub unsafe fn get_wasm_interrupt_signal_mem() -> *mut u8 {
    INTERRUPT_SIGNAL_MEM.0
}

/// Sets the wasm interrupt on the given `Ctx`.
pub unsafe fn set_wasm_interrupt_on_ctx(ctx: *mut vm::Ctx) {
    if mprotect(
        (&*ctx).internal.interrupt_signal_mem as _,
        INTERRUPT_SIGNAL_MEM_SIZE,
        PROT_NONE,
    ) < 0
    {
        panic!("cannot set PROT_NONE on signal mem");
    }
}

/// Sets a wasm interrupt.
pub unsafe fn set_wasm_interrupt() {
    let mem: *mut u8 = INTERRUPT_SIGNAL_MEM.0;
    if mprotect(mem as _, INTERRUPT_SIGNAL_MEM_SIZE, PROT_NONE) < 0 {
        panic!("cannot set PROT_NONE on signal mem");
    }
}

/// Clears the wasm interrupt.
pub unsafe fn clear_wasm_interrupt() {
    let mem: *mut u8 = INTERRUPT_SIGNAL_MEM.0;
    if mprotect(mem as _, INTERRUPT_SIGNAL_MEM_SIZE, PROT_READ | PROT_WRITE) < 0 {
        panic!("cannot set PROT_READ | PROT_WRITE on signal mem");
    }
}

/// Catches an unsafe unwind with the given functions and breakpoints.
pub unsafe fn catch_unsafe_unwind<R, F: FnOnce() -> R>(
    f: F,
    breakpoints: Option<BreakpointMap>,
) -> Result<R, RuntimeError> {
    let unwind = UNWIND.with(|x| x.get());
    let old = (*unwind).take();
    *unwind = Some(UnwindInfo {
        jmpbuf: [0; SETJMP_BUFFER_LEN],
        breakpoints: breakpoints,
        payload: None,
    });

    if raw::setjmp(&mut (*unwind).as_mut().unwrap().jmpbuf as *mut SetJmpBuffer as *mut _) != 0 {
        // error
        let ret = (*unwind).as_mut().unwrap().payload.take().unwrap();
        *unwind = old;
        Err(*ret)
    } else {
        let ret = f();
        // implicit control flow to the error case...
        *unwind = old;
        Ok(ret)
    }
}

/// Begins an unsafe unwind.
pub unsafe fn begin_unsafe_unwind(e: Box<RuntimeError>) -> ! {
    let unwind = UNWIND.with(|x| x.get());
    let inner = (*unwind)
        .as_mut()
        .expect("not within a catch_unsafe_unwind scope");
    inner.payload = Some(e);
    raw::longjmp(&mut inner.jmpbuf as *mut SetJmpBuffer as *mut _, 0xffff);
}

unsafe fn with_breakpoint_map<R, F: FnOnce(Option<&BreakpointMap>) -> R>(f: F) -> R {
    let unwind = UNWIND.with(|x| x.get());
    let inner = (*unwind)
        .as_mut()
        .expect("not within a catch_unsafe_unwind scope");
    f(inner.breakpoints.as_ref())
}

#[cfg(not(target_arch = "x86_64"))]
/// Allocates and runs with the given stack size and closure.
pub fn allocate_and_run<R, F: FnOnce() -> R>(_size: usize, f: F) -> R {
    f()
}

#[cfg(target_arch = "x86_64")]
/// Allocates and runs with the given stack size and closure.
pub fn allocate_and_run<R, F: FnOnce() -> R>(size: usize, f: F) -> R {
    struct Context<F: FnOnce() -> R, R> {
        f: Option<F>,
        ret: Option<R>,
    }

    extern "C" fn invoke<F: FnOnce() -> R, R>(ctx: &mut Context<F, R>) {
        let f = ctx.f.take().unwrap();
        ctx.ret = Some(f());
    }

    unsafe {
        let mut ctx = Context {
            f: Some(f),
            ret: None,
        };
        assert!(size % 16 == 0);
        assert!(size >= 4096);

        let mut stack: Vec<u64> = vec![0; size / 8];
        let end_offset = stack.len();

        stack[end_offset - 4] = invoke::<F, R> as usize as u64;

        // NOTE: Keep this consistent with `image-loading-*.s`.
        stack[end_offset - 4 - 10] = &mut ctx as *mut Context<F, R> as usize as u64; // rdi
        const NUM_SAVED_REGISTERS: usize = 31;
        let stack_begin = stack.as_mut_ptr().add(end_offset - 4 - NUM_SAVED_REGISTERS);
        let stack_end = stack.as_mut_ptr().add(end_offset);

        raw::run_on_alternative_stack(stack_end, stack_begin);
        ctx.ret.take().unwrap()
    }
}

extern "C" fn signal_trap_handler(
    signum: ::nix::libc::c_int,
    siginfo: *mut siginfo_t,
    ucontext: *mut c_void,
) {
    use crate::backend::{Architecture, InlineBreakpointType};

