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#pragma once
#if defined(__cplusplus)
extern "C" {
#endif
#include <inttypes.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef _MSC_VER
#include <intrin.h>
#endif
#include "krml/internal/target.h"
#include "krml/lowstar_endianness.h"
#define LowStar_Ignore_ignore(e, t, _ret_t) ((void)e)
// SLICES, ARRAYS, ETC.
#if defined(__cplusplus)
#define CLITERAL(type) type
#else
#define CLITERAL(type) (type)
#endif
// We represent a slice as a pair of an (untyped) pointer, along with the length
// of the slice, i.e. the number of elements in the slice (this is NOT the
// number of bytes). This design choice has two important consequences.
// - if you need to use `ptr`, you MUST cast it to a proper type *before*
// performing pointer
// arithmetic on it (remember that C desugars pointer arithmetic based on the
// type of the address)
// - if you need to use `len` for a C style function (e.g. memcpy, memcmp), you
// need to multiply it
// by sizeof t, where t is the type of the elements.
typedef struct {
void *ptr;
size_t len;
} Eurydice_slice;
// Helper macro to create a slice out of a pointer x, a start index in x
// (included), and an end index in x (excluded). The argument x must be suitably
// cast to something that can decay (see remark above about how pointer
// arithmetic works in C), meaning either pointer or array type.
#define EURYDICE_SLICE(x, start, end) \
(CLITERAL(Eurydice_slice){ .ptr = (void *)(x + start), .len = end - start })
#define EURYDICE_SLICE_LEN(s, _) s.len
// This macro is a pain because in case the dereferenced element type is an
// array, you cannot simply write `t x` as it would yield `int[4] x` instead,
// which is NOT correct C syntax, so we add a dedicated phase in Eurydice that
// adds an extra argument to this macro at the last minute so that we have the
// correct type of *pointers* to elements.
#define Eurydice_slice_index(s, i, t, t_ptr_t) (((t_ptr_t)s.ptr)[i])
#define Eurydice_slice_subslice(s, r, t, _) \
EURYDICE_SLICE((t *)s.ptr, r.start, r.end)
// Variant for when the start and end indices are statically known (i.e., the
// range argument `r` is a literal).
#define Eurydice_slice_subslice2(s, start, end, t) \
EURYDICE_SLICE((t *)s.ptr, start, end)
#define Eurydice_slice_subslice_to(s, subslice_end_pos, t, _) \
EURYDICE_SLICE((t *)s.ptr, 0, subslice_end_pos)
#define Eurydice_slice_subslice_from(s, subslice_start_pos, t, _) \
EURYDICE_SLICE((t *)s.ptr, subslice_start_pos, s.len)
#define Eurydice_array_to_slice(end, x, t) \
EURYDICE_SLICE(x, 0, \
end) /* x is already at an array type, no need for cast */
#define Eurydice_array_to_subslice(_arraylen, x, r, t, _) \
EURYDICE_SLICE((t *)x, r.start, r.end)
// Same as above, variant for when start and end are statically known
#define Eurydice_array_to_subslice2(x, start, end, t) \
EURYDICE_SLICE((t *)x, start, end)
#define Eurydice_array_to_subslice_to(_size, x, r, t, _range_t) \
EURYDICE_SLICE((t *)x, 0, r)
#define Eurydice_array_to_subslice_from(size, x, r, t, _range_t) \
EURYDICE_SLICE((t *)x, r, size)
#define Eurydice_array_repeat(dst, len, init, t) \
ERROR "should've been desugared"
#define Eurydice_slice_len(s, t) EURYDICE_SLICE_LEN(s, t)
#define Eurydice_slice_copy(dst, src, t) \
memcpy(dst.ptr, src.ptr, dst.len * sizeof(t))
#define core_array___Array_T__N__23__as_slice(len_, ptr_, t, _ret_t) \
((Eurydice_slice){ .ptr = ptr_, .len = len_ })
#define core_array___core__clone__Clone_for__Array_T__N___20__clone( \
len, src, dst, elem_type, _ret_t) \
(memcpy(dst, src, len * sizeof(elem_type)))
#define core_array_TryFromSliceError uint8_t
#define Eurydice_array_eq(sz, a1, a2, t, _) \
(memcmp(a1, a2, sz * sizeof(t)) == 0)
#define core_array_equality___core__cmp__PartialEq__Array_U__N___for__Array_T__N____eq( \
sz, a1, a2, t, _, _ret_t) \
Eurydice_array_eq(sz, a1, a2, t, _)
#define core_array_equality___core__cmp__PartialEq__0___Slice_U____for__Array_T__N___3__eq( \
sz, a1, a2, t, _, _ret_t) \
Eurydice_array_eq(sz, a1, ((a2)->ptr), t, _)
#define Eurydice_slice_split_at(slice, mid, element_type, ret_t) \
(CLITERAL(ret_t){ \
.fst = EURYDICE_SLICE((element_type *)slice.ptr, 0, mid), \
.snd = EURYDICE_SLICE((element_type *)slice.ptr, mid, slice.len) })
#define Eurydice_slice_split_at_mut(slice, mid, element_type, ret_t) \
(CLITERAL(ret_t){ \
.fst = { .ptr = slice.ptr, .len = mid }, \
.snd = { .ptr = (char *)slice.ptr + mid * sizeof(element_type), \
.len = slice.len - mid } })
// Conversion of slice to an array, rewritten (by Eurydice) to name the
// destination array, since arrays are not values in C.
