/*
* libvirt-utils.h: misc helper APIs for python binding
*
* Copyright (C) 2013 Red Hat, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library. If not, see
* .
*
*/
#ifndef __LIBVIRT_UTILS_H__
# define __LIBVIRT_UTILS_H__
# include
# include
# define STREQ(a,b) (strcmp(a,b) == 0)
# ifndef MIN
# define MIN(a,b) (((a) < (b)) ? (a) : (b))
# endif
/**
* libvirt.h provides this as of version 1.2.0, but we want to be able
* to support older versions of libvirt so copy and paste the macro from
* libvirt.h
*/
# ifndef LIBVIR_CHECK_VERSION
# define LIBVIR_CHECK_VERSION(major, minor, micro) \
((major) * 1000000 + (minor) * 1000 + (micro) <= LIBVIR_VERSION_NUMBER)
# endif
/* Return 1 if an array of N objects, each of size S, cannot exist due
to size arithmetic overflow. S must be positive and N must be
nonnegative. This is a macro, not a function, so that it
works correctly even when SIZE_MAX < N.
By gnulib convention, SIZE_MAX represents overflow in size
calculations, so the conservative dividend to use here is
SIZE_MAX - 1, since SIZE_MAX might represent an overflowed value.
However, malloc (SIZE_MAX) fails on all known hosts where
sizeof (ptrdiff_t) <= sizeof (size_t), so do not bother to test for
exactly-SIZE_MAX allocations on such hosts; this avoids a test and
branch when S is known to be 1. */
# define xalloc_oversized(n, s) \
((size_t) (sizeof (ptrdiff_t) <= sizeof (size_t) ? -1 : -2) / (s) < (n))
/* The __attribute__((__warn_unused_result__)) feature
is available in gcc versions 3.4 and newer,
while the typeof feature has been available since 2.7 at least. */
# if 3 < __GNUC__ + (4 <= __GNUC_MINOR__)
# define ignore_value(x) \
(__extension__ ({ __typeof__ (x) __x = (x); (void) __x; }))
# else
# define ignore_value(x) ((void) (x))
# endif
# ifdef __GNUC__
# ifndef __GNUC_PREREQ
# if defined __GNUC__ && defined __GNUC_MINOR__
# define __GNUC_PREREQ(maj, min) \
((__GNUC__ << 16) + __GNUC_MINOR__ >= ((maj) << 16) + (min))
# else
# define __GNUC_PREREQ(maj, min) 0
# endif
# endif /* __GNUC_PREREQ */
/**
* ATTRIBUTE_UNUSED:
*
* Macro to flag consciously unused parameters to functions
*/
# ifndef ATTRIBUTE_UNUSED
# define ATTRIBUTE_UNUSED __attribute__((__unused__))
# endif
/* gcc's handling of attribute nonnull is less than stellar - it does
* NOT improve diagnostics, and merely allows gcc to optimize away
* null code checks even when the caller manages to pass null in spite
* of the attribute, leading to weird crashes. Coverity, on the other
* hand, knows how to do better static analysis based on knowing
* whether a parameter is nonnull. Make this attribute conditional
* based on whether we are compiling for real or for analysis, while
* still requiring correct gcc syntax when it is turned off. See also
* http://gcc.gnu.org/bugzilla/show_bug.cgi?id=17308 */
# ifndef ATTRIBUTE_NONNULL
# if __GNUC_PREREQ (3, 3)
# if STATIC_ANALYSIS
# define ATTRIBUTE_NONNULL(m) __attribute__((__nonnull__(m)))
# else
# define ATTRIBUTE_NONNULL(m) __attribute__(())
# endif
# else
# define ATTRIBUTE_NONNULL(m)
# endif
# endif
# ifndef ATTRIBUTE_RETURN_CHECK
# if __GNUC_PREREQ (3, 4)
# define ATTRIBUTE_RETURN_CHECK __attribute__((__warn_unused_result__))
# else
# define ATTRIBUTE_RETURN_CHECK
# endif
# endif
# else
# ifndef ATTRIBUTE_UNUSED
# define ATTRIBUTE_UNUSED
# endif
# ifndef ATTRIBUTE_NONNULL
# define ATTRIBUTE_NONNULL(m)
# endif
# ifndef ATTRIBUTE_RETURN_CHECK
# define ATTRIBUTE_RETURN_CHECK
# endif
# endif /* __GNUC__ */
/* Don't call these directly - use the macros below */
