2 * SPDX-License-Identifier: BSD-3-Clause
4 * Copyright (c) 1987, 1993
5 * The Regents of the University of California.
6 * Copyright (c) 2005, 2009 Robert N. M. Watson
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33 * @(#)malloc.h 8.5 (Berkeley) 5/3/95
37 #ifndef _SYS_MALLOC_H_
38 #define _SYS_MALLOC_H_
41 #include <sys/param.h>
43 #include <sys/systm.h>
45 #include <sys/queue.h>
46 #include <sys/_lock.h>
47 #include <sys/_mutex.h>
48 #include <machine/_limits.h>
50 #define MINALLOCSIZE UMA_SMALLEST_UNIT
53 * Flags to memory allocation functions.
55 #define M_NOWAIT 0x0001 /* do not block */
56 #define M_WAITOK 0x0002 /* ok to block */
57 #define M_ZERO 0x0100 /* bzero the allocation */
58 #define M_NOVM 0x0200 /* don't ask VM for pages */
59 #define M_USE_RESERVE 0x0400 /* can alloc out of reserve memory */
60 #define M_NODUMP 0x0800 /* don't dump pages in this allocation */
61 #define M_FIRSTFIT 0x1000 /* only for vmem, fast fit */
62 #define M_BESTFIT 0x2000 /* only for vmem, low fragmentation */
63 #define M_EXEC 0x4000 /* allocate executable space */
64 #define M_NEXTFIT 0x8000 /* only for vmem, follow cursor */
66 #define M_MAGIC 877983977 /* time when first defined :-) */
69 * Two malloc type structures are present: malloc_type, which is used by a
70 * type owner to declare the type, and malloc_type_internal, which holds
71 * malloc-owned statistics and other ABI-sensitive fields, such as the set of
72 * malloc statistics indexed by the compile-time MAXCPU constant.
73 * Applications should avoid introducing dependence on the allocator private
74 * data layout and size.
76 * The malloc_type ks_next field is protected by malloc_mtx. Other fields in
77 * malloc_type are static after initialization so unsynchronized.
79 * Statistics in malloc_type_stats are written only when holding a critical
80 * section and running on the CPU associated with the index into the stat
81 * array, but read lock-free resulting in possible (minor) races, which the
82 * monitoring app should take into account.
84 struct malloc_type_stats {
85 uint64_t mts_memalloced; /* Bytes allocated on CPU. */
86 uint64_t mts_memfreed; /* Bytes freed on CPU. */
87 uint64_t mts_numallocs; /* Number of allocates on CPU. */
88 uint64_t mts_numfrees; /* number of frees on CPU. */
89 uint64_t mts_size; /* Bitmask of sizes allocated on CPU. */
90 uint64_t _mts_reserved1; /* Reserved field. */
91 uint64_t _mts_reserved2; /* Reserved field. */
92 uint64_t _mts_reserved3; /* Reserved field. */
96 * Index definitions for the mti_probes[] array.
98 #define DTMALLOC_PROBE_MALLOC 0
99 #define DTMALLOC_PROBE_FREE 1
100 #define DTMALLOC_PROBE_MAX 2
102 struct malloc_type_internal {
103 uint32_t mti_probes[DTMALLOC_PROBE_MAX];
104 /* DTrace probe ID array. */
106 struct malloc_type_stats *mti_stats;
110 * Public data structure describing a malloc type. Private data is hung off
111 * of ks_handle to avoid encoding internal malloc(9) data structures in
112 * modules, which will statically allocate struct malloc_type.
115 struct malloc_type *ks_next; /* Next in global chain. */
116 u_long ks_magic; /* Detect programmer error. */
117 const char *ks_shortdesc; /* Printable type name. */
118 void *ks_handle; /* Priv. data, was lo_class. */
122 * Statistics structure headers for user space. The kern.malloc sysctl
123 * exposes a structure stream consisting of a stream header, then a series of
124 * malloc type headers and statistics structures (quantity maxcpus). For
125 * convenience, the kernel will provide the current value of maxcpus at the
126 * head of the stream.
128 #define MALLOC_TYPE_STREAM_VERSION 0x00000001
129 struct malloc_type_stream_header {
130 uint32_t mtsh_version; /* Stream format version. */
131 uint32_t mtsh_maxcpus; /* Value of MAXCPU for stream. */
132 uint32_t mtsh_count; /* Number of records. */
133 uint32_t _mtsh_pad; /* Pad/reserved field. */
136 #define MALLOC_MAX_NAME 32
137 struct malloc_type_header {
138 char mth_name[MALLOC_MAX_NAME];
142 #define MALLOC_DEFINE(type, shortdesc, longdesc) \
143 struct malloc_type type[1] = { \
144 { NULL, M_MAGIC, shortdesc, NULL } \
146 SYSINIT(type##_init, SI_SUB_KMEM, SI_ORDER_THIRD, malloc_init, \
148 SYSUNINIT(type##_uninit, SI_SUB_KMEM, SI_ORDER_ANY, \
151 #define MALLOC_DECLARE(type) \
152 extern struct malloc_type type[1]
154 MALLOC_DECLARE(M_CACHE);
155 MALLOC_DECLARE(M_DEVBUF);
156 MALLOC_DECLARE(M_TEMP);
159 * XXX this should be declared in <sys/uio.h>, but that tends to fail
160 * because <sys/uio.h> is included in a header before the source file
161 * has a chance to include <sys/malloc.h> to get MALLOC_DECLARE() defined.
163 MALLOC_DECLARE(M_IOV);
166 extern struct mtx malloc_mtx;
169 * Function type used when iterating over the list of malloc types.
