zig.h

#undef linux

#ifndef __STDC_WANT_IEC_60559_TYPES_EXT__
#define __STDC_WANT_IEC_60559_TYPES_EXT__
#endif
#include <float.h>
#include <limits.h>
#include <stdarg.h>
#include <stddef.h>
#include <stdint.h>

#if _MSC_VER
#include <intrin.h>
#elif defined(__i386__) || defined(__x86_64__)
#include <cpuid.h>
#endif

#if !defined(__cplusplus) && __STDC_VERSION__ <= 201710L
#if __STDC_VERSION__ >= 199901L
#include <stdbool.h>
#else
typedef char bool;
#define false 0
#define true  1
#endif
#endif

#if defined(__has_builtin)
#define zig_has_builtin(builtin) __has_builtin(__builtin_##builtin)
#else
#define zig_has_builtin(builtin) 0
#endif

#if defined(__has_attribute)
#define zig_has_attribute(attribute) __has_attribute(attribute)
#else
#define zig_has_attribute(attribute) 0
#endif

#if __LITTLE_ENDIAN__ || _MSC_VER
#define zig_little_endian 1
#define zig_big_endian 0
#else
#define zig_little_endian 0
#define zig_big_endian 1
#endif

#if __STDC_VERSION__ >= 201112L
#define zig_threadlocal _Thread_local
#elif defined(__GNUC__)
#define zig_threadlocal __thread
#elif _MSC_VER
#define zig_threadlocal __declspec(thread)
#else
#define zig_threadlocal zig_threadlocal_unavailable
#endif

#if defined(__clang__)
#define zig_clang
#elif defined(__GNUC__)
#define zig_gnuc
#endif

#if _MSC_VER
#define zig_const_arr
#define zig_callconv(c) __##c
#else
#define zig_const_arr static const
#define zig_callconv(c) __attribute__((c))
#endif

#if zig_has_attribute(naked) || defined(zig_gnuc)
#define zig_naked_decl __attribute__((naked))
#define zig_naked __attribute__((naked))
#elif defined(_MSC_VER)
#define zig_naked_decl
#define zig_naked __declspec(naked)
#else
#define zig_naked_decl zig_naked_unavailable
#define zig_naked zig_naked_unavailable
#endif

#if zig_has_attribute(cold)
#define zig_cold __attribute__((cold))
#else
#define zig_cold
#endif

#if zig_has_attribute(flatten)
#define zig_maybe_flatten __attribute__((flatten))
#else
#define zig_maybe_flatten
#endif

#if zig_has_attribute(noinline)
#define zig_never_inline __attribute__((noinline)) zig_maybe_flatten
#elif defined(_MSC_VER)
#define zig_never_inline __declspec(noinline) zig_maybe_flatten
#else
#define zig_never_inline zig_never_inline_unavailable
#endif

#if zig_has_attribute(not_tail_called)
#define zig_never_tail __attribute__((not_tail_called)) zig_never_inline
#else
#define zig_never_tail zig_never_tail_unavailable
#endif

#if zig_has_attribute(always_inline)
#define zig_always_tail __attribute__((musttail))
#else
#define zig_always_tail zig_always_tail_unavailable
#endif

#if __STDC_VERSION__ >= 199901L
#define zig_restrict restrict
#elif defined(__GNUC__)
#define zig_restrict __restrict
#else
#define zig_restrict
#endif

#if __STDC_VERSION__ >= 201112L
#define zig_align(alignment) _Alignas(alignment)
#elif zig_has_attribute(aligned)
#define zig_align(alignment) __attribute__((aligned(alignment)))
#elif _MSC_VER
#define zig_align(alignment) __declspec(align(alignment))
#else
#define zig_align zig_align_unavailable
#endif

#if zig_has_attribute(aligned)
#define zig_under_align(alignment) __attribute__((aligned(alignment)))
#elif _MSC_VER
#define zig_under_align(alignment) zig_align(alignment)
#else
#define zig_align zig_align_unavailable
#endif

#if zig_has_attribute(aligned)
#define zig_align_fn(alignment) __attribute__((aligned(alignment)))
#elif _MSC_VER
#define zig_align_fn(alignment)
#else
#define zig_align_fn zig_align_fn_unavailable
#endif

#if zig_has_attribute(packed)
#define zig_packed(definition) __attribute__((packed)) definition
#elif _MSC_VER
#define zig_packed(definition) __pragma(pack(1)) definition __pragma(pack())
#else
#define zig_packed(definition) zig_packed_unavailable
#endif

#if zig_has_attribute(section)
#define zig_linksection(name, def, ...) def __attribute__((section(name)))
#elif _MSC_VER
#define zig_linksection(name, def, ...) __pragma(section(name, __VA_ARGS__)) __declspec(allocate(name)) def
#else
#define zig_linksection(name, def, ...) zig_linksection_unavailable
#endif

#if zig_has_builtin(unreachable) || defined(zig_gnuc)
#define zig_unreachable() __builtin_unreachable()
#else
#define zig_unreachable()
#endif

#if defined(__cplusplus)
#define zig_extern extern "C"
#else
#define zig_extern extern
#endif

#if zig_has_attribute(alias)
#define zig_export(sig, symbol, name) zig_extern sig __attribute__((alias(symbol)))
#elif _MSC_VER
#if _M_X64
#define zig_export(sig, symbol, name) sig;\
    __pragma(comment(linker, "/alternatename:" name "=" symbol ))
#else /*_M_X64 */
#define zig_export(sig, symbol, name) sig;\
    __pragma(comment(linker, "/alternatename:_" name "=_" symbol ))
#endif /*_M_X64 */
#else
#define zig_export(sig, symbol, name) __asm(name " = " symbol)
#endif

#if zig_has_attribute(weak) || defined(zig_gnuc)
#define zig_weak_linkage __attribute__((weak))
#define zig_weak_linkage_fn __attribute__((weak))
#elif _MSC_VER
#define zig_weak_linkage __declspec(selectany)
#define zig_weak_linkage_fn
#else
#define zig_weak_linkage zig_weak_linkage_unavailable
#define zig_weak_linkage_fn zig_weak_linkage_unavailable
#endif

#if zig_has_builtin(trap)
#define zig_trap() __builtin_trap()
#elif _MSC_VER && (_M_IX86 || _M_X64)
#define zig_trap() __ud2()
#elif _MSC_VER
#define zig_trap() __fastfail(0)
#elif defined(__i386__) || defined(__x86_64__)
#define zig_trap() __asm__ volatile("ud2");
#elif defined(__arm__) || defined(__aarch64__)
#define zig_trap() __asm__ volatile("udf #0");
#else
#include <stdlib.h>
#define zig_trap() abort()
#endif

#if zig_has_builtin(debugtrap)
#define zig_breakpoint() __builtin_debugtrap()
#elif defined(_MSC_VER) || defined(__MINGW32__) || defined(__MINGW64__)
#define zig_breakpoint() __debugbreak()
#elif defined(__i386__) || defined(__x86_64__)
#define zig_breakpoint() __asm__ volatile("int $0x03");
#elif defined(__arm__)
#define zig_breakpoint() __asm__ volatile("bkpt #0");
#elif defined(__aarch64__)
#define zig_breakpoint() __asm__ volatile("brk #0");
#else
#include <signal.h>
#if defined(SIGTRAP)
#define zig_breakpoint() raise(SIGTRAP)
#else
#define zig_breakpoint() zig_breakpoint_unavailable
#endif
#endif

#if zig_has_builtin(return_address) || defined(zig_gnuc)
#define zig_return_address() __builtin_extract_return_addr(__builtin_return_address(0))
#elif defined(_MSC_VER)
#define zig_return_address() _ReturnAddress()
#else
#define zig_return_address() 0
#endif

#if zig_has_builtin(frame_address) || defined(zig_gnuc)
#define zig_frame_address() __builtin_frame_address(0)
#else
#define zig_frame_address() 0
#endif

#if zig_has_builtin(prefetch) || defined(zig_gnuc)
#define zig_prefetch(addr, rw, locality) __builtin_prefetch(addr, rw, locality)
#else
#define zig_prefetch(addr, rw, locality)
#endif

#if zig_has_builtin(memory_size) && zig_has_builtin(memory_grow)
#define zig_wasm_memory_size(index) __builtin_wasm_memory_size(index)
#define zig_wasm_memory_grow(index, delta) __builtin_wasm_memory_grow(index, delta)
#else
#define zig_wasm_memory_size(index) zig_unimplemented()
#define zig_wasm_memory_grow(index, delta) zig_unimplemented()
#endif

#define zig_concat(lhs, rhs) lhs##rhs
#define zig_expand_concat(lhs, rhs) zig_concat(lhs, rhs)

#if __STDC_VERSION__ >= 201112L
#define zig_noreturn _Noreturn
#elif zig_has_attribute(noreturn) || defined(zig_gnuc)
#define zig_noreturn __attribute__((noreturn))
#elif _MSC_VER
#define zig_noreturn __declspec(noreturn)
#else
#define zig_noreturn
#endif

#define zig_bitSizeOf(T) (CHAR_BIT * sizeof(T))

#define zig_compiler_rt_abbrev_uint32_t si
#define zig_compiler_rt_abbrev_int32_t  si
#define zig_compiler_rt_abbrev_uint64_t di
#define zig_compiler_rt_abbrev_int64_t  di
#define zig_compiler_rt_abbrev_zig_u128 ti
#define zig_compiler_rt_abbrev_zig_i128 ti
#define zig_compiler_rt_abbrev_zig_f16  hf
#define zig_compiler_rt_abbrev_zig_f32  sf
#define zig_compiler_rt_abbrev_zig_f64  df
#define zig_compiler_rt_abbrev_zig_f80  xf
#define zig_compiler_rt_abbrev_zig_f128 tf

zig_extern void *memcpy (void *zig_restrict, void const *zig_restrict, size_t);
zig_extern void *memset (void *, int, size_t);

/* ===================== 8/16/32/64-bit Integer Support ===================== */

#if __STDC_VERSION__ >= 199901L || _MSC_VER
#include <stdint.h>
#else

#if SCHAR_MIN == ~0x7F && SCHAR_MAX == 0x7F && UCHAR_MAX == 0xFF
typedef unsigned      char uint8_t;
typedef   signed      char  int8_t;
#define  INT8_C(c) c
#define UINT8_C(c) c##U
#elif SHRT_MIN == ~0x7F && SHRT_MAX == 0x7F && USHRT_MAX == 0xFF
typedef unsigned     short uint8_t;
typedef   signed     short  int8_t;
#define  INT8_C(c) c
#define UINT8_C(c) c##U
#elif INT_MIN == ~0x7F && INT_MAX == 0x7F && UINT_MAX == 0xFF
typedef unsigned       int uint8_t;
typedef   signed       int  int8_t;
#define  INT8_C(c) c
#define UINT8_C(c) c##U
#elif LONG_MIN == ~0x7F && LONG_MAX == 0x7F && ULONG_MAX == 0xFF
typedef unsigned      long uint8_t;
typedef   signed      long  int8_t;
#define  INT8_C(c) c##L
#define UINT8_C(c) c##LU
#elif LLONG_MIN == ~0x7F && LLONG_MAX == 0x7F && ULLONG_MAX == 0xFF
typedef unsigned long long uint8_t;
typedef   signed long long  int8_t;
#define  INT8_C(c) c##LL
#define UINT8_C(c) c##LLU
#endif
#define  INT8_MIN (~INT8_C(0x7F))
#define  INT8_MAX ( INT8_C(0x7F))
#define UINT8_MAX ( INT8_C(0xFF))

#if SCHAR_MIN == ~0x7FFF && SCHAR_MAX == 0x7FFF && UCHAR_MAX == 0xFFFF
typedef unsigned      char uint16_t;
typedef   signed      char  int16_t;
#define  INT16_C(c) c
#define UINT16_C(c) c##U
#elif SHRT_MIN == ~0x7FFF && SHRT_MAX == 0x7FFF && USHRT_MAX == 0xFFFF
typedef unsigned     short uint16_t;
typedef   signed     short  int16_t;
#define  INT16_C(c) c
#define UINT16_C(c) c##U
#elif INT_MIN == ~0x7FFF && INT_MAX == 0x7FFF && UINT_MAX == 0xFFFF
typedef unsigned       int uint16_t;
typedef   signed       int  int16_t;
#define  INT16_C(c) c
#define UINT16_C(c) c##U
#elif LONG_MIN == ~0x7FFF && LONG_MAX == 0x7FFF && ULONG_MAX == 0xFFFF
typedef unsigned      long uint16_t;
typedef   signed      long  int16_t;
#define  INT16_C(c) c##L
#define UINT16_C(c) c##LU
#elif LLONG_MIN == ~0x7FFF && LLONG_MAX == 0x7FFF && ULLONG_MAX == 0xFFFF
typedef unsigned long long uint16_t;
typedef   signed long long  int16_t;
#define  INT16_C(c) c##LL
#define UINT16_C(c) c##LLU
#endif
#define  INT16_MIN (~INT16_C(0x7FFF))
#define  INT16_MAX ( INT16_C(0x7FFF))
#define UINT16_MAX ( INT16_C(0xFFFF))

#if SCHAR_MIN == ~0x7FFFFFFF && SCHAR_MAX == 0x7FFFFFFF && UCHAR_MAX == 0xFFFFFFFF
typedef unsigned      char uint32_t;
typedef   signed      char  int32_t;
#define  INT32_C(c) c
#define UINT32_C(c) c##U
#elif SHRT_MIN == ~0x7FFFFFFF && SHRT_MAX == 0x7FFFFFFF && USHRT_MAX == 0xFFFFFFFF
typedef unsigned     short uint32_t;
typedef   signed     short  int32_t;
#define  INT32_C(c) c
#define UINT32_C(c) c##U
#elif INT_MIN == ~0x7FFFFFFF && INT_MAX == 0x7FFFFFFF && UINT_MAX == 0xFFFFFFFF
typedef unsigned       int uint32_t;
typedef   signed       int  int32_t;
#define  INT32_C(c) c
#define UINT32_C(c) c##U
#elif LONG_MIN == ~0x7FFFFFFF && LONG_MAX == 0x7FFFFFFF && ULONG_MAX == 0xFFFFFFFF
typedef unsigned      long uint32_t;
typedef   signed      long  int32_t;
#define  INT32_C(c) c##L
#define UINT32_C(c) c##LU
#elif LLONG_MIN == ~0x7FFFFFFF && LLONG_MAX == 0x7FFFFFFF && ULLONG_MAX == 0xFFFFFFFF
typedef unsigned long long uint32_t;
typedef   signed long long  int32_t;
#define  INT32_C(c) c##LL
#define UINT32_C(c) c##LLU
#endif
#define  INT32_MIN (~INT32_C(0x7FFFFFFF))
#define  INT32_MAX ( INT32_C(0x7FFFFFFF))
#define UINT32_MAX ( INT32_C(0xFFFFFFFF))

#if SCHAR_MIN == ~0x7FFFFFFFFFFFFFFF && SCHAR_MAX == 0x7FFFFFFFFFFFFFFF && UCHAR_MAX == 0xFFFFFFFFFFFFFFFF
typedef unsigned      char uint64_t;
typedef   signed      char  int64_t;
#define  INT64_C(c) c
#define UINT64_C(c) c##U
#elif SHRT_MIN == ~0x7FFFFFFFFFFFFFFF && SHRT_MAX == 0x7FFFFFFFFFFFFFFF && USHRT_MAX == 0xFFFFFFFFFFFFFFFF
typedef unsigned     short uint64_t;
typedef   signed     short  int64_t;
#define  INT64_C(c) c
#define UINT64_C(c) c##U
#elif INT_MIN == ~0x7FFFFFFFFFFFFFFF && INT_MAX == 0x7FFFFFFFFFFFFFFF && UINT_MAX == 0xFFFFFFFFFFFFFFFF
typedef unsigned       int uint64_t;
typedef   signed       int  int64_t;
#define  INT64_C(c) c
#define UINT64_C(c) c##U
#elif LONG_MIN == ~0x7FFFFFFFFFFFFFFF && LONG_MAX == 0x7FFFFFFFFFFFFFFF && ULONG_MAX == 0xFFFFFFFFFFFFFFFF
typedef unsigned      long uint64_t;
typedef   signed      long  int64_t;
#define  INT64_C(c) c##L
#define UINT64_C(c) c##LU
#elif LLONG_MIN == ~0x7FFFFFFFFFFFFFFF && LLONG_MAX == 0x7FFFFFFFFFFFFFFF && ULLONG_MAX == 0xFFFFFFFFFFFFFFFF
typedef unsigned long long uint64_t;
typedef   signed long long  int64_t;
#define  INT64_C(c) c##LL
#define UINT64_C(c) c##LLU
#endif
#define  INT64_MIN (~INT64_C(0x7FFFFFFFFFFFFFFF))
#define  INT64_MAX ( INT64_C(0x7FFFFFFFFFFFFFFF))
#define UINT64_MAX ( INT64_C(0xFFFFFFFFFFFFFFFF))

typedef size_t uintptr_t;
typedef ptrdiff_t intptr_t;

