Add a platform for Performance Co-Pilot (PCP) metrics

This introduces an initial platform for extracting metrics
using the PCP performance metrics API - PMAPI(3).  It can
be used via the --enable-pcp=yes configure option.

So far I've added support for live localhost metrics only,
and only using pre-defined metrics already found in htop.
If available, all sampling is performed by pmcd(1) - else,
we fallback to htop doing the metric sampling itself (all
below the PMAPI).  When pmcd is used, it may be configured
to run children with elevated privileges, so htop does not
need to be setuid (authentication with pmcd is available).

Additionally, the PMAPI allows us to support archives (for
historical analysis and for automated regression tests in
htop).  We'll need platform-specific command line argument
additions, which isn't yet feasible in htop (not difficult
to add though).

The goal of this first version is minimal impact in terms
of modifying the htop codebase, to introduce key ideas in
PCP (metric namespace, metadata, APIs and so on) and give
us something to discuss, experiment with and build on.
This commit is contained in:
Nathan Scott 2021-02-17 14:43:56 +11:00
parent d075d49a0c
commit c14a45ba35
9 changed files with 2504 additions and 0 deletions

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@ -328,6 +328,29 @@ myhtopplatheaders = $(solaris_platform_headers)
myhtopplatsources = $(solaris_platform_sources)
endif
# Performance Co-Pilot (PCP)
# --------------------------
pcp_platform_headers = \
pcp/PCPProcess.h \
pcp/PCPProcessList.h \
pcp/Platform.h \
pcp/ProcessField.h \
linux/PressureStallMeter.h \
linux/ZramMeter.h \
linux/ZramStats.h
if HTOP_PCP
myhtopplatsources = \
pcp/PCPProcess.c \
pcp/PCPProcessList.c \
pcp/Platform.c \
linux/PressureStallMeter.c \
linux/ZramMeter.c
myhtopplatheaders = $(pcp_platform_headers)
endif
# Unsupported
# -----------

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@ -95,6 +95,31 @@ esac
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# Checks for a PCP-based htop build. (https://pcp.io)
# ----------------------------------------------------------------------
AC_ARG_ENABLE([pcp],
[AS_HELP_STRING([--enable-pcp],
[build a pcp htop binary @<:@default=no@:>@])],
[],
[enable_pcp=no])
case "$enable_pcp" in
no)
;;
yes)
AC_CHECK_HEADERS([pcp/pmapi.h], [my_htop_platform=pcp],
[AC_MSG_ERROR([can not find PCP header file])])
AC_SEARCH_LIBS([pmNewContext], [pcp], [], [AC_MSG_ERROR([can not find pcp library])])
AC_DEFINE([HTOP_PCP], [1], [Define if building pcp htop binary.])
;;
*)
AC_MSG_ERROR([bad value '$enable_static' for --enable-static option])
;;
esac
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# Checks for generic header files.
@ -608,6 +633,7 @@ AM_CONDITIONAL([HTOP_DRAGONFLYBSD], [test "$my_htop_platform" = dragonflybsd])
AM_CONDITIONAL([HTOP_OPENBSD], [test "$my_htop_platform" = openbsd])
AM_CONDITIONAL([HTOP_DARWIN], [test "$my_htop_platform" = darwin])
AM_CONDITIONAL([HTOP_SOLARIS], [test "$my_htop_platform" = solaris])
AM_CONDITIONAL([HTOP_PCP], [test "$my_htop_platform" = pcp])
AM_CONDITIONAL([HTOP_UNSUPPORTED], [test "$my_htop_platform" = unsupported])
AC_SUBST(my_htop_platform)

517
pcp/PCPProcess.c Normal file
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@ -0,0 +1,517 @@
/*
htop - PCPProcess.c
(C) 2014 Hisham H. Muhammad
(C) 2020 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "PCPProcess.h"
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <syscall.h>
#include <unistd.h>
#include "CRT.h"
#include "Process.h"
#include "ProvideCurses.h"
#include "XUtils.h"
