circuitpython/py/misc.h

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/*
* This file is part of the MicroPython project, http://micropython.org/
*
* The MIT License (MIT)
*
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* SPDX-FileCopyrightText: Copyright (c) 2013, 2014 Damien P. George
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#ifndef MICROPY_INCLUDED_PY_MISC_H
#define MICROPY_INCLUDED_PY_MISC_H
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// a mini library of useful types and functions
/** types *******************************************************/
#include <stdbool.h>
#include <stdint.h>
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#include <stddef.h>
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#include "mpconfig.h"
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typedef unsigned char byte;
typedef unsigned int uint;
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/** generic ops *************************************************/
#ifndef MIN
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#define MIN(x, y) ((x) < (y) ? (x) : (y))
#endif
#ifndef MAX
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#define MAX(x, y) ((x) > (y) ? (x) : (y))
#endif
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// Classical double-indirection stringification of preprocessor macro's value
#define MP_STRINGIFY_HELPER(x) #x
#define MP_STRINGIFY(x) MP_STRINGIFY_HELPER(x)
// Static assertion macro
#define MP_STATIC_ASSERT(cond) ((void)sizeof(char[1 - 2 * !(cond)]))
// Round-up integer division
#define MP_CEIL_DIVIDE(a, b) (((a) + (b) - 1) / (b))
#define MP_ROUND_DIVIDE(a, b) (((a) + (b) / 2) / (b))
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/** memory allocation ******************************************/
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// TODO make a lazy m_renew that can increase by a smaller amount than requested (but by at least 1 more element)
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#define m_new(type, num) ((type *)(m_malloc(sizeof(type) * (num), false)))
#define m_new_ll(type, num) ((type *)(m_malloc(sizeof(type) * (num), true)))
#define m_new_maybe(type, num) ((type *)(m_malloc_maybe(sizeof(type) * (num), false)))
#define m_new_ll_maybe(type, num) ((type *)(m_malloc_maybe(sizeof(type) * (num), true)))
#define m_new0(type, num) ((type *)(m_malloc0(sizeof(type) * (num), false)))
#define m_new0_ll(type, num) ((type *)(m_malloc0(sizeof(type) * (num), true)))
#define m_new_obj(type) (m_new(type, 1))
Introduce a long lived section of the heap. This adapts the allocation process to start from either end of the heap when searching for free space. The default behavior is identical to the existing behavior where it starts with the lowest block and looks higher. Now it can also look from the highest block and lower depending on the long_lived parameter to gc_alloc. As the heap fills, the two sections may overlap. When they overlap, a collect may be triggered in order to keep the long lived section compact. However, free space is always eligable for each type of allocation. By starting from either of the end of the heap we have ability to separate short lived objects from long lived ones. This separation reduces heap fragmentation because long lived objects are easy to densely pack. Most objects are short lived initially but may be made long lived when they are referenced by a type or module. This involves copying the memory and then letting the collect phase free the old portion. QSTR pools and chunks are always long lived because they are never freed. The reallocation, collection and free processes are largely unchanged. They simply also maintain an index to the highest free block as well as the lowest. These indices are used to speed up the allocation search until the next collect. In practice, this change may slightly slow down import statements with the benefit that memory is much less fragmented afterwards. For example, a test import into a 20k heap that leaves ~6k free previously had the largest continuous free space of ~400 bytes. After this change, the largest continuous free space is over 3400 bytes.
