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/*
* Copyright (c) 2015 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
Copyright (c) 2001, 2002, 2003 Eliot Dresselhaus
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 _included_clib_mem_h
#define _included_clib_mem_h
#include <stdarg.h>
#include <unistd.h>
#include <sys/mman.h>
#include <vppinfra/clib.h> /* uword, etc */
#include <vppinfra/clib_error.h>
#include <vppinfra/os.h>
#include <vppinfra/string.h> /* memcpy, clib_memset */
#include <vppinfra/sanitizer.h>
#define CLIB_MAX_MHEAPS 256
#define CLIB_MAX_NUMAS 16
#define CLIB_MEM_VM_MAP_FAILED ((void *) ~0)
#define CLIB_MEM_ERROR (-1)
typedef enum
{
CLIB_MEM_PAGE_SZ_UNKNOWN = 0,
CLIB_MEM_PAGE_SZ_DEFAULT = 1,
CLIB_MEM_PAGE_SZ_DEFAULT_HUGE = 2,
CLIB_MEM_PAGE_SZ_4K = 12,
CLIB_MEM_PAGE_SZ_16K = 14,
CLIB_MEM_PAGE_SZ_64K = 16,
CLIB_MEM_PAGE_SZ_1M = 20,
CLIB_MEM_PAGE_SZ_2M = 21,
CLIB_MEM_PAGE_SZ_16M = 24,
CLIB_MEM_PAGE_SZ_32M = 25,
CLIB_MEM_PAGE_SZ_512M = 29,
CLIB_MEM_PAGE_SZ_1G = 30,
CLIB_MEM_PAGE_SZ_16G = 34,
} clib_mem_page_sz_t;
typedef struct _clib_mem_vm_map_hdr
{
/* base address */
uword base_addr;
/* number of pages */
uword num_pages;
/* page size (log2) */
clib_mem_page_sz_t log2_page_sz;
/* file descriptor, -1 if memory is not shared */
int fd;
/* allocation mame */
#define CLIB_VM_MAP_HDR_NAME_MAX_LEN 64
char name[CLIB_VM_MAP_HDR_NAME_MAX_LEN];
/* linked list */
struct _clib_mem_vm_map_hdr *prev, *next;
} clib_mem_vm_map_hdr_t;
typedef struct
{
/* log2 system page size */
clib_mem_page_sz_t log2_page_sz;
/* log2 system default hugepage size */
clib_mem_page_sz_t log2_default_hugepage_sz;
/* bitmap of available numa nodes */
u32 numa_node_bitmap;
/* per CPU heaps */
void *per_cpu_mheaps[CLIB_MAX_MHEAPS];
/* per NUMA heaps */
void *per_numa_mheaps[CLIB_MAX_NUMAS];
/* memory maps */
clib_mem_vm_map_hdr_t *first_map, *last_map;
/* last error */
clib_error_t *error;
} clib_mem_main_t;
extern clib_mem_main_t clib_mem_main;
/* Unspecified NUMA socket */
#define VEC_NUMA_UNSPECIFIED (0xFF)
always_inline void *
clib_mem_get_per_cpu_heap (void)
{
int cpu = os_get_thread_index ();
return clib_mem_main.per_cpu_mheaps[cpu];
}
always_inline void *
clib_mem_set_per_cpu_heap (u8 * new_heap)
{
int cpu = os_get_thread_index ();
void *old = clib_mem_main.per_cpu_mheaps[cpu];
clib_mem_main.per_cpu_mheaps[cpu] = new_heap;
return old;
}
always_inline void *
clib_mem_get_per_numa_heap (u32 numa_id)
{
ASSERT (numa_id < ARRAY_LEN (clib_mem_main.per_numa_mheaps));
return clib_mem_main.per_numa_mheaps[numa_id];
}
always_inline void *
clib_mem_set_per_numa_heap (u8 * new_heap)
{
int numa = os_get_numa_index ();
void *old = clib_mem_main.per_numa_mheaps[numa];
clib_mem_main.per_numa_mheaps[numa] = new_heap;
return old;
}
always_inline void
clib_mem_set_thread_index (void)
{
/*
* Find an unused slot in the per-cpu-mheaps array,
* and grab it for this thread. We need to be able to
* push/pop the thread heap without affecting other thread(s).