/* Used to identify kernel threads in Comm column */
static const char *const kthreadID = "KTHREAD";
const ProcessFieldData Process_fields[] = {
[0] = { .name = "", .title = NULL, .description = NULL, .flags = 0, },
[PID] = { .name = "PID", .title = "PID", .description = "Process/thread ID", .flags = 0, .pidColumn = true, },
[COMM] = { .name = "Command", .title = "Command ", .description = "Command line", .flags = 0, },
[STATE] = { .name = "STATE", .title = "S ", .description = "Process state (S sleeping, R running, D disk, Z zombie, T traced, W paging, I idle)", .flags = 0, },
[PPID] = { .name = "PPID", .title = "PPID", .description = "Parent process ID", .flags = 0, },
[PGRP] = { .name = "PGRP", .title = "PGRP", .description = "Process group ID", .flags = 0, },
[SESSION] = { .name = "SESSION", .title = "SID", .description = "Process's session ID", .flags = 0, },
[TTY_NR] = { .name = "TTY_NR", .title = "TTY ", .description = "Controlling terminal", .flags = 0, },
[TPGID] = { .name = "TPGID", .title = "TPGID", .description = "Process ID of the fg process group of the controlling terminal", .flags = 0, },
[MINFLT] = { .name = "MINFLT", .title = " MINFLT ", .description = "Number of minor faults which have not required loading a memory page from disk", .flags = 0, .defaultSortDesc = true, },
[CMINFLT] = { .name = "CMINFLT", .title = " CMINFLT ", .description = "Children processes' minor faults", .flags = 0, .defaultSortDesc = true, },
[MAJFLT] = { .name = "MAJFLT", .title = " MAJFLT ", .description = "Number of major faults which have required loading a memory page from disk", .flags = 0, .defaultSortDesc = true, },
[CMAJFLT] = { .name = "CMAJFLT", .title = " CMAJFLT ", .description = "Children processes' major faults", .flags = 0, .defaultSortDesc = true, },
[UTIME] = { .name = "UTIME", .title = " UTIME+ ", .description = "User CPU time - time the process spent executing in user mode", .flags = 0, .defaultSortDesc = true, },
[STIME] = { .name = "STIME", .title = " STIME+ ", .description = "System CPU time - time the kernel spent running system calls for this process", .flags = 0, .defaultSortDesc = true, },
[CUTIME] = { .name = "CUTIME", .title = " CUTIME+ ", .description = "Children processes' user CPU time", .flags = 0, .defaultSortDesc = true, },
[CSTIME] = { .name = "CSTIME", .title = " CSTIME+ ", .description = "Children processes' system CPU time", .flags = 0, .defaultSortDesc = true, },
[PRIORITY] = { .name = "PRIORITY", .title = "PRI ", .description = "Kernel's internal priority for the process", .flags = 0, },
[NICE] = { .name = "NICE", .title = " NI ", .description = "Nice value (the higher the value, the more it lets other processes take priority)", .flags = 0, },
[STARTTIME] = { .name = "STARTTIME", .title = "START ", .description = "Time the process was started", .flags = 0, },
[PROCESSOR] = { .name = "PROCESSOR", .title = "CPU ", .description = "If of the CPU the process last executed on", .flags = 0, },
[M_VIRT] = { .name = "M_VIRT", .title = " VIRT ", .description = "Total program size in virtual memory", .flags = 0, .defaultSortDesc = true, },
[M_RESIDENT] = { .name = "M_RESIDENT", .title = " RES ", .description = "Resident set size, size of the text and data sections, plus stack usage", .flags = 0, .defaultSortDesc = true, },
[M_SHARE] = { .name = "M_SHARE", .title = " SHR ", .description = "Size of the process's shared pages", .flags = 0, .defaultSortDesc = true, },
[M_TRS] = { .name = "M_TRS", .title = " CODE ", .description = "Size of the text segment of the process", .flags = 0, .defaultSortDesc = true, },