    #[cfg(target_arch = "x86_64")]
    static ARCH: Architecture = Architecture::X64;

    #[cfg(target_arch = "aarch64")]
    static ARCH: Architecture = Architecture::Aarch64;

    let mut should_unwind = false;
    let mut unwind_result: Option<Box<RuntimeError>> = None;
    let get_unwind_result = |uw_result: Option<Box<RuntimeError>>| -> Box<RuntimeError> {
        uw_result
            .unwrap_or_else(|| Box::new(RuntimeError::InvokeError(InvokeError::FailedWithNoError)))
    };

    unsafe {
        let fault = get_fault_info(siginfo as _, ucontext);
        let early_return = allocate_and_run(TRAP_STACK_SIZE, || {
            CURRENT_CODE_VERSIONS.with(|versions| {
                let versions = versions.borrow();
                for v in versions.iter() {
                    let magic_size =
                        if let Some(x) = v.runnable_module.get_inline_breakpoint_size(ARCH) {
                            x
                        } else {
                            continue;
                        };
                    let ip = fault.ip.get();
                    let end = v.base + v.msm.total_size;
                    if ip >= v.base && ip < end && ip + magic_size <= end {
                        if let Some(ib) = v.runnable_module.read_inline_breakpoint(
                            ARCH,
                            std::slice::from_raw_parts(ip as *const u8, magic_size),
                        ) {
                            match ib.ty {
                                InlineBreakpointType::Middleware => {
                                    let out: Option<Result<(), RuntimeError>> =
                                        with_breakpoint_map(|bkpt_map| {
                                            bkpt_map.and_then(|x| x.get(&ip)).map(|x| {
                                                x(BreakpointInfo {
                                                    fault: Some(&fault),
                                                })
                                            })
                                        });
                                    if let Some(Ok(())) = out {
                                    } else if let Some(Err(e)) = out {
                                        should_unwind = true;
                                        unwind_result = Some(Box::new(e));
                                    }
                                }
                            }

                            fault.ip.set(ip + magic_size);
                            return true;
                        }
                        break;
                    }
                }
                false
            })
        });
        if should_unwind {
            begin_unsafe_unwind(get_unwind_result(unwind_result));
        }
        if early_return {
            return;
        }

        should_unwind = allocate_and_run(TRAP_STACK_SIZE, || {
            let mut is_suspend_signal = false;

            WAS_SIGINT_TRIGGERED.with(|x| x.set(false));

            match Signal::from_c_int(signum) {
                Ok(SIGTRAP) => {
                    // breakpoint
                    let out: Option<Result<(), RuntimeError>> =
                        with_breakpoint_map(|bkpt_map| -> Option<Result<(), RuntimeError>> {
                            bkpt_map.and_then(|x| x.get(&(fault.ip.get()))).map(
                                |x| -> Result<(), RuntimeError> {
                                    x(BreakpointInfo {
                                        fault: Some(&fault),
                                    })
                                },
                            )
                        });
                    match out {
                        Some(Ok(())) => {
                            return false;
                        }
                        Some(Err(e)) => {
                            unwind_result = Some(Box::new(e));
                            return true;
                        }
                        None => {}
                    }
                }
                Ok(SIGSEGV) | Ok(SIGBUS) => {
                    if fault.faulting_addr as usize == get_wasm_interrupt_signal_mem() as usize {
                        is_suspend_signal = true;
                        clear_wasm_interrupt();
                        if INTERRUPT_SIGNAL_DELIVERED.swap(false, Ordering::SeqCst) {
                            WAS_SIGINT_TRIGGERED.with(|x| x.set(true));
                        }
                    }
                }
                _ => {}
            }

            // Now we have looked up all possible handler tables but failed to find a handler
            // for this exception that allows a normal return.
            //
            // So here we check whether this exception is caused by a suspend signal, return the
            // state image if so, or throw the exception out otherwise.

            let ctx: &mut vm::Ctx = &mut **CURRENT_CTX.with(|x| x.get());
            let es_image = fault
                .read_stack(None)
                .expect("fault.read_stack() failed. Broken invariants?");

            if is_suspend_signal {
                // If this is a suspend signal, we parse the runtime state and return the resulting image.
                let image = build_instance_image(ctx, es_image);
                unwind_result = Some(Box::new(RuntimeError::InstanceImage(Box::new(image))));
            } else {
                // Otherwise, this is a real exception and we just throw it to the caller.
                if !es_image.frames.is_empty() {
                    eprintln!(
                        "\n{}",
                        "Wasmer encountered an error while running your WebAssembly program."
                    );
                    es_image.print_backtrace_if_needed();
                }