#endif

#define zig_minInt_i8    INT8_MIN
#define zig_maxInt_i8    INT8_MAX
#define zig_minInt_u8   UINT8_C(0)
#define zig_maxInt_u8   UINT8_MAX
#define zig_minInt_i16  INT16_MIN
#define zig_maxInt_i16  INT16_MAX
#define zig_minInt_u16 UINT16_C(0)
#define zig_maxInt_u16 UINT16_MAX
#define zig_minInt_i32  INT32_MIN
#define zig_maxInt_i32  INT32_MAX
#define zig_minInt_u32 UINT32_C(0)
#define zig_maxInt_u32 UINT32_MAX
#define zig_minInt_i64  INT64_MIN
#define zig_maxInt_i64  INT64_MAX
#define zig_minInt_u64 UINT64_C(0)
#define zig_maxInt_u64 UINT64_MAX

#define zig_intLimit(s, w, limit, bits) zig_shr_##s##w(zig_##limit##Int_##s##w, w - (bits))
#define zig_minInt_i(w, bits) zig_intLimit(i, w, min, bits)
#define zig_maxInt_i(w, bits) zig_intLimit(i, w, max, bits)
#define zig_minInt_u(w, bits) zig_intLimit(u, w, min, bits)
#define zig_maxInt_u(w, bits) zig_intLimit(u, w, max, bits)

#define zig_operator(Type, RhsType, operation, operator) \
    static inline Type zig_##operation(Type lhs, RhsType rhs) { \
        return lhs operator rhs; \
    }
#define zig_basic_operator(Type, operation, operator) \
    zig_operator(Type,    Type, operation, operator)
#define zig_shift_operator(Type, operation, operator) \
    zig_operator(Type, uint8_t, operation, operator)
#define zig_int_helpers(w) \
    zig_basic_operator(uint##w##_t, and_u##w,  &) \
    zig_basic_operator( int##w##_t, and_i##w,  &) \
    zig_basic_operator(uint##w##_t,  or_u##w,  |) \
    zig_basic_operator( int##w##_t,  or_i##w,  |) \
    zig_basic_operator(uint##w##_t, xor_u##w,  ^) \
    zig_basic_operator( int##w##_t, xor_i##w,  ^) \
    zig_shift_operator(uint##w##_t, shl_u##w, <<) \
    zig_shift_operator( int##w##_t, shl_i##w, <<) \
    zig_shift_operator(uint##w##_t, shr_u##w, >>) \
\
    static inline int##w##_t zig_shr_i##w(int##w##_t lhs, uint8_t rhs) { \
        int##w##_t sign_mask = lhs < INT##w##_C(0) ? -INT##w##_C(1) : INT##w##_C(0); \
        return ((lhs ^ sign_mask) >> rhs) ^ sign_mask; \
    } \
\
    static inline uint##w##_t zig_not_u##w(uint##w##_t val, uint8_t bits) { \
        return val ^ zig_maxInt_u(w, bits); \
    } \
\
    static inline int##w##_t zig_not_i##w(int##w##_t val, uint8_t bits) { \
        (void)bits; \
        return ~val; \
    } \
\
    static inline uint##w##_t zig_wrap_u##w(uint##w##_t val, uint8_t bits) { \
        return val & zig_maxInt_u(w, bits); \
    } \
\
    static inline int##w##_t zig_wrap_i##w(int##w##_t val, uint8_t bits) { \
        return (val & UINT##w##_C(1) << (bits - UINT8_C(1))) != 0 \
            ? val | zig_minInt_i(w, bits) : val & zig_maxInt_i(w, bits); \
    } \
\
    zig_basic_operator(uint##w##_t, div_floor_u##w, /) \
\
    static inline int##w##_t zig_div_floor_i##w(int##w##_t lhs, int##w##_t rhs) { \
        return lhs / rhs + (lhs % rhs != INT##w##_C(0) ? zig_shr_i##w(lhs ^ rhs, UINT8_C(w) - UINT8_C(1)) : INT##w##_C(0)); \
    } \
\
    zig_basic_operator(uint##w##_t, mod_u##w, %) \
\
    static inline int##w##_t zig_mod_i##w(int##w##_t lhs, int##w##_t rhs) { \
        int##w##_t rem = lhs % rhs; \
        return rem + (rem != INT##w##_C(0) ? rhs & zig_shr_i##w(lhs ^ rhs, UINT8_C(w) - UINT8_C(1)) : INT##w##_C(0)); \
    } \
\
    static inline uint##w##_t zig_shlw_u##w(uint##w##_t lhs, uint8_t rhs, uint8_t bits) { \
        return zig_wrap_u##w(zig_shl_u##w(lhs, rhs), bits); \
    } \
\
    static inline int##w##_t zig_shlw_i##w(int##w##_t lhs, uint8_t rhs, uint8_t bits) { \
        return zig_wrap_i##w((int##w##_t)zig_shl_u##w((uint##w##_t)lhs, rhs), bits); \
    } \
\
    static inline uint##w##_t zig_addw_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        return zig_wrap_u##w(lhs + rhs, bits); \
    } \
\
    static inline int##w##_t zig_addw_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        return zig_wrap_i##w((int##w##_t)((uint##w##_t)lhs + (uint##w##_t)rhs), bits); \
    } \
\
    static inline uint##w##_t zig_subw_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        return zig_wrap_u##w(lhs - rhs, bits); \
    } \
\
    static inline int##w##_t zig_subw_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        return zig_wrap_i##w((int##w##_t)((uint##w##_t)lhs - (uint##w##_t)rhs), bits); \
    } \
\
    static inline uint##w##_t zig_mulw_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        return zig_wrap_u##w(lhs * rhs, bits); \
    } \
\
    static inline int##w##_t zig_mulw_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        return zig_wrap_i##w((int##w##_t)((uint##w##_t)lhs * (uint##w##_t)rhs), bits); \
    }
zig_int_helpers(8)
zig_int_helpers(16)
zig_int_helpers(32)
zig_int_helpers(64)

static inline bool zig_addo_u32(uint32_t *res, uint32_t lhs, uint32_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    uint32_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u32(full_res, bits);
    return overflow || full_res < zig_minInt_u(32, bits) || full_res > zig_maxInt_u(32, bits);
#else
    *res = zig_addw_u32(lhs, rhs, bits);
    return *res < lhs;
#endif
}

zig_extern int32_t  __addosi4(int32_t lhs, int32_t rhs, int *overflow);
static inline bool zig_addo_i32(int32_t *res, int32_t lhs, int32_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    int32_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int32_t full_res = __addosi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i32(full_res, bits);
    return overflow || full_res < zig_minInt_i(32, bits) || full_res > zig_maxInt_i(32, bits);
}

static inline bool zig_addo_u64(uint64_t *res, uint64_t lhs, uint64_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    uint64_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u64(full_res, bits);
    return overflow || full_res < zig_minInt_u(64, bits) || full_res > zig_maxInt_u(64, bits);
#else
    *res = zig_addw_u64(lhs, rhs, bits);
    return *res < lhs;
#endif
}

zig_extern int64_t  __addodi4(int64_t lhs, int64_t rhs, int *overflow);
static inline bool zig_addo_i64(int64_t *res, int64_t lhs, int64_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    int64_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int64_t full_res = __addodi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i64(full_res, bits);
    return overflow || full_res < zig_minInt_i(64, bits) || full_res > zig_maxInt_i(64, bits);
}

static inline bool zig_addo_u8(uint8_t *res, uint8_t lhs, uint8_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    uint8_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u8(full_res, bits);
    return overflow || full_res < zig_minInt_u(8, bits) || full_res > zig_maxInt_u(8, bits);
#else
    uint32_t full_res;
    bool overflow = zig_addo_u32(&full_res, lhs, rhs, bits);
    *res = (uint8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_addo_i8(int8_t *res, int8_t lhs, int8_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    int8_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i8(full_res, bits);
    return overflow || full_res < zig_minInt_i(8, bits) || full_res > zig_maxInt_i(8, bits);
#else
    int32_t full_res;
    bool overflow = zig_addo_i32(&full_res, lhs, rhs, bits);
    *res = (int8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_addo_u16(uint16_t *res, uint16_t lhs, uint16_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    uint16_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u16(full_res, bits);
    return overflow || full_res < zig_minInt_u(16, bits) || full_res > zig_maxInt_u(16, bits);
#else
    uint32_t full_res;
    bool overflow = zig_addo_u32(&full_res, lhs, rhs, bits);
    *res = (uint16_t)full_res;
    return overflow;
#endif
}

static inline bool zig_addo_i16(int16_t *res, int16_t lhs, int16_t rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow) || defined(zig_gnuc)
    int16_t full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i16(full_res, bits);
    return overflow || full_res < zig_minInt_i(16, bits) || full_res > zig_maxInt_i(16, bits);
#else
    int32_t full_res;
    bool overflow = zig_addo_i32(&full_res, lhs, rhs, bits);
    *res = (int16_t)full_res;
    return overflow;
#endif
}

static inline bool zig_subo_u32(uint32_t *res, uint32_t lhs, uint32_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    uint32_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u32(full_res, bits);
    return overflow || full_res < zig_minInt_u(32, bits) || full_res > zig_maxInt_u(32, bits);
#else
    *res = zig_subw_u32(lhs, rhs, bits);
    return *res > lhs;
#endif
}

zig_extern int32_t  __subosi4(int32_t lhs, int32_t rhs, int *overflow);
static inline bool zig_subo_i32(int32_t *res, int32_t lhs, int32_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    int32_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int32_t full_res = __subosi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i32(full_res, bits);
    return overflow || full_res < zig_minInt_i(32, bits) || full_res > zig_maxInt_i(32, bits);
}

static inline bool zig_subo_u64(uint64_t *res, uint64_t lhs, uint64_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    uint64_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u64(full_res, bits);
    return overflow || full_res < zig_minInt_u(64, bits) || full_res > zig_maxInt_u(64, bits);
#else
    *res = zig_subw_u64(lhs, rhs, bits);
    return *res > lhs;
#endif
}

zig_extern int64_t  __subodi4(int64_t lhs, int64_t rhs, int *overflow);
static inline bool zig_subo_i64(int64_t *res, int64_t lhs, int64_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    int64_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int64_t full_res = __subodi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i64(full_res, bits);
    return overflow || full_res < zig_minInt_i(64, bits) || full_res > zig_maxInt_i(64, bits);
}

static inline bool zig_subo_u8(uint8_t *res, uint8_t lhs, uint8_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    uint8_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u8(full_res, bits);
    return overflow || full_res < zig_minInt_u(8, bits) || full_res > zig_maxInt_u(8, bits);
#else
    uint32_t full_res;
    bool overflow = zig_subo_u32(&full_res, lhs, rhs, bits);
    *res = (uint8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_subo_i8(int8_t *res, int8_t lhs, int8_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    int8_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i8(full_res, bits);
    return overflow || full_res < zig_minInt_i(8, bits) || full_res > zig_maxInt_i(8, bits);
#else
    int32_t full_res;
    bool overflow = zig_subo_i32(&full_res, lhs, rhs, bits);
    *res = (int8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_subo_u16(uint16_t *res, uint16_t lhs, uint16_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    uint16_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u16(full_res, bits);
    return overflow || full_res < zig_minInt_u(16, bits) || full_res > zig_maxInt_u(16, bits);
#else
    uint32_t full_res;
    bool overflow = zig_subo_u32(&full_res, lhs, rhs, bits);
    *res = (uint16_t)full_res;
    return overflow;
#endif
}

static inline bool zig_subo_i16(int16_t *res, int16_t lhs, int16_t rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow) || defined(zig_gnuc)
    int16_t full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i16(full_res, bits);
    return overflow || full_res < zig_minInt_i(16, bits) || full_res > zig_maxInt_i(16, bits);
#else
    int32_t full_res;
    bool overflow = zig_subo_i32(&full_res, lhs, rhs, bits);
    *res = (int16_t)full_res;
    return overflow;
#endif
}

static inline bool zig_mulo_u32(uint32_t *res, uint32_t lhs, uint32_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    uint32_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u32(full_res, bits);
    return overflow || full_res < zig_minInt_u(32, bits) || full_res > zig_maxInt_u(32, bits);
#else
    *res = zig_mulw_u32(lhs, rhs, bits);
    return rhs != UINT32_C(0) && lhs > zig_maxInt_u(32, bits) / rhs;
#endif
}

zig_extern int32_t  __mulosi4(int32_t lhs, int32_t rhs, int *overflow);
static inline bool zig_mulo_i32(int32_t *res, int32_t lhs, int32_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    int32_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int32_t full_res = __mulosi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i32(full_res, bits);
    return overflow || full_res < zig_minInt_i(32, bits) || full_res > zig_maxInt_i(32, bits);
}

static inline bool zig_mulo_u64(uint64_t *res, uint64_t lhs, uint64_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    uint64_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u64(full_res, bits);
    return overflow || full_res < zig_minInt_u(64, bits) || full_res > zig_maxInt_u(64, bits);
#else
    *res = zig_mulw_u64(lhs, rhs, bits);
    return rhs != UINT64_C(0) && lhs > zig_maxInt_u(64, bits) / rhs;
#endif
}

zig_extern int64_t  __mulodi4(int64_t lhs, int64_t rhs, int *overflow);
static inline bool zig_mulo_i64(int64_t *res, int64_t lhs, int64_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    int64_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    int64_t full_res = __mulodi4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i64(full_res, bits);
    return overflow || full_res < zig_minInt_i(64, bits) || full_res > zig_maxInt_i(64, bits);
}

static inline bool zig_mulo_u8(uint8_t *res, uint8_t lhs, uint8_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    uint8_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u8(full_res, bits);
    return overflow || full_res < zig_minInt_u(8, bits) || full_res > zig_maxInt_u(8, bits);
#else
    uint32_t full_res;
    bool overflow = zig_mulo_u32(&full_res, lhs, rhs, bits);
    *res = (uint8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_mulo_i8(int8_t *res, int8_t lhs, int8_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    int8_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i8(full_res, bits);
    return overflow || full_res < zig_minInt_i(8, bits) || full_res > zig_maxInt_i(8, bits);
#else
    int32_t full_res;
    bool overflow = zig_mulo_i32(&full_res, lhs, rhs, bits);
    *res = (int8_t)full_res;
    return overflow;
#endif
}

static inline bool zig_mulo_u16(uint16_t *res, uint16_t lhs, uint16_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    uint16_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u16(full_res, bits);
    return overflow || full_res < zig_minInt_u(16, bits) || full_res > zig_maxInt_u(16, bits);
#else
    uint32_t full_res;
    bool overflow = zig_mulo_u32(&full_res, lhs, rhs, bits);
    *res = (uint16_t)full_res;
    return overflow;
#endif
}

static inline bool zig_mulo_i16(int16_t *res, int16_t lhs, int16_t rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow) || defined(zig_gnuc)
    int16_t full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_i16(full_res, bits);
    return overflow || full_res < zig_minInt_i(16, bits) || full_res > zig_maxInt_i(16, bits);
#else
    int32_t full_res;
    bool overflow = zig_mulo_i32(&full_res, lhs, rhs, bits);
    *res = (int16_t)full_res;
    return overflow;
#endif
}

