mirror of
https://github.com/DarkFlippers/unleashed-firmware
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287 lines
7.9 KiB
C
287 lines
7.9 KiB
C
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/*
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* Copyright (c) 2016 Cesanta Software Limited
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* All rights reserved
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*/
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#ifndef MJS_CORE_PUBLIC_H_
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#define MJS_CORE_PUBLIC_H_
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#if !defined(_MSC_VER) || _MSC_VER >= 1700
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#include <stdint.h>
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#else
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typedef unsigned __int64 uint64_t;
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typedef int int32_t;
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typedef unsigned char uint8_t;
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#endif
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#include <stdio.h>
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#include <stddef.h>
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#include "mjs_features.h"
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#if defined(__cplusplus)
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extern "C" {
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#endif /* __cplusplus */
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#ifndef MJS_ENABLE_DEBUG
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#define MJS_ENABLE_DEBUG 0
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#endif
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/*
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* Double-precision floating-point number, IEEE 754
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*
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* 64 bit (8 bytes) in total
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* 1 bit sign
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* 11 bits exponent
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* 52 bits mantissa
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* 7 6 5 4 3 2 1 0
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* seeeeeee|eeeemmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm
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*
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* If an exponent is all-1 and mantissa is all-0, then it is an INFINITY:
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* 11111111|11110000|00000000|00000000|00000000|00000000|00000000|00000000
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*
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* If an exponent is all-1 and mantissa's MSB is 1, it is a quiet NaN:
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* 11111111|11111000|00000000|00000000|00000000|00000000|00000000|00000000
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*
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* MJS NaN-packing:
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* sign and exponent is 0xfff
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* 4 bits specify type (tag), must be non-zero
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* 48 bits specify value
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*
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* 11111111|1111tttt|vvvvvvvv|vvvvvvvv|vvvvvvvv|vvvvvvvv|vvvvvvvv|vvvvvvvv
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* NaN marker |type| 48-bit placeholder for values: pointers, strings
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*
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* On 64-bit platforms, pointers are really 48 bit only, so they can fit,
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* provided they are sign extended
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*/
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typedef uint64_t mjs_val_t;
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/*
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* A tag is made of the sign bit and the 4 lower order bits of byte 6.
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* So in total we have 32 possible tags.
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*
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* Tag (1,0) however cannot hold a zero payload otherwise it's interpreted as an
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* INFINITY; for simplicity we're just not going to use that combination.
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*/
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#define MAKE_TAG(s, t) ((uint64_t)(s) << 63 | (uint64_t)0x7ff0 << 48 | (uint64_t)(t) << 48)
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#define MJS_TAG_OBJECT MAKE_TAG(1, 1)
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#define MJS_TAG_FOREIGN MAKE_TAG(1, 2)
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#define MJS_TAG_UNDEFINED MAKE_TAG(1, 3)
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#define MJS_TAG_BOOLEAN MAKE_TAG(1, 4)
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#define MJS_TAG_NAN MAKE_TAG(1, 5)
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#define MJS_TAG_STRING_I MAKE_TAG(1, 6) /* Inlined string len < 5 */
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#define MJS_TAG_STRING_5 MAKE_TAG(1, 7) /* Inlined string len 5 */
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#define MJS_TAG_STRING_O MAKE_TAG(1, 8) /* Owned string */
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#define MJS_TAG_STRING_F MAKE_TAG(1, 9) /* Foreign string */
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#define MJS_TAG_STRING_C MAKE_TAG(1, 10) /* String chunk */
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#define MJS_TAG_STRING_D MAKE_TAG(1, 11) /* Dictionary string */
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#define MJS_TAG_ARRAY MAKE_TAG(1, 12)
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#define MJS_TAG_FUNCTION MAKE_TAG(1, 13)
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#define MJS_TAG_FUNCTION_FFI MAKE_TAG(1, 14)
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#define MJS_TAG_NULL MAKE_TAG(1, 15)
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#define MJS_TAG_ARRAY_BUF MAKE_TAG(0, 1) /* ArrayBuffer */
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#define MJS_TAG_ARRAY_BUF_VIEW MAKE_TAG(0, 2) /* DataView */
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#define MJS_TAG_MASK MAKE_TAG(1, 15)
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/* This if-0 is a dirty workaround to force etags to pick `struct mjs` */
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#if 0
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/* Opaque structure. MJS engine context. */
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struct mjs {
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/* ... */
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};
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#endif
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struct mjs;
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enum mjs_type {
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/* Primitive types */
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MJS_TYPE_UNDEFINED,
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MJS_TYPE_NULL,
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MJS_TYPE_BOOLEAN,
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MJS_TYPE_NUMBER,
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MJS_TYPE_STRING,
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MJS_TYPE_FOREIGN,
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MJS_TYPE_ARRAY_BUF,
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MJS_TYPE_ARRAY_BUF_VIEW,
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/* Different classes of Object type */
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MJS_TYPE_OBJECT_GENERIC,
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MJS_TYPE_OBJECT_ARRAY,
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MJS_TYPE_OBJECT_FUNCTION,
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/*
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* TODO(dfrank): if we support prototypes, need to add items for them here
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*/
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MJS_TYPES_CNT
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};
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typedef enum mjs_err {
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MJS_OK,
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MJS_SYNTAX_ERROR,
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MJS_REFERENCE_ERROR,
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MJS_TYPE_ERROR,
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MJS_OUT_OF_MEMORY,
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MJS_INTERNAL_ERROR,
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MJS_NOT_IMPLEMENTED_ERROR,
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MJS_FILE_READ_ERROR,
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MJS_BAD_ARGS_ERROR,
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MJS_NEED_EXIT,
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MJS_ERRS_CNT
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} mjs_err_t;
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typedef void (*mjs_flags_poller_t)(struct mjs* mjs);
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struct mjs;
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/* Create MJS instance */
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struct mjs* mjs_create(void* context);
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/* Destroy MJS instance */
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void mjs_destroy(struct mjs* mjs);
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mjs_val_t mjs_get_global(struct mjs* mjs);
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/*
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* Tells the GC about an MJS value variable/field owned by C code.