                // Look up the exception tables and try to find an exception code.
                let exc_code = CURRENT_CODE_VERSIONS.with(|versions| {
                    let versions = versions.borrow();
                    for v in versions.iter() {
                        if let Some(table) = v.runnable_module.get_exception_table() {
                            let ip = fault.ip.get();
                            let end = v.base + v.msm.total_size;
                            if ip >= v.base && ip < end {
                                if let Some(exc_code) = table.offset_to_code.get(&(ip - v.base)) {
                                    return Some(*exc_code);
                                }
                            }
                        }
                    }
                    None
                });
                if let Some(code) = exc_code {
                    unwind_result =
                        Some(Box::new(RuntimeError::InvokeError(InvokeError::TrapCode {
                            code,
                            // TODO:
                            srcloc: 0,
                        })));
                }
            }

            true
        });

        if should_unwind {
            begin_unsafe_unwind(get_unwind_result(unwind_result));
        }
    }
}

extern "C" fn sigint_handler(
    _signum: ::nix::libc::c_int,
    _siginfo: *mut siginfo_t,
    _ucontext: *mut c_void,
) {
    if INTERRUPT_SIGNAL_DELIVERED.swap(true, Ordering::SeqCst) {
        eprintln!("Got another SIGINT before trap is triggered on WebAssembly side, aborting");
        process::abort();
    }
    unsafe {
        set_wasm_interrupt();
    }
}

/// Ensure the signal handler is installed.
pub fn ensure_sighandler() {
    INSTALL_SIGHANDLER.call_once(|| unsafe {
        install_sighandler();
    });
}

static INSTALL_SIGHANDLER: Once = Once::new();

unsafe fn install_sighandler() {
    let sa_trap = SigAction::new(
        SigHandler::SigAction(signal_trap_handler),
        SaFlags::SA_ONSTACK,
        SigSet::empty(),
    );
    sigaction(SIGFPE, &sa_trap).unwrap();
    sigaction(SIGILL, &sa_trap).unwrap();
    sigaction(SIGSEGV, &sa_trap).unwrap();
    sigaction(SIGBUS, &sa_trap).unwrap();
    sigaction(SIGTRAP, &sa_trap).unwrap();

    let sa_interrupt = SigAction::new(
        SigHandler::SigAction(sigint_handler),
        SaFlags::SA_ONSTACK,
        SigSet::empty(),
    );
    sigaction(SIGINT, &sa_interrupt).unwrap();
}

#[derive(Debug, Clone)]
/// Info about the fault
pub struct FaultInfo {
    /// Faulting address.
    pub faulting_addr: *const c_void,
    /// Instruction pointer.
    pub ip: &'static Cell<usize>,
    /// Values of known registers.
    pub known_registers: [Option<u64>; 32],
}

impl FaultInfo {
    /// Parses the stack and builds an execution state image.
    pub unsafe fn read_stack(&self, max_depth: Option<usize>) -> Option<ExecutionStateImage> {
        let rsp = self.known_registers[X64Register::GPR(GPR::RSP).to_index().0]?;

        Some(CURRENT_CODE_VERSIONS.with(|versions| {
            let versions = versions.borrow();
            read_stack(
                || versions.iter(),
                rsp as usize as *const u64,
                self.known_registers,
                Some(self.ip.get() as u64),
                max_depth,
            )
        }))
    }
}

#[cfg(all(target_os = "freebsd", target_arch = "aarch64"))]
/// Get fault info from siginfo and ucontext.
pub unsafe fn get_fault_info(siginfo: *const c_void, ucontext: *mut c_void) -> FaultInfo {
    #[repr(C)]
    pub struct ucontext_t {
        uc_sigmask: libc::sigset_t,
        uc_mcontext: mcontext_t,
        uc_link: *mut ucontext_t,
        uc_stack: libc::stack_t,
        uc_flags: i32,
        __spare__: [i32; 4],
    }
    #[repr(C)]
    pub struct gpregs {
        gp_x: [u64; 30],
        gp_lr: u64,
        gp_sp: u64,
        gp_elr: u64,
        gp_spsr: u64,
        gp_pad: i32,
    };
    #[repr(C)]
    pub struct fpregs {
        fp_q: [u128; 32],
        fp_sr: u32,
        fp_cr: u32,
        fp_flags: i32,
        fp_pad: i32,
    };
    #[repr(C)]
    pub struct mcontext_t {
        mc_gpregs: gpregs,
        mc_fpregs: fpregs,
        mc_flags: i32,
        mc_pad: i32,
        mc_spare: [u64; 8],
    }

    let siginfo = siginfo as *const siginfo_t;
    let si_addr = (*siginfo).si_addr;

    let ucontext = ucontext as *mut ucontext_t;
    let gregs = &(*ucontext).uc_mcontext.mc_gpregs;

    let mut known_registers: [Option<u64>; 32] = [None; 32];

