/* Copyright (C) 1995-1998 Eric Young (eay@cryptsoft.com) * All rights reserved. * * This package is an SSL implementation written * by Eric Young (eay@cryptsoft.com). * The implementation was written so as to conform with Netscapes SSL. * * This library is free for commercial and non-commercial use as long as * the following conditions are aheared to. The following conditions * apply to all code found in this distribution, be it the RC4, RSA, * lhash, DES, etc., code; not just the SSL code. The SSL documentation * included with this distribution is covered by the same copyright terms * except that the holder is Tim Hudson (tjh@cryptsoft.com). * * Copyright remains Eric Young's, and as such any Copyright notices in * the code are not to be removed. * If this package is used in a product, Eric Young should be given attribution * as the author of the parts of the library used. * This can be in the form of a textual message at program startup or * in documentation (online or textual) provided with the package. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * "This product includes cryptographic software written by * Eric Young (eay@cryptsoft.com)" * The word 'cryptographic' can be left out if the rouines from the library * being used are not cryptographic related :-). * 4. If you include any Windows specific code (or a derivative thereof) from * the apps directory (application code) you must include an acknowledgement: * "This product includes software written by Tim Hudson (tjh@cryptsoft.com)" * * THIS SOFTWARE IS PROVIDED BY ERIC YOUNG ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * The licence and distribution terms for any publically available version or * derivative of this code cannot be changed. i.e. this code cannot simply be * copied and put under another distribution licence * [including the GNU Public Licence.] */ #ifndef OPENSSL_HEADER_STACK_H #define OPENSSL_HEADER_STACK_H #include #if defined(__cplusplus) extern "C" { #endif // A stack, in OpenSSL, is an array of pointers. They are the most commonly // used collection object. // // This file defines macros for type-safe use of the stack functions. A stack // type is named like |STACK_OF(FOO)| and is accessed with functions named // like |sk_FOO_*|. Note the stack will typically contain /pointers/ to |FOO|. // // The |DECLARE_STACK_OF| macro makes |STACK_OF(FOO)| available, and // |DEFINE_STACK_OF| makes the corresponding functions available. // Defining stacks. // STACK_OF expands to the stack type for |type|. #define STACK_OF(type) struct stack_st_##type // DECLARE_STACK_OF declares the |STACK_OF(type)| type. It does not make the // corresponding |sk_type_*| functions available. This macro should be used in // files which only need the type. #define DECLARE_STACK_OF(type) STACK_OF(type); // DEFINE_NAMED_STACK_OF defines |STACK_OF(name)| to be a stack whose elements // are |type| *. This macro makes the |sk_name_*| functions available. // // It is not necessary to use |DECLARE_STACK_OF| in files which use this macro. #define DEFINE_NAMED_STACK_OF(name, type) \ BORINGSSL_DEFINE_STACK_OF_IMPL(name, type *, const type *) \ BORINGSSL_DEFINE_STACK_TRAITS(name, type, false) // DEFINE_STACK_OF defines |STACK_OF(type)| to be a stack whose elements are // |type| *. This macro makes the |sk_type_*| functions available. // // It is not necessary to use |DECLARE_STACK_OF| in files which use this macro. #define DEFINE_STACK_OF(type) DEFINE_NAMED_STACK_OF(type, type) // DEFINE_CONST_STACK_OF defines |STACK_OF(type)| to be a stack whose elements // are const |type| *. This macro makes the |sk_type_*| functions available. // // It is not necessary to use |DECLARE_STACK_OF| in files which use this