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/*
* util.h
*
* helper function header file
*
* a Net::DNS like library for C
*
* (c) NLnet Labs, 2004
*
* See the file LICENSE for the license
*/
#ifndef _UTIL_H
#define _UTIL_H
#include <inttypes.h>
#include <sys/types.h>
#include <unistd.h>
#include <ldns/common.h>
#include <time.h>
#include <stdio.h>
#ifdef __cplusplus
extern "C" {
#endif
#define dprintf(X,Y) fprintf(stderr, (X), (Y))
/* #define dprintf(X, Y) */
#define LDNS_VERSION "1.6.12"
#define LDNS_REVISION ((1<<16)|(6<<8)|(12))
/**
* splint static inline workaround
*/
#ifdef S_SPLINT_S
# define INLINE
#else
# ifdef SWIG
# define INLINE static
# else
# define INLINE static inline
# endif
#endif
/**
* Memory management macros
*/
#define LDNS_MALLOC(type) LDNS_XMALLOC(type, 1)
#define LDNS_XMALLOC(type, count) ((type *) malloc((count) * sizeof(type)))
#define LDNS_CALLOC(type, count) ((type *) calloc((count), sizeof(type)))
#define LDNS_REALLOC(ptr, type) LDNS_XREALLOC((ptr), type, 1)
#define LDNS_XREALLOC(ptr, type, count) \
((type *) realloc((ptr), (count) * sizeof(type)))
#define LDNS_FREE(ptr) \
do { free((ptr)); (ptr) = NULL; } while (0)
#define LDNS_DEP printf("DEPRECATED FUNCTION!\n");
/*
* Copy data allowing for unaligned accesses in network byte order
* (big endian).
*/
INLINE uint16_t
ldns_read_uint16(const void *src)
{
#ifdef ALLOW_UNALIGNED_ACCESSES
return ntohs(*(uint16_t *) src);
#else
uint8_t *p = (uint8_t *) src;
return ((uint16_t) p[0] << 8) | (uint16_t) p[1];
#endif
}
INLINE uint32_t
ldns_read_uint32(const void *src)
{
#ifdef ALLOW_UNALIGNED_ACCESSES
return ntohl(*(uint32_t *) src);
#else
uint8_t *p = (uint8_t *) src;
return ( ((uint32_t) p[0] << 24)
| ((uint32_t) p[1] << 16)
| ((uint32_t) p[2] << 8)
| (uint32_t) p[3]);
#endif
}
/*
* Copy data allowing for unaligned accesses in network byte order
* (big endian).
*/
INLINE void
ldns_write_uint16(void *dst, uint16_t data)
{
#ifdef ALLOW_UNALIGNED_ACCESSES
* (uint16_t *) dst = htons(data);
#else
uint8_t *p = (uint8_t *) dst;
p[0] = (uint8_t) ((data >> 8) & 0xff);
p[1] = (uint8_t) (data & 0xff);
#endif
}
INLINE void
ldns_write_uint32(void *dst, uint32_t data)
{
#ifdef ALLOW_UNALIGNED_ACCESSES
* (uint32_t *) dst = htonl(data);
#else
uint8_t *p = (uint8_t *) dst;
p[0] = (uint8_t) ((data >> 24) & 0xff);
p[1] = (uint8_t) ((data >> 16) & 0xff);
p[2] = (uint8_t) ((data >> 8) & 0xff);
p[3] = (uint8_t) (data & 0xff);
#endif
}
/* warning. */
INLINE void
ldns_write_uint64_as_uint48(void *dst, uint64_t data)
{
uint8_t *p = (uint8_t *) dst;
p[0] = (uint8_t) ((data >> 40) & 0xff);
p[1] = (uint8_t) ((data >> 32) & 0xff);
p[2] = (uint8_t) ((data >> 24) & 0xff);
p[3] = (uint8_t) ((data >> 16) & 0xff);
p[4] = (uint8_t) ((data >> 8) & 0xff);
p[5] = (uint8_t) (data & 0xff);
}
/**
* Structure to do a Schwartzian-like transformation, for instance when
* sorting. If you need a transformation on the objects that are sorted,
* you can sue this to store the transformed values, so you do not
* need to do the transformation again for each comparison
*/
struct ldns_schwartzian_compare_struct {
void *original_object;
void *transformed_object;
};
/** A general purpose lookup table
*
* Lookup tables are arrays of (id, name) pairs,
* So you can for instance lookup the RCODE 3, which is "NXDOMAIN",
* and vice versa. The lookup tables themselves are defined wherever needed,
* for instance in \ref host2str.c
*/
struct ldns_struct_lookup_table {
int id;
const char *name;
};
typedef struct ldns_struct_lookup_table ldns_lookup_table;
/**
* Looks up the table entry by name, returns NULL if not found.
* \param[in] table the lookup table to search in
* \param[in] name what to search for
* \return the item found
*/
ldns_lookup_table *ldns_lookup_by_name(ldns_lookup_table table[],
const char *name);
/**
* Looks up the table entry by id, returns NULL if not found.
* \param[in] table the lookup table to search in
* \param[in] id what to search for
* \return the item found
*/
ldns_lookup_table *ldns_lookup_by_id(ldns_lookup_table table[], int id);
/**
* Returns the value of the specified bit
* The bits are counted from left to right, so bit #0 is the
* left most bit.
* \param[in] bits array holding the bits
* \param[in] index to the wanted bit
* \return
*/
int ldns_get_bit(uint8_t bits[], size_t index);
/**
* Returns the value of the specified bit
* The bits are counted from right to left, so bit #0 is the
* right most bit.
