df8fb11a47
Now that we may be getting serious with documentation, that stat module was revisited with an eye toward user friendliness. Heck, even this author puzzled over some of the existing notes and naming conventions employed. So, this patch will adjust some identifiers and expand the notes to (hopefully) better serve potential users. The most significant change was making the STAT_TIC_ID always valid for numa nodes, even if any are inactive. Thus the -22222 special STAT_NODE_INVALID constant now is applied only to STAT_TIC_NUMA_NODE. It will be used on the cpu summary and reaps with STAT_REAP_CPUS_ONLY. And it will also mark any numa node that was inactive. Signed-off-by: Jim Warner <james.warner@comcast.net>
1207 lines
42 KiB
C
1207 lines
42 KiB
C
/*
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* libprocps - Library to read proc filesystem
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Lesser General Public
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* License as published by the Free Software Foundation; either
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* version 2.1 of the License, or (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General Public
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* License along with this library; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*/
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#include <errno.h>
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#include <fcntl.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <time.h>
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#include <unistd.h>
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#include <sys/stat.h>
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#include <sys/types.h>
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#include <proc/numa.h>
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#include <proc/procps-private.h>
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#include <proc/stat.h>
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#define STAT_FILE "/proc/stat"
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#define BUFFER_INCR 4096 // amount i/p buffer allocations grow
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#define STACKS_INCR 32 // amount reap stack allocations grow
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#define NEWOLD_INCR 32 // amount jiffs hist allocations grow
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/* ------------------------------------------------------------------------- +
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because 'reap' would be forced to duplicate the global SYS stuff in every |
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TIC type results stack, the following #define can be used to enforce that |
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only STAT_noop and STAT_extra plus all the STAT_TIC items will be allowed | */
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//#define ENFORCE_LOGICAL // ensure only logical items are accepted by reap |
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// ------------------------------------------------------------------------- +
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/* --------------------------------------------------------------------------+
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this next define is equivalent to the master top's CPU_ZEROTICS provision |
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except that here in newlib we'll take an opposite approach to our default | */
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//#define CPU_IDLE_FORCED // show as 100% idle if fewer ticks than expected |
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// --------------------------------------------------------------------------+
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#ifdef CPU_IDLE_FORCED
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/* this is the % used in establishing a ticks threshold below which some |
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cpu will be treated 'idle' rather than reflect misleading tick values | */
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#define TICS_THRESHOLD ( 100 / 20 )
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#endif
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struct stat_jifs {
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unsigned long long user, nice, system, idle, iowait, irq, sirq, stolen, guest, gnice;
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unsigned long long xtot, xbsy, xidl, xusr, xsys;
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};
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struct stat_data {
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unsigned long intr;
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unsigned long ctxt;
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unsigned long btime;
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unsigned long procs_created;
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unsigned long procs_blocked;
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unsigned long procs_running;
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};
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struct hist_sys {
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struct stat_data new;
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struct stat_data old;
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};
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struct hist_tic {
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int id;
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int numa_node;
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int count;
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struct stat_jifs new;
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struct stat_jifs old;
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#ifdef CPU_IDLE_FORCED
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unsigned long edge; // only valued/valid with cpu summary |
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#endif
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};
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struct stacks_extent {
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int ext_numstacks;
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struct stacks_extent *next;
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struct stat_stack **stacks;
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};
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struct item_support {
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int num; // includes 'logical_end' delimiter
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enum stat_item *enums; // includes 'logical_end' delimiter
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};
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struct ext_support {
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struct item_support *items; // how these stacks are configured
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struct stacks_extent *extents; // anchor for these extents
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};
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struct tic_support {
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int n_alloc; // number of below structs allocated
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int n_inuse; // number of below structs occupied
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struct hist_tic *tics; // actual new/old jiffies
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};
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struct reap_support {
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int total; // independently obtained # of cpus/nodes
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struct ext_support fetch; // extents plus items details
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struct tic_support hist; // cpu and node jiffies management
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int n_alloc; // last known anchor pointers allocation
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struct stat_stack **anchor; // reapable stacks (consolidated extents)
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int n_alloc_save; // last known results.stacks allocation
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struct stat_reap result; // summary + stacks returned to caller
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};
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struct stat_info {
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int refcount;
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FILE *stat_fp;
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char *stat_buf; // grows to accommodate all /proc/stat
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int stat_buf_size; // current size for the above stat_buf
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struct hist_sys sys_hist; // SYS type management
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struct hist_tic cpu_hist; // TIC type management for cpu summary
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struct reap_support cpus; // TIC type management for real cpus
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struct reap_support nodes; // TIC type management for numa nodes
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struct ext_support cpu_summary; // supports /proc/stat line #1 results
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struct ext_support select; // support for 'procps_stat_select()'
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struct stat_reaped results; // for return to caller after a reap
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struct stat_result get_this; // for return to caller after a get
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struct item_support reap_items; // items used for reap (shared among 3)
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struct item_support select_items; // items unique to select