macro. #define DEFINE_CONST_STACK_OF(type) \ BORINGSSL_DEFINE_STACK_OF_IMPL(type, const type *, const type *) \ BORINGSSL_DEFINE_STACK_TRAITS(type, const type, true) // Using stacks. // // After the |DEFINE_STACK_OF| macro is used, the following functions are // available. #if 0 // Sample // sk_SAMPLE_free_func is a callback to free an element in a stack. typedef void (*sk_SAMPLE_free_func)(SAMPLE *); // sk_SAMPLE_copy_func is a callback to copy an element in a stack. It should // return the copy or NULL on error. typedef SAMPLE *(*sk_SAMPLE_copy_func)(const SAMPLE *); // sk_SAMPLE_cmp_func is a callback to compare |*a| to |*b|. It should return a // value < 0, 0, or > 0 if |*a| is less than, equal to, or greater than |*b|, // respectively. Note the extra indirection - the function is given a pointer // to a pointer to the element. This is the |qsort|/|bsearch| comparison // function applied to an array of |SAMPLE*|. typedef int (*sk_SAMPLE_cmp_func)(const SAMPLE *const *a, const SAMPLE *const *b); // sk_SAMPLE_new creates a new, empty stack with the given comparison function, // which may be NULL. It returns the new stack or NULL on allocation failure. STACK_OF(SAMPLE) *sk_SAMPLE_new(sk_SAMPLE_cmp_func comp); // sk_SAMPLE_new_null creates a new, empty stack. It returns the new stack or // NULL on allocation failure. STACK_OF(SAMPLE) *sk_SAMPLE_new_null(void); // sk_SAMPLE_num returns the number of elements in |sk|. size_t sk_SAMPLE_num(const STACK_OF(SAMPLE) *sk); // sk_SAMPLE_zero resets |sk| to the empty state but does nothing to free the // individual elements themselves. void sk_SAMPLE_zero(STACK_OF(SAMPLE) *sk); // sk_SAMPLE_value returns the |i|th pointer in |sk|, or NULL if |i| is out of // range. SAMPLE *sk_SAMPLE_value(const STACK_OF(SAMPLE) *sk, size_t i); // sk_SAMPLE_set sets the |i|th pointer in |sk| to |p| and returns |p|. If |i| // is out of range, it returns NULL. SAMPLE *sk_SAMPLE_set(STACK_OF(SAMPLE) *sk, size_t i, SAMPLE *p); // sk_SAMPLE_free frees |sk|, but does nothing to free the individual elements. // Use |sk_SAMPLE_pop_free| to also free the elements. void sk_SAMPLE_free(STACK_OF(SAMPLE) *sk); // sk_SAMPLE_pop_free calls |free_func| on each element in |sk| and then // frees the stack itself. void sk_SAMPLE_pop_free(STACK_OF(SAMPLE) *sk, sk_SAMPLE_free_func free_func); // sk_SAMPLE_insert inserts |p| into the stack at index |where|, moving existing // elements if needed. It returns the length of the new stack, or zero on // error. size_t sk_SAMPLE_insert(STACK_OF(SAMPLE) *sk, SAMPLE *p, size_t where); // sk_SAMPLE_delete removes the pointer at index |where|, moving other elements // down if needed. It returns the removed pointer, or NULL if |where| is out of // range. SAMPLE *sk_SAMPLE_delete(STACK_OF(SAMPLE) *sk, size_t where); // sk_SAMPLE_delete_ptr removes, at most, one instance of |p| from |sk| based on // pointer equality. If an instance of |p| is found then |p| is returned, // otherwise it returns NULL. SAMPLE *sk_SAMPLE_delete_ptr(STACK_OF(SAMPLE) *sk, const SAMPLE *p); // sk_SAMPLE_delete_if_func is the callback function for |sk_SAMPLE_delete_if|. // It should return one to remove |p| and zero to keep it. typedef int (*sk_SAMPLE_delete_if_func)(SAMPLE *p, void *data); // sk_SAMPLE_delete_if calls |func| with each element of |sk| and removes the // entries where |func| returned one. This function does not free or return // removed pointers so, if |sk| owns its contents, |func| should release the // pointers prior to returning one. void sk_SAMPLE_delete_if(STACK_OF(SAMPLE) *sk, sk_SAMPLE_delete_if_func func, void *data); // sk_SAMPLE_find find the first value in |sk| equal to |p|. |sk|'s comparison // function determines