[M_DRS] = { .name = "M_DRS", .title = " DATA ", .description = "Size of the data segment plus stack usage of the process", .flags = 0, .defaultSortDesc = true, },
[M_LRS] = { .name = "M_LRS", .title = " LIB ", .description = "The library size of the process (unused since Linux 2.6; always 0)", .flags = 0, .defaultSortDesc = true, },
[M_DT] = { .name = "M_DT", .title = " DIRTY ", .description = "Size of the dirty pages of the process (unused since Linux 2.6; always 0)", .flags = 0, .defaultSortDesc = true, },
[ST_UID] = { .name = "ST_UID", .title = " UID ", .description = "User ID of the process owner", .flags = 0, },
[PERCENT_CPU] = { .name = "PERCENT_CPU", .title = "CPU% ", .description = "Percentage of the CPU time the process used in the last sampling", .flags = 0, .defaultSortDesc = true, },
[PERCENT_NORM_CPU] = { .name = "PERCENT_NORM_CPU", .title = "NCPU%", .description = "Normalized percentage of the CPU time the process used in the last sampling (normalized by cpu count)", .flags = 0, .defaultSortDesc = true, },
[PERCENT_MEM] = { .name = "PERCENT_MEM", .title = "MEM% ", .description = "Percentage of the memory the process is using, based on resident memory size", .flags = 0, .defaultSortDesc = true, },
[USER] = { .name = "USER", .title = "USER ", .description = "Username of the process owner (or user ID if name cannot be determined)", .flags = 0, },
[TIME] = { .name = "TIME", .title = " TIME+ ", .description = "Total time the process has spent in user and system time", .flags = 0, .defaultSortDesc = true, },
[NLWP] = { .name = "NLWP", .title = "NLWP ", .description = "Number of threads in the process", .flags = 0, .defaultSortDesc = true, },
[TGID] = { .name = "TGID", .title = "TGID", .description = "Thread group ID (i.e. process ID)", .flags = 0, },
[RCHAR] = { .name = "RCHAR", .title = "RCHAR ", .description = "Number of bytes the process has read", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[WCHAR] = { .name = "WCHAR", .title = "WCHAR ", .description = "Number of bytes the process has written", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[SYSCR] = { .name = "SYSCR", .title = " READ_SYSC ", .description = "Number of read(2) syscalls for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[SYSCW] = { .name = "SYSCW", .title = " WRITE_SYSC ", .description = "Number of write(2) syscalls for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[RBYTES] = { .name = "RBYTES", .title = " IO_R ", .description = "Bytes of read(2) I/O for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[WBYTES] = { .name = "WBYTES", .title = " IO_W ", .description = "Bytes of write(2) I/O for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[CNCLWB] = { .name = "CNCLWB", .title = " IO_C ", .description = "Bytes of cancelled write(2) I/O", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[IO_READ_RATE] = { .name = "IO_READ_RATE", .title = " DISK READ ", .description = "The I/O rate of read(2) in bytes per second for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[IO_WRITE_RATE] = { .name = "IO_WRITE_RATE", .title = " DISK WRITE ", .description = "The I/O rate of write(2) in bytes per second for the process", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[IO_RATE] = { .name = "IO_RATE", .title = " DISK R/W ", .description = "Total I/O rate in bytes per second", .flags = PROCESS_FLAG_IO, .defaultSortDesc = true, },
[CGROUP] = { .name = "CGROUP", .title = " CGROUP ", .description = "Which cgroup the process is in", .flags = PROCESS_FLAG_LINUX_CGROUP, },
[OOM] = { .name = "OOM", .title = " OOM ", .description = "OOM (Out-of-Memory) killer score", .flags = PROCESS_FLAG_LINUX_OOM, .defaultSortDesc = true, },