    known_registers[X64Register::GPR(GPR::R15).to_index().0] = Some(gregs.gp_x[15] as _);
    known_registers[X64Register::GPR(GPR::R14).to_index().0] = Some(gregs.gp_x[14] as _);
    known_registers[X64Register::GPR(GPR::R13).to_index().0] = Some(gregs.gp_x[13] as _);
    known_registers[X64Register::GPR(GPR::R12).to_index().0] = Some(gregs.gp_x[12] as _);
    known_registers[X64Register::GPR(GPR::R11).to_index().0] = Some(gregs.gp_x[11] as _);
    known_registers[X64Register::GPR(GPR::R10).to_index().0] = Some(gregs.gp_x[10] as _);
    known_registers[X64Register::GPR(GPR::R9).to_index().0] = Some(gregs.gp_x[9] as _);
    known_registers[X64Register::GPR(GPR::R8).to_index().0] = Some(gregs.gp_x[8] as _);
    known_registers[X64Register::GPR(GPR::RSI).to_index().0] = Some(gregs.gp_x[6] as _);
    known_registers[X64Register::GPR(GPR::RDI).to_index().0] = Some(gregs.gp_x[7] as _);
    known_registers[X64Register::GPR(GPR::RDX).to_index().0] = Some(gregs.gp_x[2] as _);
    known_registers[X64Register::GPR(GPR::RCX).to_index().0] = Some(gregs.gp_x[1] as _);
    known_registers[X64Register::GPR(GPR::RBX).to_index().0] = Some(gregs.gp_x[3] as _);
    known_registers[X64Register::GPR(GPR::RAX).to_index().0] = Some(gregs.gp_x[0] as _);

    known_registers[X64Register::GPR(GPR::RBP).to_index().0] = Some(gregs.gp_x[5] as _);
    known_registers[X64Register::GPR(GPR::RSP).to_index().0] = Some(gregs.gp_x[28] as _);

    FaultInfo {
        faulting_addr: si_addr as usize as _,
        ip: std::mem::transmute::<&mut u64, &'static Cell<usize>>(
            &mut (*ucontext).uc_mcontext.mc_gpregs.gp_elr,
        ),
        known_registers,
    }
}

#[cfg(all(target_os = "freebsd", target_arch = "x86_64"))]
/// Get fault info from siginfo and ucontext.
pub unsafe fn get_fault_info(siginfo: *const c_void, ucontext: *mut c_void) -> FaultInfo {
    use crate::state::x64::XMM;
    #[repr(C)]
    pub struct ucontext_t {
        uc_sigmask: libc::sigset_t,
        uc_mcontext: mcontext_t,
        uc_link: *mut ucontext_t,
        uc_stack: libc::stack_t,
        uc_flags: i32,
        __spare__: [i32; 4],
    }
    #[repr(C)]
    pub struct mcontext_t {
        mc_onstack: u64,
        mc_rdi: u64,
        mc_rsi: u64,
        mc_rdx: u64,
        mc_rcx: u64,
        mc_r8: u64,
        mc_r9: u64,
        mc_rax: u64,
        mc_rbx: u64,
        mc_rbp: u64,
        mc_r10: u64,
        mc_r11: u64,
        mc_r12: u64,
        mc_r13: u64,
        mc_r14: u64,
        mc_r15: u64,
        mc_trapno: u32,
        mc_fs: u16,
        mc_gs: u16,
        mc_addr: u64,
        mc_flags: u32,
        mc_es: u16,
        mc_ds: u16,
        mc_err: u64,
        mc_rip: u64,
        mc_cs: u64,
        mc_rflags: u64,
        mc_rsp: u64,
        mc_ss: u64,
        mc_len: i64,

        mc_fpformat: i64,
        mc_ownedfp: i64,
        mc_savefpu: *const savefpu,
        mc_fpstate: [i64; 63], // mc_fpstate[0] is a pointer to savefpu

        mc_fsbase: u64,
        mc_gsbase: u64,

        mc_xfpustate: u64,
        mc_xfpustate_len: u64,

        mc_spare: [i64; 4],
    }
    #[repr(C)]
    pub struct xmmacc {
        element: [u32; 4],
    }
    #[repr(C)]
    pub struct __envxmm64 {
        en_cw: u16,
        en_sw: u16,
        en_tw: u8,
        en_zero: u8,
        en_opcode: u16,
        en_rip: u64,
        en_rdp: u64,
        en_mxcsr: u32,
        en_mxcsr_mask: u32,
    }
    #[repr(C)]
    pub struct fpacc87 {
        fp_bytes: [u8; 10],
    }
    #[repr(C)]
    pub struct sv_fp {
        fp_acc: fpacc87,
        fp_pad: [u8; 6],
    }
    #[repr(C, align(16))]
    pub struct savefpu {
        sv_env: __envxmm64,
        sv_fp_t: [sv_fp; 8],
        sv_xmm: [xmmacc; 16],
        sv_pad: [u8; 96],
    }

    let siginfo = siginfo as *const siginfo_t;
    let si_addr = (*siginfo).si_addr;

