procps/proc/meminfo.c
Jim Warner b700d91f84 library: whack a superfluous assignment, <MEMINFO> api
This patch was prompted through work on the <slabinfo>
upgrade from 2nd gen to 3rd. And while this assignment
caused no real harm, it most certainly was misleading.

[ plus add a couple of overlooked #undef directives! ]

Signed-off-by: Jim Warner <james.warner@comcast.net>
2016-06-09 20:51:06 +10:00

1020 lines
37 KiB
C

/*
* libprocps - Library to read proc filesystem
*
* 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, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <proc/procps-private.h>
#include <proc/meminfo.h>
#define MEMINFO_FILE "/proc/meminfo"
struct meminfo_data {
/** == man 5 proc shows these as: to be documented, so the hell with 'em */
unsigned long Active;
unsigned long Active_anon; // as: (anon)
unsigned long Active_file; // as: (file)
unsigned long AnonHugePages;
unsigned long AnonPages;
unsigned long Bounce;
unsigned long Buffers;
unsigned long Cached;
/** unsigned long CmaFree; ----------- */
/** unsigned long CmaTotal; ---------- */
unsigned long CommitLimit;
unsigned long Committed_AS;
/** unsigned long DirectMap1G; ------- */
/** unsigned long DirectMap2M; ------- */
/** unsigned long DirectMap4k; ------- */
unsigned long Dirty;
unsigned long HardwareCorrupted;
unsigned long HighFree;
unsigned long HighTotal;
unsigned long HugePages_Free;
unsigned long HugePages_Rsvd;
unsigned long HugePages_Surp;
unsigned long HugePages_Total;
unsigned long Hugepagesize;
unsigned long Inactive;
unsigned long Inactive_anon; // as: (anon)
unsigned long Inactive_file; // as: (file)
unsigned long KernelStack;
unsigned long LowFree;
unsigned long LowTotal;
unsigned long Mapped;
unsigned long MemAvailable;
unsigned long MemFree;
unsigned long MemTotal;
unsigned long Mlocked;
unsigned long NFS_Unstable;
unsigned long PageTables;
unsigned long SReclaimable;
unsigned long SUnreclaim;
unsigned long Shmem;
unsigned long Slab;
unsigned long SwapCached;
unsigned long SwapFree;
unsigned long SwapTotal;
unsigned long Unevictable;
unsigned long VmallocChunk;
unsigned long VmallocTotal;
unsigned long VmallocUsed;
unsigned long Writeback;
unsigned long WritebackTmp;
unsigned long derived_mem_hi_used;
unsigned long derived_mem_lo_used;
unsigned long derived_mem_used;
unsigned long derived_swap_used;
};
struct hist_mem {
struct meminfo_data new;
struct meminfo_data old;
};
struct stacks_extent {
int ext_numstacks;
struct stacks_extent *next;
struct meminfo_stack **stacks;
};
struct procps_meminfo {
int refcount;
int meminfo_fd;
int meminfo_was_read;
int dirty_stacks;
struct hist_mem mem_hist;
int numitems;
enum meminfo_item *items;
struct stacks_extent *extents;
};
// ___ Results 'Set' Support ||||||||||||||||||||||||||||||||||||||||||||||||||
#define setNAME(e) set_results_ ## e
#define setDECL(e) static void setNAME(e) \
(struct meminfo_result *R, struct hist_mem *H)
// regular assignment
#define MEM_set(e,t,x) setDECL(e) { R->result. t = H->new . x; }
// delta assignment
#define HST_set(e,t,x) setDECL(e) { R->result. t = ( H->new . x - H->old. x ); }
setDECL(noop) { (void)R; (void)H; }
setDECL(extra) { (void)R; (void)H; }
MEM_set(MEM_ACTIVE, ul_int, Active)
MEM_set(MEM_ACTIVE_ANON, ul_int, Active_anon)
MEM_set(MEM_ACTIVE_FILE, ul_int, Active_file)
MEM_set(MEM_ANON, ul_int, AnonPages)
MEM_set(MEM_AVAILABLE, ul_int, MemAvailable)
MEM_set(MEM_BOUNCE, ul_int, Bounce)
MEM_set(MEM_BUFFERS, ul_int, Buffers)
MEM_set(MEM_CACHED, ul_int, Cached)
MEM_set(MEM_COMMIT_LIMIT, ul_int, CommitLimit)
MEM_set(MEM_COMMITTED_AS, ul_int, Committed_AS)
MEM_set(MEM_HARD_CORRUPTED, ul_int, HardwareCorrupted)