[PERCENT_CPU_DELAY] = { .name = "PERCENT_CPU_DELAY", .title = "CPUD% ", .description = "CPU delay %", .flags = 0, .defaultSortDesc = true, },
[PERCENT_IO_DELAY] = { .name = "PERCENT_IO_DELAY", .title = "IOD% ", .description = "Block I/O delay %", .flags = 0, .defaultSortDesc = true, },
[PERCENT_SWAP_DELAY] = { .name = "PERCENT_SWAP_DELAY", .title = "SWAPD% ", .description = "Swapin delay %", .flags = 0, .defaultSortDesc = true, },
[M_PSS] = { .name = "M_PSS", .title = " PSS ", .description = "proportional set size, same as M_RESIDENT but each page is divided by the number of processes sharing it.", .flags = PROCESS_FLAG_LINUX_SMAPS, .defaultSortDesc = true, },
[M_SWAP] = { .name = "M_SWAP", .title = " SWAP ", .description = "Size of the process's swapped pages", .flags = PROCESS_FLAG_LINUX_SMAPS, .defaultSortDesc = true, },
[M_PSSWP] = { .name = "M_PSSWP", .title = " PSSWP ", .description = "shows proportional swap share of this mapping, Unlike \"Swap\", this does not take into account swapped out page of underlying shmem objects.", .flags = PROCESS_FLAG_LINUX_SMAPS, .defaultSortDesc = true, },
[CTXT] = { .name = "CTXT", .title = " CTXT ", .description = "Context switches (incremental sum of voluntary_ctxt_switches and nonvoluntary_ctxt_switches)", .flags = PROCESS_FLAG_LINUX_CTXT, .defaultSortDesc = true, },
[SECATTR] = { .name = "SECATTR", .title = " Security Attribute ", .description = "Security attribute of the process (e.g. SELinux or AppArmor)", .flags = PROCESS_FLAG_LINUX_SECATTR, },
[PROC_COMM] = { .name = "COMM", .title = "COMM ", .description = "comm string of the process from /proc/[pid]/comm", .flags = 0, },
};
/* This function returns the string displayed in Command column, so that sorting
* happens on what is displayed - whether comm, full path, basename, etc.. So
* this follows PCPProcess_writeField(COMM) and PCPProcess_writeCommand */
static const char* PCPProcess_getCommandStr(const Process *this) {
const PCPProcess *pp = (const PCPProcess *)this;
if ((Process_isUserlandThread(this) && this->settings->showThreadNames) || !pp->mergedCommand.str) {
return this->comm;
}
return pp->mergedCommand.str;
}
Process* PCPProcess_new(const Settings* settings) {
PCPProcess* this = xCalloc(1, sizeof(PCPProcess));
Object_setClass(this, Class(PCPProcess));
Process_init(&this->super, settings);
return &this->super;
}
void Process_delete(Object* cast) {
PCPProcess* this = (PCPProcess*) cast;
Process_done((Process*)cast);
free(this->cgroup);
free(this->secattr);
free(this->ttyDevice);
free(this->procComm);
free(this->mergedCommand.str);
free(this);
}
static void PCPProcess_printDelay(float delay_percent, char* buffer, int n) {
if (isnan(delay_percent)) {
xSnprintf(buffer, n, " N/A ");
} else {
xSnprintf(buffer, n, "%4.1f ", delay_percent);
}
}
/*
TASK_COMM_LEN is defined to be 16 for /proc/[pid]/comm in man proc(5), but is
not available in an userspace header - so define it. Note: when colorizing a
basename with the comm prefix, the entire basename (not just the comm prefix)
is colorized for better readability, and it is implicit that only up to
(TASK_COMM_LEN - 1) could be comm.
*/
#define TASK_COMM_LEN 16
/*
This function makes the merged Command string. It also stores the offsets of
the basename, comm w.r.t the merged Command string - these offsets will be used
by PCPProcess_writeCommand() for coloring. The merged Command string is also
returned by PCPProcess_getCommandStr() for searching, sorting and filtering.
*/
void PCPProcess_makeCommandStr(Process* this) {
PCPProcess *pp = (PCPProcess *)this;
PCPProcessMergedCommand *mc = &pp->mergedCommand;
bool showMergedCommand = this->settings->showMergedCommand;