171 typedef void malloc_type_list_func_t(struct malloc_type *, void *);
173 void contigfree(void *addr, unsigned long size, struct malloc_type *type);
174 void *contigmalloc(unsigned long size, struct malloc_type *type, int flags,
175 vm_paddr_t low, vm_paddr_t high, unsigned long alignment,
176 vm_paddr_t boundary) __malloc_like __result_use_check
177 __alloc_size(1) __alloc_align(6);
178 void *contigmalloc_domainset(unsigned long size, struct malloc_type *type,
179 struct domainset *ds, int flags, vm_paddr_t low, vm_paddr_t high,
180 unsigned long alignment, vm_paddr_t boundary)
181 __malloc_like __result_use_check __alloc_size(1) __alloc_align(7);
182 void free(void *addr, struct malloc_type *type);
183 void zfree(void *addr, struct malloc_type *type);
184 void *malloc(size_t size, struct malloc_type *type, int flags) __malloc_like
185 __result_use_check __alloc_size(1);
187 * Try to optimize malloc(..., ..., M_ZERO) allocations by doing zeroing in
188 * place if the size is known at compilation time.
190 * Passing the flag down requires malloc to blindly zero the entire object.
191 * In practice a lot of the zeroing can be avoided if most of the object
192 * gets explicitly initialized after the allocation. Letting the compiler
193 * zero in place gives it the opportunity to take advantage of this state.
195 * Note that the operation is only applicable if both flags and size are
196 * known at compilation time. If M_ZERO is passed but M_WAITOK is not, the
197 * allocation can fail and a NULL check is needed. However, if M_WAITOK is
198 * passed we know the allocation must succeed and the check can be elided.
200 * _malloc_item = malloc(_size, type, (flags) &~ M_ZERO);
201 * if (((flags) & M_WAITOK) != 0 || _malloc_item != NULL)
202 * bzero(_malloc_item, _size);
204 * If the flag is set, the compiler knows the left side is always true,
205 * therefore the entire statement is true and the callsite is:
207 * _malloc_item = malloc(_size, type, (flags) &~ M_ZERO);
208 * bzero(_malloc_item, _size);
210 * If the flag is not set, the compiler knows the left size is always false
211 * and the NULL check is needed, therefore the callsite is:
213 * _malloc_item = malloc(_size, type, (flags) &~ M_ZERO);
214 * if (_malloc_item != NULL)
215 * bzero(_malloc_item, _size);
217 * The implementation is a macro because of what appears to be a clang 6 bug:
218 * an inline function variant ended up being compiled to a mere malloc call
219 * regardless of argument. gcc generates expected code (like the above).
221 #define malloc(size, type, flags) ({ \
222 void *_malloc_item; \
223 size_t _size = (size); \
224 if (__builtin_constant_p(size) && __builtin_constant_p(flags) &&\
225 ((flags) & M_ZERO) != 0) { \
226 _malloc_item = malloc(_size, type, (flags) &~ M_ZERO); \
227 if (((flags) & M_WAITOK) != 0 || \
228 __predict_true(_malloc_item != NULL)) \
229 bzero(_malloc_item, _size); \
231 _malloc_item = malloc(_size, type, flags); \
236 void *malloc_domainset(size_t size, struct malloc_type *type,
237 struct domainset *ds, int flags) __malloc_like __result_use_check
239 void *mallocarray(size_t nmemb, size_t size, struct malloc_type *type,
240 int flags) __malloc_like __result_use_check
242 void malloc_init(void *);
243 int malloc_last_fail(void);
244 void malloc_type_allocated(struct malloc_type *type, unsigned long size);
245 void malloc_type_freed(struct malloc_type *type, unsigned long size);
246 void malloc_type_list(malloc_type_list_func_t *, void *);
247 void malloc_uninit(void *);
248 size_t malloc_usable_size(const void *);
249 void *realloc(void *addr, size_t size, struct malloc_type *type, int flags)
250 __result_use_check __alloc_size(2);
251 void *reallocf(void *addr, size_t size, struct malloc_type *type, int flags)
252 __result_use_check __alloc_size(2);
254 struct malloc_type *malloc_desc2type(const char *desc);
257 * This is sqrt(SIZE_MAX+1), as s1*s2 <= SIZE_MAX
258 * if both s1 < MUL_NO_OVERFLOW and s2 < MUL_NO_OVERFLOW
260 #define MUL_NO_OVERFLOW (1UL << (sizeof(size_t) * 8 / 2))
262 WOULD_OVERFLOW(size_t nmemb, size_t size)
265 return ((nmemb >= MUL_NO_OVERFLOW || size >= MUL_NO_OVERFLOW) &&
266 nmemb > 0 && __SIZE_T_MAX / nmemb < size);
268 #undef MUL_NO_OVERFLOW
273 * The native stand malloc / free interface we're mapping to
275 extern void Free(void *p, const char *file, int line);
276 extern void *Malloc(size_t bytes, const char *file, int line);
279 * Minimal standalone malloc implementation / environment. None of the
280 * flags mean anything and there's no need declare malloc types.
281 * Define the simple alloc / free routines in terms of Malloc and
282 * Free. None of the kernel features that this stuff disables are needed.
284 * XXX we are setting ourselves up for a potential crash if we can't allocate
285 * memory for a M_WAITOK call.
290 #define MALLOC_DECLARE(x)
292 #define kmem_zalloc(size, flags) Malloc((size), __FILE__, __LINE__)
293 #define kmem_free(p, size) Free(p, __FILE__, __LINE__)
296 * ZFS mem.h define that's the OpenZFS porting layer way of saying
297 * M_WAITOK. Given the above, it will also be a nop.
299 #define KM_SLEEP M_WAITOK
300 #endif /* _STANDALONE */
301 #endif /* !_SYS_MALLOC_H_ */