MEM_set(MEM_DIRTY, ul_int, Dirty)
MEM_set(MEM_FREE, ul_int, MemFree)
MEM_set(MEM_HUGE_ANON, ul_int, AnonHugePages)
MEM_set(MEM_HUGE_FREE, ul_int, HugePages_Free)
MEM_set(MEM_HUGE_RSVD, ul_int, HugePages_Rsvd)
MEM_set(MEM_HUGE_SIZE, ul_int, Hugepagesize)
MEM_set(MEM_HUGE_SURPLUS, ul_int, HugePages_Surp)
MEM_set(MEM_HUGE_TOTAL, ul_int, HugePages_Total)
MEM_set(MEM_INACTIVE, ul_int, Inactive)
MEM_set(MEM_INACTIVE_ANON, ul_int, Inactive_anon)
MEM_set(MEM_INACTIVE_FILE, ul_int, Inactive_file)
MEM_set(MEM_KERNEL_STACK, ul_int, KernelStack)
MEM_set(MEM_LOCKED, ul_int, Mlocked)
MEM_set(MEM_MAPPED, ul_int, Mapped)
MEM_set(MEM_NFS_UNSTABLE, ul_int, NFS_Unstable)
MEM_set(MEM_PAGE_TABLES, ul_int, PageTables)
MEM_set(MEM_SHARED, ul_int, Shmem)
MEM_set(MEM_SLAB, ul_int, Slab)
MEM_set(MEM_SLAB_RECLAIM, ul_int, SReclaimable)
MEM_set(MEM_SLAB_UNRECLAIM, ul_int, SUnreclaim)
MEM_set(MEM_TOTAL, ul_int, MemTotal)
MEM_set(MEM_UNEVICTABLE, ul_int, Unevictable)
MEM_set(MEM_USED, ul_int, derived_mem_used)
MEM_set(MEM_VM_ALLOC_CHUNK, ul_int, VmallocChunk)
MEM_set(MEM_VM_ALLOC_TOTAL, ul_int, VmallocTotal)
MEM_set(MEM_VM_ALLOC_USED, ul_int, VmallocUsed)
MEM_set(MEM_WRITEBACK, ul_int, Writeback)
MEM_set(MEM_WRITEBACK_TMP, ul_int, WritebackTmp)
HST_set(DELTA_ACTIVE, s_int, Active)
HST_set(DELTA_ACTIVE_ANON, s_int, Active_anon)
HST_set(DELTA_ACTIVE_FILE, s_int, Active_file)
HST_set(DELTA_ANON, s_int, AnonPages)
HST_set(DELTA_AVAILABLE, s_int, MemAvailable)
HST_set(DELTA_BOUNCE, s_int, Bounce)
HST_set(DELTA_BUFFERS, s_int, Buffers)
HST_set(DELTA_CACHED, s_int, Cached)
HST_set(DELTA_COMMIT_LIMIT, s_int, CommitLimit)
HST_set(DELTA_COMMITTED_AS, s_int, Committed_AS)
HST_set(DELTA_HARD_CORRUPTED, s_int, HardwareCorrupted)
HST_set(DELTA_DIRTY, s_int, Dirty)
HST_set(DELTA_FREE, s_int, MemFree)
HST_set(DELTA_HUGE_ANON, s_int, AnonHugePages)
HST_set(DELTA_HUGE_FREE, s_int, HugePages_Free)
HST_set(DELTA_HUGE_RSVD, s_int, HugePages_Rsvd)
HST_set(DELTA_HUGE_SIZE, s_int, Hugepagesize)
HST_set(DELTA_HUGE_SURPLUS, s_int, HugePages_Surp)
HST_set(DELTA_HUGE_TOTAL, s_int, HugePages_Total)
HST_set(DELTA_INACTIVE, s_int, Inactive)
HST_set(DELTA_INACTIVE_ANON, s_int, Inactive_anon)
HST_set(DELTA_INACTIVE_FILE, s_int, Inactive_file)
HST_set(DELTA_KERNEL_STACK, s_int, KernelStack)
HST_set(DELTA_LOCKED, s_int, Mlocked)
HST_set(DELTA_MAPPED, s_int, Mapped)
HST_set(DELTA_NFS_UNSTABLE, s_int, NFS_Unstable)
HST_set(DELTA_PAGE_TABLES, s_int, PageTables)
HST_set(DELTA_SHARED, s_int, Shmem)
HST_set(DELTA_SLAB, s_int, Slab)
HST_set(DELTA_SLAB_RECLAIM, s_int, SReclaimable)
HST_set(DELTA_SLAB_UNRECLAIM, s_int, SUnreclaim)
HST_set(DELTA_TOTAL, s_int, MemTotal)
HST_set(DELTA_UNEVICTABLE, s_int, Unevictable)
HST_set(DELTA_USED, s_int, derived_mem_used)
HST_set(DELTA_VM_ALLOC_CHUNK, s_int, VmallocChunk)
HST_set(DELTA_VM_ALLOC_TOTAL, s_int, VmallocTotal)
HST_set(DELTA_VM_ALLOC_USED, s_int, VmallocUsed)
HST_set(DELTA_WRITEBACK, s_int, Writeback)
HST_set(DELTA_WRITEBACK_TMP, s_int, WritebackTmp)
MEM_set(MEMHI_FREE, ul_int, HighFree)
MEM_set(MEMHI_TOTAL, ul_int, HighTotal)
MEM_set(MEMHI_USED, ul_int, derived_mem_hi_used)
MEM_set(MEMLO_FREE, ul_int, LowFree)
MEM_set(MEMLO_TOTAL, ul_int, LowTotal)
MEM_set(MEMLO_USED, ul_int, derived_mem_lo_used)
MEM_set(SWAP_CACHED, ul_int, SwapCached)
MEM_set(SWAP_FREE, ul_int, SwapFree)
MEM_set(SWAP_TOTAL, ul_int, SwapTotal)
MEM_set(SWAP_USED, ul_int, derived_swap_used)
// ___ Results 'Get' Support ||||||||||||||||||||||||||||||||||||||||||||||||||
#define getNAME(e) get_results_ ## e
#define getDECL(e) static signed long getNAME(e) \
(struct procps_meminfo *I)
// regular get
#define MEM_get(e,x) getDECL(e) { return I->mem_hist.new. x; }