* \param[in] bits array holding the bits
* \param[in] index to the wanted bit
* \return 1 or 0 depending no the bit state
*/
int ldns_get_bit_r(uint8_t bits[], size_t index);
/**
* sets the specified bit in the specified byte to
* 1 if value is true, 0 if false
* The bits are counted from right to left, so bit #0 is the
* right most bit.
* \param[in] byte the bit to set the bit in
* \param[in] bit_nr the bit to set (0 <= n <= 7)
* \param[in] value whether to set the bit to 1 or 0
* \return 1 or 0 depending no the bit state
*/
void ldns_set_bit(uint8_t *byte, int bit_nr, bool value);
/**
* Returns the value of a to the power of b
* (or 1 of b < 1)
*/
/*@unused@*/
INLINE long
ldns_power(long a, long b) {
long result = 1;
while (b > 0) {
if (b & 1) {
result *= a;
if (b == 1) {
return result;
}
}
a *= a;
b /= 2;
}
return result;
}
/**
* Returns the int value of the given (hex) digit
* \param[in] ch the hex char to convert
* \return the converted decimal value
*/
int ldns_hexdigit_to_int(char ch);
/**
* Returns the char (hex) representation of the given int
* \param[in] ch the int to convert
* \return the converted hex char
*/
char ldns_int_to_hexdigit(int ch);
/**
* Converts a hex string to binary data
*
* \param[out] data The binary result is placed here.
* At least strlen(str)/2 bytes should be allocated
* \param[in] str The hex string to convert.
* This string should not contain spaces
* \return The number of bytes of converted data, or -1 if one of the arguments * is NULL, or -2 if the string length is not an even number
*/
int
ldns_hexstring_to_data(uint8_t *data, const char *str);
/**
* Show the internal library version
* \return a string with the version in it
*/
const char * ldns_version(void);
/**
* Convert TM to seconds since epoch (midnight, January 1st, 1970).
* Like timegm(3), which is not always available.
* \param[in] tm a struct tm* with the date
* \return the seconds since epoch
*/
time_t mktime_from_utc(const struct tm *tm);
/**
* The function interprets time as the number of seconds since epoch
* with respect to now using serial arithmitics (rfc1982).
* That number of seconds is then converted to broken-out time information.
* This is especially usefull when converting the inception and expiration
* fields of RRSIG records.
*
* \param[in] time number of seconds since epoch (midnight, January 1st, 1970)
* to be intepreted as a serial arithmitics number relative to now.
* \param[in] now number of seconds since epoch (midnight, January 1st, 1970)
* to which the time value is compared to determine the final value.
* \param[out] result the struct with the broken-out time information
* \return result on success or NULL on error
*/
struct tm * ldns_serial_arithmitics_gmtime_r(int32_t time, time_t now, struct tm *result);
/**
* Seed the random function.
* If the file descriptor is specified, the random generator is seeded with
* data from that file. If not, /dev/urandom is used.
*
* applications should call this if they need entropy data within ldns
* If openSSL is available, it is automatically seeded from /dev/urandom
* or /dev/random.
*
* If you need more entropy, or have no openssl available, this function
* MUST be called at the start of the program
*
* If openssl *is* available, this function just adds more entropy
*
* \param[in] fd a file providing entropy data for the seed
* \param[in] size the number of bytes to use as entropy data. If this is 0,
* only the minimal amount is taken (usually 4 bytes)
* \return 0 if seeding succeeds, 1 if it fails
*/
int ldns_init_random(FILE *fd, unsigned int size);
/**
* Get random number.
* \return random number.
*
*/
uint16_t ldns_get_random(void);
/**
* Encode data as BubbleBabble
*
* \param[in] data a pointer to data to be encoded
* \param[in] len size the number of bytes of data
* \return a string of BubbleBabble
*/
char *ldns_bubblebabble(uint8_t *data, size_t len);
#ifndef B32_NTOP
int ldns_b32_ntop(uint8_t const *src, size_t srclength,
char *target, size_t targsize);
int b32_ntop(uint8_t const *src, size_t srclength,
char *target, size_t targsize);
int ldns_b32_ntop_extended_hex(uint8_t const *src, size_t srclength,
char *target, size_t targsize);
int b32_ntop_extended_hex(uint8_t const *src, size_t srclength,
char *target, size_t targsize);
/**
* calculates the size needed to store the result of b32_ntop
*/
/*@unused@*/
INLINE size_t ldns_b32_ntop_calculate_size(size_t srcsize)
{
size_t result = ((((srcsize / 5) * 8) - 2) + 2);
return result;
}
#endif /* !B32_NTOP */
#ifndef B32_PTON
int ldns_b32_pton(char const *src, size_t hashed_owner_str_len, uint8_t *target, size_t targsize);
int b32_pton(char const *src, size_t hashed_owner_str_len, uint8_t *target, size_t targsize);
int ldns_b32_pton_extended_hex(char const *src, size_t hashed_owner_str_len, uint8_t *target, size_t targsize);
int b32_pton_extended_hex(char const *src, size_t hashed_owner_str_len, uint8_t *target, size_t targsize);
/**
* calculates the size needed to store the result of b32_pton
*/
/*@unused@*/
INLINE size_t ldns_b32_pton_calculate_size(size_t srcsize)
{
size_t result = ((((srcsize) / 8) * 5));
return result;
}
#endif /* !B32_PTON */
INLINE time_t ldns_time(time_t *t) { return time(t); }
#ifdef __cplusplus
}
#endif
#endif /* !_UTIL_H */
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