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#define m_new_ll_obj(type) (m_new_ll(type, 1))
#define m_new_obj_maybe(type) (m_new_maybe(type, 1))
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#define m_new_obj_var(obj_type, var_type, var_num) ((obj_type *)m_malloc(sizeof(obj_type) + sizeof(var_type) * (var_num), false))
#define m_new_obj_var_maybe(obj_type, var_type, var_num) ((obj_type *)m_malloc_maybe(sizeof(obj_type) + sizeof(var_type) * (var_num), false))
#define m_new_ll_obj_var_maybe(obj_type, var_type, var_num) ((obj_type *)m_malloc_maybe(sizeof(obj_type) + sizeof(var_type) * (var_num), true))
#if MICROPY_ENABLE_FINALISER
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#define m_new_obj_with_finaliser(type) ((type *)(m_malloc_with_finaliser(sizeof(type), false)))
#define m_new_obj_var_with_finaliser(type, var_type, var_num) ((type *)m_malloc_with_finaliser(sizeof(type) + sizeof(var_type) * (var_num), false))
#define m_new_ll_obj_with_finaliser(type) ((type *)(m_malloc_with_finaliser(sizeof(type), true)))
#else
#define m_new_obj_with_finaliser(type) m_new_obj(type)
#define m_new_obj_var_with_finaliser(type, var_type, var_num) m_new_obj_var(type, var_type, var_num)
#define m_new_ll_obj_with_finaliser(type) m_new_ll_obj(type)
#endif
#if MICROPY_MALLOC_USES_ALLOCATED_SIZE
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#define m_renew(type, ptr, old_num, new_num) ((type *)(m_realloc((ptr), sizeof(type) * (old_num), sizeof(type) * (new_num))))
#define m_renew_maybe(type, ptr, old_num, new_num, allow_move) ((type *)(m_realloc_maybe((ptr), sizeof(type) * (old_num), sizeof(type) * (new_num), (allow_move))))
#define m_del(type, ptr, num) m_free(ptr, sizeof(type) * (num))
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#define m_del_var(obj_type, var_type, var_num, ptr) (m_free(ptr, sizeof(obj_type) + sizeof(var_type) * (var_num)))
#else
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#define m_renew(type, ptr, old_num, new_num) ((type *)(m_realloc((ptr), sizeof(type) * (new_num))))
#define m_renew_maybe(type, ptr, old_num, new_num, allow_move) ((type *)(m_realloc_maybe((ptr), sizeof(type) * (new_num), (allow_move))))
#define m_del(type, ptr, num) ((void)(num), m_free(ptr))
#define m_del_var(obj_type, var_type, var_num, ptr) ((void)(var_num), m_free(ptr))
#endif
#define m_del_obj(type, ptr) (m_del(type, ptr, 1))
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Introduce a long lived section of the heap. This adapts the allocation process to start from either end of the heap when searching for free space. The default behavior is identical to the existing behavior where it starts with the lowest block and looks higher. Now it can also look from the highest block and lower depending on the long_lived parameter to gc_alloc. As the heap fills, the two sections may overlap. When they overlap, a collect may be triggered in order to keep the long lived section compact. However, free space is always eligable for each type of allocation. By starting from either of the end of the heap we have ability to separate short lived objects from long lived ones. This separation reduces heap fragmentation because long lived objects are easy to densely pack. Most objects are short lived initially but may be made long lived when they are referenced by a type or module. This involves copying the memory and then letting the collect phase free the old portion. QSTR pools and chunks are always long lived because they are never freed. The reallocation, collection and free processes are largely unchanged. They simply also maintain an index to the highest free block as well as the lowest. These indices are used to speed up the allocation search until the next collect. In practice, this change may slightly slow down import statements with the benefit that memory is much less fragmented afterwards. For example, a test import into a 20k heap that leaves ~6k free previously had the largest continuous free space of ~400 bytes. After this change, the largest continuous free space is over 3400 bytes.
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void *m_malloc(size_t num_bytes, bool long_lived);
void *m_malloc_maybe(size_t num_bytes, bool long_lived);
void *m_malloc_with_finaliser(size_t num_bytes, bool long_lived);
Introduce a long lived section of the heap. This adapts the allocation process to start from either end of the heap when searching for free space. The default behavior is identical to the existing behavior where it starts with the lowest block and looks higher. Now it can also look from the highest block and lower depending on the long_lived parameter to gc_alloc. As the heap fills, the two sections may overlap. When they overlap, a collect may be triggered in order to keep the long lived section compact. However, free space is always eligable for each type of allocation. By starting from either of the end of the heap we have ability to separate short lived objects from long lived ones. This separation reduces heap fragmentation because long lived objects are easy to densely pack. Most objects are short lived initially but may be made long lived when they are referenced by a type or module. This involves copying the memory and then letting the collect phase free the old portion. QSTR pools and chunks are always long lived because they are never freed. The reallocation, collection and free processes are largely unchanged. They simply also maintain an index to the highest free block as well as the lowest. These indices are used to speed up the allocation search until the next collect. In practice, this change may slightly slow down import statements with the benefit that memory is much less fragmented afterwards. For example, a test import into a 20k heap that leaves ~6k free previously had the largest continuous free space of ~400 bytes. After this change, the largest continuous free space is over 3400 bytes.