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};
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// ___ Results 'Set' Support ||||||||||||||||||||||||||||||||||||||||||||||||||
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#define setNAME(e) set_stat_ ## e
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#define setDECL(e) static void setNAME(e) \
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(struct stat_result *R, struct hist_sys *S, struct hist_tic *T)
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// regular assignment
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#define TIC_set(e,t,x) setDECL(e) { \
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(void)S; R->result. t = T->new. x; }
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#define SYS_set(e,t,x) setDECL(e) { \
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(void)T; R->result. t = S->new. x; }
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// delta assignment
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#define TICsetH(e,t,x) setDECL(e) { \
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(void)S; R->result. t = ( T->new. x - T->old. x ); \
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if (R->result. t < 0) R->result. t = 0; }
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#define SYSsetH(e,t,x) setDECL(e) { \
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(void)T; R->result. t = ( S->new. x - S->old. x ); }
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setDECL(noop) { (void)R; (void)S; (void)T; }
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setDECL(extra) { (void)S; (void)T; R->result.ull_int = 0; }
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setDECL(TIC_ID) { (void)S; R->result.s_int = T->id; }
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setDECL(TIC_NUMA_NODE) { (void)S; R->result.s_int = T->numa_node; }
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setDECL(TIC_NUM_CONTRIBUTORS) { (void)S; R->result.s_int = T->count; }
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TIC_set(TIC_USER, ull_int, user)
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TIC_set(TIC_NICE, ull_int, nice)
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TIC_set(TIC_SYSTEM, ull_int, system)
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TIC_set(TIC_IDLE, ull_int, idle)
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TIC_set(TIC_IOWAIT, ull_int, iowait)
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TIC_set(TIC_IRQ, ull_int, irq)
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TIC_set(TIC_SOFTIRQ, ull_int, sirq)
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TIC_set(TIC_STOLEN, ull_int, stolen)
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TIC_set(TIC_GUEST, ull_int, guest)
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TIC_set(TIC_GUEST_NICE, ull_int, gnice)
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TICsetH(TIC_DELTA_USER, sl_int, user)
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TICsetH(TIC_DELTA_NICE, sl_int, nice)
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TICsetH(TIC_DELTA_SYSTEM, sl_int, system)
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TICsetH(TIC_DELTA_IDLE, sl_int, idle)
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TICsetH(TIC_DELTA_IOWAIT, sl_int, iowait)
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TICsetH(TIC_DELTA_IRQ, sl_int, irq)
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TICsetH(TIC_DELTA_SOFTIRQ, sl_int, sirq)
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TICsetH(TIC_DELTA_STOLEN, sl_int, stolen)
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TICsetH(TIC_DELTA_GUEST, sl_int, guest)
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TICsetH(TIC_DELTA_GUEST_NICE, sl_int, gnice)
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TIC_set(TIC_SUM_TOTAL, ull_int, xtot)
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TIC_set(TIC_SUM_IDLE, ull_int, xidl)
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TIC_set(TIC_SUM_USER, ull_int, xusr)
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TIC_set(TIC_SUM_BUSY, ull_int, xbsy)
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TIC_set(TIC_SUM_SYSTEM, ull_int, xsys)
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TICsetH(TIC_SUM_DELTA_TOTAL, sl_int, xtot)
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TICsetH(TIC_SUM_DELTA_IDLE, sl_int, xidl)
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TICsetH(TIC_SUM_DELTA_USER, sl_int, xusr)
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TICsetH(TIC_SUM_DELTA_BUSY, sl_int, xbsy)
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TICsetH(TIC_SUM_DELTA_SYSTEM, sl_int, xsys)
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SYS_set(SYS_CTX_SWITCHES, ul_int, ctxt)
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SYS_set(SYS_INTERRUPTS, ul_int, intr)
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SYS_set(SYS_PROC_BLOCKED, ul_int, procs_blocked)
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SYS_set(SYS_PROC_CREATED, ul_int, procs_created)
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SYS_set(SYS_PROC_RUNNING, ul_int, procs_running)
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SYS_set(SYS_TIME_OF_BOOT, ul_int, btime)
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SYSsetH(SYS_DELTA_CTX_SWITCHES, s_int, ctxt)
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SYSsetH(SYS_DELTA_INTERRUPTS, s_int, intr)
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SYSsetH(SYS_DELTA_PROC_BLOCKED, s_int, procs_blocked)
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SYSsetH(SYS_DELTA_PROC_CREATED, s_int, procs_created)
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SYSsetH(SYS_DELTA_PROC_RUNNING, s_int, procs_running)
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#undef setDECL
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#undef TIC_set
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#undef SYS_set
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#undef TICsetH
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#undef SYSsetH
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// ___ Sorting Support ||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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struct sort_parms {
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int offset;
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enum stat_sort_order order;
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};
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#define srtNAME(t) sort_stat_ ## t
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#define srtDECL(t) static int srtNAME(t) \
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(const struct stat_stack **A, const struct stat_stack **B, struct sort_parms *P)
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srtDECL(s_int) {
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const struct stat_result *a = (*A)->head + P->offset; \
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const struct stat_result *b = (*B)->head + P->offset; \
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return P->order * (a->result.s_int - b->result.s_int);
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}
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srtDECL(sl_int) {
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const struct stat_result *a = (*A)->head + P->offset; \
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const struct stat_result *b = (*B)->head + P->offset; \
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return P->order * (a->result.sl_int - b->result.sl_int);
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}
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srtDECL(ul_int) {
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const struct stat_result *a = (*A)->head + P->offset; \
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const struct stat_result *b = (*B)->head + P->offset; \
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if ( a->result.ul_int > b->result.ul_int ) return P->order > 0 ? 1 : -1; \
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if ( a->result.ul_int < b->result.ul_int ) return P->order > 0 ? -1 : 1; \
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return 0;
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}
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srtDECL(ull_int) {
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const struct stat_result *a = (*A)->head + P->offset; \
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const struct stat_result *b = (*B)->head + P->offset; \
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if ( a->result.ull_int > b->result.ull_int ) return P->order > 0 ? 1 : -1; \
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if ( a->result.ull_int < b->result.ull_int ) return P->order > 0 ? -1 : 1; \
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return 0;
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}
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srtDECL(noop) { \
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(void)A; (void)B; (void)P; \
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return 0;
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}
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#undef srtDECL
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// ___ Controlling Table ||||||||||||||||||||||||||||||||||||||||||||||||||||||
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typedef void (*SET_t)(struct stat_result *, struct hist_sys *, struct hist_tic *);
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#define RS(e) (SET_t)setNAME(e)
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typedef int (*QSR_t)(const void *, const void *, void *);
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#define QS(t) (QSR_t)srtNAME(t)
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#define TS(t) STRINGIFY(t)
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#define TS_noop ""
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/*
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* Need it be said?