    let ucontext = ucontext as *mut ucontext_t;
    let gregs = &mut (*ucontext).uc_mcontext;

    fn read_xmm(reg: &xmmacc) -> u64 {
        (reg.element[0] as u64) | ((reg.element[1] as u64) << 32)
    }

    let mut known_registers: [Option<u64>; 32] = [None; 32];
    known_registers[X64Register::GPR(GPR::R15).to_index().0] = Some(gregs.mc_r15);
    known_registers[X64Register::GPR(GPR::R14).to_index().0] = Some(gregs.mc_r14);
    known_registers[X64Register::GPR(GPR::R13).to_index().0] = Some(gregs.mc_r13);
    known_registers[X64Register::GPR(GPR::R12).to_index().0] = Some(gregs.mc_r12);
    known_registers[X64Register::GPR(GPR::R11).to_index().0] = Some(gregs.mc_r11);
    known_registers[X64Register::GPR(GPR::R10).to_index().0] = Some(gregs.mc_r10);
    known_registers[X64Register::GPR(GPR::R9).to_index().0] = Some(gregs.mc_r9);
    known_registers[X64Register::GPR(GPR::R8).to_index().0] = Some(gregs.mc_r8);
    known_registers[X64Register::GPR(GPR::RSI).to_index().0] = Some(gregs.mc_rsi);
    known_registers[X64Register::GPR(GPR::RDI).to_index().0] = Some(gregs.mc_rdi);
    known_registers[X64Register::GPR(GPR::RDX).to_index().0] = Some(gregs.mc_rdx);
    known_registers[X64Register::GPR(GPR::RCX).to_index().0] = Some(gregs.mc_rcx);
    known_registers[X64Register::GPR(GPR::RBX).to_index().0] = Some(gregs.mc_rbx);
    known_registers[X64Register::GPR(GPR::RAX).to_index().0] = Some(gregs.mc_rax);

    known_registers[X64Register::GPR(GPR::RBP).to_index().0] = Some(gregs.mc_rbp);
    known_registers[X64Register::GPR(GPR::RSP).to_index().0] = Some(gregs.mc_rsp);

    // https://lists.freebsd.org/pipermail/freebsd-arch/2011-December/012077.html
    // https://people.freebsd.org/~kib/misc/defer_sig.c
    const _MC_HASFPXSTATE: u32 = 0x4;
    if (gregs.mc_flags & _MC_HASFPXSTATE) == 0 {
        // XXX mc_fpstate[0] is actually a pointer to a struct savefpu
        let fpregs = &*(*ucontext).uc_mcontext.mc_savefpu;
        known_registers[X64Register::XMM(XMM::XMM0).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[0]));
        known_registers[X64Register::XMM(XMM::XMM1).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[1]));
        known_registers[X64Register::XMM(XMM::XMM2).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[2]));
        known_registers[X64Register::XMM(XMM::XMM3).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[3]));
        known_registers[X64Register::XMM(XMM::XMM4).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[4]));
        known_registers[X64Register::XMM(XMM::XMM5).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[5]));
        known_registers[X64Register::XMM(XMM::XMM6).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[6]));
        known_registers[X64Register::XMM(XMM::XMM7).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[7]));
        known_registers[X64Register::XMM(XMM::XMM8).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[8]));
        known_registers[X64Register::XMM(XMM::XMM9).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[9]));
        known_registers[X64Register::XMM(XMM::XMM10).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[10]));
        known_registers[X64Register::XMM(XMM::XMM11).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[11]));
        known_registers[X64Register::XMM(XMM::XMM12).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[12]));
        known_registers[X64Register::XMM(XMM::XMM13).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[13]));
        known_registers[X64Register::XMM(XMM::XMM14).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[14]));
        known_registers[X64Register::XMM(XMM::XMM15).to_index().0] =
            Some(read_xmm(&fpregs.sv_xmm[15]));
    }

    FaultInfo {
        faulting_addr: si_addr,
        ip: std::mem::transmute::<&mut u64, &'static Cell<usize>>(
            &mut (*ucontext).uc_mcontext.mc_rip,
        ),
        known_registers,
    }
}

#[cfg(all(
    any(target_os = "linux", target_os = "android"),
    target_arch = "aarch64"
))]
/// Get fault info from siginfo and ucontext.
pub unsafe fn get_fault_info(siginfo: *const c_void, ucontext: *mut c_void) -> FaultInfo {
    #[allow(dead_code)]
    #[allow(non_camel_case_types)]
    #[repr(packed)]
    struct sigcontext {
        fault_address: u64,
        regs: [u64; 31],
        sp: u64,
        pc: u64,
        pstate: u64,
        reserved: [u8; 4096],
    }

    #[allow(dead_code)]
    #[allow(non_camel_case_types)]
    #[repr(packed)]
    struct ucontext {
        unknown: [u8; 176],
        uc_mcontext: sigcontext,
    }