// delta get
#define HST_get(e,x) getDECL(e) { return ( I->mem_hist.new. x - I->mem_hist.old. x ); }
getDECL(noop) { (void)I; return 0; }
getDECL(extra) { (void)I; return 0; }
MEM_get(MEM_ACTIVE, Active)
MEM_get(MEM_ACTIVE_ANON, Active_anon)
MEM_get(MEM_ACTIVE_FILE, Active_file)
MEM_get(MEM_ANON, AnonPages)
MEM_get(MEM_AVAILABLE, MemAvailable)
MEM_get(MEM_BOUNCE, Bounce)
MEM_get(MEM_BUFFERS, Buffers)
MEM_get(MEM_CACHED, Cached)
MEM_get(MEM_COMMIT_LIMIT, CommitLimit)
MEM_get(MEM_COMMITTED_AS, Committed_AS)
MEM_get(MEM_HARD_CORRUPTED, HardwareCorrupted)
MEM_get(MEM_DIRTY, Dirty)
MEM_get(MEM_FREE, MemFree)
MEM_get(MEM_HUGE_ANON, AnonHugePages)
MEM_get(MEM_HUGE_FREE, HugePages_Free)
MEM_get(MEM_HUGE_RSVD, HugePages_Rsvd)
MEM_get(MEM_HUGE_SIZE, Hugepagesize)
MEM_get(MEM_HUGE_SURPLUS, HugePages_Surp)
MEM_get(MEM_HUGE_TOTAL, HugePages_Total)
MEM_get(MEM_INACTIVE, Inactive)
MEM_get(MEM_INACTIVE_ANON, Inactive_anon)
MEM_get(MEM_INACTIVE_FILE, Inactive_file)
MEM_get(MEM_KERNEL_STACK, KernelStack)
MEM_get(MEM_LOCKED, Mlocked)
MEM_get(MEM_MAPPED, Mapped)
MEM_get(MEM_NFS_UNSTABLE, NFS_Unstable)
MEM_get(MEM_PAGE_TABLES, PageTables)
MEM_get(MEM_SHARED, Shmem)
MEM_get(MEM_SLAB, Slab)
MEM_get(MEM_SLAB_RECLAIM, SReclaimable)
MEM_get(MEM_SLAB_UNRECLAIM, SUnreclaim)
MEM_get(MEM_TOTAL, MemTotal)
MEM_get(MEM_UNEVICTABLE, Unevictable)
MEM_get(MEM_USED, derived_mem_used)
MEM_get(MEM_VM_ALLOC_CHUNK, VmallocChunk)
MEM_get(MEM_VM_ALLOC_TOTAL, VmallocTotal)
MEM_get(MEM_VM_ALLOC_USED, VmallocUsed)
MEM_get(MEM_WRITEBACK, Writeback)
MEM_get(MEM_WRITEBACK_TMP, WritebackTmp)
HST_get(DELTA_ACTIVE, Active)
HST_get(DELTA_ACTIVE_ANON, Active_anon)
HST_get(DELTA_ACTIVE_FILE, Active_file)
HST_get(DELTA_ANON, AnonPages)
HST_get(DELTA_AVAILABLE, MemAvailable)
HST_get(DELTA_BOUNCE, Bounce)
HST_get(DELTA_BUFFERS, Buffers)
HST_get(DELTA_CACHED, Cached)
HST_get(DELTA_COMMIT_LIMIT, CommitLimit)
HST_get(DELTA_COMMITTED_AS, Committed_AS)
HST_get(DELTA_HARD_CORRUPTED, HardwareCorrupted)
HST_get(DELTA_DIRTY, Dirty)
HST_get(DELTA_FREE, MemFree)
HST_get(DELTA_HUGE_ANON, AnonHugePages)
HST_get(DELTA_HUGE_FREE, HugePages_Free)
HST_get(DELTA_HUGE_RSVD, HugePages_Rsvd)
HST_get(DELTA_HUGE_SIZE, Hugepagesize)
HST_get(DELTA_HUGE_SURPLUS, HugePages_Surp)
HST_get(DELTA_HUGE_TOTAL, HugePages_Total)
HST_get(DELTA_INACTIVE, Inactive)
HST_get(DELTA_INACTIVE_ANON, Inactive_anon)
HST_get(DELTA_INACTIVE_FILE, Inactive_file)
HST_get(DELTA_KERNEL_STACK, KernelStack)
HST_get(DELTA_LOCKED, Mlocked)
HST_get(DELTA_MAPPED, Mapped)
HST_get(DELTA_NFS_UNSTABLE, NFS_Unstable)
HST_get(DELTA_PAGE_TABLES, PageTables)
HST_get(DELTA_SHARED, Shmem)
HST_get(DELTA_SLAB, Slab)
HST_get(DELTA_SLAB_RECLAIM, SReclaimable)
HST_get(DELTA_SLAB_UNRECLAIM, SUnreclaim)
HST_get(DELTA_TOTAL, MemTotal)
HST_get(DELTA_UNEVICTABLE, Unevictable)
HST_get(DELTA_USED, derived_mem_used)
HST_get(DELTA_VM_ALLOC_CHUNK, VmallocChunk)
HST_get(DELTA_VM_ALLOC_TOTAL, VmallocTotal)
HST_get(DELTA_VM_ALLOC_USED, VmallocUsed)
HST_get(DELTA_WRITEBACK, Writeback)
HST_get(DELTA_WRITEBACK_TMP, WritebackTmp)
MEM_get(MEMHI_FREE, HighFree)
MEM_get(MEMHI_TOTAL, HighTotal)
MEM_get(MEMHI_USED, derived_mem_hi_used)
MEM_get(MEMLO_FREE, LowFree)
MEM_get(MEMLO_TOTAL, LowTotal)
MEM_get(MEMLO_USED, derived_mem_lo_used)
MEM_get(SWAP_CACHED, SwapCached)
MEM_get(SWAP_FREE, SwapFree)
MEM_get(SWAP_TOTAL, SwapTotal)
MEM_get(SWAP_USED, derived_swap_used)
// ___ Controlling Table ||||||||||||||||||||||||||||||||||||||||||||||||||||||
typedef void (*SET_t)(struct meminfo_result *, struct hist_mem *);
#define RS(e) (SET_t)setNAME(e)
typedef long (*GET_t)(struct procps_meminfo *);
#define RG(e) (GET_t)getNAME(e)
/*
* Need it be said?