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* This table must be kept in the exact same order as
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* those 'enum stat_item' guys ! */
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static struct {
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SET_t setsfunc; // the actual result setting routine
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QSR_t sortfunc; // sort cmp func for a specific type
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char *type2str; // the result type as a string value
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} Item_table[] = {
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/* setsfunc sortfunc type2str
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--------------------------- ------------ ----------- */
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{ RS(noop), QS(noop), TS_noop },
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{ RS(extra), QS(ull_int), TS_noop },
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{ RS(TIC_ID), QS(s_int), TS(s_int) },
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{ RS(TIC_NUMA_NODE), QS(s_int), TS(s_int) },
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{ RS(TIC_NUM_CONTRIBUTORS), QS(s_int), TS(s_int) },
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{ RS(TIC_USER), QS(ull_int), TS(ull_int) },
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{ RS(TIC_NICE), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SYSTEM), QS(ull_int), TS(ull_int) },
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{ RS(TIC_IDLE), QS(ull_int), TS(ull_int) },
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{ RS(TIC_IOWAIT), QS(ull_int), TS(ull_int) },
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{ RS(TIC_IRQ), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SOFTIRQ), QS(ull_int), TS(ull_int) },
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{ RS(TIC_STOLEN), QS(ull_int), TS(ull_int) },
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{ RS(TIC_GUEST), QS(ull_int), TS(ull_int) },
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{ RS(TIC_GUEST_NICE), QS(ull_int), TS(ull_int) },
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{ RS(TIC_DELTA_USER), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_NICE), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_SYSTEM), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_IDLE), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_IOWAIT), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_IRQ), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_SOFTIRQ), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_STOLEN), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_GUEST), QS(sl_int), TS(sl_int) },
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{ RS(TIC_DELTA_GUEST_NICE), QS(sl_int), TS(sl_int) },
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{ RS(TIC_SUM_TOTAL), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SUM_IDLE), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SUM_USER), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SUM_BUSY), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SUM_SYSTEM), QS(ull_int), TS(ull_int) },
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{ RS(TIC_SUM_DELTA_TOTAL), QS(sl_int), TS(sl_int) },
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{ RS(TIC_SUM_DELTA_IDLE), QS(sl_int), TS(sl_int) },
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{ RS(TIC_SUM_DELTA_USER), QS(sl_int), TS(sl_int) },
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{ RS(TIC_SUM_DELTA_BUSY), QS(sl_int), TS(sl_int) },
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{ RS(TIC_SUM_DELTA_SYSTEM), QS(sl_int), TS(sl_int) },
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{ RS(SYS_CTX_SWITCHES), QS(ul_int), TS(ul_int) },
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{ RS(SYS_INTERRUPTS), QS(ul_int), TS(ul_int) },
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{ RS(SYS_PROC_BLOCKED), QS(ul_int), TS(ul_int) },
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{ RS(SYS_PROC_CREATED), QS(ul_int), TS(ul_int) },
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{ RS(SYS_PROC_RUNNING), QS(ul_int), TS(ul_int) },
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{ RS(SYS_TIME_OF_BOOT), QS(ul_int), TS(ul_int) },
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{ RS(SYS_DELTA_CTX_SWITCHES), QS(s_int), TS(s_int) },
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{ RS(SYS_DELTA_INTERRUPTS), QS(s_int), TS(s_int) },
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{ RS(SYS_DELTA_PROC_BLOCKED), QS(s_int), TS(s_int) },
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{ RS(SYS_DELTA_PROC_CREATED), QS(s_int), TS(s_int) },
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{ RS(SYS_DELTA_PROC_RUNNING), QS(s_int), TS(s_int) },
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// dummy entry corresponding to STAT_logical_end ...
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{ NULL, NULL, NULL }
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};
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/* please note,
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* 1st enum MUST be kept in sync with highest TIC type
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* 2nd enum MUST be 1 greater than the highest value of any enum */
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#ifdef ENFORCE_LOGICAL
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enum stat_item STAT_TIC_highest = STAT_TIC_DELTA_GUEST_NICE;
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#endif
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enum stat_item STAT_logical_end = STAT_SYS_DELTA_PROC_RUNNING + 1;
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#undef setNAME
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#undef srtNAME
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#undef RS
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#undef QS
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// ___ Private Functions ||||||||||||||||||||||||||||||||||||||||||||||||||||||
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static inline void stat_assign_results (
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struct stat_stack *stack,
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struct hist_sys *sys_hist,
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struct hist_tic *tic_hist)
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{
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struct stat_result *this = stack->head;
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for (;;) {
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enum stat_item item = this->item;
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if (item >= STAT_logical_end)
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break;
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Item_table[item].setsfunc(this, sys_hist, tic_hist);
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++this;
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}
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return;
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} // end: stat_assign_results
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static inline void stat_derive_unique (
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struct hist_tic *this)
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{
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/* note: we exclude guest tics from xtot since ...
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'user' already includes 'guest'
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'nice' already includes 'gnice'
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( see: ./kernel/sched/cputime.c, account_guest_time ) */
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this->new.xtot
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= this->new.user
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+ this->new.nice
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+ this->new.system
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+ this->new.idle
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+ this->new.iowait
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+ this->new.irq
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+ this->new.sirq
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+ this->new.stolen;
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this->new.xusr = this->new.user + this->new.nice;
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/* this stolen guy is one i'm not sure of yet, but it's documented as:
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"the time spent in other operating systems
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when running in a virtualized environment"
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so it would seem to apply to an 'involuntary wait' for a guest OS */
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this->new.xidl = this->new.idle + this->new.iowait + this->new.stolen;
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this->new.xbsy = this->new.xtot - this->new.xidl;
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this->new.xsys = this->new.xbsy - this->new.xusr;
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|
|
// don't distort deltas when cpus are taken offline or brought online
|
|
if (this->new.xtot < this->old.xtot
|
|
|| (this->new.xusr < this->old.xusr)
|
|
|| (this->new.xidl < this->old.xidl)
|
|
|| (this->new.xbsy < this->old.xbsy)
|
|
|| (this->new.xsys < this->old.xsys))
|
|
memcpy(&this->old, &this->new, sizeof(struct stat_jifs));
|
|
} // end: stat_derive_unique
|
|
|
|
|
|
static void stat_extents_free_all (
|
|
struct ext_support *this)
|
|
{
|
|
while (this->extents) {
|
|
struct stacks_extent *p = this->extents;
|
|
this->extents = this->extents->next;
|
|
free(p);
|
|
};
|
|
} // end: stat_extents_free_all
|
|
|
|
|
|
static inline struct stat_result *stat_itemize_stack (
|
|
struct stat_result *p,
|
|
int depth,
|
|
enum stat_item *items)
|
|
{
|
|
struct stat_result *p_sav = p;
|
|
int i;
|
|
|
|
for (i = 0; i < depth; i++) {
|
|
p->item = items[i];
|
|
++p;
|
|
}
|
|
return p_sav;
|
|
} // end: stat_itemize_stack
|
|
|
|
|
|
static inline int stat_items_check_failed (
|
|
int numitems,
|
|
enum stat_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 stat_item *'
|
|
* my_stack = procps_stat_select(info, STAT_noop, num);
|
|
* ^~~~~~~~~~~~~~~~
|
|
*/
|
|
if (numitems < 1
|
|
|| (void *)items < (void *)(unsigned long)(2 * STAT_logical_end))
|
|
return 1;
|
|
|
|
for (i = 0; i < numitems; i++) {
|
|
// a stat_item is currently unsigned, but we'll protect our future
|
|
if (items[i] < 0)
|
|
return 1;
|
|
if (items[i] >= STAT_logical_end) {
|
|
return 1;
|
|
}
|
|
}
|
|
return 0;
|
|
} // end: stat_items_check_failed
|
|
|
|
|
|
static int stat_make_numa_hist (
|
|
struct stat_info *info)
|
|
{
|
|
struct hist_tic *cpu_ptr, *nod_ptr;
|
|
int i, node;
|
|
|
|
/* are numa nodes dynamic like online cpus can be?