    #[allow(dead_code)]
    #[allow(non_camel_case_types)]
    #[repr(C)]
    struct siginfo_t {
        si_signo: i32,
        si_errno: i32,
        si_code: i32,
        si_addr: u64,
        // ...
    }

    let siginfo = siginfo as *const siginfo_t;
    let si_addr = (*siginfo).si_addr;

    let ucontext = ucontext as *mut ucontext;
    let gregs = &(*ucontext).uc_mcontext.regs;

    let mut known_registers: [Option<u64>; 32] = [None; 32];

    known_registers[X64Register::GPR(GPR::R15).to_index().0] = Some(gregs[15] as _);
    known_registers[X64Register::GPR(GPR::R14).to_index().0] = Some(gregs[14] as _);
    known_registers[X64Register::GPR(GPR::R13).to_index().0] = Some(gregs[13] as _);
    known_registers[X64Register::GPR(GPR::R12).to_index().0] = Some(gregs[12] as _);
    known_registers[X64Register::GPR(GPR::R11).to_index().0] = Some(gregs[11] as _);
    known_registers[X64Register::GPR(GPR::R10).to_index().0] = Some(gregs[10] as _);
    known_registers[X64Register::GPR(GPR::R9).to_index().0] = Some(gregs[9] as _);
    known_registers[X64Register::GPR(GPR::R8).to_index().0] = Some(gregs[8] as _);
    known_registers[X64Register::GPR(GPR::RSI).to_index().0] = Some(gregs[6] as _);
    known_registers[X64Register::GPR(GPR::RDI).to_index().0] = Some(gregs[7] as _);
    known_registers[X64Register::GPR(GPR::RDX).to_index().0] = Some(gregs[2] as _);
    known_registers[X64Register::GPR(GPR::RCX).to_index().0] = Some(gregs[1] as _);
    known_registers[X64Register::GPR(GPR::RBX).to_index().0] = Some(gregs[3] as _);
    known_registers[X64Register::GPR(GPR::RAX).to_index().0] = Some(gregs[0] as _);

    known_registers[X64Register::GPR(GPR::RBP).to_index().0] = Some(gregs[5] as _);
    known_registers[X64Register::GPR(GPR::RSP).to_index().0] = Some(gregs[28] as _);

    FaultInfo {
        faulting_addr: si_addr as usize as _,
        ip: std::mem::transmute::<&mut u64, &'static Cell<usize>>(&mut (*ucontext).uc_mcontext.pc),
        known_registers,
    }
}

#[cfg(all(
    any(target_os = "linux", target_os = "android"),
    target_arch = "x86_64"
))]
/// Get fault info from siginfo and ucontext.
pub unsafe fn get_fault_info(siginfo: *const c_void, ucontext: *mut c_void) -> FaultInfo {
    use libc::{
        ucontext_t, REG_R10, REG_R11, REG_R12, REG_R13, REG_R14, REG_R15, REG_R8, REG_R9, REG_RAX,
        REG_RBP, REG_RBX, REG_RCX, REG_RDI, REG_RDX, REG_RIP, REG_RSI, REG_RSP,
    };

    #[cfg(not(target_env = "musl"))]
    fn read_xmm(reg: &libc::_libc_xmmreg) -> u64 {
        (reg.element[0] as u64) | ((reg.element[1] as u64) << 32)
    }

    #[allow(dead_code)]
    #[repr(C)]
    struct siginfo_t {
        si_signo: i32,
        si_errno: i32,
        si_code: i32,
        si_addr: u64,
        // ...
    }

    let siginfo = siginfo as *const siginfo_t;
    let si_addr = (*siginfo).si_addr;

    let ucontext = ucontext as *mut ucontext_t;
    let gregs = &mut (*ucontext).uc_mcontext.gregs;

    let mut known_registers: [Option<u64>; 32] = [None; 32];
    known_registers[X64Register::GPR(GPR::R15).to_index().0] = Some(gregs[REG_R15 as usize] as _);
    known_registers[X64Register::GPR(GPR::R14).to_index().0] = Some(gregs[REG_R14 as usize] as _);
    known_registers[X64Register::GPR(GPR::R13).to_index().0] = Some(gregs[REG_R13 as usize] as _);
    known_registers[X64Register::GPR(GPR::R12).to_index().0] = Some(gregs[REG_R12 as usize] as _);
    known_registers[X64Register::GPR(GPR::R11).to_index().0] = Some(gregs[REG_R11 as usize] as _);
    known_registers[X64Register::GPR(GPR::R10).to_index().0] = Some(gregs[REG_R10 as usize] as _);
    known_registers[X64Register::GPR(GPR::R9).to_index().0] = Some(gregs[REG_R9 as usize] as _);
    known_registers[X64Register::GPR(GPR::R8).to_index().0] = Some(gregs[REG_R8 as usize] as _);
    known_registers[X64Register::GPR(GPR::RSI).to_index().0] = Some(gregs[REG_RSI as usize] as _);
    known_registers[X64Register::GPR(GPR::RDI).to_index().0] = Some(gregs[REG_RDI as usize] as _);
    known_registers[X64Register::GPR(GPR::RDX).to_index().0] = Some(gregs[REG_RDX as usize] as _);
    known_registers[X64Register::GPR(GPR::RCX).to_index().0] = Some(gregs[REG_RCX as usize] as _);
    known_registers[X64Register::GPR(GPR::RBX).to_index().0] = Some(gregs[REG_RBX as usize] as _);
    known_registers[X64Register::GPR(GPR::RAX).to_index().0] = Some(gregs[REG_RAX as usize] as _);