int virAlloc(void *ptrptr, size_t size)
ATTRIBUTE_RETURN_CHECK ATTRIBUTE_NONNULL(1);
int virAllocN(void *ptrptr, size_t size, size_t count)
ATTRIBUTE_RETURN_CHECK ATTRIBUTE_NONNULL(1);
int virReallocN(void *ptrptr, size_t size, size_t count)
ATTRIBUTE_RETURN_CHECK ATTRIBUTE_NONNULL(1);
void virFree(void *ptrptr) ATTRIBUTE_NONNULL(1);
# define libvirt_PyString_Check PyUnicode_Check
#define VIR_N_ELEMENTS(array) (sizeof(array) / sizeof(*(array)))
/* The two-statement sequence "Py_INCREF(Py_None); return Py_None;"
is so common that we encapsulate it here. Now, each use is simply
return VIR_PY_NONE; */
#define VIR_PY_NONE (Py_INCREF (Py_None), Py_None)
#define VIR_PY_INT_FAIL (libvirt_intWrap(-1))
#define VIR_PY_INT_SUCCESS (libvirt_intWrap(0))
/**
* VIR_PY_TUPLE_SET_GOTO:
* @TUPLE: a pointer to a tuple object
* @INDEX: a position in the tuple object
* @VALUE: a pointer to a python object to add into the tuple
* @GOTO: a label to jump to in case of error
*
* Add the new value to specific place into the python tuple object. In case of
* error it will jump to provided label and DECREF the value to not leak memory.
*/
#define VIR_PY_TUPLE_SET_GOTO(TUPLE, INDEX, VALUE, GOTO) \
do { \
PyObject *tmpVal = VALUE; \
if (!tmpVal || PyTuple_SetItem(TUPLE, INDEX, tmpVal) < 0) \
goto GOTO; \
} while (0)
/**
* VIR_PY_LIST_SET_GOTO:
* @LIST: a pointer to a list object
* @INDEX: a position in the list object
* @VALUE: a pointer to a python object to add into the list
* @GOTO: a label to jump to in case of error
*
* Add the new value to specific place into the python list object. In case of
* error it will jump to provided label and DECREF the value to not leak memory.
*/
#define VIR_PY_LIST_SET_GOTO(LIST, INDEX, VALUE, GOTO) \
do { \
PyObject *tmpVal = VALUE; \
if (!tmpVal || PyList_SetItem(LIST, INDEX, tmpVal) < 0) \
goto GOTO; \
} while (0)
/**
* VIR_PY_LIST_APPEND_GOTO:
* @LIST: a pointer to a python list object
* @VALUE: a pointer to a python object to add into the list
* @GOTO: a label to jump to in case of error
*
* Append the new value into the end of the python list object. In case of
* error it will jump to provided label and DECREF the value to not leak memory.
*/
#define VIR_PY_LIST_APPEND_GOTO(LIST, VALUE, GOTO) \
do { \
PyObject *tmpVal = VALUE; \
if (!tmpVal || PyList_Append(LIST, tmpVal) < 0) { \
Py_XDECREF(tmpVal); \
goto GOTO; \
} \
Py_DECREF(tmpVal); \
} while (0)
/**
* VIR_PY_DICT_SET_GOTO:
* @DICT: a pointer to a python dict object
* @KEY: a pointer to a python string object which will be used as a key
* @VALUE: a pointer to a python object to add into the dict under provided key
* @GOTO: a label to jump to in case of error
*
* Add a new pair of key:value into the python dict object. In case of error it
* will jump to provided label. It will DECREF both key and value in case of
* success or error.
*/
#define VIR_PY_DICT_SET_GOTO(DICT, KEY, VALUE, GOTO) \
do { \
PyObject *tmpKey = KEY; \
PyObject *tmpVal = VALUE; \
if (!tmpKey || !tmpVal || \
PyDict_SetItem(DICT, tmpKey, tmpVal) < 0) { \
Py_XDECREF(tmpKey); \
Py_XDECREF(tmpVal); \
goto GOTO; \
} \
Py_DECREF(tmpKey); \
Py_DECREF(tmpVal); \
} while (0)
/**
* VIR_ALLOC:
* @ptr: pointer to hold address of allocated memory
*
* Allocate sizeof(*ptr) bytes of memory and store
* the address of allocated memory in 'ptr'. Fill the
* newly allocated memory with zeros.