|
|
( and be careful, this libnuma call returns the highest node id in use, )
|
|
( NOT an actual number of nodes - some of those 'slots' might be unused ) */
|
|
if (!(info->nodes.total = numa_max_node() + 1))
|
|
return 0;
|
|
|
|
if (info->nodes.hist.n_alloc == 0
|
|
|| (info->nodes.total >= info->nodes.hist.n_alloc)) {
|
|
info->nodes.hist.n_alloc = info->nodes.total + NEWOLD_INCR;
|
|
info->nodes.hist.tics = realloc(info->nodes.hist.tics, info->nodes.hist.n_alloc * sizeof(struct hist_tic));
|
|
if (info->nodes.hist.tics == NULL)
|
|
return -ENOMEM;
|
|
}
|
|
|
|
// forget all of the prior node statistics & anticipate unassigned slots
|
|
memset(info->nodes.hist.tics, 0, info->nodes.hist.n_alloc * sizeof(struct hist_tic));
|
|
nod_ptr = info->nodes.hist.tics;
|
|
for (i = 0; i < info->nodes.total; i++) {
|
|
nod_ptr->numa_node = STAT_NODE_INVALID;
|
|
nod_ptr->id = i;
|
|
++nod_ptr;
|
|
}
|
|
|
|
// spin thru each cpu and value the jiffs for it's numa node
|
|
for (i = 0; i < info->cpus.hist.n_inuse; i++) {
|
|
cpu_ptr = info->cpus.hist.tics + i;
|
|
if (-1 < (node = numa_node_of_cpu(cpu_ptr->id))) {
|
|
nod_ptr = info->nodes.hist.tics + node;
|
|
nod_ptr->new.user += cpu_ptr->new.user; nod_ptr->old.user += cpu_ptr->old.user;
|
|
nod_ptr->new.nice += cpu_ptr->new.nice; nod_ptr->old.nice += cpu_ptr->old.nice;
|
|
nod_ptr->new.system += cpu_ptr->new.system; nod_ptr->old.system += cpu_ptr->old.system;
|
|
nod_ptr->new.idle += cpu_ptr->new.idle; nod_ptr->old.idle += cpu_ptr->old.idle;
|
|
nod_ptr->new.iowait += cpu_ptr->new.iowait; nod_ptr->old.iowait += cpu_ptr->old.iowait;
|
|
nod_ptr->new.irq += cpu_ptr->new.irq; nod_ptr->old.irq += cpu_ptr->old.irq;
|
|
nod_ptr->new.sirq += cpu_ptr->new.sirq; nod_ptr->old.sirq += cpu_ptr->old.sirq;
|
|
nod_ptr->new.stolen += cpu_ptr->new.stolen; nod_ptr->old.stolen += cpu_ptr->old.stolen;
|
|
nod_ptr->new.guest += cpu_ptr->new.guest; nod_ptr->old.guest += cpu_ptr->old.guest;
|
|
nod_ptr->new.gnice += cpu_ptr->new.gnice; nod_ptr->old.gnice += cpu_ptr->old.gnice;
|
|
|
|
nod_ptr->new.xtot += cpu_ptr->new.xtot; nod_ptr->old.xtot += cpu_ptr->old.xtot;
|
|
nod_ptr->new.xbsy += cpu_ptr->new.xbsy; nod_ptr->old.xbsy += cpu_ptr->old.xbsy;
|
|
nod_ptr->new.xidl += cpu_ptr->new.xidl; nod_ptr->old.xidl += cpu_ptr->old.xidl;
|
|
nod_ptr->new.xusr += cpu_ptr->new.xusr; nod_ptr->old.xusr += cpu_ptr->old.xusr;
|
|
nod_ptr->new.xsys += cpu_ptr->new.xsys; nod_ptr->old.xsys += cpu_ptr->old.xsys;
|
|
|
|
cpu_ptr->numa_node = nod_ptr->numa_node = node;
|
|
nod_ptr->count++; ;
|
|
}
|
|
}
|
|
info->nodes.hist.n_inuse = info->nodes.total;
|
|
return info->nodes.hist.n_inuse;
|
|
} // end: stat_make_numa_hist
|
|
|
|
|
|
static int stat_read_failed (
|
|
struct stat_info *info)
|
|
{
|
|
struct hist_tic *sum_ptr, *cpu_ptr;
|
|
char *bp, *b;
|
|
int i, rc, num, tot_read;
|
|
unsigned long long llnum;
|
|
|
|
if (!info->cpus.hist.n_alloc) {
|
|
info->cpus.hist.tics = calloc(NEWOLD_INCR, sizeof(struct hist_tic));
|
|
if (!(info->cpus.hist.tics))
|
|
return 1;
|
|
info->cpus.hist.n_alloc = NEWOLD_INCR;
|
|
info->cpus.hist.n_inuse = 0;
|
|
}
|
|
|
|
if (!info->stat_fp
|
|
&& (!(info->stat_fp = fopen(STAT_FILE, "r"))))
|
|
return 1;
|
|
fflush(info->stat_fp);
|
|
rewind(info->stat_fp);
|
|
|
|
#define maxSIZ info->stat_buf_size
|
|
#define curSIZ ( maxSIZ - tot_read )
|
|
#define curPOS ( info->stat_buf + tot_read )
|
|
/* we slurp in the entire directory thus avoiding repeated calls to fread, |
|
|
especially in a massively parallel environment. additionally, each cpu |
|
|
line is then frozen in time rather than changing until we get around to |
|
|
accessing it. this helps to minimize (not eliminate) some distortions. | */
|
|
tot_read = 0;
|
|
while ((0 < (num = fread(curPOS, 1, curSIZ, info->stat_fp)))) {
|
|
tot_read += num;
|
|
if (tot_read < maxSIZ)
|
|
break;
|
|
maxSIZ += BUFFER_INCR;
|
|
if (!(info->stat_buf = realloc(info->stat_buf, maxSIZ)))
|
|
return 1;
|
|
};
|
|
#undef maxSIZ
|
|
#undef curSIZ
|
|
#undef curPOS
|
|
|
|
if (!feof(info->stat_fp)) {
|
|
errno = EIO;