#define zig_int_builtins(w) \
    static inline bool zig_shlo_u##w(uint##w##_t *res, uint##w##_t lhs, uint8_t rhs, uint8_t bits) { \
        *res = zig_shlw_u##w(lhs, rhs, bits); \
        return lhs > zig_maxInt_u(w, bits) >> rhs; \
    } \
\
    static inline bool zig_shlo_i##w(int##w##_t *res, int##w##_t lhs, uint8_t rhs, uint8_t bits) { \
        *res = zig_shlw_i##w(lhs, rhs, bits); \
        int##w##_t mask = (int##w##_t)(UINT##w##_MAX << (bits - rhs - 1)); \
        return (lhs & mask) != INT##w##_C(0) && (lhs & mask) != mask; \
    } \
\
    static inline uint##w##_t zig_shls_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        uint##w##_t res; \
        if (rhs >= bits) return lhs != UINT##w##_C(0) ? zig_maxInt_u(w, bits) : lhs; \
        return zig_shlo_u##w(&res, lhs, (uint8_t)rhs, bits) ? zig_maxInt_u(w, bits) : res; \
    } \
\
    static inline int##w##_t zig_shls_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        int##w##_t res; \
        if ((uint##w##_t)rhs < (uint##w##_t)bits && !zig_shlo_i##w(&res, lhs, (uint8_t)rhs, bits)) return res; \
        return lhs < INT##w##_C(0) ? zig_minInt_i(w, bits) : zig_maxInt_i(w, bits); \
    } \
\
    static inline uint##w##_t zig_adds_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        uint##w##_t res; \
        return zig_addo_u##w(&res, lhs, rhs, bits) ? zig_maxInt_u(w, bits) : res; \
    } \
\
    static inline int##w##_t zig_adds_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        int##w##_t res; \
        if (!zig_addo_i##w(&res, lhs, rhs, bits)) return res; \
        return res >= INT##w##_C(0) ? zig_minInt_i(w, bits) : zig_maxInt_i(w, bits); \
    } \
\
    static inline uint##w##_t zig_subs_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        uint##w##_t res; \
        return zig_subo_u##w(&res, lhs, rhs, bits) ? zig_minInt_u(w, bits) : res; \
    } \
\
    static inline int##w##_t zig_subs_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        int##w##_t res; \
        if (!zig_subo_i##w(&res, lhs, rhs, bits)) return res; \
        return res >= INT##w##_C(0) ? zig_minInt_i(w, bits) : zig_maxInt_i(w, bits); \
    } \
\
    static inline uint##w##_t zig_muls_u##w(uint##w##_t lhs, uint##w##_t rhs, uint8_t bits) { \
        uint##w##_t res; \
        return zig_mulo_u##w(&res, lhs, rhs, bits) ? zig_maxInt_u(w, bits) : res; \
    } \
\
    static inline int##w##_t zig_muls_i##w(int##w##_t lhs, int##w##_t rhs, uint8_t bits) { \
        int##w##_t res; \
        if (!zig_mulo_i##w(&res, lhs, rhs, bits)) return res; \
        return (lhs ^ rhs) < INT##w##_C(0) ? zig_minInt_i(w, bits) : zig_maxInt_i(w, bits); \
    }
zig_int_builtins(8)
zig_int_builtins(16)
zig_int_builtins(32)
zig_int_builtins(64)

#define zig_builtin8(name, val) __builtin_##name(val)
typedef unsigned int zig_Builtin8;

#define zig_builtin16(name, val) __builtin_##name(val)
typedef unsigned int zig_Builtin16;

#if INT_MIN <= INT32_MIN
#define zig_builtin32(name, val) __builtin_##name(val)
typedef unsigned int zig_Builtin32;
#elif LONG_MIN <= INT32_MIN
#define zig_builtin32(name, val) __builtin_##name##l(val)
typedef unsigned long zig_Builtin32;
#endif

#if INT_MIN <= INT64_MIN
#define zig_builtin64(name, val) __builtin_##name(val)
typedef unsigned int zig_Builtin64;
#elif LONG_MIN <= INT64_MIN
#define zig_builtin64(name, val) __builtin_##name##l(val)
typedef unsigned long zig_Builtin64;
#elif LLONG_MIN <= INT64_MIN
#define zig_builtin64(name, val) __builtin_##name##ll(val)
typedef unsigned long long zig_Builtin64;
#endif

#define zig_builtin8_rev(name, val) __builtin_##name(val)

#define zig_builtin16_rev(name, val) __builtin_##name(val)

#if INT_MIN <= INT32_MIN
#define zig_builtin32_rev(name, val) __builtin_##name(val)
#elif LONG_MIN <= INT32_MIN
#define zig_builtin32_rev(name, val) __builtin_l##name(val)
#endif

#if INT_MIN <= INT64_MIN
#define zig_builtin64_rev(name, val) __builtin_##name(val)
#elif LONG_MIN <= INT64_MIN
#define zig_builtin64_rev(name, val) __builtin_l##name(val)
#elif LLONG_MIN <= INT64_MIN
#define zig_builtin64_rev(name, val) __builtin_ll##name(val)
#endif

static inline uint8_t zig_byte_swap_u8(uint8_t val, uint8_t bits) {
    return zig_wrap_u8(val >> (8 - bits), bits);
}

static inline int8_t zig_byte_swap_i8(int8_t val, uint8_t bits) {
    return zig_wrap_i8((int8_t)zig_byte_swap_u8((uint8_t)val, bits), bits);
}

static inline uint16_t zig_byte_swap_u16(uint16_t val, uint8_t bits) {
    uint16_t full_res;
#if zig_has_builtin(bswap16) || defined(zig_gnuc)
    full_res = __builtin_bswap16(val);
#else
    full_res = (uint16_t)zig_byte_swap_u8((uint8_t)(val >>  0), 8) <<  8 |
               (uint16_t)zig_byte_swap_u8((uint8_t)(val >>  8), 8) >>  0;
#endif
    return zig_wrap_u16(full_res >> (16 - bits), bits);
}

static inline int16_t zig_byte_swap_i16(int16_t val, uint8_t bits) {
    return zig_wrap_i16((int16_t)zig_byte_swap_u16((uint16_t)val, bits), bits);
}

static inline uint32_t zig_byte_swap_u32(uint32_t val, uint8_t bits) {
    uint32_t full_res;
#if zig_has_builtin(bswap32) || defined(zig_gnuc)
    full_res = __builtin_bswap32(val);
#else
    full_res = (uint32_t)zig_byte_swap_u16((uint16_t)(val >>  0), 16) << 16 |
               (uint32_t)zig_byte_swap_u16((uint16_t)(val >> 16), 16) >>  0;
#endif
    return zig_wrap_u32(full_res >> (32 - bits), bits);
}

static inline int32_t zig_byte_swap_i32(int32_t val, uint8_t bits) {
    return zig_wrap_i32((int32_t)zig_byte_swap_u32((uint32_t)val, bits), bits);
}

static inline uint64_t zig_byte_swap_u64(uint64_t val, uint8_t bits) {
    uint64_t full_res;
#if zig_has_builtin(bswap64) || defined(zig_gnuc)
    full_res = __builtin_bswap64(val);
#else
    full_res = (uint64_t)zig_byte_swap_u32((uint32_t)(val >>  0), 32) << 32 |
               (uint64_t)zig_byte_swap_u32((uint32_t)(val >> 32), 32) >>  0;
#endif
    return zig_wrap_u64(full_res >> (64 - bits), bits);
}

static inline int64_t zig_byte_swap_i64(int64_t val, uint8_t bits) {
    return zig_wrap_i64((int64_t)zig_byte_swap_u64((uint64_t)val, bits), bits);
}

static inline uint8_t zig_bit_reverse_u8(uint8_t val, uint8_t bits) {
    uint8_t full_res;
#if zig_has_builtin(bitreverse8)
    full_res = __builtin_bitreverse8(val);
#else
    static uint8_t const lut[0x10] = {
        0x0, 0x8, 0x4, 0xc, 0x2, 0xa, 0x6, 0xe,
        0x1, 0x9, 0x5, 0xd, 0x3, 0xb, 0x7, 0xf
    };
    full_res = lut[val >> 0 & 0xF] << 4 | lut[val >> 4 & 0xF] << 0;
#endif
    return zig_wrap_u8(full_res >> (8 - bits), bits);
}

static inline int8_t zig_bit_reverse_i8(int8_t val, uint8_t bits) {
    return zig_wrap_i8((int8_t)zig_bit_reverse_u8((uint8_t)val, bits), bits);
}

static inline uint16_t zig_bit_reverse_u16(uint16_t val, uint8_t bits) {
    uint16_t full_res;
#if zig_has_builtin(bitreverse16)
    full_res = __builtin_bitreverse16(val);
#else
    full_res = (uint16_t)zig_bit_reverse_u8((uint8_t)(val >>  0), 8) <<  8 |
               (uint16_t)zig_bit_reverse_u8((uint8_t)(val >>  8), 8) >>  0;
#endif
    return zig_wrap_u16(full_res >> (16 - bits), bits);
}

static inline int16_t zig_bit_reverse_i16(int16_t val, uint8_t bits) {
    return zig_wrap_i16((int16_t)zig_bit_reverse_u16((uint16_t)val, bits), bits);
}

static inline uint32_t zig_bit_reverse_u32(uint32_t val, uint8_t bits) {
    uint32_t full_res;
#if zig_has_builtin(bitreverse32)
    full_res = __builtin_bitreverse32(val);
#else
    full_res = (uint32_t)zig_bit_reverse_u16((uint16_t)(val >>  0), 16) << 16 |
               (uint32_t)zig_bit_reverse_u16((uint16_t)(val >> 16), 16) >>  0;
#endif
    return zig_wrap_u32(full_res >> (32 - bits), bits);
}

static inline int32_t zig_bit_reverse_i32(int32_t val, uint8_t bits) {
    return zig_wrap_i32((int32_t)zig_bit_reverse_u32((uint32_t)val, bits), bits);
}

static inline uint64_t zig_bit_reverse_u64(uint64_t val, uint8_t bits) {
    uint64_t full_res;
#if zig_has_builtin(bitreverse64)
    full_res = __builtin_bitreverse64(val);
#else
    full_res = (uint64_t)zig_bit_reverse_u32((uint32_t)(val >>  0), 32) << 32 |
               (uint64_t)zig_bit_reverse_u32((uint32_t)(val >> 32), 32) >>  0;
#endif
    return zig_wrap_u64(full_res >> (64 - bits), bits);
}

static inline int64_t zig_bit_reverse_i64(int64_t val, uint8_t bits) {
    return zig_wrap_i64((int64_t)zig_bit_reverse_u64((uint64_t)val, bits), bits);
}

#define zig_builtin_popcount_common(w) \
    static inline uint8_t zig_popcount_i##w(int##w##_t val, uint8_t bits) { \
        return zig_popcount_u##w((uint##w##_t)val, bits); \
    }
#if zig_has_builtin(popcount) || defined(zig_gnuc)
#define zig_builtin_popcount(w) \
    static inline uint8_t zig_popcount_u##w(uint##w##_t val, uint8_t bits) { \
        (void)bits; \
        return zig_builtin##w(popcount, val); \
    } \
\
    zig_builtin_popcount_common(w)
#else
#define zig_builtin_popcount(w) \
    static inline uint8_t zig_popcount_u##w(uint##w##_t val, uint8_t bits) { \
        (void)bits; \
        uint##w##_t temp = val - ((val >> 1) & (UINT##w##_MAX / 3)); \
        temp = (temp & (UINT##w##_MAX / 5)) + ((temp >> 2) & (UINT##w##_MAX / 5)); \
        temp = (temp + (temp >> 4)) & (UINT##w##_MAX / 17); \
        return temp * (UINT##w##_MAX / 255) >> (UINT8_C(w) - UINT8_C(8)); \
    } \
\
    zig_builtin_popcount_common(w)
#endif
zig_builtin_popcount(8)
zig_builtin_popcount(16)
zig_builtin_popcount(32)
zig_builtin_popcount(64)

#define zig_builtin_ctz_common(w) \
    static inline uint8_t zig_ctz_i##w(int##w##_t val, uint8_t bits) { \
        return zig_ctz_u##w((uint##w##_t)val, bits); \
    }
#if zig_has_builtin(ctz) || defined(zig_gnuc)
#define zig_builtin_ctz(w) \
    static inline uint8_t zig_ctz_u##w(uint##w##_t val, uint8_t bits) { \
        if (val == 0) return bits; \
        return zig_builtin##w(ctz, val); \
    } \
\
    zig_builtin_ctz_common(w)
#else
#define zig_builtin_ctz(w) \
    static inline uint8_t zig_ctz_u##w(uint##w##_t val, uint8_t bits) { \
        return zig_popcount_u##w(zig_not_u##w(val, bits) & zig_subw_u##w(val, 1, bits), bits); \
    } \
\
    zig_builtin_ctz_common(w)
#endif
zig_builtin_ctz(8)
zig_builtin_ctz(16)
zig_builtin_ctz(32)
zig_builtin_ctz(64)

#define zig_builtin_clz_common(w) \
    static inline uint8_t zig_clz_i##w(int##w##_t val, uint8_t bits) { \
        return zig_clz_u##w((uint##w##_t)val, bits); \
    }
#if zig_has_builtin(clz) || defined(zig_gnuc)
#define zig_builtin_clz(w) \
    static inline uint8_t zig_clz_u##w(uint##w##_t val, uint8_t bits) { \
        if (val == 0) return bits; \
        return zig_builtin##w(clz, val) - (zig_bitSizeOf(zig_Builtin##w) - bits); \
    } \
\
    zig_builtin_clz_common(w)
#else
#define zig_builtin_clz(w) \
    static inline uint8_t zig_clz_u##w(uint##w##_t val, uint8_t bits) { \
        return zig_ctz_u##w(zig_bit_reverse_u##w(val, bits), bits); \
    } \
\
    zig_builtin_clz_common(w)
#endif
zig_builtin_clz(8)
zig_builtin_clz(16)
zig_builtin_clz(32)
zig_builtin_clz(64)

#if zig_has_builtin(abs) || defined(zig_gnuc)
#define zig_builtin_abs(w) \
    static inline int##w##_t zig_abs_i##w(int##w##_t val) { \
        return zig_builtin##w##_rev(abs, val); \
    }
#else
#define zig_builtin_abs(w) \
    static inline int##w##_t zig_abs_i##w(int##w##_t val) { \
        if (val == INT##w##_MIN) return val; \
        int##w##_t tmp = val >> (w - 1); \
        return (val ^ tmp) - tmp; \
    }
#endif
zig_builtin_abs(8)
zig_builtin_abs(16)
zig_builtin_abs(32)
zig_builtin_abs(64)

/* ======================== 128-bit Integer Support ========================= */

#if !defined(zig_has_int128)
# if defined(__SIZEOF_INT128__)
#  define zig_has_int128 1
# else
#  define zig_has_int128 0
# endif
#endif

#if zig_has_int128

typedef unsigned __int128 zig_u128;
typedef   signed __int128 zig_i128;

#define zig_make_u128(hi, lo) ((zig_u128)(hi)<<64|(lo))
#define zig_make_i128(hi, lo) ((zig_i128)zig_make_u128(hi, lo))
#define zig_init_u128(hi, lo) zig_make_u128(hi, lo)
#define zig_init_i128(hi, lo) zig_make_i128(hi, lo)
#define zig_hi_u128(val) ((uint64_t)((val) >> 64))
#define zig_lo_u128(val) ((uint64_t)((val) >>  0))
#define zig_hi_i128(val) (( int64_t)((val) >> 64))
#define zig_lo_i128(val) ((uint64_t)((val) >>  0))
#define zig_bitCast_u128(val) ((zig_u128)(val))
#define zig_bitCast_i128(val) ((zig_i128)(val))
#define zig_cmp_int128(Type) \
    static inline int32_t zig_cmp_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return (lhs > rhs) - (lhs < rhs); \
    }
#define zig_bit_int128(Type, operation, operator) \
    static inline zig_##Type zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return lhs operator rhs; \
    }

#else /* zig_has_int128 */

#if zig_little_endian
typedef struct { zig_align(16) uint64_t lo; uint64_t hi; } zig_u128;
typedef struct { zig_align(16) uint64_t lo;  int64_t hi; } zig_i128;
#else
typedef struct { zig_align(16) uint64_t hi; uint64_t lo; } zig_u128;
typedef struct { zig_align(16)  int64_t hi; uint64_t lo; } zig_i128;
#endif

#define zig_make_u128(hi, lo) ((zig_u128){ .h##i = (hi), .l##o = (lo) })
#define zig_make_i128(hi, lo) ((zig_i128){ .h##i = (hi), .l##o = (lo) })

#if _MSC_VER /* MSVC doesn't allow struct literals in constant expressions */
#define zig_init_u128(hi, lo) { .h##i = (hi), .l##o = (lo) }
#define zig_init_i128(hi, lo) { .h##i = (hi), .l##o = (lo) }
#else /* But non-MSVC doesn't like the unprotected commas */
#define zig_init_u128(hi, lo) zig_make_u128(hi, lo)
#define zig_init_i128(hi, lo) zig_make_i128(hi, lo)
#endif
#define zig_hi_u128(val) ((val).hi)
#define zig_lo_u128(val) ((val).lo)
#define zig_hi_i128(val) ((val).hi)
#define zig_lo_i128(val) ((val).lo)
#define zig_bitCast_u128(val) zig_make_u128((uint64_t)(val).hi, (val).lo)
#define zig_bitCast_i128(val) zig_make_i128(( int64_t)(val).hi, (val).lo)
#define zig_cmp_int128(Type) \
    static inline int32_t zig_cmp_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return (lhs.hi == rhs.hi) \
            ? (lhs.lo > rhs.lo) - (lhs.lo < rhs.lo) \
            : (lhs.hi > rhs.hi) - (lhs.hi < rhs.hi); \
    }
#define zig_bit_int128(Type, operation, operator) \
    static inline zig_##Type zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return (zig_##Type){ .hi = lhs.hi operator rhs.hi, .lo = lhs.lo operator rhs.lo }; \
    }