// N.B.: see note in karamel/lib/Inlining.ml if you change this.
#define Eurydice_slice_to_array2(dst, src, _, t_arr) \
Eurydice_slice_to_array3(&(dst)->tag, (char *)&(dst)->val.case_Ok, src, \
sizeof(t_arr))
static inline void
Eurydice_slice_to_array3(uint8_t *dst_tag, char *dst_ok,
Eurydice_slice src, size_t sz)
{
*dst_tag = 0;
memcpy(dst_ok, src.ptr, sz);
}
// CORE STUFF (conversions, endianness, ...)
static inline void
core_num__u32_8__to_be_bytes(uint32_t src, uint8_t dst[4])
{
// TODO: why not store32_be?
uint32_t x = htobe32(src);
memcpy(dst, &x, 4);
}
static inline uint32_t
core_num__u32_8__from_le_bytes(uint8_t buf[4])
{
return load32_le(buf);
}
static inline void
core_num__u64_9__to_le_bytes(uint64_t v, uint8_t buf[8])
{
store64_le(buf, v);
}
static inline uint64_t
core_num__u64_9__from_le_bytes(uint8_t buf[8])
{
return load64_le(buf);
}
static inline int64_t
core_convert_num___core__convert__From_i32__for_i64__59__from(int32_t x)
{
return x;
}
static inline uint64_t
core_convert_num___core__convert__From_u8__for_u64__66__from(uint8_t x)
{
return x;
}
static inline uint64_t
core_convert_num___core__convert__From_u16__for_u64__70__from(uint16_t x)
{
return x;
}
static inline size_t
core_convert_num___core__convert__From_u16__for_usize__96__from(uint16_t x)
{
return x;
}
static inline uint32_t
core_num__u8_6__count_ones(uint8_t x0)
{
#ifdef _MSC_VER
return __popcnt(x0);
#else
return __builtin_popcount(x0);
#endif
}
// unsigned overflow wraparound semantics in C
static inline uint16_t
core_num__u16_7__wrapping_add(uint16_t x, uint16_t y)
{
return x + y;
}
static inline uint8_t
core_num__u8_6__wrapping_sub(uint8_t x, uint8_t y)
{
return x - y;
}
static inline void
core_ops_arith__i32_319__add_assign(int32_t *x0,
int32_t *x1)
{
*x0 = *x0 + *x1;
}
static inline uint8_t
Eurydice_bitand_pv_u8(uint8_t *p, uint8_t v)
{
return (*p) & v;
}
static inline uint8_t
Eurydice_shr_pv_u8(uint8_t *p, int32_t v)
{
return (*p) >> v;
}
#define core_num_nonzero_private_NonZeroUsizeInner size_t
static inline core_num_nonzero_private_NonZeroUsizeInner
core_num_nonzero_private___core__clone__Clone_for_core__num__nonzero__private__NonZeroUsizeInner__26__clone(
core_num_nonzero_private_NonZeroUsizeInner *x0)
{
return *x0;
}
// ITERATORS
#define Eurydice_range_iter_next(iter_ptr, t, ret_t) \
(((iter_ptr)->start == (iter_ptr)->end) \
? (CLITERAL(ret_t){ .tag = core_option_None }) \
: (CLITERAL(ret_t){ .tag = core_option_Some, \
.f0 = (iter_ptr)->start++ }))
// Old name (TODO: remove once everyone has upgraded to the latest Charon)
#define core_iter_range___core__iter__traits__iterator__Iterator_for_core__ops__range__Range_A___3__next \
Eurydice_range_iter_next
#define core_iter_range___core__iter__traits__iterator__Iterator_for_core__ops__range__Range_A___6__next \
Eurydice_range_iter_next
// See note in karamel/lib/Inlining.ml if you change this
#define Eurydice_into_iter(x, t, _ret_t) (x)
#define core_iter_traits_collect___core__iter__traits__collect__IntoIterator_for_I___into_iter \
Eurydice_into_iter
// This name changed on 20240627
#define core_iter_traits_collect___core__iter__traits__collect__IntoIterator_for_I__1__into_iter \
Eurydice_into_iter
typedef struct {
Eurydice_slice slice;
size_t chunk_size;
} Eurydice_chunks;
// Can't use macros Eurydice_slice_subslice_{to,from} because they require a
// type, and this static inline function cannot receive a type as an argument.
