2023-02-24 08:09:26 +08:00
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#ifndef HEX_H
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#define HEX_H
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2023-04-23 04:17:20 +08:00
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#include "hash-ll.h"
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2023-02-24 08:09:26 +08:00
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extern const signed char hexval_table[256];
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static inline unsigned int hexval(unsigned char c)
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{
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return hexval_table[c];
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}
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/*
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* Convert two consecutive hexadecimal digits into a char. Return a
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* negative value on error. Don't run over the end of short strings.
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*/
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static inline int hex2chr(const char *s)
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{
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unsigned int val = hexval(s[0]);
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return (val & ~0xf) ? val : (val << 4) | hexval(s[1]);
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}
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/*
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* Try to read a SHA1 in hexadecimal format from the 40 characters
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* starting at hex. Write the 20-byte result to sha1 in binary form.
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* Return 0 on success. Reading stops if a NUL is encountered in the
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* input, so it is safe to pass this function an arbitrary
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* null-terminated string.
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*/
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int get_sha1_hex(const char *hex, unsigned char *sha1);
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int get_oid_hex(const char *hex, struct object_id *sha1);
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/* Like get_oid_hex, but for an arbitrary hash algorithm. */
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int get_oid_hex_algop(const char *hex, struct object_id *oid, const struct git_hash_algo *algop);
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/*
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* Read `len` pairs of hexadecimal digits from `hex` and write the
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* values to `binary` as `len` bytes. Return 0 on success, or -1 if
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* the input does not consist of hex digits).
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*/
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int hex_to_bytes(unsigned char *binary, const char *hex, size_t len);
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/*
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* Convert a binary hash in "unsigned char []" or an object name in
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* "struct object_id *" to its hex equivalent. The `_r` variant is reentrant,
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* and writes the NUL-terminated output to the buffer `out`, which must be at
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* least `GIT_MAX_HEXSZ + 1` bytes, and returns a pointer to out for
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* convenience.
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*
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* The non-`_r` variant returns a static buffer, but uses a ring of 4
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* buffers, making it safe to make multiple calls for a single statement, like:
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*
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* printf("%s -> %s", hash_to_hex(one), hash_to_hex(two));
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* printf("%s -> %s", oid_to_hex(one), oid_to_hex(two));
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*/
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char *hash_to_hex_algop_r(char *buffer, const unsigned char *hash, const struct git_hash_algo *);
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char *oid_to_hex_r(char *out, const struct object_id *oid);
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char *hash_to_hex_algop(const unsigned char *hash, const struct git_hash_algo *); /* static buffer result! */
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char *hash_to_hex(const unsigned char *hash); /* same static buffer */
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char *oid_to_hex(const struct object_id *oid); /* same static buffer */
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/*
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* Parse a 40-character hexadecimal object ID starting from hex, updating the
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* pointer specified by end when parsing stops. The resulting object ID is
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* stored in oid. Returns 0 on success. Parsing will stop on the first NUL or
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* other invalid character. end is only updated on success; otherwise, it is
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* unmodified.
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*/
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int parse_oid_hex(const char *hex, struct object_id *oid, const char **end);
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/* Like parse_oid_hex, but for an arbitrary hash algorithm. */
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int parse_oid_hex_algop(const char *hex, struct object_id *oid, const char **end,
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const struct git_hash_algo *algo);
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/*
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* These functions work like get_oid_hex and parse_oid_hex, but they will parse
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* a hex value for any algorithm. The algorithm is detected based on the length
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* and the algorithm in use is returned. If this is not a hex object ID in any
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* algorithm, returns GIT_HASH_UNKNOWN.
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*/
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int get_oid_hex_any(const char *hex, struct object_id *oid);
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int parse_oid_hex_any(const char *hex, struct object_id *oid, const char **end);
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#endif
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