Ubuntu Manpage: ipsec_atoaddr, ipsec_addrtoa, ipsec_atosubnet, ipsec_subnettoa

NAME

       ipsec_atoaddr,   ipsec_addrtoa,   ipsec_atosubnet,   ipsec_subnettoa  -  convert  Internet
       addresses and Subnet masks to and from ASCII

SYNOPSIS

       #include <freeswan.h>

       const char *atoaddr(const char *src, size_t srclen,
           struct in_addr *addr);
       size_t addrtoa(struct in_addr addr, int format,
           char *dst, size_t dstlen);

       const char *atosubnet(const char *src, size_t srclen,
           struct in_addr *addr, struct in_addr *mask);
       size_t subnettoa(struct in_addr addr, struct in_addr mask,
           int format, char *dst, size_t dstlen);

DESCRIPTION

These functions are obsolete; see ipsec_ttoaddr(3) for their replacements.

Atoaddr converts an ASCII name or dotted-decimal address into a binary address (in network
byte order). Addrtoa does the reverse conversion, back to an ASCII dotted-decimal
address. Atosubnet and subnettoa do likewise for the ``address/mask'' ASCII form used to
write a specification of a subnet.

An address is specified in ASCII as a dotted-decimal address (e.g. 1.2.3.4), an eight-
digit network-order hexadecimal number with the usual C prefix (e.g. 0x01020304, which is
synonymous with 1.2.3.4), an eight-digit host-order hexadecimal number with a 0h prefix
(e.g. 0h01020304, which is synonymous with 1.2.3.4 on a big-endian host and 4.3.2.1 on a
little-endian host), a DNS name to be looked up via gethostbyname(3), or an old-style
network name to be looked up via getnetbyname(3).

A dotted-decimal address may be incomplete, in which case ASCII-to-binary conversion
implicitly appends as many instances of .0 as necessary to bring it up to four components.
The components of a dotted-decimal address are always taken as decimal, and leading zeros
are ignored. For example, 10 is synonymous with 10.0.0.0, and 128.009.000.032 is
synonymous with 128.9.0.32 (the latter example is verbatim from RFC 1166). The result of
addrtoa is always complete and does not contain leading zeros.

The letters in a hexadecimal address may be uppercase or lowercase or any mixture thereof.
Use of hexadecimal addresses is strongly discouraged; they are included only to save
hassles when dealing with the handful of perverted programs which already print network
addresses in hexadecimal.

DNS names may be complete (optionally terminated with a ``.'') or incomplete, and are
looked up as specified by local system configuration (see resolver(5)). The h_addr value
returned by gethostbyname(3) is used, so with current DNS implementations, the result when
the name corresponds to more than one address is difficult to predict. Name lookup
resorts to getnetbyname(3) only if gethostbyname(3) fails.

A subnet specification is of the form network/mask. The network and mask can be any form
acceptable to atoaddr. In addition, the mask can be a decimal integer (leading zeros
ignored) giving a bit count, in which case it stands for a mask with that number of high
bits on and all others off (e.g., 24 means 255.255.255.0). In any case, the mask must be
contiguous (a sequence of high bits on and all remaining low bits off). As a special
case, the subnet specification %default is a synonym for 0.0.0.0/0.

Atosubnet ANDs the mask with the address before returning, so that any non-network bits in
the address are turned off (e.g., 10.1.2.3/24 is synonymous with 10.1.2.0/24). Subnettoa
generates the decimal-integer-bit-count form of the mask, with no leading zeros, unless
the mask is non-contiguous.

The srclen parameter of atoaddr and atosubnet specifies the length of the ASCII string
pointed to by src; it is an error for there to be anything else (e.g., a terminating NUL)
within that length. As a convenience for cases where an entire NUL-terminated string is
to be converted, a srclen value of 0 is taken to mean strlen(src).

The dstlen parameter of addrtoa and subnettoa specifies the size of the dst parameter;
under no circumstances are more than dstlen bytes written to dst. A result which will not
fit is truncated. Dstlen can be zero, in which case dst need not be valid and no result
is written, but the return value is unaffected; in all other cases, the (possibly
truncated) result is NUL-terminated. The freeswan.h header file defines constants,
ADDRTOA_BUF and SUBNETTOA_BUF, which are the sizes of buffers just large enough for worst-
case results.

The format parameter of addrtoa and subnettoa specifies what format is to be used for the
conversion. The value 0 (not the ASCII character '0', but a zero value) specifies a
reasonable default, and is in fact the only format currently available. This parameter is
a hedge against future needs.

The ASCII-to-binary functions return NULL for success and a pointer to a string-literal
error message for failure; see DIAGNOSTICS. The binary-to-ASCII functions return 0 for a
failure, and otherwise always return the size of buffer which would be needed to
accommodate the full conversion result, including terminating NUL; it is the caller's
responsibility to check this against the size of the provided buffer to determine whether
truncation has occurred.

DIAGNOSTICS

       Fatal errors in atoaddr are: empty input; attempt to allocate temporary storage for a very
       long name failed; name lookup failed; syntax error in dotted-decimal form;  dotted-decimal
       component too large to fit in 8 bits.

       Fatal  errors  in  atosubnet  are:  no / in src; atoaddr error in conversion of network or
       mask; bit-count mask too big; mask non-contiguous.

       Fatal errors in addrtoa and subnettoa are: unknown format.

HISTORY

       Written for the FreeS/WAN project by Henry Spencer.

BUGS