* This table must be kept in the exact same order as
* those 'enum meminfo_item' guys ! */
static struct {
SET_t setsfunc; // the actual result setting routine
GET_t getsfunc; // a routine to return single result
} Item_table[] = {
/* setsfunc getsfunc
--------------------------- --------------------------- */
{ RS(noop), RG(noop) },
{ RS(extra), RG(extra) },
{ RS(MEM_ACTIVE), RG(MEM_ACTIVE) },
{ RS(MEM_ACTIVE_ANON), RG(MEM_ACTIVE_ANON) },
{ RS(MEM_ACTIVE_FILE), RG(MEM_ACTIVE_FILE) },
{ RS(MEM_ANON), RG(MEM_ANON) },
{ RS(MEM_AVAILABLE), RG(MEM_AVAILABLE) },
{ RS(MEM_BOUNCE), RG(MEM_BOUNCE) },
{ RS(MEM_BUFFERS), RG(MEM_BUFFERS) },
{ RS(MEM_CACHED), RG(MEM_CACHED) },
{ RS(MEM_COMMIT_LIMIT), RG(MEM_COMMIT_LIMIT) },
{ RS(MEM_COMMITTED_AS), RG(MEM_COMMITTED_AS) },
{ RS(MEM_HARD_CORRUPTED), RG(MEM_HARD_CORRUPTED) },
{ RS(MEM_DIRTY), RG(MEM_DIRTY) },
{ RS(MEM_FREE), RG(MEM_FREE) },
{ RS(MEM_HUGE_ANON), RG(MEM_HUGE_ANON) },
{ RS(MEM_HUGE_FREE), RG(MEM_HUGE_FREE) },
{ RS(MEM_HUGE_RSVD), RG(MEM_HUGE_RSVD) },
{ RS(MEM_HUGE_SIZE), RG(MEM_HUGE_SIZE) },
{ RS(MEM_HUGE_SURPLUS), RG(MEM_HUGE_SURPLUS) },
{ RS(MEM_HUGE_TOTAL), RG(MEM_HUGE_TOTAL) },
{ RS(MEM_INACTIVE), RG(MEM_INACTIVE) },
{ RS(MEM_INACTIVE_ANON), RG(MEM_INACTIVE_ANON) },
{ RS(MEM_INACTIVE_FILE), RG(MEM_INACTIVE_FILE) },
{ RS(MEM_KERNEL_STACK), RG(MEM_KERNEL_STACK) },
{ RS(MEM_LOCKED), RG(MEM_LOCKED) },
{ RS(MEM_MAPPED), RG(MEM_MAPPED) },
{ RS(MEM_NFS_UNSTABLE), RG(MEM_NFS_UNSTABLE) },
{ RS(MEM_PAGE_TABLES), RG(MEM_PAGE_TABLES) },
{ RS(MEM_SHARED), RG(MEM_SHARED) },
{ RS(MEM_SLAB), RG(MEM_SLAB) },
{ RS(MEM_SLAB_RECLAIM), RG(MEM_SLAB_RECLAIM) },
{ RS(MEM_SLAB_UNRECLAIM), RG(MEM_SLAB_UNRECLAIM) },
{ RS(MEM_TOTAL), RG(MEM_TOTAL) },
{ RS(MEM_UNEVICTABLE), RG(MEM_UNEVICTABLE) },
{ RS(MEM_USED), RG(MEM_USED) },
{ RS(MEM_VM_ALLOC_CHUNK), RG(MEM_VM_ALLOC_CHUNK) },
{ RS(MEM_VM_ALLOC_TOTAL), RG(MEM_VM_ALLOC_TOTAL) },
{ RS(MEM_VM_ALLOC_USED), RG(MEM_VM_ALLOC_USED) },
{ RS(MEM_WRITEBACK), RG(MEM_WRITEBACK) },
{ RS(MEM_WRITEBACK_TMP), RG(MEM_WRITEBACK_TMP) },
{ RS(DELTA_ACTIVE), RG(DELTA_ACTIVE) },
{ RS(DELTA_ACTIVE_ANON), RG(DELTA_ACTIVE_ANON) },
{ RS(DELTA_ACTIVE_FILE), RG(DELTA_ACTIVE_FILE) },
{ RS(DELTA_ANON), RG(DELTA_ANON) },
{ RS(DELTA_AVAILABLE), RG(DELTA_AVAILABLE) },
{ RS(DELTA_BOUNCE), RG(DELTA_BOUNCE) },
{ RS(DELTA_BUFFERS), RG(DELTA_BUFFERS) },
{ RS(DELTA_CACHED), RG(DELTA_CACHED) },
{ RS(DELTA_COMMIT_LIMIT), RG(DELTA_COMMIT_LIMIT) },
{ RS(DELTA_COMMITTED_AS), RG(DELTA_COMMITTED_AS) },
{ RS(DELTA_HARD_CORRUPTED), RG(DELTA_HARD_CORRUPTED) },
{ RS(DELTA_DIRTY), RG(DELTA_DIRTY) },
{ RS(DELTA_FREE), RG(DELTA_FREE) },
{ RS(DELTA_HUGE_ANON), RG(DELTA_HUGE_ANON) },
{ RS(DELTA_HUGE_FREE), RG(DELTA_HUGE_FREE) },
{ RS(DELTA_HUGE_RSVD), RG(DELTA_HUGE_RSVD) },
{ RS(DELTA_HUGE_SIZE), RG(DELTA_HUGE_SIZE) },
{ RS(DELTA_HUGE_SURPLUS), RG(DELTA_HUGE_SURPLUS) },
{ RS(DELTA_HUGE_TOTAL), RG(DELTA_HUGE_TOTAL) },
{ RS(DELTA_INACTIVE), RG(DELTA_INACTIVE) },
{ RS(DELTA_INACTIVE_ANON), RG(DELTA_INACTIVE_ANON) },
{ RS(DELTA_INACTIVE_FILE), RG(DELTA_INACTIVE_FILE) },
{ RS(DELTA_KERNEL_STACK), RG(DELTA_KERNEL_STACK) },
{ RS(DELTA_LOCKED), RG(DELTA_LOCKED) },
{ RS(DELTA_MAPPED), RG(DELTA_MAPPED) },
{ RS(DELTA_NFS_UNSTABLE), RG(DELTA_NFS_UNSTABLE) },