equality, or pointer equality if |sk| has no comparison // function. // // If the stack is sorted (see |sk_SAMPLE_sort|), this function uses a binary // search. Otherwise it performs a linear search. If it finds a matching // element, it writes the index to |*out_index| (if |out_index| is not NULL) and // returns one. Otherwise, it returns zero. // // Note this differs from OpenSSL. The type signature is slightly different, and // OpenSSL's version will implicitly sort |sk| if it has a comparison function // defined. int sk_SAMPLE_find(const STACK_OF(SAMPLE) *sk, size_t *out_index, const SAMPLE *p); // sk_SAMPLE_shift removes and returns the first element in |sk|, or NULL if // |sk| is empty. SAMPLE *sk_SAMPLE_shift(STACK_OF(SAMPLE) *sk); // sk_SAMPLE_push appends |p| to |sk| and returns the length of the new stack, // or 0 on allocation failure. size_t sk_SAMPLE_push(STACK_OF(SAMPLE) *sk, SAMPLE *p); // sk_SAMPLE_pop removes and returns the last element of |sk|, or NULL if |sk| // is empty. SAMPLE *sk_SAMPLE_pop(STACK_OF(SAMPLE) *sk); // sk_SAMPLE_dup performs a shallow copy of a stack and returns the new stack, // or NULL on error. Use |sk_SAMPLE_deep_copy| to also copy the elements. STACK_OF(SAMPLE) *sk_SAMPLE_dup(const STACK_OF(SAMPLE) *sk); // sk_SAMPLE_sort sorts the elements of |sk| into ascending order based on the // comparison function. The stack maintains a "sorted" flag and sorting an // already sorted stack is a no-op. void sk_SAMPLE_sort(STACK_OF(SAMPLE) *sk); // sk_SAMPLE_is_sorted returns one if |sk| is known to be sorted and zero // otherwise. int sk_SAMPLE_is_sorted(const STACK_OF(SAMPLE) *sk); // sk_SAMPLE_set_cmp_func sets the comparison function to be used by |sk| and // returns the previous one. sk_SAMPLE_cmp_func sk_SAMPLE_set_cmp_func(STACK_OF(SAMPLE) *sk, sk_SAMPLE_cmp_func comp); // sk_SAMPLE_deep_copy performs a copy of |sk| and of each of the non-NULL // elements in |sk| by using |copy_func|. If an error occurs, it calls // |free_func| to free any copies already made and returns NULL. STACK_OF(SAMPLE) *sk_SAMPLE_deep_copy(const STACK_OF(SAMPLE) *sk, sk_SAMPLE_copy_func copy_func, sk_SAMPLE_free_func free_func); #endif // Sample // Private functions. // // TODO(https://crbug.com/boringssl/499): Rename to |OPENSSL_sk_foo|, after // external code that calls them is fixed. // OPENSSL_sk_free_func is a function that frees an element in a stack. Note its // actual type is void (*)(T *) for some T. Low-level |sk_*| functions will be // passed a type-specific wrapper to call it correctly. typedef void (*OPENSSL_sk_free_func)(void *ptr); // OPENSSL_sk_copy_func is a function that copies an element in a stack. Note // its actual type is T *(*)(const T *) for some T. Low-level |sk_*| functions // will be passed a type-specific wrapper to call it correctly. typedef void *(*OPENSSL_sk_copy_func)(const void *ptr); // OPENSSL_sk_cmp_func is a comparison function that returns a value < 0, 0 or > // 0 if |*a| is less than, equal to or greater than |*b|, respectively. Note // the extra indirection - the function is given a pointer to a pointer to the // element. This differs from the usual qsort/bsearch comparison function. // // Note its actual type is |int (*)(const T *const *a, const T *const *b)|. // Low-level |sk_*| functions will be passed a type-specific wrapper to call it // correctly. typedef int (*OPENSSL_sk_cmp_func)(const void *const *a, const void *const *b); // OPENSSL_sk_delete_if_func is the generic version of // |sk_SAMPLE_delete_if_func|. typedef int (*OPENSSL_sk_delete_if_func)(void *obj, void *data); // The following function types call the above type-erased signatures with the // true types. typedef void (*OPENSSL_sk_call_free_func)(OPENSSL_sk_free_func, void *); typedef void *(*OPENSSL_sk_call_copy_func)(OPENSSL_sk_copy_func, const void *); typedef int (*OPENSSL_sk_call_cmp_func)(OPENSSL_sk_cmp_func, const void *const *, const void *const *); typedef int (*OPENSSL_sk_call_delete_if_func)(OPENSSL_sk_delete_if_func, void *, void *); // stack_st contains an array of pointers. It is not designed to be used // directly, rather the wrapper macros should be used. typedef struct stack_st { // num contains the number of valid pointers in |data|. size_t num; void **data; // sorted is non-zero if the values pointed to by |data| are in ascending // order, based on |comp|. int sorted; // num_alloc contains the number of pointers allocated in the buffer pointed // to by |data|, which may be larger than |num|. size_t num_alloc; // comp is an optional comparison function. OPENSSL_sk_cmp_func comp; } _STACK; // The following are raw stack functions. They implement the corresponding typed // |sk_SAMPLE_*| functions generated by |DEFINE_STACK_OF|. Callers shouldn't be // using them. Rather, callers should use the typed functions. OPENSSL_EXPORT _STACK *sk_new(OPENSSL_sk_cmp_func comp); OPENSSL_EXPORT _STACK *sk_new_null(void); OPENSSL_EXPORT size_t sk_num(const _STACK *sk); OPENSSL_EXPORT void sk_zero(_STACK *sk); OPENSSL_EXPORT void *sk_value(const _STACK *sk, size_t i); OPENSSL_EXPORT void *sk_set(_STACK *sk, size_t i, void *p); OPENSSL_EXPORT void sk_free(_STACK *sk); OPENSSL_EXPORT void sk_pop_free_ex(_STACK *sk, OPENSSL_sk_call_free_func call_free_func, OPENSSL_sk_free_func free_func); OPENSSL_EXPORT size_t sk_insert(_STACK *sk, void *p, size_t where); OPENSSL_EXPORT void *sk_delete(_STACK *sk, size_t where); OPENSSL_EXPORT void *sk_delete_ptr(_STACK *sk, const void *p); OPENSSL_EXPORT void sk_delete_if(_STACK *sk, OPENSSL_sk_call_delete_if_func call_func, OPENSSL_sk_delete_if_func func, void *data); OPENSSL_EXPORT int sk_find(const _STACK *sk, size_t *out_index, const void *p, OPENSSL_sk_call_cmp_func call_cmp_func); OPENSSL_EXPORT void *sk_shift(_STACK *sk); OPENSSL_EXPORT size_t sk_push(_STACK *sk, void *p); OPENSSL_EXPORT void *sk_pop(_STACK *sk); OPENSSL_EXPORT _STACK *sk_dup(const _STACK *sk); OPENSSL_EXPORT void sk_sort(_STACK *sk, OPENSSL_sk_call_cmp_func call_cmp_func); OPENSSL_EXPORT int sk_is_sorted(const _STACK *sk); OPENSSL_EXPORT OPENSSL_sk_cmp_func sk_set_cmp_func(_STACK *sk, OPENSSL_sk_cmp_func comp); OPENSSL_EXPORT _STACK *sk_deep_copy(const _STACK *sk, OPENSSL_sk_call_copy_func call_copy_func, OPENSSL_sk_copy_func copy_func, OPENSSL_sk_call_free_func call_free_func, OPENSSL_sk_free_func free_func); // sk_pop_free behaves like |sk_pop_free_ex| but performs an invalid function // pointer cast. It exists because some existing callers called |sk_pop_free| // directly. // // TODO(davidben): Migrate callers to bssl::UniquePtr and remove this. OPENSSL_EXPORT void sk_pop_free(_STACK *sk, OPENSSL_sk_free_func free_func); #if !defined(BORINGSSL_NO_CXX) extern "C++" { BSSL_NAMESPACE_BEGIN namespace internal { template struct StackTraits {}; } BSSL_NAMESPACE_END } #define BORINGSSL_DEFINE_STACK_TRAITS(name, type, is_const) \ extern "C++" { \ BSSL_NAMESPACE_BEGIN \ namespace internal { \ template <> \ struct StackTraits { \ static constexpr bool kIsStack = true; \ using Type = type; \ static constexpr bool kIsConst = is_const; \ }; \ } \ BSSL_NAMESPACE_END \ } #else #define BORINGSSL_DEFINE_STACK_TRAITS(name, type, is_const) #endif #define BORINGSSL_DEFINE_STACK_OF_IMPL(name, ptrtype, constptrtype) \ /* We disable MSVC C4191 in this macro, which warns when pointers are cast \ * to the wrong type. While the cast itself is valid, it is often a bug \ * because calling it through the