    known_registers[X64Register::GPR(GPR::RBP).to_index().0] = Some(gregs[REG_RBP as usize] as _);
    known_registers[X64Register::GPR(GPR::RSP).to_index().0] = Some(gregs[REG_RSP as usize] as _);

    // Skip reading floating point registers when building with musl libc.
    // FIXME: Depends on https://github.com/rust-lang/libc/pull/1646
    #[cfg(not(target_env = "musl"))]
    {
        use crate::state::x64::XMM;
        if !(*ucontext).uc_mcontext.fpregs.is_null() {
            let fpregs = &*(*ucontext).uc_mcontext.fpregs;
            known_registers[X64Register::XMM(XMM::XMM0).to_index().0] =
                Some(read_xmm(&fpregs._xmm[0]));
            known_registers[X64Register::XMM(XMM::XMM1).to_index().0] =
                Some(read_xmm(&fpregs._xmm[1]));
            known_registers[X64Register::XMM(XMM::XMM2).to_index().0] =
                Some(read_xmm(&fpregs._xmm[2]));
            known_registers[X64Register::XMM(XMM::XMM3).to_index().0] =
                Some(read_xmm(&fpregs._xmm[3]));
            known_registers[X64Register::XMM(XMM::XMM4).to_index().0] =
                Some(read_xmm(&fpregs._xmm[4]));
            known_registers[X64Register::XMM(XMM::XMM5).to_index().0] =
                Some(read_xmm(&fpregs._xmm[5]));
            known_registers[X64Register::XMM(XMM::XMM6).to_index().0] =
                Some(read_xmm(&fpregs._xmm[6]));
            known_registers[X64Register::XMM(XMM::XMM7).to_index().0] =
                Some(read_xmm(&fpregs._xmm[7]));
            known_registers[X64Register::XMM(XMM::XMM8).to_index().0] =
                Some(read_xmm(&fpregs._xmm[8]));
            known_registers[X64Register::XMM(XMM::XMM9).to_index().0] =
                Some(read_xmm(&fpregs._xmm[9]));
            known_registers[X64Register::XMM(XMM::XMM10).to_index().0] =
                Some(read_xmm(&fpregs._xmm[10]));
            known_registers[X64Register::XMM(XMM::XMM11).to_index().0] =
                Some(read_xmm(&fpregs._xmm[11]));
            known_registers[X64Register::XMM(XMM::XMM12).to_index().0] =
                Some(read_xmm(&fpregs._xmm[12]));
            known_registers[X64Register::XMM(XMM::XMM13).to_index().0] =
                Some(read_xmm(&fpregs._xmm[13]));
            known_registers[X64Register::XMM(XMM::XMM14).to_index().0] =
                Some(read_xmm(&fpregs._xmm[14]));
            known_registers[X64Register::XMM(XMM::XMM15).to_index().0] =
                Some(read_xmm(&fpregs._xmm[15]));
        }
    }

    FaultInfo {
        faulting_addr: si_addr as usize as _,
        ip: std::mem::transmute::<&mut i64, &'static Cell<usize>>(&mut gregs[REG_RIP as usize]),
        known_registers,
    }
}

/// Get fault info from siginfo and ucontext.
#[cfg(all(target_os = "macos", target_arch = "x86_64"))]
pub unsafe fn get_fault_info(siginfo: *const c_void, ucontext: *mut c_void) -> FaultInfo {
    use crate::state::x64::XMM;
    #[allow(dead_code)]
    #[repr(C)]
    struct ucontext_t {
        uc_onstack: u32,
        uc_sigmask: u32,
        uc_stack: libc::stack_t,
        uc_link: *const ucontext_t,
        uc_mcsize: u64,
        uc_mcontext: *mut mcontext_t,
    }
    #[repr(C)]
    struct exception_state {
        trapno: u16,
        cpu: u16,
        err: u32,
        faultvaddr: u64,
    }
    #[repr(C)]
    struct regs {
        rax: u64,
        rbx: u64,
        rcx: u64,
        rdx: u64,
        rdi: u64,
        rsi: u64,
        rbp: u64,
        rsp: u64,
        r8: u64,
        r9: u64,
        r10: u64,
        r11: u64,
        r12: u64,
        r13: u64,
        r14: u64,
        r15: u64,
        rip: u64,
        rflags: u64,
        cs: u64,
        fs: u64,
        gs: u64,
    }
    #[repr(C)]
    struct fpstate {
        _cwd: u16,
        _swd: u16,
        _ftw: u16,
        _fop: u16,
        _rip: u64,
        _rdp: u64,
        _mxcsr: u32,
        _mxcr_mask: u32,
        _st: [[u16; 8]; 8],
        xmm: [[u64; 2]; 16],
        _padding: [u32; 24],
    }
    #[allow(dead_code)]
    #[repr(C)]
    struct mcontext_t {
        es: exception_state,
        ss: regs,
        fs: fpstate,
    }