{ RS(DELTA_PAGE_TABLES), RG(DELTA_PAGE_TABLES) },
{ RS(DELTA_SHARED), RG(DELTA_SHARED) },
{ RS(DELTA_SLAB), RG(DELTA_SLAB) },
{ RS(DELTA_SLAB_RECLAIM), RG(DELTA_SLAB_RECLAIM) },
{ RS(DELTA_SLAB_UNRECLAIM), RG(DELTA_SLAB_UNRECLAIM) },
{ RS(DELTA_TOTAL), RG(DELTA_TOTAL) },
{ RS(DELTA_UNEVICTABLE), RG(DELTA_UNEVICTABLE) },
{ RS(DELTA_USED), RG(DELTA_USED) },
{ RS(DELTA_VM_ALLOC_CHUNK), RG(DELTA_VM_ALLOC_CHUNK) },
{ RS(DELTA_VM_ALLOC_TOTAL), RG(DELTA_VM_ALLOC_TOTAL) },
{ RS(DELTA_VM_ALLOC_USED), RG(DELTA_VM_ALLOC_USED) },
{ RS(DELTA_WRITEBACK), RG(DELTA_WRITEBACK) },
{ RS(DELTA_WRITEBACK_TMP), RG(DELTA_WRITEBACK_TMP) },
{ RS(MEMHI_FREE), RG(MEMHI_FREE) },
{ RS(MEMHI_TOTAL), RG(MEMHI_TOTAL) },
{ RS(MEMHI_USED), RG(MEMHI_USED) },
{ RS(MEMLO_FREE), RG(MEMLO_FREE) },
{ RS(MEMLO_TOTAL), RG(MEMLO_TOTAL) },
{ RS(MEMLO_USED), RG(MEMLO_USED) },
{ RS(SWAP_CACHED), RG(SWAP_CACHED) },
{ RS(SWAP_FREE), RG(SWAP_FREE) },
{ RS(SWAP_TOTAL), RG(SWAP_TOTAL) },
{ RS(SWAP_USED), RG(SWAP_USED) },
{ NULL, NULL }
};
/* please note,
* this enum MUST be 1 greater than the highest value of any enum */
enum meminfo_item PROCPS_MEMINFO_logical_end = PROCPS_MEMINFO_SWAP_USED + 1;
#undef setNAME
#undef setDECL
#undef MEM_set
#undef HST_set
#undef getNAME
#undef getDECL
#undef MEM_get
#undef HST_get
#undef RS
#undef RG
// ___ Private Functions ||||||||||||||||||||||||||||||||||||||||||||||||||||||
static inline void assign_results (
struct meminfo_stack *stack,
struct hist_mem *mem_hist)
{
struct meminfo_result *this = stack->head;
for (;;) {
enum meminfo_item item = this->item;
if (item >= PROCPS_MEMINFO_logical_end)
break;
Item_table[item].setsfunc(this, mem_hist);
++this;
}
return;
} // end: assign_results
static inline void cleanup_stack (
struct meminfo_result *this)
{
for (;;) {
if (this->item >= PROCPS_MEMINFO_logical_end)
break;
if (this->item > PROCPS_MEMINFO_noop)
this->result.ul_int = 0;
++this;
}
} // end: cleanup_stack
static inline void cleanup_stacks_all (
struct procps_meminfo *info)
{
int i;
struct stacks_extent *ext = info->extents;
while (ext) {
for (i = 0; ext->stacks[i]; i++)
cleanup_stack(ext->stacks[i]->head);
ext = ext->next;
};
info->dirty_stacks = 0;
} // end: cleanup_stacks_all
static void extents_free_all (
struct procps_meminfo *info)
{
do {
struct stacks_extent *p = info->extents;
info->extents = info->extents->next;
free(p);
} while (info->extents);
} // end: extents_free_all
static inline struct meminfo_result *itemize_stack (
struct meminfo_result *p,
int depth,
enum meminfo_item *items)
{
struct meminfo_result *p_sav = p;
int i;
for (i = 0; i < depth; i++) {
p->item = items[i];
p->result.ul_int = 0;
++p;
}
return p_sav;
} // end: itemize_stack
static inline int items_check_failed (
int numitems,
enum meminfo_item *items)
{
int i;
/* if an enum is passed instead of an address of one or more enums, ol' gcc
* will silently convert it to an address (possibly NULL). only clang will
* offer any sort of warning like the following:
*
* warning: incompatible integer to pointer conversion passing 'int' to parameter of type 'enum meminfo_item *'
* my_stack = procps_meminfo_select(info, PROCPS_MEMINFO_noop, num);
* ^~~~~~~~~~~~~~~~
*/
if (numitems < 1
|| (void *)items < (void *)(unsigned long)(2 * PROCPS_MEMINFO_logical_end))