// Instead, we receive the element size and use it to peform manual offset
// computations rather than going through the macros.
static inline Eurydice_slice
chunk_next(Eurydice_chunks *chunks,
size_t element_size)
{
size_t chunk_size = chunks->slice.len >= chunks->chunk_size
? chunks->chunk_size
: chunks->slice.len;
Eurydice_slice curr_chunk;
curr_chunk.ptr = chunks->slice.ptr;
curr_chunk.len = chunk_size;
chunks->slice.ptr = (char *)(chunks->slice.ptr) + chunk_size * element_size;
chunks->slice.len = chunks->slice.len - chunk_size;
return curr_chunk;
}
#define core_slice___Slice_T___chunks(slice_, sz_, t, _ret_t) \
((Eurydice_chunks){ .slice = slice_, .chunk_size = sz_ })
#define core_slice___Slice_T___chunks_exact(slice_, sz_, t, _ret_t) \
((Eurydice_chunks){ \
.slice = { .ptr = slice_.ptr, .len = slice_.len - (slice_.len % sz_) }, \
.chunk_size = sz_ })
#define core_slice_iter_Chunks Eurydice_chunks
#define core_slice_iter_ChunksExact Eurydice_chunks
#define Eurydice_chunks_next(iter, t, ret_t) \
(((iter)->slice.len == 0) ? ((ret_t){ .tag = core_option_None }) \
: ((ret_t){ .tag = core_option_Some, \
.f0 = chunk_next(iter, sizeof(t)) }))
#define core_slice_iter___core__iter__traits__iterator__Iterator_for_core__slice__iter__Chunks__a__T___70__next \
Eurydice_chunks_next
// This name changed on 20240627
#define core_slice_iter___core__iter__traits__iterator__Iterator_for_core__slice__iter__Chunks__a__T___71__next \
Eurydice_chunks_next
#define core_slice_iter__core__slice__iter__ChunksExact__a__T__89__next( \
iter, t, _ret_t) \
core_slice_iter__core__slice__iter__Chunks__a__T__70__next(iter, t)
typedef struct {
Eurydice_slice s;
size_t index;
} Eurydice_slice_iterator;
#define core_slice___Slice_T___iter(x, t, _ret_t) \
((Eurydice_slice_iterator){ .s = x, .index = 0 })
#define core_slice_iter_Iter Eurydice_slice_iterator
#define core_slice_iter__core__slice__iter__Iter__a__T__181__next(iter, t, \
ret_t) \
(((iter)->index == (iter)->s.len) \
? (CLITERAL(ret_t){ .tag = core_option_None }) \
: (CLITERAL(ret_t){ \
.tag = core_option_Some, \
.f0 = ((iter)->index++, \
&((t *)((iter)->s.ptr))[(iter)->index - 1]) }))
// STRINGS
typedef const char *Prims_string;
// MISC (UNTESTED)
typedef void *core_fmt_Formatter;
typedef void *core_fmt_Arguments;
typedef void *core_fmt_rt_Argument;
#define core_fmt_rt__core__fmt__rt__Argument__a__1__new_display(x1, x2, x3, \
x4) \
NULL
// VECTORS (ANCIENT, POSSIBLY UNTESTED)
/* For now these are passed by value -- three words. We could conceivably change
* the representation to heap-allocate this struct and only pass around the
* pointer (one word). */
typedef struct {
void *ptr;
size_t len; /* the number of elements */
size_t alloc_size; /* the size of the allocation, in number of BYTES */
} Eurydice_vec_s, *Eurydice_vec;
/* Here, we set everything to zero rather than use a non-standard GCC
* statement-expression -- this suitably initializes ptr to NULL and len and
* size to 0. */
#define EURYDICE_VEC_NEW(_) calloc(1, sizeof(Eurydice_vec_s))
#define EURYDICE_VEC_PUSH(v, x, t) \
do { \
/* Grow the vector if capacity has been reached. */ \
if (v->len == v->alloc_size / sizeof(t)) { \
/* Assuming that this does not exceed SIZE_MAX, because code proven \
* correct by Aeneas. Would this even happen in practice? */ \
size_t new_size; \
if (v->alloc_size == 0) \
new_size = 8 * sizeof(t); \
else if (v->alloc_size <= SIZE_MAX / 2) \
/* TODO: discuss growth policy */ \
new_size = 2 * v->alloc_size; \
else \
new_size = (SIZE_MAX / sizeof(t)) * sizeof(t); \
v->ptr = realloc(v->ptr, new_size); \
v->alloc_size = new_size; \
} \
((t *)v->ptr)[v->len] = x; \
v->len++; \
} while (0)
#define EURYDICE_VEC_DROP(v, t) \
do { \
free(v->ptr); \
free(v); \
} while (0)
#define EURYDICE_VEC_INDEX(v, i, t) &((t *)v->ptr)[i]
#define EURYDICE_VEC_LEN(v, t) (v)->len
/* TODO: remove GCC-isms */
#define EURYDICE_BOX_NEW(x, t) \
({ \
t *p = malloc(sizeof(t)); \
*p = x; \
p; \
})
#define EURYDICE_REPLACE(ptr, new_v, t) \
({ \
t old_v = *ptr; \
*ptr = new_v; \
old_v; \
})
#if defined(__cplusplus)
}
#endif