bool showProgramPath = this->settings->showProgramPath;
bool searchCommInCmdline = this->settings->findCommInCmdline;
/* pp->mergedCommand.str needs updating only if its state or contents
* changed. Its content is based on the fields cmdline and comm. */
if (
mc->prevMergeSet == showMergedCommand &&
mc->prevPathSet == showProgramPath &&
mc->prevCommSet == searchCommInCmdline &&
!mc->cmdlineChanged &&
!mc->commChanged
) {
return;
}
/* The field separtor "│" has been chosen such that it will not match any
* valid string used for searching or filtering */
const char *SEPARATOR = CRT_treeStr[TREE_STR_VERT];
const int SEPARATOR_LEN = strlen(SEPARATOR);
/* Check for any changed fields since we last built this string */
if (mc->cmdlineChanged || mc->commChanged) {
free(mc->str);
/* Accommodate the column text, two field separators and terminating NUL */
mc->str = xCalloc(1, mc->maxLen + 2*SEPARATOR_LEN + 1);
}
/* Preserve the settings used in this run */
mc->prevMergeSet = showMergedCommand;
mc->prevPathSet = showProgramPath;
mc->prevCommSet = searchCommInCmdline;
/* Mark everything as unchanged */
mc->cmdlineChanged = false;
mc->commChanged = false;
/* Clear any separators */
mc->sep1 = 0;
mc->sep2 = 0;
/* Clear any highlighting locations */
mc->baseStart = 0;
mc->baseEnd = 0;
mc->commStart = 0;
mc->commEnd = 0;
const char *cmdline = this->comm;
const char *procComm = pp->procComm;
char *strStart = mc->str;
char *str = strStart;
int cmdlineBasenameOffset = pp->procCmdlineBasenameOffset;
int cmdlineBasenameEnd = pp->procCmdlineBasenameEnd;
if (!cmdline) {
cmdlineBasenameOffset = 0;
cmdlineBasenameEnd = 0;
cmdline = "(zombie)";
}
assert(cmdlineBasenameOffset >= 0);
assert(cmdlineBasenameOffset <= (int)strlen(cmdline));
if (showMergedCommand && procComm && strlen(procComm)) { /* Prefix column with comm */
if (strncmp(cmdline + cmdlineBasenameOffset, procComm, MINIMUM(TASK_COMM_LEN - 1, strlen(procComm))) != 0) {
mc->commStart = 0;
mc->commEnd = strlen(procComm);
str = stpcpy(str, procComm);
mc->sep1 = str - strStart;
str = stpcpy(str, SEPARATOR);
}
}
if (showProgramPath) {
(void) stpcpy(str, cmdline);
mc->baseStart = cmdlineBasenameOffset;
mc->baseEnd = cmdlineBasenameEnd;
} else {
(void) stpcpy(str, cmdline + cmdlineBasenameOffset);
mc->baseStart = 0;
mc->baseEnd = cmdlineBasenameEnd - cmdlineBasenameOffset;
}
if (mc->sep1) {
mc->baseStart += str - strStart - SEPARATOR_LEN + 1;
mc->baseEnd += str - strStart - SEPARATOR_LEN + 1;
}
}
static void PCPProcess_writeCommand(const Process* this, int attr, int baseAttr, RichString* str) {
const PCPProcess *pp = (const PCPProcess *)this;
const PCPProcessMergedCommand *mc = &pp->mergedCommand;
int strStart = RichString_size(str);
int baseStart = strStart + pp->mergedCommand.baseStart;
int baseEnd = strStart + pp->mergedCommand.baseEnd;
int commStart = strStart + pp->mergedCommand.commStart;
int commEnd = strStart + pp->mergedCommand.commEnd;
int commAttr = CRT_colors[Process_isUserlandThread(this) ? PROCESS_THREAD_COMM : PROCESS_COMM];
bool highlightBaseName = this->settings->highlightBaseName;
RichString_appendWide(str, attr, pp->mergedCommand.str);
if (pp->mergedCommand.commEnd) {
if (!pp->mergedCommand.separateComm && commStart == baseStart && highlightBaseName) {
/* If it was matched with binaries basename, make it bold if needed */
if (commEnd > baseEnd) {
RichString_setAttrn(str, A_BOLD | baseAttr, baseStart, baseEnd - baseStart);
RichString_setAttrn(str, A_BOLD | commAttr, baseEnd, commEnd - baseEnd);
} else if (commEnd < baseEnd) {
RichString_setAttrn(str, A_BOLD | commAttr, commStart, commEnd - commStart);