return -1;
for (i = 0; i < numitems; i++) {
// a meminfo_item is currently unsigned, but we'll protect our future
if (items[i] < 0)
return -1;
if (items[i] >= PROCPS_MEMINFO_logical_end)
return -1;
}
return 0;
} // end: items_check_failed
/*
* read_meminfo_failed():
*
* Read the data out of /proc/meminfo putting the information
* into the supplied info structure
*/
PROCPS_EXPORT int read_meminfo_failed (
struct procps_meminfo *info)
{
/* a 'memory history reference' macro for readability,
so we can focus the field names ... */
#define mHr(f) info->mem_hist.new. f
char buf[8192];
char *head, *tail;
int size;
unsigned long *valptr;
signed long mem_used;
if (info == NULL)
return -1;
// remember history from last time around
memcpy(&info->mem_hist.old, &info->mem_hist.new, sizeof(struct meminfo_data));
// clear out the soon to be 'current' values
memset(&info->mem_hist.new, 0, sizeof(struct meminfo_data));
if (-1 == info->meminfo_fd
&& (info->meminfo_fd = open(MEMINFO_FILE, O_RDONLY)) == -1)
return -errno;
if (lseek(info->meminfo_fd, 0L, SEEK_SET) == -1)
return -errno;
for (;;) {
if ((size = read(info->meminfo_fd, buf, sizeof(buf)-1)) < 0) {
if (errno == EINTR || errno == EAGAIN)
continue;
return -errno;
}
break;
}
if (size == 0)
return 0;
buf[size] = '\0';
/* Scan the file */
head = buf;
do {
tail = strchr(head, ' ');
if (!tail)
break;
*tail = '\0';
valptr = NULL;
switch (*head) {
case 'A':
if (0 == strcmp(head, "Active:"))
valptr = &(mHr(Active));
else
if (0 == strcmp(head, "Active(anon):"))
valptr = &(mHr(Active_anon));
else
if (0 == strcmp(head, "Active(file):"))
valptr = &(mHr(Active_file));
else
if (0 == strcmp(head, "AnonHugePages:"))
valptr = &(mHr(AnonHugePages));
else
if (0 == strcmp(head, "AnonPages:"))
valptr = &(mHr(AnonPages));
break;
case 'B':
if (0 == strcmp(head, "Bounce:"))
valptr = &(mHr(Bounce));
else
if (0 == strcmp(head, "Buffers:"))
valptr = &(mHr(Buffers));
break;
case 'C':
if (0 == strcmp(head, "Cached:"))
valptr = &(mHr(Cached));
else
if (0 == strcmp(head, "CommitLimit:"))
valptr = &(mHr(CommitLimit));
else
if (0 == strcmp(head, "Committed_AS:"))
valptr = &(mHr(Committed_AS));
break;
case 'D':
if (0 == strcmp(head, "Dirty:"))
valptr = &(mHr(Dirty));
break;
case 'H':
if (0 == strcmp(head, "HardwareCorrupted:"))
valptr = &(mHr(HardwareCorrupted));
else
if (0 == strcmp(head, "HighFree:"))
valptr = &(mHr(HighFree));
else
if (0 == strcmp(head, "HighTotal:"))
valptr = &(mHr(HighTotal));
else
if (0 == strcmp(head, "HugePages_Free:"))
valptr = &(mHr(HugePages_Free));
else
if (0 == strcmp(head, "HugePages_Rsvd:"))
valptr = &(mHr(HugePages_Rsvd));
else
if (0 == strcmp(head, "HugePages_Surp:"))
valptr = &(mHr(HugePages_Surp));
else
if (0 == strcmp(head, "HugePages_Total:"))
valptr = &(mHr(HugePages_Total));
else
if (0 == strcmp(head, "Hugepagesize:"))
valptr = &(mHr(Hugepagesize));
break;
case 'I':
if (0 == strcmp(head, "Inactive:"))
valptr = &(mHr(Inactive));
else
if (0 == strcmp(head, "Inactive(anon):"))
valptr = &(mHr(Inactive_anon));
else
if (0 == strcmp(head, "Inactive(file):"))
valptr = &(mHr(Inactive_file));
break;
case 'K':
if (0 == strcmp(head, "KernelStack:"))
valptr = &(mHr(KernelStack));
break;
case 'L':
if (0 == strcmp(head, "LowFree:"))
valptr = &(mHr(LowFree));