|
|
return 1;
|
|
}
|
|
info->stat_buf[tot_read] = '\0';
|
|
bp = info->stat_buf;
|
|
|
|
sum_ptr = &info->cpu_hist;
|
|
// remember summary from last time around
|
|
memcpy(&sum_ptr->old, &sum_ptr->new, sizeof(struct stat_jifs));
|
|
|
|
sum_ptr->id = STAT_SUMMARY_ID; // mark as summary
|
|
sum_ptr->numa_node = STAT_NODE_INVALID; // mark as invalid
|
|
|
|
// now value the cpu summary tics from line #1
|
|
if (8 > sscanf(bp, "cpu %llu %llu %llu %llu %llu %llu %llu %llu %llu %llu"
|
|
, &sum_ptr->new.user, &sum_ptr->new.nice, &sum_ptr->new.system
|
|
, &sum_ptr->new.idle, &sum_ptr->new.iowait, &sum_ptr->new.irq
|
|
, &sum_ptr->new.sirq, &sum_ptr->new.stolen
|
|
, &sum_ptr->new.guest, &sum_ptr->new.gnice)) {
|
|
errno = ERANGE;
|
|
return 1;
|
|
}
|
|
stat_derive_unique(sum_ptr);
|
|
#ifdef CPU_IDLE_FORCED
|
|
/* if any cpu accumulated substantially fewer tics than what is expected |
|
|
we'll force it to be treated as 'idle' so as not to return misleading |
|
|
statistics (and that sum_ptr->count also serves as first time switch) | */
|
|
if (sum_ptr->count) sum_ptr->edge =
|
|
((sum_ptr->new.xtot - sum_ptr->old.xtot) / sum_ptr->count) / TICS_THRESHOLD;
|
|
#endif
|
|
|
|
i = 0;
|
|
reap_em_again:
|
|
cpu_ptr = info->cpus.hist.tics + i; // adapt to relocated if reap_em_again
|
|
|
|
do {
|
|
bp = 1 + strchr(bp, '\n');
|
|
// remember this cpu from last time around
|
|
memcpy(&cpu_ptr->old, &cpu_ptr->new, sizeof(struct stat_jifs));
|
|
// next can be overridden under 'stat_make_numa_hist'
|
|
cpu_ptr->numa_node = STAT_NODE_INVALID;
|
|
cpu_ptr->count = 1;
|
|
|
|
if (8 > (rc = sscanf(bp, "cpu%d %llu %llu %llu %llu %llu %llu %llu %llu %llu %llu"
|
|
, &cpu_ptr->id
|
|
, &cpu_ptr->new.user, &cpu_ptr->new.nice, &cpu_ptr->new.system
|
|
, &cpu_ptr->new.idle, &cpu_ptr->new.iowait, &cpu_ptr->new.irq
|
|
, &cpu_ptr->new.sirq, &cpu_ptr->new.stolen
|
|
, &cpu_ptr->new.guest, &cpu_ptr->new.gnice))) {
|
|
break; // we must tolerate cpus taken offline
|
|
}
|
|
stat_derive_unique(cpu_ptr);
|
|
#ifdef CPU_IDLE_FORCED
|
|
// first time through (that priming read) sum_ptr->edge will be zero |
|
|
if (cpu_ptr->new.xtot < sum_ptr->edge) {
|
|
cpu_ptr->old.xtot = cpu_ptr->old.xbsy = cpu_ptr->old.xidl = cpu_ptr->old.xusr = cpu_ptr->old.xsys
|
|
= cpu_ptr->new.xbsy = cpu_ptr->new.xusr = cpu_ptr->new.xsys = 0;
|
|
cpu_ptr->new.xtot = cpu_ptr->new.xidl = 1;
|
|
}
|
|
#endif
|
|
++cpu_ptr;
|
|
++i;
|
|
} while (i < info->cpus.hist.n_alloc);
|
|
|
|
if (i == info->cpus.hist.n_alloc && rc >= 8) {
|
|
info->cpus.hist.n_alloc += NEWOLD_INCR;
|
|
info->cpus.hist.tics = realloc(info->cpus.hist.tics, info->cpus.hist.n_alloc * sizeof(struct hist_tic));
|
|
if (!(info->cpus.hist.tics))
|
|
return 1;
|
|
goto reap_em_again;
|
|
}
|
|
|
|
info->cpus.total = info->cpus.hist.n_inuse = sum_ptr->count = i;
|
|
|
|
// remember sys_hist stuff from last time around
|
|
memcpy(&info->sys_hist.old, &info->sys_hist.new, sizeof(struct stat_data));
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "intr ")))
|
|
sscanf(b, "intr %llu", &llnum);
|
|
info->sys_hist.new.intr = llnum;
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "ctxt ")))
|
|
sscanf(b, "ctxt %llu", &llnum);
|
|
info->sys_hist.new.ctxt = llnum;
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "btime ")))
|
|
sscanf(b, "btime %llu", &llnum);
|
|
info->sys_hist.new.btime = llnum;
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "processes ")))
|
|
sscanf(b, "processes %llu", &llnum);
|
|
info->sys_hist.new.procs_created = llnum;
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "procs_blocked ")))
|
|
sscanf(b, "procs_blocked %llu", &llnum);
|
|
info->sys_hist.new.procs_blocked = llnum;
|
|
|
|
llnum = 0;
|
|
if ((b = strstr(bp, "procs_running ")))
|
|
sscanf(b, "procs_running %llu", &llnum);
|
|
info->sys_hist.new.procs_running = llnum;
|
|
|
|
return 0;
|
|
} // end: stat_read_failed
|
|
|
|
|
|
/*
|
|
* stat_stacks_alloc():
|
|
*
|
|
* Allocate and initialize one or more stacks each of which is anchored in an
|
|
* associated context structure.