RichString_setAttrn(str, A_BOLD | baseAttr, commEnd, baseEnd - commEnd);
} else {
// Actually should be highlighted commAttr, but marked baseAttr to reduce visual noise
RichString_setAttrn(str, A_BOLD | baseAttr, commStart, commEnd - commStart);
}
baseStart = baseEnd;
} else {
RichString_setAttrn(str, commAttr, commStart, commEnd - commStart);
}
}
if (baseStart < baseEnd && highlightBaseName) {
RichString_setAttrn(str, baseAttr, baseStart, baseEnd - baseStart);
}
if (mc->sep1)
RichString_setAttrn(str, CRT_colors[FAILED_READ], strStart + mc->sep1, 1);
if (mc->sep2)
RichString_setAttrn(str, CRT_colors[FAILED_READ], strStart + mc->sep2, 1);
}
static void PCPProcess_writeCommandField(const Process *this, RichString *str, char *buffer, int n, int attr) {
/* This code is from Process_writeField for COMM, but we invoke
* PCPProcess_writeCommand to display the full binary path
* (or its basename)/proc/pid/comm/proc/pid/cmdline */
int baseattr = CRT_colors[PROCESS_BASENAME];
if (this->settings->highlightThreads && Process_isThread(this)) {
attr = CRT_colors[PROCESS_THREAD];
baseattr = CRT_colors[PROCESS_THREAD_BASENAME];
}
if (!this->settings->treeView || this->indent == 0) {
PCPProcess_writeCommand(this, attr, baseattr, str);
} else {
char* buf = buffer;
int maxIndent = 0;
bool lastItem = (this->indent < 0);
int indent = (this->indent < 0 ? -this->indent : this->indent);
int vertLen = strlen(CRT_treeStr[TREE_STR_VERT]);
for (int i = 0; i < 32; i++) {
if (indent & (1U << i)) {
maxIndent = i+1;
}
}
for (int i = 0; i < maxIndent - 1; i++) {
if (indent & (1 << i)) {
if (buf - buffer + (vertLen + 3) > n) {
break;
}
buf = stpcpy(buf, CRT_treeStr[TREE_STR_VERT]);
buf = stpcpy(buf, " ");
} else {
if (buf - buffer + 4 > n) {
break;
}
buf = stpcpy(buf, " ");
}
}
n -= (buf - buffer);
const char* draw = CRT_treeStr[lastItem ? TREE_STR_BEND : TREE_STR_RTEE];
xSnprintf(buf, n, "%s%s ", draw, this->showChildren ? CRT_treeStr[TREE_STR_SHUT] : CRT_treeStr[TREE_STR_OPEN] );
RichString_appendWide(str, CRT_colors[PROCESS_TREE], buffer);
PCPProcess_writeCommand(this, attr, baseattr, str);
}
}
static void PCPProcess_writeField(const Process* this, RichString* str, ProcessField field) {
const PCPProcess* pp = (const PCPProcess*) this;
bool coloring = this->settings->highlightMegabytes;
char buffer[256]; buffer[255] = '\0';
int attr = CRT_colors[DEFAULT_COLOR];
int n = sizeof(buffer) - 1;
switch ((int)field) {
case TTY_NR:
if (pp->ttyDevice) {
xSnprintf(buffer, n, "%-8s", pp->ttyDevice + 5 /* skip "/dev/" */);
break;
}
Process_writeField(this, str, field);
break;
case CMINFLT: Process_colorNumber(str, pp->cminflt, coloring); return;
case CMAJFLT: Process_colorNumber(str, pp->cmajflt, coloring); return;
case M_DRS: Process_humanNumber(str, pp->m_drs, coloring); return;
case M_DT: Process_humanNumber(str, pp->m_dt, coloring); return;
case M_LRS: Process_humanNumber(str, pp->m_lrs, coloring); return;
case M_TRS: Process_humanNumber(str, pp->m_trs, coloring); return;
case M_SHARE: Process_humanNumber(str, pp->m_share, coloring); return;
case M_PSS: Process_humanNumber(str, pp->m_pss, coloring); return;
case M_SWAP: Process_humanNumber(str, pp->m_swap, coloring); return;
case M_PSSWP: Process_humanNumber(str, pp->m_psswp, coloring); return;
case UTIME: Process_printTime(str, pp->utime); return;
case STIME: Process_printTime(str, pp->stime); return;
case CUTIME: Process_printTime(str, pp->cutime); return;
case CSTIME: Process_printTime(str, pp->cstime); return;
case RCHAR: Process_humanNumber(str, pp->io_rchar, coloring); return;
case WCHAR: Process_humanNumber(str, pp->io_wchar, coloring); return;