else
if (0 == strcmp(head, "LowTotal:"))
valptr = &(mHr(LowTotal));
break;
case 'M':
if (0 == strcmp(head, "Mapped:"))
valptr = &(mHr(Mapped));
else
if (0 == strcmp(head, "MemAvailable:"))
valptr = &(mHr(MemAvailable));
else
if (0 == strcmp(head, "MemFree:"))
valptr = &(mHr(MemFree));
else
if (0 == strcmp(head, "MemTotal:"))
valptr = &(mHr(MemTotal));
else
if (0 == strcmp(head, "Mlocked:"))
valptr = &(mHr(Mlocked));
break;
case 'N':
if (0 == strcmp(head, "NFS_Unstable:"))
valptr = &(mHr(NFS_Unstable));
break;
case 'P':
if (0 == strcmp(head, "PageTables:"))
valptr = &(mHr(PageTables));
break;
case 'S':
if (0 == strcmp(head, "SReclaimable:"))
valptr = &(mHr(SReclaimable));
else
if (0 == strcmp(head, "SUnreclaim:"))
valptr = &(mHr(SUnreclaim));
else
if (0 == strcmp(head, "Shmem:"))
valptr = &(mHr(Shmem));
else
if (0 == strcmp(head, "Slab:"))
valptr = &(mHr(Slab));
else
if (0 == strcmp(head, "SwapCached:"))
valptr = &(mHr(SwapCached));
else
if (0 == strcmp(head, "SwapFree:"))
valptr = &(mHr(SwapFree));
else
if (0 == strcmp(head, "SwapTotal:"))
valptr = &(mHr(SwapTotal));
break;
case 'U':
if (0 == strcmp(head, "Unevictable:"))
valptr = &(mHr(Unevictable));
break;
case 'V':
if (0 == strcmp(head, "VmallocChunk:"))
valptr = &(mHr(VmallocChunk));
else
if (0 == strcmp(head, "VmallocTotal:"))
valptr = &(mHr(VmallocTotal));
else
if (0 == strcmp(head, "VmallocUsed:"))
valptr = &(mHr(VmallocUsed));
break;
case 'W':
if (0 == strcmp(head, "Writeback:"))
valptr = &(mHr(Writeback));
else
if (0 == strcmp(head, "WritebackTmp:"))
valptr = &(mHr(WritebackTmp));
break;
default:
break;
}
head = tail+1;
if (valptr) {
*valptr = strtoul(head, &tail, 10);
}
tail = strchr(head, '\n');
if (!tail)
break;
head = tail + 1;
} while(tail);
if (0 == mHr(MemAvailable))
mHr(MemAvailable) = mHr(MemFree);
/* if 'available' is greater than 'total' or our calculation of mem_used
overflows, that's symptomatic of running within a lxc container where
such values will be dramatically distorted over those of the host. */
if (mHr(MemAvailable) > mHr(MemTotal))
mHr(MemAvailable) = mHr(MemFree);
mem_used = mHr(MemTotal) - mHr(MemFree) - mHr(Cached) - mHr(Buffers);
if (mem_used < 0)
mem_used = mHr(MemTotal) - mHr(MemFree);
mHr(derived_mem_used) = (unsigned long)mem_used;
if (mHr(HighFree) < mHr(HighTotal))
mHr(derived_mem_hi_used) = mHr(HighTotal) - mHr(HighFree);
mHr(Cached) += mHr(SReclaimable);
if (0 == mHr(LowTotal)) {
mHr(LowTotal) = mHr(MemTotal);
mHr(LowFree) = mHr(MemFree);
}
if (mHr(LowFree) < mHr(LowTotal))
mHr(derived_mem_lo_used) = mHr(LowTotal) - mHr(LowFree);
if (mHr(SwapFree) < mHr(SwapTotal))
mHr(derived_swap_used) = mHr(SwapTotal) - mHr(SwapFree);
// let's not distort the deltas the first time thru ...
if (!info->meminfo_was_read)
memcpy(&info->mem_hist.old, &info->mem_hist.new, sizeof(struct meminfo_data));
info->meminfo_was_read = 1;
return 0;
#undef mHr
} // end: read_meminfo_failed
/*
* stacks_alloc():
*
* Allocate and initialize one or more stacks each of which is anchored in an
* associated meminfo_stack structure.
*
* All such stacks will have their result structures properly primed with
* 'items', while the result itself will be zeroed.
*
* Returns a stacks_extent struct anchoring the 'heads' of each new stack.