#endif /* zig_has_int128 */

#define zig_minInt_u128 zig_make_u128(zig_minInt_u64, zig_minInt_u64)
#define zig_maxInt_u128 zig_make_u128(zig_maxInt_u64, zig_maxInt_u64)
#define zig_minInt_i128 zig_make_i128(zig_minInt_i64, zig_minInt_u64)
#define zig_maxInt_i128 zig_make_i128(zig_maxInt_i64, zig_maxInt_u64)

zig_cmp_int128(u128)
zig_cmp_int128(i128)

zig_bit_int128(u128, and, &)
zig_bit_int128(i128, and, &)

zig_bit_int128(u128,  or, |)
zig_bit_int128(i128,  or, |)

zig_bit_int128(u128, xor, ^)
zig_bit_int128(i128, xor, ^)

static inline zig_u128 zig_shr_u128(zig_u128 lhs, uint8_t rhs);

#if zig_has_int128

static inline zig_u128 zig_not_u128(zig_u128 val, uint8_t bits) {
    return val ^ zig_maxInt_u(128, bits);
}

static inline zig_i128 zig_not_i128(zig_i128 val, uint8_t bits) {
    (void)bits;
    return ~val;
}

static inline zig_u128 zig_shr_u128(zig_u128 lhs, uint8_t rhs) {
    return lhs >> rhs;
}

static inline zig_u128 zig_shl_u128(zig_u128 lhs, uint8_t rhs) {
    return lhs << rhs;
}

static inline zig_i128 zig_shr_i128(zig_i128 lhs, uint8_t rhs) {
    zig_i128 sign_mask = lhs < zig_make_i128(0, 0) ? -zig_make_i128(0, 1) : zig_make_i128(0, 0);
    return ((lhs ^ sign_mask) >> rhs) ^ sign_mask;
}

static inline zig_i128 zig_shl_i128(zig_i128 lhs, uint8_t rhs) {
    return lhs << rhs;
}

static inline zig_u128 zig_add_u128(zig_u128 lhs, zig_u128 rhs) {
    return lhs + rhs;
}

static inline zig_i128 zig_add_i128(zig_i128 lhs, zig_i128 rhs) {
    return lhs + rhs;
}

static inline zig_u128 zig_sub_u128(zig_u128 lhs, zig_u128 rhs) {
    return lhs - rhs;
}

static inline zig_i128 zig_sub_i128(zig_i128 lhs, zig_i128 rhs) {
    return lhs - rhs;
}

static inline zig_u128 zig_mul_u128(zig_u128 lhs, zig_u128 rhs) {
    return lhs * rhs;
}

static inline zig_i128 zig_mul_i128(zig_i128 lhs, zig_i128 rhs) {
    return lhs * rhs;
}

static inline zig_u128 zig_div_trunc_u128(zig_u128 lhs, zig_u128 rhs) {
    return lhs / rhs;
}

static inline zig_i128 zig_div_trunc_i128(zig_i128 lhs, zig_i128 rhs) {
    return lhs / rhs;
}

static inline zig_u128 zig_rem_u128(zig_u128 lhs, zig_u128 rhs) {
    return lhs % rhs;
}

static inline zig_i128 zig_rem_i128(zig_i128 lhs, zig_i128 rhs) {
    return lhs % rhs;
}

#else /* zig_has_int128 */

static inline zig_u128 zig_not_u128(zig_u128 val, uint8_t bits) {
    return (zig_u128){ .hi = zig_not_u64(val.hi, bits - UINT8_C(64)), .lo = zig_not_u64(val.lo, UINT8_C(64)) };
}

static inline zig_i128 zig_not_i128(zig_i128 val, uint8_t bits) {
    return (zig_i128){ .hi = zig_not_i64(val.hi, bits - UINT8_C(64)), .lo = zig_not_u64(val.lo, UINT8_C(64)) };
}

static inline zig_u128 zig_shr_u128(zig_u128 lhs, uint8_t rhs) {
    if (rhs == UINT8_C(0)) return lhs;
    if (rhs >= UINT8_C(64)) return (zig_u128){ .hi = zig_minInt_u64, .lo = lhs.hi >> (rhs - UINT8_C(64)) };
    return (zig_u128){ .hi = lhs.hi >> rhs, .lo = lhs.hi << (UINT8_C(64) - rhs) | lhs.lo >> rhs };
}

static inline zig_u128 zig_shl_u128(zig_u128 lhs, uint8_t rhs) {
    if (rhs == UINT8_C(0)) return lhs;
    if (rhs >= UINT8_C(64)) return (zig_u128){ .hi = lhs.lo << (rhs - UINT8_C(64)), .lo = zig_minInt_u64 };
    return (zig_u128){ .hi = lhs.hi << rhs | lhs.lo >> (UINT8_C(64) - rhs), .lo = lhs.lo << rhs };
}

static inline zig_i128 zig_shr_i128(zig_i128 lhs, uint8_t rhs) {
    if (rhs == UINT8_C(0)) return lhs;
    if (rhs >= UINT8_C(64)) return (zig_i128){ .hi = zig_shr_i64(lhs.hi, 63), .lo = zig_shr_i64(lhs.hi, (rhs - UINT8_C(64))) };
    return (zig_i128){ .hi = zig_shr_i64(lhs.hi, rhs), .lo = lhs.lo >> rhs | (uint64_t)lhs.hi << (UINT8_C(64) - rhs) };
}

static inline zig_i128 zig_shl_i128(zig_i128 lhs, uint8_t rhs) {
    if (rhs == UINT8_C(0)) return lhs;
    if (rhs >= UINT8_C(64)) return (zig_i128){ .hi = lhs.lo << (rhs - UINT8_C(64)), .lo = zig_minInt_u64 };
    return (zig_i128){ .hi = lhs.hi << rhs | lhs.lo >> (UINT8_C(64) - rhs), .lo = lhs.lo << rhs };
}

static inline zig_u128 zig_add_u128(zig_u128 lhs, zig_u128 rhs) {
    zig_u128 res;
    res.hi = lhs.hi + rhs.hi + zig_addo_u64(&res.lo, lhs.lo, rhs.lo, 64);
    return res;
}

static inline zig_i128 zig_add_i128(zig_i128 lhs, zig_i128 rhs) {
    zig_i128 res;
    res.hi = lhs.hi + rhs.hi + zig_addo_u64(&res.lo, lhs.lo, rhs.lo, 64);
    return res;
}

static inline zig_u128 zig_sub_u128(zig_u128 lhs, zig_u128 rhs) {
    zig_u128 res;
    res.hi = lhs.hi - rhs.hi - zig_subo_u64(&res.lo, lhs.lo, rhs.lo, 64);
    return res;
}

static inline zig_i128 zig_sub_i128(zig_i128 lhs, zig_i128 rhs) {
    zig_i128 res;
    res.hi = lhs.hi - rhs.hi - zig_subo_u64(&res.lo, lhs.lo, rhs.lo, 64);
    return res;
}

zig_extern zig_i128 __multi3(zig_i128 lhs, zig_i128 rhs);
static zig_i128 zig_mul_i128(zig_i128 lhs, zig_i128 rhs) {
    return __multi3(lhs, rhs);
}

static zig_u128 zig_mul_u128(zig_u128 lhs, zig_u128 rhs) {
    return zig_bitCast_u128(zig_mul_i128(zig_bitCast_i128(lhs), zig_bitCast_i128(rhs)));
}

zig_extern zig_u128 __udivti3(zig_u128 lhs, zig_u128 rhs);
static zig_u128 zig_div_trunc_u128(zig_u128 lhs, zig_u128 rhs) {
    return __udivti3(lhs, rhs);
}

zig_extern zig_i128 __divti3(zig_i128 lhs, zig_i128 rhs);
static zig_i128 zig_div_trunc_i128(zig_i128 lhs, zig_i128 rhs) {
    return __divti3(lhs, rhs);
}

zig_extern zig_u128 __umodti3(zig_u128 lhs, zig_u128 rhs);
static zig_u128 zig_rem_u128(zig_u128 lhs, zig_u128 rhs) {
    return __umodti3(lhs, rhs);
}

zig_extern zig_i128 __modti3(zig_i128 lhs, zig_i128 rhs);
static zig_i128 zig_rem_i128(zig_i128 lhs, zig_i128 rhs) {
    return __modti3(lhs, rhs);
}

#endif /* zig_has_int128 */

#define zig_div_floor_u128 zig_div_trunc_u128

static inline zig_i128 zig_div_floor_i128(zig_i128 lhs, zig_i128 rhs) {
    zig_i128 rem = zig_rem_i128(lhs, rhs);
    int64_t mask = zig_or_u64((uint64_t)zig_hi_i128(rem), zig_lo_i128(rem)) != UINT64_C(0)
        ? zig_shr_i64(zig_xor_i64(zig_hi_i128(lhs), zig_hi_i128(rhs)), UINT8_C(63)) : INT64_C(0);
    return zig_add_i128(zig_div_trunc_i128(lhs, rhs), zig_make_i128(mask, (uint64_t)mask));
}

#define zig_mod_u128 zig_rem_u128

static inline zig_i128 zig_mod_i128(zig_i128 lhs, zig_i128 rhs) {
    zig_i128 rem = zig_rem_i128(lhs, rhs);
    int64_t mask = zig_or_u64((uint64_t)zig_hi_i128(rem), zig_lo_i128(rem)) != UINT64_C(0)
        ? zig_shr_i64(zig_xor_i64(zig_hi_i128(lhs), zig_hi_i128(rhs)), UINT8_C(63)) : INT64_C(0);
    return zig_add_i128(rem, zig_and_i128(rhs, zig_make_i128(mask, (uint64_t)mask)));
}

static inline zig_u128 zig_min_u128(zig_u128 lhs, zig_u128 rhs) {
    return zig_cmp_u128(lhs, rhs) < INT32_C(0) ? lhs : rhs;
}

static inline zig_i128 zig_min_i128(zig_i128 lhs, zig_i128 rhs) {
    return zig_cmp_i128(lhs, rhs) < INT32_C(0) ? lhs : rhs;
}

static inline zig_u128 zig_max_u128(zig_u128 lhs, zig_u128 rhs) {
    return zig_cmp_u128(lhs, rhs) > INT32_C(0) ? lhs : rhs;
}

static inline zig_i128 zig_max_i128(zig_i128 lhs, zig_i128 rhs) {
    return zig_cmp_i128(lhs, rhs) > INT32_C(0) ? lhs : rhs;
}

static inline zig_u128 zig_wrap_u128(zig_u128 val, uint8_t bits) {
    return zig_and_u128(val, zig_maxInt_u(128, bits));
}

static inline zig_i128 zig_wrap_i128(zig_i128 val, uint8_t bits) {
    if (bits > UINT8_C(64)) return zig_make_i128(zig_wrap_i64(zig_hi_i128(val), bits - UINT8_C(64)), zig_lo_i128(val));
    int64_t lo = zig_wrap_i64((int64_t)zig_lo_i128(val), bits);
    return zig_make_i128(zig_shr_i64(lo, 63), (uint64_t)lo);
}

static inline zig_u128 zig_shlw_u128(zig_u128 lhs, uint8_t rhs, uint8_t bits) {
    return zig_wrap_u128(zig_shl_u128(lhs, rhs), bits);
}

static inline zig_i128 zig_shlw_i128(zig_i128 lhs, uint8_t rhs, uint8_t bits) {
    return zig_wrap_i128(zig_bitCast_i128(zig_shl_u128(zig_bitCast_u128(lhs), rhs)), bits);
}

static inline zig_u128 zig_addw_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    return zig_wrap_u128(zig_add_u128(lhs, rhs), bits);
}

static inline zig_i128 zig_addw_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    return zig_wrap_i128(zig_bitCast_i128(zig_add_u128(zig_bitCast_u128(lhs), zig_bitCast_u128(rhs))), bits);
}

static inline zig_u128 zig_subw_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    return zig_wrap_u128(zig_sub_u128(lhs, rhs), bits);
}

static inline zig_i128 zig_subw_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    return zig_wrap_i128(zig_bitCast_i128(zig_sub_u128(zig_bitCast_u128(lhs), zig_bitCast_u128(rhs))), bits);
}

static inline zig_u128 zig_mulw_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    return zig_wrap_u128(zig_mul_u128(lhs, rhs), bits);
}

static inline zig_i128 zig_mulw_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    return zig_wrap_i128(zig_bitCast_i128(zig_mul_u128(zig_bitCast_u128(lhs), zig_bitCast_u128(rhs))), bits);
}

static inline zig_u128 zig_abs_i128(zig_i128 val) {
    zig_i128 tmp = zig_shr_i128(val, 127);
    return zig_bitCast_u128(zig_sub_i128(zig_xor_i128(val, tmp), tmp));
}

#if zig_has_int128

static inline bool zig_addo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow)
    zig_u128 full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u128(full_res, bits);
    return overflow || full_res < zig_minInt_u(128, bits) || full_res > zig_maxInt_u(128, bits);
#else
    *res = zig_addw_u128(lhs, rhs, bits);
    return *res < lhs;
#endif
}

zig_extern zig_i128  __addoti4(zig_i128 lhs, zig_i128 rhs, int *overflow);
static inline bool zig_addo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
#if zig_has_builtin(add_overflow)
    zig_i128 full_res;
    bool overflow = __builtin_add_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    zig_i128 full_res =  __addoti4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i128(full_res, bits);
    return overflow || full_res < zig_minInt_i(128, bits) || full_res > zig_maxInt_i(128, bits);
}

static inline bool zig_subo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow)
    zig_u128 full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u128(full_res, bits);
    return overflow || full_res < zig_minInt_u(128, bits) || full_res > zig_maxInt_u(128, bits);
#else
    *res = zig_subw_u128(lhs, rhs, bits);
    return *res > lhs;
#endif
}

zig_extern zig_i128  __suboti4(zig_i128 lhs, zig_i128 rhs, int *overflow);
static inline bool zig_subo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
#if zig_has_builtin(sub_overflow)
    zig_i128 full_res;
    bool overflow = __builtin_sub_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    zig_i128 full_res = __suboti4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i128(full_res, bits);
    return overflow || full_res < zig_minInt_i(128, bits) || full_res > zig_maxInt_i(128, bits);
}

static inline bool zig_mulo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow)
    zig_u128 full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
    *res = zig_wrap_u128(full_res, bits);
    return overflow || full_res < zig_minInt_u(128, bits) || full_res > zig_maxInt_u(128, bits);
#else
    *res = zig_mulw_u128(lhs, rhs, bits);
    return rhs != zig_make_u128(0, 0) && lhs > zig_maxInt_u(128, bits) / rhs;
#endif
}

zig_extern zig_i128  __muloti4(zig_i128 lhs, zig_i128 rhs, int *overflow);
static inline bool zig_mulo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
#if zig_has_builtin(mul_overflow)
    zig_i128 full_res;
    bool overflow = __builtin_mul_overflow(lhs, rhs, &full_res);
#else
    int overflow_int;
    zig_i128 full_res =  __muloti4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0;
#endif
    *res = zig_wrap_i128(full_res, bits);
    return overflow || full_res < zig_minInt_i(128, bits) || full_res > zig_maxInt_i(128, bits);
}

#else /* zig_has_int128 */

static inline bool zig_addo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    uint64_t hi;
    bool overflow = zig_addo_u64(&hi, lhs.hi, rhs.hi, bits - 64);
    return overflow ^ zig_addo_u64(&res->hi, hi, zig_addo_u64(&res->lo, lhs.lo, rhs.lo, 64), bits - 64);
}

static inline bool zig_addo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    int64_t hi;
    bool overflow = zig_addo_i64(&hi, lhs.hi, rhs.hi, bits - 64);
    return overflow ^ zig_addo_i64(&res->hi, hi, zig_addo_u64(&res->lo, lhs.lo, rhs.lo, 64), bits - 64);
}

static inline bool zig_subo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    uint64_t hi;
    bool overflow = zig_subo_u64(&hi, lhs.hi, rhs.hi, bits - 64);
    return overflow ^ zig_subo_u64(&res->hi, hi, zig_subo_u64(&res->lo, lhs.lo, rhs.lo, 64), bits - 64);
}

static inline bool zig_subo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    int64_t hi;
    bool overflow = zig_subo_i64(&hi, lhs.hi, rhs.hi, bits - 64);
    return overflow ^ zig_subo_i64(&res->hi, hi, zig_subo_u64(&res->lo, lhs.lo, rhs.lo, 64), bits - 64);
}

static inline bool zig_mulo_u128(zig_u128 *res, zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    *res = zig_mulw_u128(lhs, rhs, bits);
    return zig_cmp_u128(*res, zig_make_u128(0, 0)) != INT32_C(0) &&
        zig_cmp_u128(lhs, zig_div_trunc_u128(zig_maxInt_u(128, bits), rhs)) > INT32_C(0);
}

zig_extern zig_i128 __muloti4(zig_i128 lhs, zig_i128 rhs, int *overflow);
static inline bool zig_mulo_i128(zig_i128 *res, zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    int overflow_int;
    zig_i128 full_res = __muloti4(lhs, rhs, &overflow_int);
    bool overflow = overflow_int != 0 ||
        zig_cmp_i128(full_res, zig_minInt_i(128, bits)) < INT32_C(0) ||
        zig_cmp_i128(full_res, zig_maxInt_i(128, bits)) > INT32_C(0);
    *res = zig_wrap_i128(full_res, bits);
    return overflow;
}