    let siginfo = siginfo as *const siginfo_t;
    let si_addr = (*siginfo).si_addr;

    let ucontext = ucontext as *mut ucontext_t;
    let ss = &mut (*(*ucontext).uc_mcontext).ss;
    let fs = &(*(*ucontext).uc_mcontext).fs;

    let mut known_registers: [Option<u64>; 32] = [None; 32];

    known_registers[X64Register::GPR(GPR::R15).to_index().0] = Some(ss.r15);
    known_registers[X64Register::GPR(GPR::R14).to_index().0] = Some(ss.r14);
    known_registers[X64Register::GPR(GPR::R13).to_index().0] = Some(ss.r13);
    known_registers[X64Register::GPR(GPR::R12).to_index().0] = Some(ss.r12);
    known_registers[X64Register::GPR(GPR::R11).to_index().0] = Some(ss.r11);
    known_registers[X64Register::GPR(GPR::R10).to_index().0] = Some(ss.r10);
    known_registers[X64Register::GPR(GPR::R9).to_index().0] = Some(ss.r9);
    known_registers[X64Register::GPR(GPR::R8).to_index().0] = Some(ss.r8);
    known_registers[X64Register::GPR(GPR::RSI).to_index().0] = Some(ss.rsi);
    known_registers[X64Register::GPR(GPR::RDI).to_index().0] = Some(ss.rdi);
    known_registers[X64Register::GPR(GPR::RDX).to_index().0] = Some(ss.rdx);
    known_registers[X64Register::GPR(GPR::RCX).to_index().0] = Some(ss.rcx);
    known_registers[X64Register::GPR(GPR::RBX).to_index().0] = Some(ss.rbx);
    known_registers[X64Register::GPR(GPR::RAX).to_index().0] = Some(ss.rax);

    known_registers[X64Register::GPR(GPR::RBP).to_index().0] = Some(ss.rbp);
    known_registers[X64Register::GPR(GPR::RSP).to_index().0] = Some(ss.rsp);

    known_registers[X64Register::XMM(XMM::XMM0).to_index().0] = Some(fs.xmm[0][0]);
    known_registers[X64Register::XMM(XMM::XMM1).to_index().0] = Some(fs.xmm[1][0]);
    known_registers[X64Register::XMM(XMM::XMM2).to_index().0] = Some(fs.xmm[2][0]);
    known_registers[X64Register::XMM(XMM::XMM3).to_index().0] = Some(fs.xmm[3][0]);
    known_registers[X64Register::XMM(XMM::XMM4).to_index().0] = Some(fs.xmm[4][0]);
    known_registers[X64Register::XMM(XMM::XMM5).to_index().0] = Some(fs.xmm[5][0]);
    known_registers[X64Register::XMM(XMM::XMM6).to_index().0] = Some(fs.xmm[6][0]);
    known_registers[X64Register::XMM(XMM::XMM7).to_index().0] = Some(fs.xmm[7][0]);
    known_registers[X64Register::XMM(XMM::XMM8).to_index().0] = Some(fs.xmm[8][0]);
    known_registers[X64Register::XMM(XMM::XMM9).to_index().0] = Some(fs.xmm[9][0]);
    known_registers[X64Register::XMM(XMM::XMM10).to_index().0] = Some(fs.xmm[10][0]);
    known_registers[X64Register::XMM(XMM::XMM11).to_index().0] = Some(fs.xmm[11][0]);
    known_registers[X64Register::XMM(XMM::XMM12).to_index().0] = Some(fs.xmm[12][0]);
    known_registers[X64Register::XMM(XMM::XMM13).to_index().0] = Some(fs.xmm[13][0]);
    known_registers[X64Register::XMM(XMM::XMM14).to_index().0] = Some(fs.xmm[14][0]);
    known_registers[X64Register::XMM(XMM::XMM15).to_index().0] = Some(fs.xmm[15][0]);

    FaultInfo {
        faulting_addr: si_addr,
        ip: std::mem::transmute::<&mut u64, &'static Cell<usize>>(&mut ss.rip),
        known_registers,
    }
}