|
|
*
|
|
* All such stacks will have their result structures properly primed with
|
|
* 'items', while the result itself will be zeroed.
|
|
*
|
|
* Returns a stack_extent struct anchoring the 'heads' of each new stack.
|
|
*/
|
|
static struct stacks_extent *stat_stacks_alloc (
|
|
struct ext_support *this,
|
|
int maxstacks)
|
|
{
|
|
struct stacks_extent *p_blob;
|
|
struct stat_stack **p_vect;
|
|
struct stat_stack *p_head;
|
|
size_t vect_size, head_size, list_size, blob_size;
|
|
void *v_head, *v_list;
|
|
int i;
|
|
|
|
vect_size = sizeof(void *) * maxstacks; // size of the addr vectors |
|
|
vect_size += sizeof(void *); // plus NULL addr delimiter |
|
|
head_size = sizeof(struct stat_stack); // size of that head struct |
|
|
list_size = sizeof(struct stat_result) * this->items->num; // 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 one single blob, facilitating a later free(). |
|
|
as a minimum, it is important that those result structures themselves always be |
|
|
contiguous within each stack since they are accessed through relative position. | */
|
|
if (NULL == (p_blob = calloc(1, blob_size)))
|
|
return NULL;
|
|
|
|
p_blob->next = this->extents; // push this extent onto... |
|
|
this->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 stat_stack *)v_head;
|
|
p_head->head = stat_itemize_stack((struct stat_result *)v_list, this->items->num, this->items->enums);
|
|
p_blob->stacks[i] = p_head;
|
|
v_list += list_size;
|
|
v_head += head_size;
|
|
}
|
|
p_blob->ext_numstacks = maxstacks;
|
|
return p_blob;
|
|
} // end: stat_stacks_alloc
|
|
|
|
|
|
static int stat_stacks_fetch (
|
|
struct stat_info *info,
|
|
struct reap_support *this)
|
|
{
|
|
#define n_alloc this->n_alloc
|
|
#define n_inuse this->hist.n_inuse
|
|
#define n_saved this->n_alloc_save
|
|
struct stacks_extent *ext;
|
|
int i;
|
|
|
|
// initialize stuff -----------------------------------
|
|
if (!this->anchor) {
|
|
if (!(this->anchor = calloc(sizeof(void *), STACKS_INCR)))
|
|
return -1;
|
|
n_alloc = STACKS_INCR;
|
|
}
|
|
if (!this->fetch.extents) {
|
|
if (!(ext = stat_stacks_alloc(&this->fetch, n_alloc)))
|
|
return -1; // here, errno was set to ENOMEM
|
|
memcpy(this->anchor, ext->stacks, sizeof(void *) * n_alloc);
|
|
}
|
|
|
|
// iterate stuff --------------------------------------
|
|
for (i = 0; i < n_inuse; i++) {
|
|
if (!(i < n_alloc)) {
|
|
n_alloc += STACKS_INCR;
|
|
if ((!(this->anchor = realloc(this->anchor, sizeof(void *) * n_alloc)))
|
|
|| (!(ext = stat_stacks_alloc(&this->fetch, STACKS_INCR))))
|
|
return -1; // here, errno was set to ENOMEM
|
|
memcpy(this->anchor + i, ext->stacks, sizeof(void *) * STACKS_INCR);
|
|
}
|
|
stat_assign_results(this->anchor[i], &info->sys_hist, &this->hist.tics[i]);
|
|
}
|
|
|
|
// finalize stuff -------------------------------------
|
|
/* note: we go to this trouble of maintaining a duplicate of the consolidated |
|
|
extent stacks addresses represented as our 'anchor' since these ptrs |
|
|
are exposed to a user (um, not that we don't trust 'em or anything). |
|
|
plus, we can NULL delimit these ptrs which we couldn't do otherwise. | */
|
|
if (n_saved < i + 1) {
|
|
n_saved = i + 1;
|
|
if (!(this->result.stacks = realloc(this->result.stacks, sizeof(void *) * n_saved)))
|
|
return -1;
|
|
}
|
|
memcpy(this->result.stacks, this->anchor, sizeof(void *) * i);
|
|
this->result.stacks[i] = NULL;
|
|
this->result.total = i;
|
|
|
|
// callers beware, this might be zero (maybe no libnuma.so) ...
|
|
return this->result.total;
|
|
#undef n_alloc
|
|
#undef n_inuse
|
|
#undef n_saved
|
|
} // end: stat_stacks_fetch
|
|
|
|
|
|
static int stat_stacks_reconfig_maybe (
|
|
struct ext_support *this,
|
|
enum stat_item *items,
|
|
int numitems)
|
|
{
|
|
if (stat_items_check_failed(numitems, items))
|
|
return -1;
|
|
/* is this the first time or have things changed since we were last called?