*/
static struct stacks_extent *stacks_alloc (
struct procps_meminfo *info,
int maxstacks)
{
struct stacks_extent *p_blob;
struct meminfo_stack **p_vect;
struct meminfo_stack *p_head;
size_t vect_size, head_size, list_size, blob_size;
void *v_head, *v_list;
int i;
if (info == NULL || info->items == NULL)
return NULL;
if (maxstacks < 1)
return NULL;
vect_size = sizeof(void *) * maxstacks; // size of the addr vectors |
vect_size += sizeof(void *); // plus NULL addr delimiter |
head_size = sizeof(struct meminfo_stack); // size of that head struct |
list_size = sizeof(struct meminfo_result)*info->numitems; // any single results stack |
blob_size = sizeof(struct stacks_extent); // the extent anchor itself |
blob_size += vect_size; // plus room for addr vects |
blob_size += head_size * maxstacks; // plus room for head thing |
blob_size += list_size * maxstacks; // plus room for our stacks |
/* note: all of our memory is allocated in a single blob, facilitating a later free(). |
as a minimum, it is important that the result structures themselves always be |
contiguous for every stack since they are accessed through relative position. | */
if (NULL == (p_blob = calloc(1, blob_size)))
return NULL;
p_blob->next = info->extents; // push this extent onto... |
info->extents = p_blob; // ...some existing extents |
p_vect = (void *)p_blob + sizeof(struct stacks_extent); // prime our vector pointer |
p_blob->stacks = p_vect; // set actual vectors start |
v_head = (void *)p_vect + vect_size; // prime head pointer start |
v_list = v_head + (head_size * maxstacks); // prime our stacks pointer |
for (i = 0; i < maxstacks; i++) {
p_head = (struct meminfo_stack *)v_head;
p_head->head = itemize_stack((struct meminfo_result *)v_list, info->numitems, info->items);
p_blob->stacks[i] = p_head;
v_list += list_size;
v_head += head_size;
}
p_blob->ext_numstacks = maxstacks;
return p_blob;
} // end: stacks_alloc
// ___ Public Functions |||||||||||||||||||||||||||||||||||||||||||||||||||||||
/*
* procps_meminfo_new:
*
* Create a new container to hold the stat information
*
* The initial refcount is 1, and needs to be decremented
* to release the resources of the structure.
*
* Returns: a pointer to a new meminfo struct
*/
PROCPS_EXPORT int procps_meminfo_new (
struct procps_meminfo **info)
{
struct procps_meminfo *p;
if (info == NULL || *info != NULL)
return -EINVAL;
if (!(p = calloc(1, sizeof(struct procps_meminfo))))
return -ENOMEM;
p->refcount = 1;
p->meminfo_fd = -1;
*info = p;
return 0;
} // end: procps_meminfo_new
PROCPS_EXPORT int procps_meminfo_ref (
struct procps_meminfo *info)
{
if (info == NULL)
return -EINVAL;
info->refcount++;
return info->refcount;
} // end: procps_meminfo_ref
PROCPS_EXPORT int procps_meminfo_unref (
struct procps_meminfo **info)
{
if (info == NULL || *info == NULL)
return -EINVAL;
(*info)->refcount--;
if ((*info)->refcount == 0) {
if ((*info)->extents)
extents_free_all((*info));
if ((*info)->items)
free((*info)->items);
free(*info);
*info = NULL;
return 0;
}
return (*info)->refcount;
} // end: procps_meminfo_unref
PROCPS_EXPORT signed long procps_meminfo_get (
struct procps_meminfo *info,
enum meminfo_item item)
{
static time_t sav_secs;
time_t cur_secs;
int rc;
if (info == NULL)
return -EINVAL;
if (item < 0 || item >= PROCPS_MEMINFO_logical_end)
return -EINVAL;
/* we will NOT read the meminfo file with every call - rather, we'll offer
a granularity of 1 second between reads ... */
cur_secs = time(NULL);
if (1 <= cur_secs - sav_secs) {
if ((rc = read_meminfo_failed(info)))
return rc;
sav_secs = cur_secs;
}
if (item < PROCPS_MEMINFO_logical_end)
return Item_table[item].getsfunc(info);
return -EINVAL;
} // end: procps_meminfo_get
/* procps_meminfo_select():
*
* Harvest all the requested MEM and/or SWAP information then return
* it in a results stack.
*
* Returns: pointer to a meminfo_stack struct on success, NULL on error.
*/
PROCPS_EXPORT struct meminfo_stack *procps_meminfo_select (
struct procps_meminfo *info,
enum meminfo_item *items,
int numitems)
{
if (info == NULL || items == NULL)
return NULL;
if (items_check_failed(numitems, items))
return NULL;
/* is this the first time or have things changed since we were last called?
if so, gotta' redo all of our stacks stuff ... */
if (info->numitems != numitems + 1
|| memcmp(info->items, items, sizeof(enum meminfo_item) * numitems)) {
// allow for our PROCPS_MEMINFO_logical_end
if (!(info->items = realloc(info->items, sizeof(enum meminfo_item) * (numitems + 1))))
return NULL;
memcpy(info->items, items, sizeof(enum meminfo_item) * numitems);
info->items[numitems] = PROCPS_MEMINFO_logical_end;
info->numitems = numitems + 1;
if (info->extents)
extents_free_all(info);
}
if (!info->extents
&& !(stacks_alloc(info, 1)))
return NULL;
if (info->dirty_stacks)
cleanup_stacks_all(info);
if (read_meminfo_failed(info))
return NULL;
assign_results(info->extents->stacks[0], &info->mem_hist);
info->dirty_stacks = 1;
return info->extents->stacks[0];
} // end: procps_meminfo_select