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void *m_malloc0(size_t num_bytes, bool long_lived);
#if MICROPY_MALLOC_USES_ALLOCATED_SIZE
void *m_realloc(void *ptr, size_t old_num_bytes, size_t new_num_bytes);
void *m_realloc_maybe(void *ptr, size_t old_num_bytes, size_t new_num_bytes, bool allow_move);
void m_free(void *ptr, size_t num_bytes);
#else
void *m_realloc(void *ptr, size_t new_num_bytes);
void *m_realloc_maybe(void *ptr, size_t new_num_bytes, bool allow_move);
void m_free(void *ptr);
#endif
NORETURN void m_malloc_fail(size_t num_bytes);
#if MICROPY_TRACKED_ALLOC
// These alloc/free functions track the pointers in a linked list so the GC does not reclaim
// them. They can be used by code that requires traditional C malloc/free semantics.
void *m_tracked_calloc(size_t nmemb, size_t size);
void m_tracked_free(void *ptr_in);
#endif
#if MICROPY_MEM_STATS
size_t m_get_total_bytes_allocated(void);
size_t m_get_current_bytes_allocated(void);
size_t m_get_peak_bytes_allocated(void);
#endif
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/** array helpers ***********************************************/
// get the number of elements in a fixed-size array
#define MP_ARRAY_SIZE(a) (sizeof(a) / sizeof((a)[0]))
// align ptr to the nearest multiple of "alignment"
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#define MP_ALIGN(ptr, alignment) (void *)(((uintptr_t)(ptr) + ((alignment) - 1)) & ~((alignment) - 1))
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#define sizeof_field(TYPE, MEMBER) sizeof((((TYPE *)0)->MEMBER))
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/** unichar / UTF-8 *********************************************/
#if MICROPY_PY_BUILTINS_STR_UNICODE
// with unicode enabled we need a type which can fit chars up to 0x10ffff
typedef uint32_t unichar;
#else
// without unicode enabled we can only need to fit chars up to 0xff
// (on 16-bit archs uint is 16-bits and more efficient than uint32_t)
typedef uint unichar;
#endif
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#if MICROPY_PY_BUILTINS_STR_UNICODE
unichar utf8_get_char(const byte *s);
const byte *utf8_next_char(const byte *s);
size_t utf8_charlen(const byte *str, size_t len);
#else
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static inline unichar utf8_get_char(const byte *s) {
return *s;
}
static inline const byte *utf8_next_char(const byte *s) {
return s + 1;
}
static inline size_t utf8_charlen(const byte *str, size_t len) {
(void)str;
return len;
}
#endif
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bool unichar_isspace(unichar c);
bool unichar_isalpha(unichar c);
bool unichar_isprint(unichar c);
bool unichar_isdigit(unichar c);
bool unichar_isxdigit(unichar c);
bool unichar_isident(unichar c);
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bool unichar_isalnum(unichar c);
bool unichar_isupper(unichar c);
bool unichar_islower(unichar c);
unichar unichar_tolower(unichar c);
unichar unichar_toupper(unichar c);
mp_uint_t unichar_xdigit_value(unichar c);
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#define UTF8_IS_NONASCII(ch) ((ch) & 0x80)
#define UTF8_IS_CONT(ch) (((ch) & 0xC0) == 0x80)
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/** variable string *********************************************/
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typedef struct _vstr_t {
size_t alloc;
size_t len;
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char *buf;
bool fixed_buf : 1;