case SYSCR: Process_colorNumber(str, pp->io_syscr, coloring); return;
case SYSCW: Process_colorNumber(str, pp->io_syscw, coloring); return;
case RBYTES: Process_humanNumber(str, pp->io_read_bytes, coloring); return;
case WBYTES: Process_humanNumber(str, pp->io_write_bytes, coloring); return;
case CNCLWB: Process_humanNumber(str, pp->io_cancelled_write_bytes, coloring); return;
case IO_READ_RATE: Process_outputRate(str, buffer, n, pp->io_rate_read_bps, coloring); return;
case IO_WRITE_RATE: Process_outputRate(str, buffer, n, pp->io_rate_write_bps, coloring); return;
case IO_RATE: {
double totalRate = NAN;
if (!isnan(pp->io_rate_read_bps) && !isnan(pp->io_rate_write_bps))
totalRate = pp->io_rate_read_bps + pp->io_rate_write_bps;
else if (!isnan(pp->io_rate_read_bps))
totalRate = pp->io_rate_read_bps;
else if (!isnan(pp->io_rate_write_bps))
totalRate = pp->io_rate_write_bps;
else
totalRate = NAN;
Process_outputRate(str, buffer, n, totalRate, coloring); return;
}
case CGROUP: xSnprintf(buffer, n, "%-10s ", pp->cgroup ? pp->cgroup : ""); break;
case OOM: xSnprintf(buffer, n, "%4u ", pp->oom); break;
case PERCENT_CPU_DELAY:
PCPProcess_printDelay(pp->cpu_delay_percent, buffer, n);
break;
case PERCENT_IO_DELAY:
PCPProcess_printDelay(pp->blkio_delay_percent, buffer, n);
break;
case PERCENT_SWAP_DELAY:
PCPProcess_printDelay(pp->swapin_delay_percent, buffer, n);
break;
case CTXT:
if (pp->ctxt_diff > 1000) {
attr |= A_BOLD;
}
xSnprintf(buffer, n, "%5lu ", pp->ctxt_diff);
break;
case SECATTR: snprintf(buffer, n, "%-30s ", pp->secattr ? pp->secattr : "?"); break;
case COMM: {
if ((Process_isUserlandThread(this) && this->settings->showThreadNames) || !pp->mergedCommand.str) {
Process_writeField(this, str, field);
} else {
PCPProcess_writeCommandField(this, str, buffer, n, attr);
}
return;
}
case PROC_COMM: {
const char* procComm;
if (pp->procComm) {
attr = CRT_colors[Process_isUserlandThread(this) ? PROCESS_THREAD_COMM : PROCESS_COMM];
procComm = pp->procComm;
} else {
attr = CRT_colors[PROCESS_SHADOW];
procComm = Process_isKernelThread(this) ? kthreadID : "N/A";
}
/* 15 being (TASK_COMM_LEN - 1) */
Process_printLeftAlignedField(str, attr, procComm, 15);
return;
}
default:
Process_writeField(this, str, field);
return;
}
RichString_appendWide(str, attr, buffer);
}
static double adjustNaN(double num) {
if (isnan(num))
return -0.0005;
return num;
}
static int PCPProcess_compareByKey(const Process* v1, const Process* v2, ProcessField key) {
const PCPProcess* p1 = (const PCPProcess*)v1;
const PCPProcess* p2 = (const PCPProcess*)v2;
switch (key) {
case M_DRS:
return SPACESHIP_NUMBER(p1->m_drs, p2->m_drs);
case M_DT:
return SPACESHIP_NUMBER(p1->m_dt, p2->m_dt);
case M_LRS:
return SPACESHIP_NUMBER(p1->m_lrs, p2->m_lrs);
case M_TRS:
return SPACESHIP_NUMBER(p1->m_trs, p2->m_trs);
case M_SHARE:
return SPACESHIP_NUMBER(p1->m_share, p2->m_share);
case M_PSS:
return SPACESHIP_NUMBER(p1->m_pss, p2->m_pss);
case M_SWAP:
return SPACESHIP_NUMBER(p1->m_swap, p2->m_swap);
case M_PSSWP:
return SPACESHIP_NUMBER(p1->m_psswp, p2->m_psswp);
case UTIME:
return SPACESHIP_NUMBER(p1->utime, p2->utime);
case CUTIME:
return SPACESHIP_NUMBER(p1->cutime, p2->cutime);
case STIME:
return SPACESHIP_NUMBER(p1->stime, p2->stime);
case CSTIME:
return SPACESHIP_NUMBER(p1->cstime, p2->cstime);
case RCHAR:
return SPACESHIP_NUMBER(p1->io_rchar, p2->io_rchar);
case WCHAR:
return SPACESHIP_NUMBER(p1->io_wchar, p2->io_wchar);
case SYSCR:
return SPACESHIP_NUMBER(p1->io_syscr, p2->io_syscr);
case SYSCW:
return SPACESHIP_NUMBER(p1->io_syscw, p2->io_syscw);
case RBYTES:
return SPACESHIP_NUMBER(p1->io_read_bytes, p2->io_read_bytes);