*/
int i;
if (__os_thread_index != 0)
return;
for (i = 0; i < ARRAY_LEN (clib_mem_main.per_cpu_mheaps); i++)
if (clib_atomic_bool_cmp_and_swap (&clib_mem_main.per_cpu_mheaps[i],
0, clib_mem_main.per_cpu_mheaps[0]))
{
os_set_thread_index (i);
break;
}
ASSERT (__os_thread_index > 0);
}
always_inline uword
clib_mem_size_nocheck (void *p)
{
size_t mspace_usable_size_with_delta (const void *p);
return mspace_usable_size_with_delta (p);
}
/* Memory allocator which may call os_out_of_memory() if it fails */
always_inline void *
clib_mem_alloc_aligned_at_offset (uword size, uword align, uword align_offset,
int os_out_of_memory_on_failure)
{
void *heap, *p;
uword cpu;
void *mspace_get_aligned (void *msp, unsigned long n_user_data_bytes,
unsigned long align, unsigned long align_offset);
if (align_offset > align)
{
if (align > 0)
align_offset %= align;
else
align_offset = align;
}
cpu = os_get_thread_index ();
heap = clib_mem_main.per_cpu_mheaps[cpu];
p = mspace_get_aligned (heap, size, align, align_offset);
if (PREDICT_FALSE (0 == p))
{
if (os_out_of_memory_on_failure)
os_out_of_memory ();
return 0;
}
CLIB_MEM_UNPOISON (p, size);
return p;
}
/* Memory allocator which calls os_out_of_memory() when it fails */
always_inline void *
clib_mem_alloc (uword size)
{
return clib_mem_alloc_aligned_at_offset (size, /* align */ 1,
/* align_offset */ 0,
/* os_out_of_memory */ 1);
}
always_inline void *
clib_mem_alloc_aligned (uword size, uword align)
{
return clib_mem_alloc_aligned_at_offset (size, align, /* align_offset */ 0,
/* os_out_of_memory */ 1);
}
/* Memory allocator which calls os_out_of_memory() when it fails */
always_inline void *
clib_mem_alloc_or_null (uword size)
{
return clib_mem_alloc_aligned_at_offset (size, /* align */ 1,
/* align_offset */ 0,
/* os_out_of_memory */ 0);
}
always_inline void *
clib_mem_alloc_aligned_or_null (uword size, uword align)
{
return clib_mem_alloc_aligned_at_offset (size, align, /* align_offset */ 0,
/* os_out_of_memory */ 0);
}
/* Memory allocator which panics when it fails.
Use macro so that clib_panic macro can expand __FUNCTION__ and __LINE__. */
#define clib_mem_alloc_aligned_no_fail(size,align) \
({ \
uword _clib_mem_alloc_size = (size); \
void * _clib_mem_alloc_p; \
_clib_mem_alloc_p = clib_mem_alloc_aligned (_clib_mem_alloc_size, (align)); \
if (! _clib_mem_alloc_p) \
clib_panic ("failed to allocate %d bytes", _clib_mem_alloc_size); \
_clib_mem_alloc_p; \
})
#define clib_mem_alloc_no_fail(size) clib_mem_alloc_aligned_no_fail(size,1)
/* Alias to stack allocator for naming consistency. */
#define clib_mem_alloc_stack(bytes) __builtin_alloca(bytes)
always_inline uword
clib_mem_is_heap_object (void *p)
{
void *heap = clib_mem_get_per_cpu_heap ();
int mspace_is_heap_object (void *msp, void *p);
return mspace_is_heap_object (heap, p);
}
always_inline void
clib_mem_free (void *p)
{
u8 *heap = clib_mem_get_per_cpu_heap ();
void mspace_put (void *msp, void *p_arg);
/* Make sure object is in the correct heap. */
ASSERT (clib_mem_is_heap_object (p));
CLIB_MEM_POISON (p, clib_mem_size_nocheck (p));
mspace_put (heap, p);
}
always_inline void *
clib_mem_realloc (void *p, uword new_size, uword old_size)
{
/* By default use alloc, copy and free to emulate realloc. */
void *q = clib_mem_alloc (new_size);
if (q)
{
uword copy_size;
if (old_size < new_size)
copy_size = old_size;
else
copy_size = new_size;
clib_memcpy_fast (q, p, copy_size);
clib_mem_free (p);
}
return q;
}
always_inline uword
clib_mem_size (void *p)
{
ASSERT (clib_mem_is_heap_object (p));
return clib_mem_size_nocheck (p);
}
always_inline void
clib_mem_free_s (void *p)
{
uword size = clib_mem_size (p);
CLIB_MEM_UNPOISON (p, size);
memset_s_inline (p, size, 0, size);
clib_mem_free (p);
}
always_inline void *
clib_mem_get_heap (void)
{
return clib_mem_get_per_cpu_heap ();
}
always_inline void *
clib_mem_set_heap (void *heap)
{
return clib_mem_set_per_cpu_heap (heap);
}
void clib_mem_destroy_heap (void *heap);
void *clib_mem_create_heap (void *base, uword size, int is_locked, char *fmt,
...);
void clib_mem_main_init ();
void *clib_mem_init (void *heap, uword size);
void *clib_mem_init_with_page_size (uword memory_size,
clib_mem_page_sz_t log2_page_sz);
void *clib_mem_init_thread_safe (void *memory, uword memory_size);
void *clib_mem_init_thread_safe_numa (void *memory, uword memory_size,
u8 numa);
void clib_mem_exit (void);
void clib_mem_trace (int enable);
int clib_mem_is_traced (void);
typedef struct
{
/* Total number of objects allocated. */
uword object_count;
/* Total allocated bytes. Bytes used and free.