cast is UB. However, we never actually \ * call functions as |OPENSSL_sk_cmp_func|. The type is just a type-erased \ * function pointer. (C does not guarantee function pointers fit in \ * |void*|, and GCC will warn on this.) Thus we just disable the false \ * positive warning. */ \ OPENSSL_MSVC_PRAGMA(warning(push)) \ OPENSSL_MSVC_PRAGMA(warning(disable : 4191)) \ \ DECLARE_STACK_OF(name) \ \ typedef void (*sk_##name##_free_func)(ptrtype); \ typedef ptrtype (*sk_##name##_copy_func)(constptrtype); \ typedef int (*sk_##name##_cmp_func)(constptrtype const *, \ constptrtype const *); \ typedef int (*sk_##name##_delete_if_func)(ptrtype, void *); \ \ OPENSSL_INLINE void sk_##name##_call_free_func( \ OPENSSL_sk_free_func free_func, void *ptr) { \ ((sk_##name##_free_func)free_func)((ptrtype)ptr); \ } \ \ OPENSSL_INLINE void *sk_##name##_call_copy_func( \ OPENSSL_sk_copy_func copy_func, const void *ptr) { \ return (void *)((sk_##name##_copy_func)copy_func)((constptrtype)ptr); \ } \ \ OPENSSL_INLINE int sk_##name##_call_cmp_func(OPENSSL_sk_cmp_func cmp_func, \ const void *const *a, \ const void *const *b) { \ /* The data is actually stored as |void*| pointers, so read the pointer \ * as |void*| and then pass the corrected type into the caller-supplied \ * function, which expects |constptrtype*|. */ \ constptrtype a_ptr = (constptrtype)*a; \ constptrtype b_ptr = (constptrtype)*b; \ return ((sk_##name##_cmp_func)cmp_func)(&a_ptr, &b_ptr); \ } \ \ OPENSSL_INLINE int sk_##name##_call_delete_if_func( \ OPENSSL_sk_delete_if_func func, void *obj, void *data) { \ return ((sk_##name##_delete_if_func)func)((ptrtype)obj, data); \ } \ \ OPENSSL_INLINE STACK_OF(name) *sk_##name##_new(sk_##name##_cmp_func comp) { \ return (STACK_OF(name) *)sk_new((OPENSSL_sk_cmp_func)comp); \ } \ \ OPENSSL_INLINE STACK_OF(name) *sk_##name##_new_null(void) { \ return (STACK_OF(name) *)sk_new_null(); \ } \ \ OPENSSL_INLINE size_t sk_##name##_num(const STACK_OF(name) *sk) { \ return sk_num((const _STACK *)sk); \ } \ \ OPENSSL_INLINE void sk_##name##_zero(STACK_OF(name) *sk) { \ sk_zero((_STACK *)sk); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_value(const STACK_OF(name) *sk, \ size_t i) { \ return (ptrtype)sk_value((const _STACK *)sk, i); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_set(STACK_OF(name) *sk, size_t i, \ ptrtype p) { \ return (ptrtype)sk_set((_STACK *)sk, i, (void *)p); \ } \ \ OPENSSL_INLINE void sk_##name##_free(STACK_OF(name) *sk) { \ sk_free((_STACK *)sk); \ } \ \ OPENSSL_INLINE void sk_##name##_pop_free(STACK_OF(name) *sk, \ sk_##name##_free_func free_func) { \ sk_pop_free_ex((_STACK *)sk, sk_##name##_call_free_func, \ (OPENSSL_sk_free_func)free_func); \ } \ \ OPENSSL_INLINE size_t sk_##name##_insert(STACK_OF(name) *sk, ptrtype p, \ size_t where) { \ return sk_insert((_STACK *)sk, (void *)p, where); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_delete(STACK_OF(name) *sk, \ size_t where) { \ return (ptrtype)sk_delete((_STACK *)sk, where); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_delete_ptr(STACK_OF(name) *sk, \ constptrtype p) { \ return (ptrtype)sk_delete_ptr((_STACK *)sk, (const void *)p); \ } \ \ OPENSSL_INLINE void sk_##name##_delete_if( \ STACK_OF(name) *sk, sk_##name##_delete_if_func func, void *data) { \ sk_delete_if((_STACK *)sk, sk_##name##_call_delete_if_func, \ (OPENSSL_sk_delete_if_func)func, data); \ } \ \ OPENSSL_INLINE int sk_##name##_find(const STACK_OF(name) *sk, \ size_t *out_index, constptrtype p) { \ return sk_find((const _STACK *)sk, out_index, (const void *)p, \ sk_##name##_call_cmp_func); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_shift(STACK_OF(name) *sk) { \ return (ptrtype)sk_shift((_STACK *)sk); \ } \ \ OPENSSL_INLINE size_t sk_##name##_push(STACK_OF(name) *sk, ptrtype p) { \ return sk_push((_STACK *)sk, (void *)p); \ } \ \ OPENSSL_INLINE ptrtype sk_##name##_pop(STACK_OF(name) *sk) { \ return (ptrtype)sk_pop((_STACK *)sk); \ } \ \ OPENSSL_INLINE STACK_OF(name) *sk_##name##_dup(const STACK_OF(name) *sk) { \ return (STACK_OF(name) *)sk_dup((const _STACK *)sk); \ } \ \ OPENSSL_INLINE void sk_##name##_sort(STACK_OF(name) *sk) { \ sk_sort((_STACK *)sk, sk_##name##_call_cmp_func); \ } \ \ OPENSSL_INLINE int sk_##name##_is_sorted(const STACK_OF(name) *sk) { \ return sk_is_sorted((const _STACK *)sk); \ } \ \ OPENSSL_INLINE sk_##name##_cmp_func sk_##name##_set_cmp_func( \ STACK_OF(name) *sk, sk_##name##_cmp_func comp) { \ return (sk_##name##_cmp_func)sk_set_cmp_func((_STACK *)sk, \ (OPENSSL_sk_cmp_func)comp); \ } \ \ OPENSSL_INLINE STACK_OF(name) *sk_##name##_deep_copy( \ const STACK_OF(name) *sk, sk_##name##_copy_func copy_func, \ sk_##name##_free_func free_func) { \ return (STACK_OF(name) *)sk_deep_copy( \ (const _STACK *)sk, sk_##name##_call_copy_func, \ (OPENSSL_sk_copy_func)copy_func, sk_##name##_call_free_func, \ (OPENSSL_sk_free_func)free_func); \ } \ \ OPENSSL_MSVC_PRAGMA(warning(pop)) // Built-in stacks. typedef char *OPENSSL_STRING; DEFINE_STACK_OF(void) DEFINE_NAMED_STACK_OF(OPENSSL_STRING, char) #if defined(__cplusplus) } // extern C #endif #if !defined(BORINGSSL_NO_CXX) extern "C++" { #include BSSL_NAMESPACE_BEGIN namespace internal { // Stacks defined with |DEFINE_CONST_STACK_OF| are freed with |sk_free|. template struct DeleterImpl::kIsConst>> { static void Free(Stack *sk) { sk_free(reinterpret_cast<_STACK *>(sk)); } }; // Stacks defined with |DEFINE_STACK_OF| are freed with |sk_pop_free| and the // corresponding type's deleter. template struct DeleterImpl::kIsConst>> { static void Free(Stack *sk) { // sk_FOO_pop_free is defined by macros and bound by name, so we cannot // access it from C++ here. using Type = typename StackTraits::Type; sk_pop_free_ex(reinterpret_cast<_STACK *>(sk), [](OPENSSL_sk_free_func /* unused */, void *ptr) { DeleterImpl::Free(reinterpret_cast(ptr)); }, nullptr); } }; template class StackIteratorImpl { public: using Type = typename StackTraits::Type; // Iterators must be default-constructable. StackIteratorImpl() : sk_(nullptr), idx_(0) {} StackIteratorImpl(const Stack *sk, size_t idx) : sk_(sk), idx_(idx) {} bool operator==(StackIteratorImpl other) const { return sk_ == other.sk_ && idx_ == other.idx_; } bool operator!=(StackIteratorImpl other) const { return !(*this == other); } Type *operator*() const { return reinterpret_cast( sk_value(reinterpret_cast(sk_), idx_)); } StackIteratorImpl &operator++(/* prefix */) { idx_++; return *this; } StackIteratorImpl operator++(int /* postfix */) { StackIteratorImpl copy(*this); ++(*this); return copy; } private: const Stack *sk_; size_t idx_; }; template using StackIterator = std::enable_if_t::kIsStack, StackIteratorImpl>; } // namespace internal // PushToStack pushes |elem| to |sk|. It returns true on success and false on // allocation failure. template inline std::enable_if_t::kIsConst, bool> PushToStack(Stack *sk, UniquePtr::Type> elem) { if (!sk_push(reinterpret_cast<_STACK *>(sk), elem.get())) { return false; } // sk_push takes ownership on success. elem.release(); return true; } BSSL_NAMESPACE_END // Define begin() and end() for stack types so C++ range for loops work. template inline bssl::internal::StackIterator begin(const Stack *sk) { return bssl::internal::StackIterator(sk, 0); } template inline bssl::internal::StackIterator end(const Stack *sk) { return bssl::internal::StackIterator( sk, sk_num(reinterpret_cast(sk))); } } // extern C++ #endif #endif // OPENSSL_HEADER_STACK_H