#endif /* zig_has_int128 */

static inline bool zig_shlo_u128(zig_u128 *res, zig_u128 lhs, uint8_t rhs, uint8_t bits) {
    *res = zig_shlw_u128(lhs, rhs, bits);
    return zig_cmp_u128(lhs, zig_shr_u128(zig_maxInt_u(128, bits), rhs)) > INT32_C(0);
}

static inline bool zig_shlo_i128(zig_i128 *res, zig_i128 lhs, uint8_t rhs, uint8_t bits) {
    *res = zig_shlw_i128(lhs, rhs, bits);
    zig_i128 mask = zig_bitCast_i128(zig_shl_u128(zig_maxInt_u128, bits - rhs - UINT8_C(1)));
    return zig_cmp_i128(zig_and_i128(lhs, mask), zig_make_i128(0, 0)) != INT32_C(0) &&
           zig_cmp_i128(zig_and_i128(lhs, mask), mask) != INT32_C(0);
}

static inline zig_u128 zig_shls_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    zig_u128 res;
    if (zig_cmp_u128(rhs, zig_make_u128(0, bits)) >= INT32_C(0))
        return zig_cmp_u128(lhs, zig_make_u128(0, 0)) != INT32_C(0) ? zig_maxInt_u(128, bits) : lhs;
    return zig_shlo_u128(&res, lhs, (uint8_t)zig_lo_u128(rhs), bits) ? zig_maxInt_u(128, bits) : res;
}

static inline zig_i128 zig_shls_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    zig_i128 res;
    if (zig_cmp_u128(zig_bitCast_u128(rhs), zig_make_u128(0, bits)) < INT32_C(0) && !zig_shlo_i128(&res, lhs, (uint8_t)zig_lo_i128(rhs), bits)) return res;
    return zig_cmp_i128(lhs, zig_make_i128(0, 0)) < INT32_C(0) ? zig_minInt_i(128, bits) : zig_maxInt_i(128, bits);
}

static inline zig_u128 zig_adds_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    zig_u128 res;
    return zig_addo_u128(&res, lhs, rhs, bits) ? zig_maxInt_u(128, bits) : res;
}

static inline zig_i128 zig_adds_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    zig_i128 res;
    if (!zig_addo_i128(&res, lhs, rhs, bits)) return res;
    return zig_cmp_i128(res, zig_make_i128(0, 0)) >= INT32_C(0) ? zig_minInt_i(128, bits) : zig_maxInt_i(128, bits);
}

static inline zig_u128 zig_subs_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    zig_u128 res;
    return zig_subo_u128(&res, lhs, rhs, bits) ? zig_minInt_u(128, bits) : res;
}

static inline zig_i128 zig_subs_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    zig_i128 res;
    if (!zig_subo_i128(&res, lhs, rhs, bits)) return res;
    return zig_cmp_i128(res, zig_make_i128(0, 0)) >= INT32_C(0) ? zig_minInt_i(128, bits) : zig_maxInt_i(128, bits);
}

static inline zig_u128 zig_muls_u128(zig_u128 lhs, zig_u128 rhs, uint8_t bits) {
    zig_u128 res;
    return zig_mulo_u128(&res, lhs, rhs, bits) ? zig_maxInt_u(128, bits) : res;
}

static inline zig_i128 zig_muls_i128(zig_i128 lhs, zig_i128 rhs, uint8_t bits) {
    zig_i128 res;
    if (!zig_mulo_i128(&res, lhs, rhs, bits)) return res;
    return zig_cmp_i128(zig_xor_i128(lhs, rhs), zig_make_i128(0, 0)) < INT32_C(0) ? zig_minInt_i(128, bits) : zig_maxInt_i(128, bits);
}

static inline uint8_t zig_clz_u128(zig_u128 val, uint8_t bits) {
    if (bits <= UINT8_C(64)) return zig_clz_u64(zig_lo_u128(val), bits);
    if (zig_hi_u128(val) != 0) return zig_clz_u64(zig_hi_u128(val), bits - UINT8_C(64));
    return zig_clz_u64(zig_lo_u128(val), UINT8_C(64)) + (bits - UINT8_C(64));
}

static inline uint8_t zig_clz_i128(zig_i128 val, uint8_t bits) {
    return zig_clz_u128(zig_bitCast_u128(val), bits);
}

static inline uint8_t zig_ctz_u128(zig_u128 val, uint8_t bits) {
    if (zig_lo_u128(val) != 0) return zig_ctz_u64(zig_lo_u128(val), UINT8_C(64));
    return zig_ctz_u64(zig_hi_u128(val), bits - UINT8_C(64)) + UINT8_C(64);
}

static inline uint8_t zig_ctz_i128(zig_i128 val, uint8_t bits) {
    return zig_ctz_u128(zig_bitCast_u128(val), bits);
}

static inline uint8_t zig_popcount_u128(zig_u128 val, uint8_t bits) {
    return zig_popcount_u64(zig_hi_u128(val), bits - UINT8_C(64)) +
           zig_popcount_u64(zig_lo_u128(val), UINT8_C(64));
}

static inline uint8_t zig_popcount_i128(zig_i128 val, uint8_t bits) {
    return zig_popcount_u128(zig_bitCast_u128(val), bits);
}

static inline zig_u128 zig_byte_swap_u128(zig_u128 val, uint8_t bits) {
    zig_u128 full_res;
#if zig_has_builtin(bswap128)
    full_res = __builtin_bswap128(val);
#else
    full_res = zig_make_u128(zig_byte_swap_u64(zig_lo_u128(val), UINT8_C(64)),
                           zig_byte_swap_u64(zig_hi_u128(val), UINT8_C(64)));
#endif
    return zig_shr_u128(full_res, UINT8_C(128) - bits);
}

static inline zig_i128 zig_byte_swap_i128(zig_i128 val, uint8_t bits) {
    return zig_bitCast_i128(zig_byte_swap_u128(zig_bitCast_u128(val), bits));
}

static inline zig_u128 zig_bit_reverse_u128(zig_u128 val, uint8_t bits) {
    return zig_shr_u128(zig_make_u128(zig_bit_reverse_u64(zig_lo_u128(val), UINT8_C(64)),
                                    zig_bit_reverse_u64(zig_hi_u128(val), UINT8_C(64))),
                        UINT8_C(128) - bits);
}

static inline zig_i128 zig_bit_reverse_i128(zig_i128 val, uint8_t bits) {
    return zig_bitCast_i128(zig_bit_reverse_u128(zig_bitCast_u128(val), bits));
}

/* ========================== Big Integer Support =========================== */

static inline uint16_t zig_int_bytes(uint16_t bits) {
    uint16_t bytes = (bits + CHAR_BIT - 1) / CHAR_BIT;
    uint16_t alignment = ZIG_TARGET_MAX_INT_ALIGNMENT;
    while (alignment / 2 >= bytes) alignment /= 2;
    return (bytes + alignment - 1) / alignment * alignment;
}

static inline int32_t zig_cmp_big(const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    bool do_signed = is_signed;
    uint16_t remaining_bytes = zig_int_bytes(bits);

#if zig_little_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
        int32_t limb_cmp;

#if zig_little_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        if (do_signed) {
            zig_i128 lhs_limb;
            zig_i128 rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_cmp = zig_cmp_i128(lhs_limb, rhs_limb);
            do_signed = false;
        } else {
            zig_u128 lhs_limb;
            zig_u128 rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_cmp = zig_cmp_u128(lhs_limb, rhs_limb);
        }

        if (limb_cmp != 0) return limb_cmp;
        remaining_bytes -= 128 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        if (do_signed) {
            int64_t lhs_limb;
            int64_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
            do_signed = false;
        } else {
            uint64_t lhs_limb;
            uint64_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
        }

        remaining_bytes -= 64 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        if (do_signed) {
            int32_t lhs_limb;
            int32_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
            do_signed = false;
        } else {
            uint32_t lhs_limb;
            uint32_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
        }

        remaining_bytes -= 32 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        if (do_signed) {
            int16_t lhs_limb;
            int16_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
            do_signed = false;
        } else {
            uint16_t lhs_limb;
            uint16_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
        }

        remaining_bytes -= 16 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        if (do_signed) {
            int8_t lhs_limb;
            int8_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
            do_signed = false;
        } else {
            uint8_t lhs_limb;
            uint8_t rhs_limb;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            if (lhs_limb != rhs_limb) return (lhs_limb > rhs_limb) - (lhs_limb < rhs_limb);
        }

        remaining_bytes -= 8 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return 0;
}

static inline void zig_and_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    uint8_t *res_bytes = res;
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    (void)is_signed;

    while (remaining_bytes >= 128 / CHAR_BIT) {
        zig_u128 res_limb;
        zig_u128 lhs_limb;
        zig_u128 rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_and_u128(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 128 / CHAR_BIT;
        byte_offset += 128 / CHAR_BIT;
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
        uint64_t res_limb;
        uint64_t lhs_limb;
        uint64_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_and_u64(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 64 / CHAR_BIT;
        byte_offset += 64 / CHAR_BIT;
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
        uint32_t res_limb;
        uint32_t lhs_limb;
        uint32_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_and_u32(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 32 / CHAR_BIT;
        byte_offset += 32 / CHAR_BIT;
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
        uint16_t res_limb;
        uint16_t lhs_limb;
        uint16_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_and_u16(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 16 / CHAR_BIT;
        byte_offset += 16 / CHAR_BIT;
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
        uint8_t res_limb;
        uint8_t lhs_limb;
        uint8_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_and_u8(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 8 / CHAR_BIT;
        byte_offset += 8 / CHAR_BIT;
    }
}

static inline void zig_or_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    uint8_t *res_bytes = res;
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    (void)is_signed;

    while (remaining_bytes >= 128 / CHAR_BIT) {
        zig_u128 res_limb;
        zig_u128 lhs_limb;
        zig_u128 rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_or_u128(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 128 / CHAR_BIT;
        byte_offset += 128 / CHAR_BIT;
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
        uint64_t res_limb;
        uint64_t lhs_limb;
        uint64_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_or_u64(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 64 / CHAR_BIT;
        byte_offset += 64 / CHAR_BIT;
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
        uint32_t res_limb;
        uint32_t lhs_limb;
        uint32_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_or_u32(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 32 / CHAR_BIT;
        byte_offset += 32 / CHAR_BIT;
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
        uint16_t res_limb;
        uint16_t lhs_limb;
        uint16_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_or_u16(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 16 / CHAR_BIT;
        byte_offset += 16 / CHAR_BIT;
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
        uint8_t res_limb;
        uint8_t lhs_limb;
        uint8_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_or_u8(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 8 / CHAR_BIT;
        byte_offset += 8 / CHAR_BIT;
    }
}

static inline void zig_xor_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    uint8_t *res_bytes = res;
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    (void)is_signed;

    while (remaining_bytes >= 128 / CHAR_BIT) {
        zig_u128 res_limb;
        zig_u128 lhs_limb;
        zig_u128 rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_xor_u128(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 128 / CHAR_BIT;
        byte_offset += 128 / CHAR_BIT;
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
        uint64_t res_limb;
        uint64_t lhs_limb;
        uint64_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_xor_u64(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 64 / CHAR_BIT;
        byte_offset += 64 / CHAR_BIT;
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
        uint32_t res_limb;
        uint32_t lhs_limb;
        uint32_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_xor_u32(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 32 / CHAR_BIT;
        byte_offset += 32 / CHAR_BIT;
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
        uint16_t res_limb;
        uint16_t lhs_limb;
        uint16_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_xor_u16(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 16 / CHAR_BIT;
        byte_offset += 16 / CHAR_BIT;
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
        uint8_t res_limb;
        uint8_t lhs_limb;
        uint8_t rhs_limb;

        memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
        memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
        res_limb = zig_xor_u8(lhs_limb, rhs_limb);
        memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));

        remaining_bytes -= 8 / CHAR_BIT;
        byte_offset += 8 / CHAR_BIT;
    }
}

static inline bool zig_addo_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    uint8_t *res_bytes = res;
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    uint16_t top_bits = remaining_bytes * 8 - bits;
    bool overflow = false;

#if zig_big_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
        uint16_t limb_bits = 128 - (remaining_bytes == 128 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        if (remaining_bytes == 128 / CHAR_BIT && is_signed) {
            zig_i128 res_limb;
            zig_i128 tmp_limb;
            zig_i128 lhs_limb;
            zig_i128 rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_i128(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_i128(&res_limb, tmp_limb, zig_make_i128(INT64_C(0), overflow ? UINT64_C(1) : UINT64_C(0)), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            zig_u128 res_limb;
            zig_u128 tmp_limb;
            zig_u128 lhs_limb;
            zig_u128 rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_u128(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_u128(&res_limb, tmp_limb, zig_make_u128(UINT64_C(0), overflow ? UINT64_C(1) : UINT64_C(0)), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 128 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
        uint16_t limb_bits = 64 - (remaining_bytes == 64 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        if (remaining_bytes == 64 / CHAR_BIT && is_signed) {
            int64_t res_limb;
            int64_t tmp_limb;
            int64_t lhs_limb;
            int64_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_i64(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_i64(&res_limb, tmp_limb, overflow ? INT64_C(1) : INT64_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint64_t res_limb;
            uint64_t tmp_limb;
            uint64_t lhs_limb;
            uint64_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_u64(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_u64(&res_limb, tmp_limb, overflow ? UINT64_C(1) : UINT64_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 64 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
        uint16_t limb_bits = 32 - (remaining_bytes == 32 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        if (remaining_bytes == 32 / CHAR_BIT && is_signed) {
            int32_t res_limb;
            int32_t tmp_limb;
            int32_t lhs_limb;
            int32_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_i32(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_i32(&res_limb, tmp_limb, overflow ? INT32_C(1) : INT32_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint32_t res_limb;
            uint32_t tmp_limb;
            uint32_t lhs_limb;
            uint32_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_u32(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_u32(&res_limb, tmp_limb, overflow ? UINT32_C(1) : UINT32_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 32 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
        uint16_t limb_bits = 16 - (remaining_bytes == 16 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        if (remaining_bytes == 16 / CHAR_BIT && is_signed) {
            int16_t res_limb;
            int16_t tmp_limb;
            int16_t lhs_limb;
            int16_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_i16(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_i16(&res_limb, tmp_limb, overflow ? INT16_C(1) : INT16_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint16_t res_limb;
            uint16_t tmp_limb;
            uint16_t lhs_limb;
            uint16_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_u16(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_u16(&res_limb, tmp_limb, overflow ? UINT16_C(1) : UINT16_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 16 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
        uint16_t limb_bits = 8 - (remaining_bytes == 8 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        if (remaining_bytes == 8 / CHAR_BIT && is_signed) {
            int8_t res_limb;
            int8_t tmp_limb;
            int8_t lhs_limb;
            int8_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_i8(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_i8(&res_limb, tmp_limb, overflow ? INT8_C(1) : INT8_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint8_t res_limb;
            uint8_t tmp_limb;
            uint8_t lhs_limb;
            uint8_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_addo_u8(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_addo_u8(&res_limb, tmp_limb, overflow ? UINT8_C(1) : UINT8_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 8 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return overflow;
}

static inline bool zig_subo_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    uint8_t *res_bytes = res;
    const uint8_t *lhs_bytes = lhs;
    const uint8_t *rhs_bytes = rhs;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    uint16_t top_bits = remaining_bytes * 8 - bits;
    bool overflow = false;