*
* This macro is safe to use on arguments with side effects.
*
* Returns -1 on failure (with OOM error reported), 0 on success
*/
# define VIR_ALLOC(ptr) virAlloc(&(ptr), sizeof(*(ptr)))
/**
* VIR_ALLOC_N:
* @ptr: pointer to hold address of allocated memory
* @count: number of elements to allocate
*
* Allocate an array of 'count' elements, each sizeof(*ptr)
* bytes long and store the address of allocated memory in
* 'ptr'. Fill the newly allocated memory with zeros.
*
* This macro is safe to use on arguments with side effects.
*
* Returns -1 on failure (with OOM error reported), 0 on success
*/
# define VIR_ALLOC_N(ptr, count) virAllocN(&(ptr), sizeof(*(ptr)), (count))
/**
* VIR_REALLOC_N:
* @ptr: pointer to hold address of allocated memory
* @count: number of elements to allocate
*
* Re-allocate an array of 'count' elements, each sizeof(*ptr)
* bytes long and store the address of allocated memory in
* 'ptr'. If 'ptr' grew, the added memory is uninitialized.
*
* This macro is safe to use on arguments with side effects.
*
* Returns -1 on failure (with OOM error reported), 0 on success
*/
# define VIR_REALLOC_N(ptr, count) virReallocN(&(ptr), sizeof(*(ptr)), (count))
/**
* VIR_FREE:
* @ptr: pointer holding address to be freed
*
* Free the memory stored in 'ptr' and update to point
* to NULL.
*
* This macro is safe to use on arguments with side effects.
*/
# if !STATIC_ANALYSIS
/* The ternary ensures that ptr is a pointer and not an integer type,
* while evaluating ptr only once. This gives us extra compiler
* safety when compiling under gcc. For now, we intentionally cast
* away const, since a number of callers safely pass const char *.
*/
# define VIR_FREE(ptr) virFree((void *) (1 ? (const void *) &(ptr) : (ptr)))
# else
/* The Coverity static analyzer considers the else path of the "?:" and
* flags the VIR_FREE() of the address of the address of memory as a
* RESOURCE_LEAK resulting in numerous false positives (eg, VIR_FREE(&ptr))
*/
# define VIR_FREE(ptr) virFree((void *) &(ptr))
# endif
/* Don't call this directly - use the macro below */
int virFileClose(int *fdptr)
ATTRIBUTE_RETURN_CHECK;
# define VIR_FORCE_CLOSE(FD) \
ignore_value(virFileClose(&(FD)))
# if ! LIBVIR_CHECK_VERSION(1, 0, 2)
void virTypedParamsClear(virTypedParameterPtr params, int nparams);
void virTypedParamsFree(virTypedParameterPtr params, int nparams);
# endif /* ! LIBVIR_CHECK_VERSION(1, 0, 2) */
PyObject * getPyVirTypedParameter(const virTypedParameter *params,
int nparams);
virTypedParameterPtr setPyVirTypedParameter(PyObject *info,
const virTypedParameter *params,
int nparams)
ATTRIBUTE_NONNULL(1) ATTRIBUTE_NONNULL(2);
# if LIBVIR_CHECK_VERSION(1, 1, 0)
typedef struct {
const char *name;
int type;
} virPyTypedParamsHint;
typedef virPyTypedParamsHint *virPyTypedParamsHintPtr;
int virPyDictToTypedPramaOne(virTypedParameterPtr *params,
int *n,
int *max,
virPyTypedParamsHintPtr hints,
int nhints,
const char *keystr,
PyObject *value);
int virPyDictToTypedParams(PyObject *dict,
virTypedParameterPtr *ret_params,
int *ret_nparams,
virPyTypedParamsHintPtr hints,
int nhints)
ATTRIBUTE_NONNULL(1) ATTRIBUTE_NONNULL(2) ATTRIBUTE_NONNULL(3);
# endif /* LIBVIR_CHECK_VERSION(1, 1, 0) */
int virPyCpumapConvert(int cpunum,
PyObject *pycpumap,
unsigned char **cpumapptr,
int *cpumaplen);
#endif /* __LIBVIRT_UTILS_H__ */