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} vstr_t;
// convenience macro to declare a vstr with a fixed size buffer on the stack
#define VSTR_FIXED(vstr, alloc) vstr_t vstr; char vstr##_buf[(alloc)]; vstr_init_fixed_buf(&vstr, (alloc), vstr##_buf);
void vstr_init(vstr_t *vstr, size_t alloc);
void vstr_init_len(vstr_t *vstr, size_t len);
void vstr_init_fixed_buf(vstr_t *vstr, size_t alloc, char *buf);
struct _mp_print_t;
void vstr_init_print(vstr_t *vstr, size_t alloc, struct _mp_print_t *print);
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void vstr_clear(vstr_t *vstr);
vstr_t *vstr_new(size_t alloc);
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void vstr_free(vstr_t *vstr);
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static inline void vstr_reset(vstr_t *vstr) {
vstr->len = 0;
}
static inline char *vstr_str(vstr_t *vstr) {
return vstr->buf;
}
static inline size_t vstr_len(vstr_t *vstr) {
return vstr->len;
}
void vstr_hint_size(vstr_t *vstr, size_t size);
char *vstr_extend(vstr_t *vstr, size_t size);
char *vstr_add_len(vstr_t *vstr, size_t len);
char *vstr_null_terminated_str(vstr_t *vstr);
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void vstr_add_byte(vstr_t *vstr, byte v);
void vstr_add_char(vstr_t *vstr, unichar chr);
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void vstr_add_str(vstr_t *vstr, const char *str);
void vstr_add_strn(vstr_t *vstr, const char *str, size_t len);
void vstr_ins_byte(vstr_t *vstr, size_t byte_pos, byte b);
void vstr_ins_char(vstr_t *vstr, size_t char_pos, unichar chr);
void vstr_cut_head_bytes(vstr_t *vstr, size_t bytes_to_cut);
void vstr_cut_tail_bytes(vstr_t *vstr, size_t bytes_to_cut);
void vstr_cut_out_bytes(vstr_t *vstr, size_t byte_pos, size_t bytes_to_cut);
void vstr_printf(vstr_t *vstr, const char *fmt, ...);
/** non-dynamic size-bounded variable buffer/string *************/
#define CHECKBUF(buf, max_size) char buf[max_size + 1]; size_t buf##_len = max_size; char *buf##_p = buf;
#define CHECKBUF_RESET(buf, max_size) buf##_len = max_size; buf##_p = buf;
#define CHECKBUF_APPEND(buf, src, src_len) \
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{ size_t l = MIN(src_len, buf##_len); \
memcpy(buf##_p, src, l); \
buf##_len -= l; \
buf##_p += l; }
#define CHECKBUF_APPEND_0(buf) { *buf##_p = 0; }
#define CHECKBUF_LEN(buf) (buf##_p - buf)
#ifdef va_start
void vstr_vprintf(vstr_t *vstr, const char *fmt, va_list ap);
#endif
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// Debugging helpers
int DEBUG_printf(const char *fmt, ...);
extern mp_uint_t mp_verbose_flag;
/** float internals *************/
#if MICROPY_PY_BUILTINS_FLOAT
#if MICROPY_FLOAT_IMPL == MICROPY_FLOAT_IMPL_DOUBLE
#define MP_FLOAT_EXP_BITS (11)
#define MP_FLOAT_FRAC_BITS (52)
typedef uint64_t mp_float_uint_t;
#elif MICROPY_FLOAT_IMPL == MICROPY_FLOAT_IMPL_FLOAT
#define MP_FLOAT_EXP_BITS (8)
#define MP_FLOAT_FRAC_BITS (23)
typedef uint32_t mp_float_uint_t;
#endif
#define MP_FLOAT_EXP_BIAS ((1 << (MP_FLOAT_EXP_BITS - 1)) - 1)
typedef union _mp_float_union_t {
mp_float_t f;
#if MP_ENDIANNESS_LITTLE
struct {
mp_float_uint_t frc : MP_FLOAT_FRAC_BITS;
mp_float_uint_t exp : MP_FLOAT_EXP_BITS;
mp_float_uint_t sgn : 1;
} p;
#else
struct {
mp_float_uint_t sgn : 1;
mp_float_uint_t exp : MP_FLOAT_EXP_BITS;
mp_float_uint_t frc : MP_FLOAT_FRAC_BITS;
} p;
#endif
mp_float_uint_t i;
} mp_float_union_t;
#endif // MICROPY_PY_BUILTINS_FLOAT
#endif // MICROPY_INCLUDED_PY_MISC_H