qemu/fsdev/p9array.h

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9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
/*
* P9Array - deep auto free C-array
*
* Copyright (c) 2021 Crudebyte
*
* Authors:
* Christian Schoenebeck <qemu_oss@crudebyte.com>
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#ifndef QEMU_P9ARRAY_H
#define QEMU_P9ARRAY_H
/**
* P9Array provides a mechanism to access arrays in common C-style (e.g. by
* square bracket [] operator) in conjunction with reference variables that
* perform deep auto free of the array when leaving the scope of the auto
* reference variable. That means not only is the array itself automatically
* freed, but also memory dynamically allocated by the individual array
* elements.
*
* Example:
*
* Consider the following user struct @c Foo which shall be used as scalar
* (element) type of an array:
* @code
* typedef struct Foo {
* int i;
* char *s;
* } Foo;
* @endcode
* and assume it has the following function to free memory allocated by @c Foo
* instances:
* @code
* void free_foo(Foo *foo) {
* free(foo->s);
* }
* @endcode
* Add the following to a shared header file:
* @code
* P9ARRAY_DECLARE_TYPE(Foo);
* @endcode
* and the following to a C unit file:
* @code
* P9ARRAY_DEFINE_TYPE(Foo, free_foo);
* @endcode
* Finally the array may then be used like this:
* @code
* void doSomething(size_t n) {
* P9ARRAY_REF(Foo) foos = NULL;
* P9ARRAY_NEW(Foo, foos, n);
* for (size_t i = 0; i < n; ++i) {
* foos[i].i = i;
* foos[i].s = calloc(4096, 1);
* snprintf(foos[i].s, 4096, "foo %d", i);
* if (...) {
* return; // array auto freed here
* }
* }
* // array auto freed here
* }
* @endcode
*/
/**
* P9ARRAY_DECLARE_TYPE() - Declares an array type for the passed @scalar_type.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*
* @scalar_type: type of the individual array elements
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*
* This is typically used from a shared header file.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*/
#define P9ARRAY_DECLARE_TYPE(scalar_type) \
typedef struct P9Array##scalar_type { \
size_t len; \
scalar_type first[]; \
} P9Array##scalar_type; \
\
void p9array_new_##scalar_type(scalar_type **auto_var, size_t len); \
void p9array_auto_free_##scalar_type(scalar_type **auto_var); \
/**
* P9ARRAY_DEFINE_TYPE() - Defines an array type for the passed @scalar_type
* and appropriate @scalar_cleanup_func.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*
* @scalar_type: type of the individual array elements
* @scalar_cleanup_func: appropriate function to free memory dynamically
* allocated by individual array elements before
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*
* This is typically used from a C unit file.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*/
#define P9ARRAY_DEFINE_TYPE(scalar_type, scalar_cleanup_func) \
void p9array_new_##scalar_type(scalar_type **auto_var, size_t len) \
{ \
p9array_auto_free_##scalar_type(auto_var); \
P9Array##scalar_type *arr = g_malloc0(sizeof(P9Array##scalar_type) + \
len * sizeof(scalar_type)); \
arr->len = len; \
*auto_var = &arr->first[0]; \
} \
\
void p9array_auto_free_##scalar_type(scalar_type **auto_var) \
{ \
scalar_type *first = (*auto_var); \
if (!first) { \
return; \
} \
P9Array##scalar_type *arr = (P9Array##scalar_type *) ( \
((char *)first) - offsetof(P9Array##scalar_type, first) \
); \
for (size_t i = 0; i < arr->len; ++i) { \
scalar_cleanup_func(&arr->first[i]); \
} \
g_free(arr); \
} \
/**
* P9ARRAY_REF() - Declare a reference variable for an array.
*
* @scalar_type: type of the individual array elements
*
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
* Used to declare a reference variable (unique pointer) for an array. After
* leaving the scope of the reference variable, the associated array is
* automatically freed.
*/
#define P9ARRAY_REF(scalar_type) \
__attribute((__cleanup__(p9array_auto_free_##scalar_type))) scalar_type*
/**
* P9ARRAY_NEW() - Allocate a new array.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*
* @scalar_type: type of the individual array elements
* @auto_var: destination reference variable
* @len: amount of array elements to be allocated immediately
*
* Allocates a new array of passed @scalar_type with @len number of array
* elements and assigns the created array to the reference variable
* @auto_var.
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
*/
#define P9ARRAY_NEW(scalar_type, auto_var, len) \
QEMU_BUILD_BUG_MSG( \
!__builtin_types_compatible_p(scalar_type, typeof(*auto_var)), \
"P9Array scalar type mismatch" \
); \
9pfs: introduce P9Array Implements deep auto free of arrays while retaining common C-style squared bracket access. Main purpose of this API is to get rid of error prone individual array deallocation pathes in user code, i.e. turning something like this: void doSomething(size_t n) { Foo *foos = malloc(n * sizeof(Foo)); for (...) { foos[i].s = malloc(...); if (...) { goto out; } } out: if (...) { for (...) { /* deep deallocation */ free(foos[i].s); } /* array deallocation */ free(foos); } } into something more simple and safer like: void doSomething(size_t n) { P9ARRAY_REF(Foo) foos = NULL; P9ARRAY_NEW(Foo, foos, n); for (...) { foos[i].s = malloc(...); if (...) { return; /* array auto freed here */ } } /* array auto freed here */ } Unlike GArray, P9Array does not require special macros, function calls or struct member dereferencing to access the individual array elements: C-array = P9Array: vs. GArray: for (...) { | for (...) { ... = arr[i].m; | ... = g_array_index(arr, Foo, i).m; arr[i].m = ... ; | g_array_index(arr, Foo, i).m = ... ; } | } So existing C-style array code can be retained with only very little changes; basically limited to replacing array allocation call and of course removing individual array deallocation pathes. In this initial version P9Array only supports the concept of unique pointers, i.e. it does not support reference counting. The array (and all dynamically allocated memory of individual array elements) is auto freed once execution leaves the scope of the reference variable (unique pointer) associated with the array. Internally a flex array struct is used in combination with macros spanned over a continuous memory space for both the array's meta data (private) and the actual C-array user data (public): struct P9Array##scalar_type { size_t len; /* private, hidden from user code */ scalar_type first[]; /* public, directly exposed to user code */ }; Which has the advantage that the compiler automatically takes care about correct padding, alignment and overall size for all scalar data types on all systems and that the user space exposed pointer can directly be translated back and forth between user space C-array pointer and internal P9Array struct whenever needed, in a type-safe manner. This header file is released under MIT license, to allow this file being used in other C-projects as well. The common QEMU license GPL2+ might have construed a conflict for other projects. Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com> Message-Id: <a954ef47b5ac26085a16c5c2aec8695374e0424d.1633097129.git.qemu_oss@crudebyte.com>
2021-10-01 17:26:17 +03:00
p9array_new_##scalar_type((&auto_var), len)
#endif /* QEMU_P9ARRAY_H */