#if zig_big_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
        uint16_t limb_bits = 128 - (remaining_bytes == 128 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        if (remaining_bytes == 128 / CHAR_BIT && is_signed) {
            zig_i128 res_limb;
            zig_i128 tmp_limb;
            zig_i128 lhs_limb;
            zig_i128 rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_i128(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_i128(&res_limb, tmp_limb, zig_make_i128(INT64_C(0), overflow ? UINT64_C(1) : UINT64_C(0)), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            zig_u128 res_limb;
            zig_u128 tmp_limb;
            zig_u128 lhs_limb;
            zig_u128 rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_u128(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_u128(&res_limb, tmp_limb, zig_make_u128(UINT64_C(0), overflow ? UINT64_C(1) : UINT64_C(0)), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 128 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
        uint16_t limb_bits = 64 - (remaining_bytes == 64 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        if (remaining_bytes == 64 / CHAR_BIT && is_signed) {
            int64_t res_limb;
            int64_t tmp_limb;
            int64_t lhs_limb;
            int64_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_i64(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_i64(&res_limb, tmp_limb, overflow ? INT64_C(1) : INT64_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint64_t res_limb;
            uint64_t tmp_limb;
            uint64_t lhs_limb;
            uint64_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_u64(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_u64(&res_limb, tmp_limb, overflow ? UINT64_C(1) : UINT64_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 64 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
        uint16_t limb_bits = 32 - (remaining_bytes == 32 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        if (remaining_bytes == 32 / CHAR_BIT && is_signed) {
            int32_t res_limb;
            int32_t tmp_limb;
            int32_t lhs_limb;
            int32_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_i32(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_i32(&res_limb, tmp_limb, overflow ? INT32_C(1) : INT32_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint32_t res_limb;
            uint32_t tmp_limb;
            uint32_t lhs_limb;
            uint32_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_u32(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_u32(&res_limb, tmp_limb, overflow ? UINT32_C(1) : UINT32_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 32 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
        uint16_t limb_bits = 16 - (remaining_bytes == 16 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        if (remaining_bytes == 16 / CHAR_BIT && is_signed) {
            int16_t res_limb;
            int16_t tmp_limb;
            int16_t lhs_limb;
            int16_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_i16(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_i16(&res_limb, tmp_limb, overflow ? INT16_C(1) : INT16_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint16_t res_limb;
            uint16_t tmp_limb;
            uint16_t lhs_limb;
            uint16_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_u16(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_u16(&res_limb, tmp_limb, overflow ? UINT16_C(1) : UINT16_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 16 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
        uint16_t limb_bits = 8 - (remaining_bytes == 8 / CHAR_BIT ? top_bits : 0);

#if zig_big_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        if (remaining_bytes == 8 / CHAR_BIT && is_signed) {
            int8_t res_limb;
            int8_t tmp_limb;
            int8_t lhs_limb;
            int8_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_i8(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_i8(&res_limb, tmp_limb, overflow ? INT8_C(1) : INT8_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        } else {
            uint8_t res_limb;
            uint8_t tmp_limb;
            uint8_t lhs_limb;
            uint8_t rhs_limb;
            bool limb_overflow;

            memcpy(&lhs_limb, &lhs_bytes[byte_offset], sizeof(lhs_limb));
            memcpy(&rhs_limb, &rhs_bytes[byte_offset], sizeof(rhs_limb));
            limb_overflow = zig_subo_u8(&tmp_limb, lhs_limb, rhs_limb, limb_bits);
            overflow = limb_overflow ^ zig_subo_u8(&res_limb, tmp_limb, overflow ? UINT8_C(1) : UINT8_C(0), limb_bits);
            memcpy(&res_bytes[byte_offset], &res_limb, sizeof(res_limb));
        }

        remaining_bytes -= 8 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return overflow;
}

static inline void zig_addw_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    (void)zig_addo_big(res, lhs, rhs, is_signed, bits);
}

static inline void zig_subw_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    (void)zig_subo_big(res, lhs, rhs, is_signed, bits);
}

zig_extern void __udivei4(uint32_t *res, const uint32_t *lhs, const uint32_t *rhs, uintptr_t bits);
static inline void zig_div_trunc_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    if (!is_signed) {
        __udivei4(res, lhs, rhs, bits);
        return;
    }

    zig_trap();
}

static inline void zig_div_floor_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    if (!is_signed) {
        zig_div_trunc_big(res, lhs, rhs, is_signed, bits);
        return;
    }

    zig_trap();
}

zig_extern void __umodei4(uint32_t *res, const uint32_t *lhs, const uint32_t *rhs, uintptr_t bits);
static inline void zig_rem_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    if (!is_signed) {
        __umodei4(res, lhs, rhs, bits);
        return;
    }

    zig_trap();
}

static inline void zig_mod_big(void *res, const void *lhs, const void *rhs, bool is_signed, uint16_t bits) {
    if (!is_signed) {
        zig_rem_big(res, lhs, rhs, is_signed, bits);
        return;
    }

    zig_trap();
}

static inline uint16_t zig_clz_big(const void *val, bool is_signed, uint16_t bits) {
    const uint8_t *val_bytes = val;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    uint16_t skip_bits = remaining_bytes * 8 - bits;
    uint16_t total_lz = 0;
    uint16_t limb_lz;
    (void)is_signed;

#if zig_little_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        {
            zig_u128 val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_lz = zig_clz_u128(val_limb, 128 - skip_bits);
        }

        total_lz += limb_lz;
        if (limb_lz < 128 - skip_bits) return total_lz;
        skip_bits = 0;
        remaining_bytes -= 128 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        {
            uint64_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_lz = zig_clz_u64(val_limb, 64 - skip_bits);
        }

        total_lz += limb_lz;
        if (limb_lz < 64 - skip_bits) return total_lz;
        skip_bits = 0;
        remaining_bytes -= 64 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        {
            uint32_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_lz = zig_clz_u32(val_limb, 32 - skip_bits);
        }

        total_lz += limb_lz;
        if (limb_lz < 32 - skip_bits) return total_lz;
        skip_bits = 0;
        remaining_bytes -= 32 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        {
            uint16_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_lz = zig_clz_u16(val_limb, 16 - skip_bits);
        }

        total_lz += limb_lz;
        if (limb_lz < 16 - skip_bits) return total_lz;
        skip_bits = 0;
        remaining_bytes -= 16 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
#if zig_little_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        {
            uint8_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_lz = zig_clz_u8(val_limb, 8 - skip_bits);
        }

        total_lz += limb_lz;
        if (limb_lz < 8 - skip_bits) return total_lz;
        skip_bits = 0;
        remaining_bytes -= 8 / CHAR_BIT;

#if zig_big_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return total_lz;
}

static inline uint16_t zig_ctz_big(const void *val, bool is_signed, uint16_t bits) {
    const uint8_t *val_bytes = val;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    uint16_t total_tz = 0;
    uint16_t limb_tz;
    (void)is_signed;

#if zig_big_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        {
            zig_u128 val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_tz = zig_ctz_u128(val_limb, 128);
        }

        total_tz += limb_tz;
        if (limb_tz < 128) return total_tz;
        remaining_bytes -= 128 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        {
            uint64_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_tz = zig_ctz_u64(val_limb, 64);
        }

        total_tz += limb_tz;
        if (limb_tz < 64) return total_tz;
        remaining_bytes -= 64 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        {
            uint32_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_tz = zig_ctz_u32(val_limb, 32);
        }

        total_tz += limb_tz;
        if (limb_tz < 32) return total_tz;
        remaining_bytes -= 32 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        {
            uint16_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_tz = zig_ctz_u16(val_limb, 16);
        }

        total_tz += limb_tz;
        if (limb_tz < 16) return total_tz;
        remaining_bytes -= 16 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        {
            uint8_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            limb_tz = zig_ctz_u8(val_limb, 8);
        }

        total_tz += limb_tz;
        if (limb_tz < 8) return total_tz;
        remaining_bytes -= 8 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return total_tz;
}

static inline uint16_t zig_popcount_big(const void *val, bool is_signed, uint16_t bits) {
    const uint8_t *val_bytes = val;
    uint16_t byte_offset = 0;
    uint16_t remaining_bytes = zig_int_bytes(bits);
    uint16_t total_pc = 0;
    (void)is_signed;

#if zig_big_endian
    byte_offset = remaining_bytes;
#endif

    while (remaining_bytes >= 128 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 128 / CHAR_BIT;
#endif

        {
            zig_u128 val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            total_pc += zig_popcount_u128(val_limb, 128);
        }

        remaining_bytes -= 128 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 128 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 64 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 64 / CHAR_BIT;
#endif

        {
            uint64_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            total_pc += zig_popcount_u64(val_limb, 64);
        }

        remaining_bytes -= 64 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 64 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 32 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 32 / CHAR_BIT;
#endif

        {
            uint32_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            total_pc += zig_popcount_u32(val_limb, 32);
        }

        remaining_bytes -= 32 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 32 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 16 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 16 / CHAR_BIT;
#endif

        {
            uint16_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            total_pc = zig_popcount_u16(val_limb, 16);
        }

        remaining_bytes -= 16 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 16 / CHAR_BIT;
#endif
    }

    while (remaining_bytes >= 8 / CHAR_BIT) {
#if zig_big_endian
        byte_offset -= 8 / CHAR_BIT;
#endif

        {
            uint8_t val_limb;

            memcpy(&val_limb, &val_bytes[byte_offset], sizeof(val_limb));
            total_pc = zig_popcount_u8(val_limb, 8);
        }

        remaining_bytes -= 8 / CHAR_BIT;

#if zig_little_endian
        byte_offset += 8 / CHAR_BIT;
#endif
    }

    return total_pc;
}

/* ========================= Floating Point Support ========================= */

#if _MSC_VER
float __cdecl nanf(char const* input);
double __cdecl nan(char const* input);
long double __cdecl nanl(char const* input);

#define zig_msvc_flt_inf ((double)(1e+300 * 1e+300))
#define zig_msvc_flt_inff ((float)(1e+300 * 1e+300))
#define zig_msvc_flt_infl ((long double)(1e+300 * 1e+300))
#define zig_msvc_flt_nan ((double)(zig_msvc_flt_inf * 0.f))
#define zig_msvc_flt_nanf ((float)(zig_msvc_flt_inf * 0.f))
#define zig_msvc_flt_nanl ((long double)(zig_msvc_flt_inf * 0.f))
#define __builtin_nan(str) nan(str)
#define __builtin_nanf(str) nanf(str)
#define __builtin_nanl(str) nanl(str)
#define __builtin_inf() zig_msvc_flt_inf
#define __builtin_inff() zig_msvc_flt_inff
#define __builtin_infl() zig_msvc_flt_infl
#endif

#if (zig_has_builtin(nan) && zig_has_builtin(nans) && zig_has_builtin(inf)) || defined(zig_gnuc)
#define  zig_make_special_f16(sign, name, arg, repr) sign zig_make_f16 (__builtin_##name, )(arg)
#define  zig_make_special_f32(sign, name, arg, repr) sign zig_make_f32 (__builtin_##name, )(arg)
#define  zig_make_special_f64(sign, name, arg, repr) sign zig_make_f64 (__builtin_##name, )(arg)
#define  zig_make_special_f80(sign, name, arg, repr) sign zig_make_f80 (__builtin_##name, )(arg)
#define zig_make_special_f128(sign, name, arg, repr) sign zig_make_f128(__builtin_##name, )(arg)
#else
#define  zig_make_special_f16(sign, name, arg, repr) zig_bitCast_f16 (repr)
#define  zig_make_special_f32(sign, name, arg, repr) zig_bitCast_f32 (repr)
#define  zig_make_special_f64(sign, name, arg, repr) zig_bitCast_f64 (repr)
#define  zig_make_special_f80(sign, name, arg, repr) zig_bitCast_f80 (repr)
#define zig_make_special_f128(sign, name, arg, repr) zig_bitCast_f128(repr)
#endif

#define zig_has_f16 1
#define zig_libc_name_f16(name) __##name##h
#define zig_init_special_f16(sign, name, arg, repr) zig_make_special_f16(sign, name, arg, repr)
#if FLT_MANT_DIG == 11
typedef float zig_f16;
#define zig_make_f16(fp, repr) fp##f
#elif DBL_MANT_DIG == 11
typedef double zig_f16;
#define zig_make_f16(fp, repr) fp
#elif LDBL_MANT_DIG == 11
typedef long double zig_f16;
#define zig_make_f16(fp, repr) fp##l
#elif FLT16_MANT_DIG == 11 && (zig_has_builtin(inff16) || defined(zig_gnuc))
typedef _Float16 zig_f16;
#define zig_make_f16(fp, repr) fp##f16
#elif defined(__SIZEOF_FP16__)
typedef __fp16 zig_f16;
#define zig_make_f16(fp, repr) fp##f16
#else
#undef zig_has_f16
#define zig_has_f16 0
#define zig_repr_f16 u16
typedef uint16_t zig_f16;
#define zig_make_f16(fp, repr) repr
#undef zig_make_special_f16
#define zig_make_special_f16(sign, name, arg, repr) repr
#undef zig_init_special_f16
#define zig_init_special_f16(sign, name, arg, repr) repr
#endif
#if __APPLE__ && (defined(__i386__) || defined(__x86_64__))
typedef uint16_t zig_compiler_rt_f16;
#else
typedef zig_f16 zig_compiler_rt_f16;
#endif

#define zig_has_f32 1
#define zig_libc_name_f32(name) name##f
#if _MSC_VER
#define zig_init_special_f32(sign, name, arg, repr) sign zig_make_f32(zig_msvc_flt_##name, )
#else
#define zig_init_special_f32(sign, name, arg, repr) zig_make_special_f32(sign, name, arg, repr)
#endif
#if FLT_MANT_DIG == 24
typedef float zig_f32;
#define zig_make_f32(fp, repr) fp##f
#elif DBL_MANT_DIG == 24
typedef double zig_f32;
#define zig_make_f32(fp, repr) fp
#elif LDBL_MANT_DIG == 24
typedef long double zig_f32;
#define zig_make_f32(fp, repr) fp##l
#elif FLT32_MANT_DIG == 24
typedef _Float32 zig_f32;
#define zig_make_f32(fp, repr) fp##f32
#else
#undef zig_has_f32
#define zig_has_f32 0
#define zig_repr_f32 u32
ypedef uint32_t zig_f32;
#define zig_make_f32(fp, repr) repr
#undef zig_make_special_f32
#define zig_make_special_f32(sign, name, arg, repr) repr
#undef zig_init_special_f32
#define zig_init_special_f32(sign, name, arg, repr) repr
#endif

#define zig_has_f64 1
#define zig_libc_name_f64(name) name
#if _MSC_VER
#define zig_init_special_f64(sign, name, arg, repr) sign zig_make_f64(zig_msvc_flt_##name, )
#else
#define zig_init_special_f64(sign, name, arg, repr) zig_make_special_f64(sign, name, arg, repr)
#endif
#if FLT_MANT_DIG == 53
typedef float zig_f64;
#define zig_make_f64(fp, repr) fp##f
#elif DBL_MANT_DIG == 53
typedef double zig_f64;
#define zig_make_f64(fp, repr) fp
#elif LDBL_MANT_DIG == 53
typedef long double zig_f64;
#define zig_make_f64(fp, repr) fp##l
#elif FLT64_MANT_DIG == 53
typedef _Float64 zig_f64;
#define zig_make_f64(fp, repr) fp##f64
#elif FLT32X_MANT_DIG == 53
typedef _Float32x zig_f64;
#define zig_make_f64(fp, repr) fp##f32x
#else
#undef zig_has_f64
#define zig_has_f64 0
#define zig_repr_f64 u64
typedef uint64_t zig_f64;
#define zig_make_f64(fp, repr) repr
#undef zig_make_special_f64
#define zig_make_special_f64(sign, name, arg, repr) repr
#undef zig_init_special_f64
#define zig_init_special_f64(sign, name, arg, repr) repr
#endif

#define zig_has_f80 1
#define zig_libc_name_f80(name) __##name##x
#define zig_init_special_f80(sign, name, arg, repr) zig_make_special_f80(sign, name, arg, repr)
#if FLT_MANT_DIG == 64
typedef float zig_f80;
#define zig_make_f80(fp, repr) fp##f
#elif DBL_MANT_DIG == 64
typedef double zig_f80;
#define zig_make_f80(fp, repr) fp
#elif LDBL_MANT_DIG == 64
typedef long double zig_f80;
#define zig_make_f80(fp, repr) fp##l
#elif FLT80_MANT_DIG == 64
typedef _Float80 zig_f80;
#define zig_make_f80(fp, repr) fp##f80
#elif FLT64X_MANT_DIG == 64
typedef _Float64x zig_f80;
#define zig_make_f80(fp, repr) fp##f64x
#elif defined(__SIZEOF_FLOAT80__)
typedef __float80 zig_f80;
#define zig_make_f80(fp, repr) fp##l
#else
#undef zig_has_f80
#define zig_has_f80 0
#define zig_repr_f80 u128
typedef zig_u128 zig_f80;
#define zig_make_f80(fp, repr) repr
#undef zig_make_special_f80
#define zig_make_special_f80(sign, name, arg, repr) repr
#undef zig_init_special_f80
#define zig_init_special_f80(sign, name, arg, repr) repr
#endif