|
|
if so, gotta' redo all of our stacks stuff ... */
|
|
if (this->items->num != numitems + 1
|
|
|| memcmp(this->items->enums, items, sizeof(enum stat_item) * numitems)) {
|
|
// allow for our STAT_logical_end
|
|
if (!(this->items->enums = realloc(this->items->enums, sizeof(enum stat_item) * (numitems + 1))))
|
|
return -1;
|
|
memcpy(this->items->enums, items, sizeof(enum stat_item) * numitems);
|
|
this->items->enums[numitems] = STAT_logical_end;
|
|
this->items->num = numitems + 1;
|
|
stat_extents_free_all(this);
|
|
return 1;
|
|
}
|
|
return 0;
|
|
} // end: stat_stacks_reconfig_maybe
|
|
|
|
|
|
static struct stat_stack *stat_update_single_stack (
|
|
struct stat_info *info,
|
|
struct ext_support *this)
|
|
{
|
|
if (!this->extents
|
|
&& !(stat_stacks_alloc(this, 1)))
|
|
return NULL;
|
|
|
|
stat_assign_results(this->extents->stacks[0], &info->sys_hist, &info->cpu_hist);
|
|
|
|
return this->extents->stacks[0];
|
|
} // end: stat_update_single_stack
|
|
|
|
|
|
|
|
// ___ Public Functions |||||||||||||||||||||||||||||||||||||||||||||||||||||||
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// --- standard required functions --------------------------------------------
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/*
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* procps_stat_new:
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*
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* Create a new container to hold the stat information
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*
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* The initial refcount is 1, and needs to be decremented
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* to release the resources of the structure.
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*
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* Returns: < 0 on failure, 0 on success along with
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* a pointer to a new context struct
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*/
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PROCPS_EXPORT int procps_stat_new (
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struct stat_info **info)
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{
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struct stat_info *p;
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if (info == NULL || *info != NULL)
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return -EINVAL;
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if (!(p = calloc(1, sizeof(struct stat_info))))
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return -ENOMEM;
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if (!(p->stat_buf = calloc(1, BUFFER_INCR))) {
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free(p);
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return -ENOMEM;
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}
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p->stat_buf_size = BUFFER_INCR;
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p->refcount = 1;
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p->results.cpus = &p->cpus.result;
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p->results.numa = &p->nodes.result;
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// these 3 are for reap, sharing a single set of items
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p->cpu_summary.items = p->cpus.fetch.items = p->nodes.fetch.items = &p->reap_items;
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// the select guy has its own set of items
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p->select.items = &p->select_items;
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numa_init();
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/* do a priming read here for the following potential benefits: |
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1) ensure there will be no problems with subsequent access |
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2) make delta results potentially useful, even if 1st time |
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3) elimnate need for history distortions 1st time 'switch' | */
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if (stat_read_failed(p)) {
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procps_stat_unref(&p);
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return -errno;
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}
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*info = p;
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return 0;
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} // end :procps_stat_new
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PROCPS_EXPORT int procps_stat_ref (
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struct stat_info *info)
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{
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if (info == NULL)
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return -EINVAL;
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info->refcount++;
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return info->refcount;
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} // end: procps_stat_ref
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PROCPS_EXPORT int procps_stat_unref (
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struct stat_info **info)
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{
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if (info == NULL || *info == NULL)
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return -EINVAL;
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(*info)->refcount--;
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if ((*info)->refcount < 1) {
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int errno_sav = errno;
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if ((*info)->stat_fp)
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fclose((*info)->stat_fp);
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if ((*info)->stat_buf)
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free((*info)->stat_buf);
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if ((*info)->cpus.anchor)
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free((*info)->cpus.anchor);
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if ((*info)->cpus.result.stacks)
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free((*info)->cpus.result.stacks);
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if ((*info)->cpus.hist.tics)
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free((*info)->cpus.hist.tics);
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if ((*info)->cpus.fetch.extents)
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stat_extents_free_all(&(*info)->cpus.fetch);
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if ((*info)->nodes.anchor)
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free((*info)->nodes.anchor);
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if ((*info)->nodes.result.stacks)
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free((*info)->nodes.result.stacks);
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if ((*info)->nodes.hist.tics)
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free((*info)->nodes.hist.tics);
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if ((*info)->nodes.fetch.extents)
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stat_extents_free_all(&(*info)->nodes.fetch);
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if ((*info)->cpu_summary.extents)
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stat_extents_free_all(&(*info)->cpu_summary);
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if ((*info)->select.extents)
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stat_extents_free_all(&(*info)->select);
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if ((*info)->reap_items.enums)
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free((*info)->reap_items.enums);
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if ((*info)->select_items.enums)
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free((*info)->select_items.enums);
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numa_uninit();
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free(*info);
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*info = NULL;
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errno = errno_sav;
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return 0;
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}
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return (*info)->refcount;
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} // end: procps_stat_unref
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// --- variable interface functions -------------------------------------------
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PROCPS_EXPORT struct stat_result *procps_stat_get (
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struct stat_info *info,
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enum stat_item item)
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{
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static time_t sav_secs;
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time_t cur_secs;
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errno = EINVAL;
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if (info == NULL)
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return NULL;
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if (item < 0 || item >= STAT_logical_end)
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return NULL;
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errno = 0;
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/* we will NOT read the source file with every call - rather, we'll offer
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a granularity of 1 second between reads ... */
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cur_secs = time(NULL);
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if (1 <= cur_secs - sav_secs) {
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if (stat_read_failed(info))
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return NULL;
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sav_secs = cur_secs;
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}
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info->get_this.item = item;
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// with 'get', we must NOT honor the usual 'noop' guarantee
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info->get_this.result.ull_int = 0;
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Item_table[item].setsfunc(&info->get_this, &info->sys_hist, &info->cpu_hist);
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return &info->get_this;
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} // end: procps_stat_get
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/* procps_stat_reap():
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*
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* Harvest all the requested NUMA NODE and/or CPU information providing the
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* result stacks along with totals and the cpu summary.
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*
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* Returns: pointer to a stat_reaped struct on success, NULL on error.
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*/
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PROCPS_EXPORT struct stat_reaped *procps_stat_reap (
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struct stat_info *info,
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enum stat_reap_type what,
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enum stat_item *items,
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int numitems)
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{
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int rc;
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errno = EINVAL;
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if (info == NULL || items == NULL)
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return NULL;
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if (what != STAT_REAP_CPUS_ONLY && what != STAT_REAP_NUMA_NODES_TOO)
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return NULL;
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#ifdef ENFORCE_LOGICAL
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{ int i;
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// those STAT_SYS_type enum's make sense only to 'select' ...