used + free = total */
uword bytes_total, bytes_used, bytes_free;
/* Number of bytes used by mheap data structure overhead
(e.g. free lists, mheap header). */
uword bytes_overhead;
/* Amount of free space returned to operating system. */
uword bytes_free_reclaimed;
/* For malloc which puts small objects in sbrk region and
large objects in mmap'ed regions. */
uword bytes_used_sbrk;
uword bytes_used_mmap;
/* Max. number of bytes in this heap. */
uword bytes_max;
} clib_mem_usage_t;
void clib_mem_get_heap_usage (void *heap, clib_mem_usage_t * usage);
void *clib_mem_get_heap_base (void *heap);
uword clib_mem_get_heap_size (void *heap);
uword clib_mem_get_heap_free_space (void *heap);
u8 *format_clib_mem_usage (u8 * s, va_list * args);
u8 *format_clib_mem_heap (u8 * s, va_list * va);
/* Allocate virtual address space. */
always_inline void *
clib_mem_vm_alloc (uword size)
{
void *mmap_addr;
uword flags = MAP_PRIVATE;
#ifdef MAP_ANONYMOUS
flags |= MAP_ANONYMOUS;
#endif
mmap_addr = mmap (0, size, PROT_READ | PROT_WRITE, flags, -1, 0);
if (mmap_addr == (void *) -1)
mmap_addr = 0;
else
CLIB_MEM_UNPOISON (mmap_addr, size);
return mmap_addr;
}
always_inline void
clib_mem_vm_free (void *addr, uword size)
{
munmap (addr, size);
}
void *clib_mem_vm_map_internal (void *base, clib_mem_page_sz_t log2_page_sz,
uword size, int fd, uword offset, char *name);
void *clib_mem_vm_map (void *start, uword size,
clib_mem_page_sz_t log2_page_size, char *fmt, ...);
void *clib_mem_vm_map_stack (uword size, clib_mem_page_sz_t log2_page_size,
char *fmt, ...);
void *clib_mem_vm_map_shared (void *start, uword size, int fd, uword offset,
char *fmt, ...);
int clib_mem_vm_unmap (void *base);
clib_mem_vm_map_hdr_t *clib_mem_vm_get_next_map_hdr (clib_mem_vm_map_hdr_t *
hdr);
typedef struct
{
#define CLIB_MEM_VM_F_SHARED (1 << 0)
#define CLIB_MEM_VM_F_HUGETLB (1 << 1)
#define CLIB_MEM_VM_F_NUMA_PREFER (1 << 2)
#define CLIB_MEM_VM_F_NUMA_FORCE (1 << 3)
#define CLIB_MEM_VM_F_HUGETLB_PREALLOC (1 << 4)
#define CLIB_MEM_VM_F_LOCKED (1 << 5)
u32 flags; /**< vm allocation flags:
<br> CLIB_MEM_VM_F_SHARED: request shared memory, file
descriptor will be provided on successful allocation.
<br> CLIB_MEM_VM_F_HUGETLB: request hugepages.
<br> CLIB_MEM_VM_F_NUMA_PREFER: numa_node field contains valid
numa node preference.
<br> CLIB_MEM_VM_F_NUMA_FORCE: fail if setting numa policy fails.
<br> CLIB_MEM_VM_F_HUGETLB_PREALLOC: pre-allocate hugepages if
number of available pages is not sufficient.
<br> CLIB_MEM_VM_F_LOCKED: request locked memory.