#define zig_has_f128 1
#define zig_libc_name_f128(name) name##q
#define zig_init_special_f128(sign, name, arg, repr) zig_make_special_f128(sign, name, arg, repr)
#if FLT_MANT_DIG == 113
typedef float zig_f128;
#define zig_make_f128(fp, repr) fp##f
#elif DBL_MANT_DIG == 113
typedef double zig_f128;
#define zig_make_f128(fp, repr) fp
#elif LDBL_MANT_DIG == 113
typedef long double zig_f128;
#define zig_make_f128(fp, repr) fp##l
#elif FLT128_MANT_DIG == 113
typedef _Float128 zig_f128;
#define zig_make_f128(fp, repr) fp##f128
#elif FLT64X_MANT_DIG == 113
typedef _Float64x zig_f128;
#define zig_make_f128(fp, repr) fp##f64x
#elif defined(__SIZEOF_FLOAT128__)
typedef __float128 zig_f128;
#define zig_make_f128(fp, repr) fp##q
#undef zig_make_special_f128
#define zig_make_special_f128(sign, name, arg, repr) sign __builtin_##name##f128(arg)
#else
#undef zig_has_f128
#define zig_has_f128 0
#undef zig_make_special_f128
#undef zig_init_special_f128
#if __APPLE__ || defined(__aarch64__)
typedef __attribute__((__vector_size__(2 * sizeof(uint64_t)))) uint64_t zig_v2u64;
zig_basic_operator(zig_v2u64, xor_v2u64, ^)
#define zig_repr_f128 v2u64
typedef zig_v2u64 zig_f128;
#define zig_make_f128_zig_make_u128(hi, lo) (zig_f128){ lo, hi }
#define zig_make_f128_zig_init_u128 zig_make_f128_zig_make_u128
#define zig_make_f128(fp, repr) zig_make_f128_##repr
#define zig_make_special_f128(sign, name, arg, repr) zig_make_f128_##repr
#define zig_init_special_f128(sign, name, arg, repr) zig_make_f128_##repr
#else
#define zig_repr_f128 u128
typedef zig_u128 zig_f128;
#define zig_make_f128(fp, repr) repr
#define zig_make_special_f128(sign, name, arg, repr) repr
#define zig_init_special_f128(sign, name, arg, repr) repr
#endif
#endif

#if !_MSC_VER && defined(ZIG_TARGET_ABI_MSVC)
/* Emulate msvc abi on a gnu compiler */
typedef zig_f64 zig_c_longdouble;
#elif _MSC_VER && !defined(ZIG_TARGET_ABI_MSVC)
/* Emulate gnu abi on an msvc compiler */
typedef zig_f128 zig_c_longdouble;
#else
/* Target and compiler abi match */
typedef long double zig_c_longdouble;
#endif

#define zig_bitCast_float(Type, ReprType) \
    static inline zig_##Type zig_bitCast_##Type(ReprType repr) { \
        zig_##Type result; \
        memcpy(&result, &repr, sizeof(result)); \
        return result; \
    }
zig_bitCast_float(f16, uint16_t)
zig_bitCast_float(f32, uint32_t)
zig_bitCast_float(f64, uint64_t)
zig_bitCast_float(f80, zig_u128)
zig_bitCast_float(f128, zig_u128)

#define zig_convert_builtin(ExternResType, ResType, operation, ExternArgType, ArgType, version) \
    zig_extern ExternResType zig_expand_concat(zig_expand_concat(zig_expand_concat(__##operation, \
        zig_compiler_rt_abbrev_##ArgType), zig_compiler_rt_abbrev_##ResType), version)(ExternArgType); \
    static inline ResType zig_expand_concat(zig_expand_concat(zig_##operation, \
        zig_compiler_rt_abbrev_##ArgType), zig_compiler_rt_abbrev_##ResType)(ArgType arg) { \
        ResType res; \
        ExternResType extern_res; \
        ExternArgType extern_arg; \
        memcpy(&extern_arg, &arg, sizeof(extern_arg)); \
        extern_res = zig_expand_concat(zig_expand_concat(zig_expand_concat(__##operation, \
            zig_compiler_rt_abbrev_##ArgType), zig_compiler_rt_abbrev_##ResType), version)(extern_arg); \
        memcpy(&res, &extern_res, sizeof(res)); \
        return extern_res; \
    }
zig_convert_builtin(zig_compiler_rt_f16, zig_f16,   trunc, zig_f32,             zig_f32,  2)
zig_convert_builtin(zig_compiler_rt_f16, zig_f16,   trunc, zig_f64,             zig_f64,  2)
zig_convert_builtin(zig_f16,             zig_f16,   trunc, zig_f80,             zig_f80,  2)
zig_convert_builtin(zig_f16,             zig_f16,   trunc, zig_f128,            zig_f128, 2)
zig_convert_builtin(zig_f32,             zig_f32,  extend, zig_compiler_rt_f16, zig_f16,  2)
zig_convert_builtin(zig_f32,             zig_f32,   trunc, zig_f80,             zig_f80,  2)
zig_convert_builtin(zig_f32,             zig_f32,   trunc, zig_f128,            zig_f128, 2)
zig_convert_builtin(zig_f64,             zig_f64,  extend, zig_compiler_rt_f16, zig_f16,  2)
zig_convert_builtin(zig_f64,             zig_f64,   trunc, zig_f80,             zig_f80,  2)
zig_convert_builtin(zig_f64,             zig_f64,   trunc, zig_f128,            zig_f128, 2)
zig_convert_builtin(zig_f80,             zig_f80,  extend, zig_f16,             zig_f16,  2)
zig_convert_builtin(zig_f80,             zig_f80,  extend, zig_f32,             zig_f32,  2)
zig_convert_builtin(zig_f80,             zig_f80,  extend, zig_f64,             zig_f64,  2)
zig_convert_builtin(zig_f80,             zig_f80,   trunc, zig_f128,            zig_f128, 2)
zig_convert_builtin(zig_f128,            zig_f128, extend, zig_f16,             zig_f16,  2)
zig_convert_builtin(zig_f128,            zig_f128, extend, zig_f32,             zig_f32,  2)
zig_convert_builtin(zig_f128,            zig_f128, extend, zig_f64,             zig_f64,  2)
zig_convert_builtin(zig_f128,            zig_f128, extend, zig_f80,             zig_f80,  2)

#ifdef __ARM_EABI__

zig_extern zig_callconv(pcs("aapcs")) zig_f32 __aeabi_d2f(zig_f64);
static inline zig_f32 zig_truncdfsf(zig_f64 arg) { return __aeabi_d2f(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f64 __aeabi_f2d(zig_f32);
static inline zig_f64 zig_extendsfdf(zig_f32 arg) { return __aeabi_f2d(arg); }

#else /* __ARM_EABI__ */

zig_convert_builtin(zig_f32,             zig_f32,   trunc, zig_f64,             zig_f64,  2)
zig_convert_builtin(zig_f64,             zig_f64,  extend, zig_f32,             zig_f32,  2)

#endif /* __ARM_EABI__ */

#define zig_float_negate_builtin_0(w, c, sb) \
    zig_expand_concat(zig_xor_, zig_repr_f##w)(arg, zig_make_f##w(-0x0.0p0, c sb))
#define zig_float_negate_builtin_1(w, c, sb) -arg
#define zig_float_negate_builtin(w, c, sb) \
    static inline zig_f##w zig_neg_f##w(zig_f##w arg) { \
        return zig_expand_concat(zig_float_negate_builtin_, zig_has_f##w)(w, c, sb); \
    }
zig_float_negate_builtin(16,               ,  UINT16_C(1) << 15              )
zig_float_negate_builtin(32,               ,  UINT32_C(1) << 31              )
zig_float_negate_builtin(64,               ,  UINT64_C(1) << 63              )
zig_float_negate_builtin(80,  zig_make_u128, (UINT64_C(1) << 15, UINT64_C(0)))
zig_float_negate_builtin(128, zig_make_u128, (UINT64_C(1) << 63, UINT64_C(0)))

#define zig_float_less_builtin_0(Type, operation) \
    zig_extern int32_t zig_expand_concat(zig_expand_concat(__##operation, \
        zig_compiler_rt_abbrev_zig_##Type), 2)(zig_##Type, zig_##Type); \
    static inline int32_t zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return zig_expand_concat(zig_expand_concat(__##operation, zig_compiler_rt_abbrev_zig_##Type), 2)(lhs, rhs); \
    }
#define zig_float_less_builtin_1(Type, operation) \
    static inline int32_t zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return (!(lhs <= rhs) - (lhs < rhs)); \
    }

#define zig_float_greater_builtin_0(Type, operation) \
    zig_float_less_builtin_0(Type, operation)
#define zig_float_greater_builtin_1(Type, operation) \
    static inline int32_t zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return ((lhs > rhs) - !(lhs >= rhs)); \
    }

#define zig_float_binary_builtin_0(Type, operation, operator) \
    zig_extern zig_##Type zig_expand_concat(zig_expand_concat(__##operation, \
        zig_compiler_rt_abbrev_zig_##Type), 3)(zig_##Type, zig_##Type); \
    static inline zig_##Type zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return zig_expand_concat(zig_expand_concat(__##operation, zig_compiler_rt_abbrev_zig_##Type), 3)(lhs, rhs); \
    }
#define zig_float_binary_builtin_1(Type, operation, operator) \
    static inline zig_##Type zig_##operation##_##Type(zig_##Type lhs, zig_##Type rhs) { \
        return lhs operator rhs; \
    }

#define zig_common_float_builtins(w) \
    zig_convert_builtin( int64_t,  int64_t, fix,     zig_f##w, zig_f##w, ) \
    zig_convert_builtin(zig_i128, zig_i128, fix,     zig_f##w, zig_f##w, ) \
    zig_convert_builtin(zig_u128, zig_u128, fixuns,  zig_f##w, zig_f##w, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, float,    int64_t,  int64_t, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, float,   zig_i128, zig_i128, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, floatun, zig_u128, zig_u128, ) \
    zig_expand_concat(zig_float_less_builtin_,    zig_has_f##w)(f##w, cmp) \
    zig_expand_concat(zig_float_less_builtin_,    zig_has_f##w)(f##w, ne) \
    zig_expand_concat(zig_float_less_builtin_,    zig_has_f##w)(f##w, eq) \
    zig_expand_concat(zig_float_less_builtin_,    zig_has_f##w)(f##w, lt) \
    zig_expand_concat(zig_float_less_builtin_,    zig_has_f##w)(f##w, le) \
    zig_expand_concat(zig_float_greater_builtin_, zig_has_f##w)(f##w, gt) \
    zig_expand_concat(zig_float_greater_builtin_, zig_has_f##w)(f##w, ge) \
    zig_expand_concat(zig_float_binary_builtin_,  zig_has_f##w)(f##w, add, +) \
    zig_expand_concat(zig_float_binary_builtin_,  zig_has_f##w)(f##w, sub, -) \
    zig_expand_concat(zig_float_binary_builtin_,  zig_has_f##w)(f##w, mul, *) \
    zig_expand_concat(zig_float_binary_builtin_,  zig_has_f##w)(f##w, div, /) \
    zig_extern zig_f##w zig_libc_name_f##w(sqrt)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(sin)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(cos)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(tan)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(exp)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(exp2)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(log)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(log2)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(log10)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(fabs)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(floor)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(ceil)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(round)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(trunc)(zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(fmod)(zig_f##w, zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(fmin)(zig_f##w, zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(fmax)(zig_f##w, zig_f##w); \
    zig_extern zig_f##w zig_libc_name_f##w(fma)(zig_f##w, zig_f##w, zig_f##w); \
\
    static inline zig_f##w zig_div_trunc_f##w(zig_f##w lhs, zig_f##w rhs) { \
        return zig_libc_name_f##w(trunc)(zig_div_f##w(lhs, rhs)); \
    } \
\
    static inline zig_f##w zig_div_floor_f##w(zig_f##w lhs, zig_f##w rhs) { \
        return zig_libc_name_f##w(floor)(zig_div_f##w(lhs, rhs)); \
    } \
\
    static inline zig_f##w zig_mod_f##w(zig_f##w lhs, zig_f##w rhs) { \
        return zig_sub_f##w(lhs, zig_mul_f##w(zig_div_floor_f##w(lhs, rhs), rhs)); \
    }
zig_common_float_builtins(16)
zig_common_float_builtins(32)
zig_common_float_builtins(64)
zig_common_float_builtins(80)
zig_common_float_builtins(128)

#define zig_float_builtins(w) \
    zig_convert_builtin( int32_t,  int32_t, fix,     zig_f##w, zig_f##w, ) \
    zig_convert_builtin(uint32_t, uint32_t, fixuns,  zig_f##w, zig_f##w, ) \
    zig_convert_builtin(uint64_t, uint64_t, fixuns,  zig_f##w, zig_f##w, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, float,    int32_t,  int32_t, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, floatun, uint32_t, uint32_t, ) \
    zig_convert_builtin(zig_f##w, zig_f##w, floatun, uint64_t, uint64_t, )
zig_float_builtins(16)
zig_float_builtins(80)
zig_float_builtins(128)

#ifdef __ARM_EABI__

zig_extern zig_callconv(pcs("aapcs")) int32_t __aeabi_f2iz(zig_f32);
static inline int32_t zig_fixsfsi(zig_f32 arg) { return __aeabi_f2iz(arg); }

zig_extern zig_callconv(pcs("aapcs")) uint32_t __aeabi_f2uiz(zig_f32);
static inline uint32_t zig_fixunssfsi(zig_f32 arg) { return __aeabi_f2uiz(arg); }

zig_extern zig_callconv(pcs("aapcs")) uint64_t __aeabi_f2ulz(zig_f32);
static inline uint64_t zig_fixunssfdi(zig_f32 arg) { return __aeabi_f2ulz(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f32 __aeabi_i2f(int32_t);
static inline zig_f32 zig_floatsisf(int32_t arg) { return __aeabi_i2f(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f32 __aeabi_ui2f(uint32_t);
static inline zig_f32 zig_floatunsisf(uint32_t arg) { return __aeabi_ui2f(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f32 __aeabi_ul2f(uint64_t);
static inline zig_f32 zig_floatundisf(uint64_t arg) { return __aeabi_ul2f(arg); }

zig_extern zig_callconv(pcs("aapcs")) int32_t __aeabi_d2iz(zig_f64);
static inline int32_t zig_fixdfsi(zig_f64 arg) { return __aeabi_d2iz(arg); }

zig_extern zig_callconv(pcs("aapcs")) uint32_t __aeabi_d2uiz(zig_f64);
static inline uint32_t zig_fixunsdfsi(zig_f64 arg) { return __aeabi_d2uiz(arg); }

zig_extern zig_callconv(pcs("aapcs")) uint64_t __aeabi_d2ulz(zig_f64);
static inline uint64_t zig_fixunsdfdi(zig_f64 arg) { return __aeabi_d2ulz(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f64 __aeabi_i2d(int32_t);
static inline zig_f64 zig_floatsidf(int32_t arg) { return __aeabi_i2d(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f64 __aeabi_ui2d(uint32_t);
static inline zig_f64 zig_floatunsidf(uint32_t arg) { return __aeabi_ui2d(arg); }

zig_extern zig_callconv(pcs("aapcs")) zig_f64 __aeabi_ul2d(uint64_t);
static inline zig_f64 zig_floatundidf(uint64_t arg) { return __aeabi_ul2d(arg); }

#else /* __ARM_EABI__ */

zig_float_builtins(32)
zig_float_builtins(64)

#endif /* __ARM_EABI__ */

/* ============================ Atomics Support ============================= */

/* Note that atomics should be implemented as macros because most
   compilers silently discard runtime atomic order information. */

/* Define fallback implementations first that can later be undef'd on compilers with builtin support. */
/* Note that zig_atomicrmw_expected is needed to handle aliasing between res and arg. */
#define zig_atomicrmw_xchg_float(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, arg, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_add_float(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_add_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_sub_float(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_sub_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_min_float(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_libc_name_##Type(fmin)(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_max_float(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_libc_name_##Type(fmax)(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)

#define zig_atomicrmw_xchg_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, arg, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_add_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_add_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_sub_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_sub_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_and_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_and_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_nand_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_not_##Type(zig_and_##Type(zig_atomicrmw_expected, arg), 128); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_or_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_or_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_xor_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_xor_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_min_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_min_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)
#define  zig_atomicrmw_max_int128(res, obj, arg, order, Type, ReprType) do { \
    zig_##Type zig_atomicrmw_expected; \
    zig_##Type zig_atomicrmw_desired; \
    zig_atomic_load(zig_atomicrmw_expected, obj, memory_order_relaxed, Type, ReprType); \
    do { \
        zig_atomicrmw_desired = zig_max_##Type(zig_atomicrmw_expected, arg); \
    } while (!zig_cmpxchg_weak(obj, zig_atomicrmw_expected, zig_atomicrmw_desired, order, memory_order_relaxed, Type, ReprType)); \
    res = zig_atomicrmw_expected; \
} while (0)