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for (i = 0; i < numitems; i++) {
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if (items[i] > STAT_TIC_highest)
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return NULL;
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}
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}
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#endif
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if (0 > (rc = stat_stacks_reconfig_maybe(&info->cpu_summary, items, numitems)))
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return NULL; // here, errno may be overridden with ENOMEM
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if (rc) {
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stat_extents_free_all(&info->cpus.fetch);
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stat_extents_free_all(&info->nodes.fetch);
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}
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errno = 0;
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if (stat_read_failed(info))
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return NULL;
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info->results.summary = stat_update_single_stack(info, &info->cpu_summary);
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/* unlike the other 'reap' functions, <stat> provides for two separate |
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stacks pointer arrays exposed to callers. Thus, to keep our promise |
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of NULL delimit we must ensure a minimal array for the optional one | */
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if (!info->nodes.result.stacks
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&& (!(info->nodes.result.stacks = malloc(sizeof(void *)))))
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return NULL;
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info->nodes.result.total = 0;
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info->nodes.result.stacks[0] = NULL;
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switch (what) {
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case STAT_REAP_CPUS_ONLY:
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if (0 > stat_stacks_fetch(info, &info->cpus))
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return NULL;
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break;
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case STAT_REAP_NUMA_NODES_TOO:
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/* note: if we're doing numa at all, we must do this numa history |
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before we build (fetch) cpu stacks since that stat_read_failed |
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guy always marks (temporarily) all the cpu node ids as invalid | */
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if (0 > stat_make_numa_hist(info))
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return NULL;
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if (0 > stat_stacks_fetch(info, &info->nodes))
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return NULL;
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if (0 > stat_stacks_fetch(info, &info->cpus))
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return NULL;
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break;
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default:
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return NULL;
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};
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return &info->results;
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} // end: procps_stat_reap
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/* procps_stat_select():
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*
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* Harvest all the requested TIC and/or SYS information then return
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* it in a results stack.
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*
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* Returns: pointer to a stat_stack struct on success, NULL on error.
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*/
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PROCPS_EXPORT struct stat_stack *procps_stat_select (
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struct stat_info *info,
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enum stat_item *items,
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int numitems)
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{
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errno = EINVAL;
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if (info == NULL || items == NULL)
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return NULL;
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if (0 > stat_stacks_reconfig_maybe(&info->select, items, numitems))
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return NULL; // here, errno may be overridden with ENOMEM
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errno = 0;
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if (stat_read_failed(info))
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return NULL;
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return stat_update_single_stack(info, &info->select);
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} // end: procps_stat_select
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/*
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* procps_stat_sort():
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*
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* Sort stacks anchored in the passed stack pointers array
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* based on the designated sort enumerator and specified order.
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*
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* Returns those same addresses sorted.
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*
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* Note: all of the stacks must be homogeneous (of equal length and content).
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*/
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PROCPS_EXPORT struct stat_stack **procps_stat_sort (
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struct stat_info *info,
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struct stat_stack *stacks[],
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int numstacked,
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enum stat_item sortitem,
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enum stat_sort_order order)
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{
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struct stat_result *p;
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struct sort_parms parms;
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int offset;
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errno = EINVAL;
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if (info == NULL || stacks == NULL)
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return NULL;
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// a stat_item is currently unsigned, but we'll protect our future
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if (sortitem < 0 || sortitem >= STAT_logical_end)
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return NULL;
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if (order != STAT_SORT_ASCEND && order != STAT_SORT_DESCEND)
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return NULL;
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if (numstacked < 2)
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return stacks;
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offset = 0;
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p = stacks[0]->head;
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for (;;) {
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if (p->item == sortitem)
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break;
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++offset;
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if (p->item >= STAT_logical_end)
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return NULL;
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++p;
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}
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errno = 0;
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parms.offset = offset;
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parms.order = order;
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qsort_r(stacks, numstacked, sizeof(void *), (QSR_t)Item_table[p->item].sortfunc, &parms);
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return stacks;
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} // end: procps_stat_sort
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// --- special debugging function(s) ------------------------------------------
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/*
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* The following isn't part of the normal programming interface. Rather,
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* it exists to validate result types referenced in application programs.
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*
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* It's used only when:
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* 1) the 'XTRA_PROCPS_DEBUG' has been defined, or
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* 2) the '#include <proc/xtra-procps-debug.h>' used
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*/
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PROCPS_EXPORT struct stat_result *xtra_stat_get (
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struct stat_info *info,
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enum stat_item actual_enum,
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const char *typestr,
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const char *file,
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int lineno)
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{
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struct stat_result *r = procps_stat_get(info, actual_enum);
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if (actual_enum < 0 || actual_enum >= STAT_logical_end) {
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fprintf(stderr, "%s line %d: invalid item = %d, type = %s\n"
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, file, lineno, actual_enum, typestr);
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}
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if (r) {
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char *str = Item_table[r->item].type2str;
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if (str[0]
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&& (strcmp(typestr, str)))
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fprintf(stderr, "%s line %d: was %s, expected %s\n", file, lineno, typestr, str);
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}
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return r;
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} // end: xtra_stat_get_
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PROCPS_EXPORT struct stat_result *xtra_stat_val (
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int relative_enum,
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const char *typestr,
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const struct stat_stack *stack,
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struct stat_info *info,
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const char *file,
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int lineno)
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{
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char *str;
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int i;
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for (i = 0; stack->head[i].item < STAT_logical_end; i++)
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;
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if (relative_enum < 0 || relative_enum >= i) {
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fprintf(stderr, "%s line %d: invalid relative_enum = %d, type = %s\n"
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, file, lineno, relative_enum, typestr);
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return NULL;
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}
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str = Item_table[stack->head[relative_enum].item].type2str;
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if (str[0]
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&& (strcmp(typestr, str))) {
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fprintf(stderr, "%s line %d: was %s, expected %s\n", file, lineno, typestr, str);
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}
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return &stack->head[relative_enum];
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(void)info;
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} // end: xtra_stat_val
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