*/
char *name; /**< Name for memory allocation, set by caller. */
uword size; /**< Allocation size, set by caller. */
int numa_node; /**< numa node preference. Valid if CLIB_MEM_VM_F_NUMA_PREFER set. */
void *addr; /**< Pointer to allocated memory, set on successful allocation. */
int fd; /**< File descriptor, set on successful allocation if CLIB_MEM_VM_F_SHARED is set. */
int log2_page_size; /* Page size in log2 format, set on successful allocation. */
int n_pages; /* Number of pages. */
uword requested_va; /**< Request fixed position mapping */
} clib_mem_vm_alloc_t;
static_always_inline clib_mem_page_sz_t
clib_mem_get_log2_page_size (void)
{
return clib_mem_main.log2_page_sz;
}
static_always_inline uword
clib_mem_get_page_size (void)
{
return 1ULL << clib_mem_main.log2_page_sz;
}
static_always_inline clib_mem_page_sz_t
clib_mem_get_log2_default_hugepage_size ()
{
return clib_mem_main.log2_default_hugepage_sz;
}
int clib_mem_vm_create_fd (clib_mem_page_sz_t log2_page_size, char *fmt, ...);
clib_error_t *clib_mem_vm_ext_alloc (clib_mem_vm_alloc_t * a);
void clib_mem_vm_ext_free (clib_mem_vm_alloc_t * a);
uword clib_mem_get_fd_page_size (int fd);
uword clib_mem_get_default_hugepage_size (void);
clib_mem_page_sz_t clib_mem_get_fd_log2_page_size (int fd);
uword clib_mem_vm_reserve (uword start, uword size,
clib_mem_page_sz_t log2_page_sz);
u64 *clib_mem_vm_get_paddr (void *mem, clib_mem_page_sz_t log2_page_size,
int n_pages);
void clib_mem_destroy (void);
int clib_mem_set_numa_affinity (u8 numa_node, int force);
int clib_mem_set_default_numa_affinity ();
typedef struct
{
uword size; /**< Map size */
int fd; /**< File descriptor to be mapped */
uword requested_va; /**< Request fixed position mapping */
void *addr; /**< Pointer to mapped memory, if successful */
u8 numa_node;
} clib_mem_vm_map_t;
clib_error_t *clib_mem_vm_ext_map (clib_mem_vm_map_t * a);
void clib_mem_vm_randomize_va (uword * requested_va,
clib_mem_page_sz_t log2_page_size);
void mheap_trace (void *v, int enable);
uword clib_mem_trace_enable_disable (uword enable);
void clib_mem_trace (int enable);
always_inline uword
clib_mem_round_to_page_size (uword size, clib_mem_page_sz_t log2_page_size)
{
ASSERT (log2_page_size != CLIB_MEM_PAGE_SZ_UNKNOWN);
if (log2_page_size == CLIB_MEM_PAGE_SZ_DEFAULT)
log2_page_size = clib_mem_get_log2_page_size ();
else if (log2_page_size == CLIB_MEM_PAGE_SZ_DEFAULT_HUGE)
log2_page_size = clib_mem_get_log2_default_hugepage_size ();
return round_pow2 (size, 1ULL << log2_page_size);
}
typedef struct
{
uword mapped;
uword not_mapped;
uword per_numa[CLIB_MAX_NUMAS];
uword unknown;
} clib_mem_page_stats_t;
void clib_mem_get_page_stats (void *start, clib_mem_page_sz_t log2_page_size,
uword n_pages, clib_mem_page_stats_t * stats);
static_always_inline int
vlib_mem_get_next_numa_node (int numa)
{
clib_mem_main_t *mm = &clib_mem_main;
u32 bitmap = mm->numa_node_bitmap;
if (numa >= 0)
bitmap &= ~pow2_mask (numa + 1);
if (bitmap == 0)
return -1;
return count_trailing_zeros (bitmap);
}
static_always_inline clib_mem_page_sz_t
clib_mem_log2_page_size_validate (clib_mem_page_sz_t log2_page_size)
{
if (log2_page_size == CLIB_MEM_PAGE_SZ_DEFAULT)
return clib_mem_get_log2_page_size ();
if (log2_page_size == CLIB_MEM_PAGE_SZ_DEFAULT_HUGE)
return clib_mem_get_log2_default_hugepage_size ();
return log2_page_size;
}
static_always_inline uword
clib_mem_page_bytes (clib_mem_page_sz_t log2_page_size)
{
return 1 << clib_mem_log2_page_size_validate (log2_page_size);
}
static_always_inline clib_error_t *
clib_mem_get_last_error (void)
{
return clib_mem_main.error;
}
#include <vppinfra/error.h> /* clib_panic */
#endif /* _included_clib_mem_h */
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/