libmtp: /tmp/libmtp-0.0.18/src/gphoto2-endian.h Source File

00001 /* This file is generated automatically by configure */
00002 /* It is valid only for the system type i486-slackware-linux */
00003 
00004 #ifndef __BYTEORDER_H
00005 #define __BYTEORDER_H
00006 
00007 /* ntohl and relatives live here */
00008 #include <arpa/inet.h>
00009 
00010 /* Define generic byte swapping functions */
00011 #include <byteswap.h>
00012 #define swap16(x) bswap_16(x)
00013 #define swap32(x) bswap_32(x)
00014 #define swap64(x) bswap_64(x)
00015 
00016 /* The byte swapping macros have the form: */
00017 /*   EENN[a]toh or htoEENN[a] where EE is be (big endian) or */
00018 /* le (little-endian), NN is 16 or 32 (number of bits) and a, */
00019 /* if present, indicates that the endian side is a pointer to an */
00020 /* array of uint8_t bytes instead of an integer of the specified length. */
00021 /* h refers to the host's ordering method. */
00022 
00023 /* So, to convert a 32-bit integer stored in a buffer in little-endian */
00024 /* format into a uint32_t usable on this machine, you could use: */
00025 /*   uint32_t value = le32atoh(&buf[3]); */
00026 /* To put that value back into the buffer, you could use: */
00027 /*   htole32a(&buf[3], value); */
00028 
00029 /* Define aliases for the standard byte swapping macros */
00030 /* Arguments to these macros must be properly aligned on natural word */
00031 /* boundaries in order to work properly on all architectures */
00032 #define htobe16(x) htons(x)
00033 #define htobe32(x) htonl(x)
00034 #define be16toh(x) ntohs(x)
00035 #define be32toh(x) ntohl(x)
00036 
00037 #define HTOBE16(x) (x) = htobe16(x)
00038 #define HTOBE32(x) (x) = htobe32(x)
00039 #define BE32TOH(x) (x) = be32toh(x)
00040 #define BE16TOH(x) (x) = be16toh(x)
00041 
00042 /* On little endian machines, these macros are null */
00043 #define htole16(x)      (x)
00044 #define htole32(x)      (x)
00045 #define htole64(x)      (x)
00046 #define le16toh(x)      (x)
00047 #define le32toh(x)      (x)
00048 #define le64toh(x)      (x)
00049 
00050 #define HTOLE16(x)      (void) (x)
00051 #define HTOLE32(x)      (void) (x)
00052 #define HTOLE64(x)      (void) (x)
00053 #define LE16TOH(x)      (void) (x)
00054 #define LE32TOH(x)      (void) (x)
00055 #define LE64TOH(x)      (void) (x)
00056 
00057 /* These don't have standard aliases */
00058 #define htobe64(x)      swap64(x)
00059 #define be64toh(x)      swap64(x)
00060 
00061 #define HTOBE64(x)      (x) = htobe64(x)
00062 #define BE64TOH(x)      (x) = be64toh(x)
00063 
00064 /* Define the C99 standard length-specific integer types */
00065 #include "libptp-stdint.h"
00066 
00067 /* Here are some macros to create integers from a byte array */
00068 /* These are used to get and put integers from/into a uint8_t array */
00069 /* with a specific endianness.  This is the most portable way to generate */
00070 /* and read messages to a network or serial device.  Each member of a */
00071 /* packet structure must be handled separately. */
00072 
00073 /* The i386 and compatibles can handle unaligned memory access, */
00074 /* so use the optimized macros above to do this job */
00075 #define be16atoh(x)     be16toh(*(uint16_t*)(x))
00076 #define be32atoh(x)     be32toh(*(uint32_t*)(x))
00077 #define be64atoh(x)     be64toh(*(uint64_t*)(x))
00078 #define le16atoh(x)     le16toh(*(uint16_t*)(x))
00079 #define le32atoh(x)     le32toh(*(uint32_t*)(x))
00080 #define le64atoh(x)     le64toh(*(uint64_t*)(x))
00081 
00082 #define htobe16a(a,x)   *(uint16_t*)(a) = htobe16(x)
00083 #define htobe32a(a,x)   *(uint32_t*)(a) = htobe32(x)
00084 #define htobe64a(a,x)   *(uint64_t*)(a) = htobe64(x)
00085 #define htole16a(a,x)   *(uint16_t*)(a) = htole16(x)
00086 #define htole32a(a,x)   *(uint32_t*)(a) = htole32(x)
00087 #define htole64a(a,x)   *(uint64_t*)(a) = htole64(x)
00088 
00089 #endif /*__BYTEORDER_H*/