#if __STDC_VERSION__ >= 201112L && !defined(__STDC_NO_ATOMICS__)
#include <stdatomic.h>
typedef enum memory_order zig_memory_order;
#define zig_atomic(Type) _Atomic(Type)
#define zig_cmpxchg_strong(     obj, expected, desired, succ, fail, Type, ReprType) atomic_compare_exchange_strong_explicit(obj, &(expected), desired, succ, fail)
#define   zig_cmpxchg_weak(     obj, expected, desired, succ, fail, Type, ReprType) atomic_compare_exchange_weak_explicit  (obj, &(expected), desired, succ, fail)
#define zig_atomicrmw_xchg(res, obj, arg, order, Type, ReprType) res = atomic_exchange_explicit  (obj, arg, order)
#define  zig_atomicrmw_add(res, obj, arg, order, Type, ReprType) res = atomic_fetch_add_explicit (obj, arg, order)
#define  zig_atomicrmw_sub(res, obj, arg, order, Type, ReprType) res = atomic_fetch_sub_explicit (obj, arg, order)
#define   zig_atomicrmw_or(res, obj, arg, order, Type, ReprType) res = atomic_fetch_or_explicit  (obj, arg, order)
#define  zig_atomicrmw_xor(res, obj, arg, order, Type, ReprType) res = atomic_fetch_xor_explicit (obj, arg, order)
#define  zig_atomicrmw_and(res, obj, arg, order, Type, ReprType) res = atomic_fetch_and_explicit (obj, arg, order)
#define zig_atomicrmw_nand(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_nand(obj, arg, order)
#define  zig_atomicrmw_min(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_min (obj, arg, order)
#define  zig_atomicrmw_max(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_max (obj, arg, order)
#define   zig_atomic_store(     obj, arg, order, Type, ReprType)       atomic_store_explicit     (obj, arg, order)
#define    zig_atomic_load(res, obj,      order, Type, ReprType) res = atomic_load_explicit      (obj,      order)
#undef  zig_atomicrmw_xchg_float
#define zig_atomicrmw_xchg_float zig_atomicrmw_xchg
#undef  zig_atomicrmw_add_float
#define zig_atomicrmw_add_float zig_atomicrmw_add
#undef  zig_atomicrmw_sub_float
#define zig_atomicrmw_sub_float zig_atomicrmw_sub
#define zig_fence(order) atomic_thread_fence(order)
#elif defined(__GNUC__)
typedef int zig_memory_order;
#define memory_order_relaxed __ATOMIC_RELAXED
#define memory_order_consume __ATOMIC_CONSUME
#define memory_order_acquire __ATOMIC_ACQUIRE
#define memory_order_release __ATOMIC_RELEASE
#define memory_order_acq_rel __ATOMIC_ACQ_REL
#define memory_order_seq_cst __ATOMIC_SEQ_CST
#define zig_atomic(Type) Type
#define zig_cmpxchg_strong(     obj, expected, desired, succ, fail, Type, ReprType) __atomic_compare_exchange(obj, &(expected), &(desired), false, succ, fail)
#define   zig_cmpxchg_weak(     obj, expected, desired, succ, fail, Type, ReprType) __atomic_compare_exchange(obj, &(expected), &(desired),  true, succ, fail)
#define zig_atomicrmw_xchg(res, obj, arg, order, Type, ReprType)       __atomic_exchange(obj, &(arg), &(res), order)
#define  zig_atomicrmw_add(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_add (obj, arg, order)
#define  zig_atomicrmw_sub(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_sub (obj, arg, order)
#define   zig_atomicrmw_or(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_or  (obj, arg, order)
#define  zig_atomicrmw_xor(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_xor (obj, arg, order)
#define  zig_atomicrmw_and(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_and (obj, arg, order)
#define zig_atomicrmw_nand(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_nand(obj, arg, order)
#define  zig_atomicrmw_min(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_min (obj, arg, order)
#define  zig_atomicrmw_max(res, obj, arg, order, Type, ReprType) res = __atomic_fetch_max (obj, arg, order)
#define   zig_atomic_store(     obj, arg, order, Type, ReprType)       __atomic_store     (obj, &(arg), order)
#define    zig_atomic_load(res, obj,      order, Type, ReprType)       __atomic_load      (obj, &(res), order)
#undef  zig_atomicrmw_xchg_float
#define zig_atomicrmw_xchg_float zig_atomicrmw_xchg
#define zig_fence(order) __atomic_thread_fence(order)
#elif _MSC_VER && (_M_IX86 || _M_X64)
#define memory_order_relaxed 0
#define memory_order_consume 1
#define memory_order_acquire 2
#define memory_order_release 3
#define memory_order_acq_rel 4
#define memory_order_seq_cst 5
#define zig_atomic(Type) Type
#define zig_cmpxchg_strong(     obj, expected, desired, succ, fail, Type, ReprType) zig_msvc_cmpxchg_##Type(obj, &(expected), desired)
#define   zig_cmpxchg_weak(     obj, expected, desired, succ, fail, Type, ReprType) zig_cmpxchg_strong(obj, expected, desired, succ, fail, Type, ReprType)
#define zig_atomicrmw_xchg(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_xchg_##Type(obj, arg)
#define  zig_atomicrmw_add(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_add_ ##Type(obj, arg)
#define  zig_atomicrmw_sub(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_sub_ ##Type(obj, arg)
#define   zig_atomicrmw_or(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_or_  ##Type(obj, arg)
#define  zig_atomicrmw_xor(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_xor_ ##Type(obj, arg)
#define  zig_atomicrmw_and(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_and_ ##Type(obj, arg)
#define zig_atomicrmw_nand(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_nand_##Type(obj, arg)
#define  zig_atomicrmw_min(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_min_ ##Type(obj, arg)
#define  zig_atomicrmw_max(res, obj, arg, order, Type, ReprType) res = zig_msvc_atomicrmw_max_ ##Type(obj, arg)
#define   zig_atomic_store(     obj, arg, order, Type, ReprType)       zig_msvc_atomic_store_  ##Type(obj, arg)
#define    zig_atomic_load(res, obj,      order, Type, ReprType) res = zig_msvc_atomic_load_   ##Type(obj)
#if _M_X64
#define zig_fence(order) __faststorefence()
#else
#define zig_fence(order) zig_msvc_atomic_barrier()
#endif
/* TODO: _MSC_VER && (_M_ARM || _M_ARM64) */
#else
#define memory_order_relaxed 0
#define memory_order_consume 1
#define memory_order_acquire 2
#define memory_order_release 3
#define memory_order_acq_rel 4
#define memory_order_seq_cst 5
#define zig_atomic(Type) Type
#define zig_cmpxchg_strong(     obj, expected, desired, succ, fail, Type, ReprType) zig_atomics_unavailable
#define   zig_cmpxchg_weak(     obj, expected, desired, succ, fail, Type, ReprType) zig_atomics_unavailable
#define zig_atomicrmw_xchg(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_add(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_sub(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define   zig_atomicrmw_or(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_xor(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_and(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define zig_atomicrmw_nand(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_min(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define  zig_atomicrmw_max(res, obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define   zig_atomic_store(     obj, arg, order, Type, ReprType) zig_atomics_unavailable
#define    zig_atomic_load(res, obj,      order, Type, ReprType) zig_atomics_unavailable
#define zig_fence(order) zig_fence_unavailable
#endif

#if _MSC_VER && (_M_IX86 || _M_X64)

/* TODO: zig_msvc_atomic_load should load 32 bit without interlocked on x86, and load 64 bit without interlocked on x64 */

#define zig_msvc_atomics(ZigType, Type, SigType, suffix) \
    static inline bool zig_msvc_cmpxchg_##ZigType(Type volatile* obj, Type* expected, Type desired) { \
        Type comparand = *expected; \
        Type initial = _InterlockedCompareExchange##suffix((SigType volatile*)obj, (SigType)desired, (SigType)comparand); \
        bool exchanged = initial == comparand; \
        if (!exchanged) { \
            *expected = initial; \
        } \
        return exchanged; \
    } \
    static inline Type zig_msvc_atomicrmw_xchg_##ZigType(Type volatile* obj, Type value) { \
        return _InterlockedExchange##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomicrmw_add_##ZigType(Type volatile* obj, Type value) { \
        return _InterlockedExchangeAdd##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomicrmw_sub_##ZigType(Type volatile* obj, Type value) { \
        bool success = false; \
        Type new; \
        Type prev; \
        while (!success) { \
            prev = *obj; \
            new = prev - value; \
            success = zig_msvc_cmpxchg_##ZigType(obj, &prev, new); \
        } \
        return prev; \
    } \
    static inline Type zig_msvc_atomicrmw_or_##ZigType(Type volatile* obj, Type value) { \
        return _InterlockedOr##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomicrmw_xor_##ZigType(Type volatile* obj, Type value) { \
        return _InterlockedXor##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomicrmw_and_##ZigType(Type volatile* obj, Type value) { \
        return _InterlockedAnd##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomicrmw_nand_##ZigType(Type volatile* obj, Type value) { \
        bool success = false; \
        Type new; \
        Type prev; \
        while (!success) { \
            prev = *obj; \
            new = ~(prev & value); \
            success = zig_msvc_cmpxchg_##ZigType(obj, &prev, new); \
        } \
        return prev; \
    } \
    static inline Type zig_msvc_atomicrmw_min_##ZigType(Type volatile* obj, Type value) { \
        bool success = false; \
        Type new; \
        Type prev; \
        while (!success) { \
            prev = *obj; \
            new = value < prev ? value : prev; \
            success = zig_msvc_cmpxchg_##ZigType(obj, &prev, new); \
        } \
        return prev; \
    } \
    static inline Type zig_msvc_atomicrmw_max_##ZigType(Type volatile* obj, Type value) { \
        bool success = false; \
        Type new; \
        Type prev; \
        while (!success) { \
            prev = *obj; \
            new = value > prev ? value : prev; \
            success = zig_msvc_cmpxchg_##ZigType(obj, &prev, new); \
        } \
        return prev; \
    } \
    static inline void zig_msvc_atomic_store_##ZigType(Type volatile* obj, Type value) { \
        (void)_InterlockedExchange##suffix((SigType volatile*)obj, (SigType)value); \
    } \
    static inline Type zig_msvc_atomic_load_##ZigType(Type volatile* obj) { \
        return _InterlockedExchangeAdd##suffix((SigType volatile*)obj, (SigType)0); \
    }

zig_msvc_atomics( u8,  uint8_t,    char,  8)
zig_msvc_atomics( i8,   int8_t,    char,  8)
zig_msvc_atomics(u16, uint16_t,   short, 16)
zig_msvc_atomics(i16,  int16_t,   short, 16)
zig_msvc_atomics(u32, uint32_t,    long, )
zig_msvc_atomics(i32,  int32_t,    long, )

#if _M_X64
zig_msvc_atomics(u64, uint64_t, __int64, 64)
zig_msvc_atomics(i64,  int64_t, __int64, 64)
#endif

#define zig_msvc_flt_atomics(Type, SigType, suffix) \
    static inline bool zig_msvc_cmpxchg_##Type(zig_##Type volatile* obj, zig_##Type* expected, zig_##Type desired) { \
        SigType exchange; \
        SigType comparand; \
        SigType initial; \
        bool success; \
        memcpy(&comparand, expected, sizeof(comparand)); \
        memcpy(&exchange, &desired, sizeof(exchange)); \
        initial = _InterlockedCompareExchange##suffix((SigType volatile*)obj, exchange, comparand); \
        success = initial == comparand; \
        if (!success) memcpy(expected, &initial, sizeof(*expected)); \
        return success; \
    } \
    static inline void zig_msvc_atomic_store_##Type(zig_##Type volatile* obj, zig_##Type arg) { \
        SigType value; \
        memcpy(&value, &arg, sizeof(value)); \
        (void)_InterlockedExchange##suffix((SigType volatile*)obj, value); \
    } \
    static inline zig_##Type zig_msvc_atomic_load_##Type(zig_##Type volatile* obj) { \
        zig_##Type result; \
        SigType initial = _InterlockedExchangeAdd##suffix((SigType volatile*)obj, (SigType)0); \
        memcpy(&result, &initial, sizeof(result)); \
        return result; \
    }
zig_msvc_flt_atomics(f32,    long,   )
#if _M_X64
zig_msvc_flt_atomics(f64, int64_t, 64)
#endif

#if _M_IX86
static inline void zig_msvc_atomic_barrier() {
    int32_t barrier;
    __asm {
        xchg barrier, eax
    }
}

static inline void* zig_msvc_atomicrmw_xchg_p32(void volatile* obj, void* arg) {
    return _InterlockedExchangePointer(obj, arg);
}

static inline void zig_msvc_atomic_store_p32(void volatile* obj, void* arg) {
    (void)_InterlockedExchangePointer(obj, arg);
}

static inline void* zig_msvc_atomic_load_p32(void volatile* obj) {
    return (void*)_InterlockedExchangeAdd(obj, 0);
}

static inline bool zig_msvc_cmpxchg_p32(void volatile* obj, void* expected, void* desired) {
    void* comparand = *(void**)expected;
    void* initial = _InterlockedCompareExchangePointer(obj, desired, comparand);
    bool success = initial == comparand;
    if (!success) *(void**)expected = initial;
    return success;
}
#else /* _M_IX86 */
static inline void* zig_msvc_atomicrmw_xchg_p64(void volatile* obj, void* arg) {
    return _InterlockedExchangePointer(obj, arg);
}

static inline void zig_msvc_atomic_store_p64(void volatile* obj, void* arg) {
    (void)_InterlockedExchangePointer(obj, arg);
}

static inline void* zig_msvc_atomic_load_p64(void volatile* obj) {
    return (void*)_InterlockedExchangeAdd64(obj, 0);
}

static inline bool zig_msvc_cmpxchg_p64(void volatile* obj, void* expected, void* desired) {
    void* comparand = *(void**)expected;
    void* initial = _InterlockedCompareExchangePointer(obj, desired, comparand);
    bool success = initial == comparand;
    if (!success) *(void**)expected = initial;
    return success;
}

static inline bool zig_msvc_cmpxchg_u128(zig_u128 volatile* obj, zig_u128* expected, zig_u128 desired) {
    return _InterlockedCompareExchange128((__int64 volatile*)obj, (__int64)zig_hi_u128(desired), (__int64)zig_lo_u128(desired), (__int64*)expected);
}

static inline bool zig_msvc_cmpxchg_i128(zig_i128 volatile* obj, zig_i128* expected, zig_i128 desired) {
    return _InterlockedCompareExchange128((__int64 volatile*)obj, (__int64)zig_hi_i128(desired), (__int64)zig_lo_i128(desired), (__int64*)expected);
}
#endif /* _M_IX86 */

#endif /* _MSC_VER && (_M_IX86 || _M_X64) */

/* ======================== Special Case Intrinsics ========================= */

#if (_MSC_VER && _M_X64) || defined(__x86_64__)

static inline void* zig_x86_64_windows_teb(void) {
#if _MSC_VER
    return (void*)__readgsqword(0x30);
#else
    void* teb;
    __asm volatile(" movq %%gs:0x30, %[ptr]": [ptr]"=r"(teb)::);
    return teb;
#endif
}

#elif (_MSC_VER && _M_IX86) || defined(__i386__) || defined(__X86__)

static inline void* zig_x86_windows_teb(void) {
#if _MSC_VER
    return (void*)__readfsdword(0x18);
#else
    void* teb;
    __asm volatile(" movl %%fs:0x18, %[ptr]": [ptr]"=r"(teb)::);
    return teb;
#endif
}

#endif

#if (_MSC_VER && (_M_IX86 || _M_X64)) || defined(__i386__) || defined(__x86_64__)

static inline void zig_x86_cpuid(uint32_t leaf_id, uint32_t subid, uint32_t* eax, uint32_t* ebx, uint32_t* ecx, uint32_t* edx) {
#if _MSC_VER
    int cpu_info[4];
    __cpuidex(cpu_info, leaf_id, subid);
    *eax = (uint32_t)cpu_info[0];
    *ebx = (uint32_t)cpu_info[1];
    *ecx = (uint32_t)cpu_info[2];
    *edx = (uint32_t)cpu_info[3];
#else
    __cpuid_count(leaf_id, subid, *eax, *ebx, *ecx, *edx);
#endif
}

static inline uint32_t zig_x86_get_xcr0(void) {
#if _MSC_VER
    return (uint32_t)_xgetbv(0);
#else
    uint32_t eax;
    uint32_t edx;
    __asm__("xgetbv" : "=a"(eax), "=d"(edx) : "c"(0));
    return eax;
#endif
}

#endif