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*
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* The user's C code should own mjs_val_t variables if the value's lifetime
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* crosses any invocation of `mjs_exec()` and friends, including `mjs_call()`.
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*
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* The registration of the variable prevents the GC from mistakenly treat the
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* object as garbage.
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*
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* User code should also explicitly disown the variables with `mjs_disown()`
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* once it goes out of scope or the structure containing the mjs_val_t field is
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* freed.
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*
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* Consider the following examples:
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*
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* Correct (owning is not necessary):
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* ```c
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* mjs_val_t res;
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* mjs_exec(mjs, "....some script", &res);
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* // ... use res somehow
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*
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* mjs_val_t res;
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* mjs_exec(mjs, "....some script2", &res);
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* // ... use new res somehow
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* ```
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*
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* WRONG:
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* ```c
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* mjs_val_t res1;
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* mjs_exec(mjs, "....some script", &res1);
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*
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* mjs_val_t res2;
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* mjs_exec(mjs, "....some script2", &res2);
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*
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* // ... use res1 (WRONG!) and res2
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* ```
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*
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* The code above is wrong, because after the second invocation of
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* `mjs_exec()`, the value of `res1` is invalidated.
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*
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* Correct (res1 is owned)
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* ```c
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* mjs_val_t res1 = MJS_UNDEFINED;
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* mjs_own(mjs, &res1);
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* mjs_exec(mjs, "....some script", &res1);
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*
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* mjs_val_t res2 = MJS_UNDEFINED;
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* mjs_exec(mjs, "....some script2", &res2);
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*
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* // ... use res1 and res2
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* mjs_disown(mjs, &res1);
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* ```
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*
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* NOTE that we explicly initialized `res1` to a valid value before owning it
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* (in this case, the value is `MJS_UNDEFINED`). Owning an uninitialized
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* variable is an undefined behaviour.
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*
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* Of course, it's not an error to own a variable even if it's not mandatory:
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* e.g. in the last example we could own both `res1` and `res2`. Probably it
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* would help us in the future, when we refactor the code so that `res2` has to
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* be owned, and we could forget to do that.
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*
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* Also, if the user code has some C function called from MJS, and in this C
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* function some MJS value (`mjs_val_t`) needs to be stored somewhere and to
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* stay alive after the C function has returned, it also needs to be properly
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* owned.
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*/
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void mjs_own(struct mjs* mjs, mjs_val_t* v);
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/*
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* Disowns the value previously owned by `mjs_own()`.
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*
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* Returns 1 if value is found, 0 otherwise.
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*/
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int mjs_disown(struct mjs* mjs, mjs_val_t* v);
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mjs_err_t mjs_set_errorf(struct mjs* mjs, mjs_err_t err, const char* fmt, ...);
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void mjs_exit(struct mjs* mjs);
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void mjs_set_exec_flags_poller(struct mjs* mjs, mjs_flags_poller_t poller);
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void* mjs_get_context(struct mjs* mjs);
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/*
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* If there is no error message already set, then it's equal to
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* `mjs_set_errorf()`.
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*
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* Otherwise, an old message gets prepended with the new one, followed by a
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* colon. (the previously set error code is kept)
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*/
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mjs_err_t mjs_prepend_errorf(struct mjs* mjs, mjs_err_t err, const char* fmt, ...);
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/*
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* Print the last error details. If print_stack_trace is non-zero, also
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* print stack trace. `msg` is the message which gets prepended to the actual
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* error message, if it's NULL, then "MJS error" is used.
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*/
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void mjs_print_error(struct mjs* mjs, FILE* fp, const char* msg, int print_stack_trace);
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/*
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* return a string representation of an error.
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* the error string might be overwritten by calls to `mjs_set_errorf`.
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*/
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const char* mjs_strerror(struct mjs* mjs, enum mjs_err err);
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const char* mjs_get_stack_trace(struct mjs* mjs);
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/*
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* Sets whether *.jsc files are generated when *.js file is executed. By
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* default it's 0.
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*
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* If either `MJS_GENERATE_JSC` or `CS_MMAP` is off, then this function has no
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* effect.
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*/
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void mjs_set_generate_jsc(struct mjs* mjs, int generate_jsc);
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/*
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* When invoked from a cfunction, returns number of arguments passed to the
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* current JS function call.
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*/
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int mjs_nargs(struct mjs* mjs);
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/*
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* When invoked from a cfunction, returns n-th argument to the current JS
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* function call.
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*/
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mjs_val_t mjs_arg(struct mjs* mjs, int n);
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/*
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* Sets return value for the current JS function call.
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*/
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void mjs_return(struct mjs* mjs, mjs_val_t v);
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#if defined(__cplusplus)
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}
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#endif /* __cplusplus */
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#endif /* MJS_CORE_PUBLIC_H_ */
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