case WBYTES:
return SPACESHIP_NUMBER(p1->io_write_bytes, p2->io_write_bytes);
case CNCLWB:
return SPACESHIP_NUMBER(p1->io_cancelled_write_bytes, p2->io_cancelled_write_bytes);
case IO_READ_RATE:
return SPACESHIP_NUMBER(adjustNaN(p1->io_rate_read_bps), adjustNaN(p2->io_rate_read_bps));
case IO_WRITE_RATE:
return SPACESHIP_NUMBER(adjustNaN(p1->io_rate_write_bps), adjustNaN(p2->io_rate_write_bps));
case IO_RATE:
return SPACESHIP_NUMBER(adjustNaN(p1->io_rate_read_bps) + adjustNaN(p1->io_rate_write_bps), adjustNaN(p2->io_rate_read_bps) + adjustNaN(p2->io_rate_write_bps));
case CGROUP:
return SPACESHIP_NULLSTR(p1->cgroup, p2->cgroup);
case OOM:
return SPACESHIP_NUMBER(p1->oom, p1->oom);
case PERCENT_CPU_DELAY:
return SPACESHIP_NUMBER(p1->cpu_delay_percent, p1->cpu_delay_percent);
case PERCENT_IO_DELAY:
return SPACESHIP_NUMBER(p1->blkio_delay_percent, p1->blkio_delay_percent);
case PERCENT_SWAP_DELAY:
return SPACESHIP_NUMBER(p1->swapin_delay_percent, p1->swapin_delay_percent);
case CTXT:
return SPACESHIP_NUMBER(p1->ctxt_diff, p1->ctxt_diff);
case SECATTR:
return SPACESHIP_NULLSTR(p1->secattr, p2->secattr);
case PROC_COMM: {
const char *comm1 = p1->procComm ? p1->procComm : (Process_isKernelThread(v1) ? kthreadID : "");
const char *comm2 = p2->procComm ? p2->procComm : (Process_isKernelThread(v2) ? kthreadID : "");
return strcmp(comm1, comm2);
}
default:
return Process_compareByKey_Base(v1, v2, key);
}
}
bool Process_isThread(const Process* this) {
return (Process_isUserlandThread(this) || Process_isKernelThread(this));
}
const ProcessClass PCPProcess_class = {
.super = {
.extends = Class(Process),
.display = Process_display,
.delete = Process_delete,
.compare = Process_compare
},
.writeField = PCPProcess_writeField,
.getCommandStr = PCPProcess_getCommandStr,
.compareByKey = PCPProcess_compareByKey
};

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#ifndef HEADER_PCPProcess
#define HEADER_PCPProcess
/*
htop - PCPProcess.h
(C) 2014 Hisham H. Muhammad
(C) 2020 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "config.h"
#include <stdbool.h>
#include <sys/types.h>
#include "Object.h"
#include "Process.h"
#include "RichString.h"
#include "Settings.h"
#define PROCESS_FLAG_LINUX_CGROUP 0x0800
#define PROCESS_FLAG_LINUX_OOM 0x1000
#define PROCESS_FLAG_LINUX_SMAPS 0x2000
#define PROCESS_FLAG_LINUX_CTXT 0x4000
#define PROCESS_FLAG_LINUX_SECATTR 0x8000
/* PCPProcessMergedCommand is populated by PCPProcess_makeCommandStr: It
* contains the merged Command string, and the information needed by
* PCPProcess_writeCommand to color the string. str will be NULL for kernel
* threads and zombies */
typedef struct PCPProcessMergedCommand_ {
char *str; /* merged Command string */
int maxLen; /* maximum expected length of Command string */
int baseStart; /* basename's start offset */
int baseEnd; /* basename's end offset */
int commStart; /* comm's start offset */
int commEnd; /* comm's end offset */
int sep1; /* first field separator, used if non-zero */
int sep2; /* second field separator, used if non-zero */
bool separateComm; /* whether comm is a separate field */
bool cmdlineChanged; /* whether cmdline changed */
bool commChanged; /* whether comm changed */
bool prevMergeSet; /* whether showMergedCommand was set */
bool prevPathSet; /* whether showProgramPath was set */
bool prevCommSet; /* whether findCommInCmdline was set */
bool prevCmdlineSet; /* whether findCommInCmdline was set */
} PCPProcessMergedCommand;
typedef struct PCPProcess_ {
Process super;
char *procComm;
int procCmdlineBasenameOffset;
int procCmdlineBasenameEnd;
PCPProcessMergedCommand mergedCommand;
bool isKernelThread;
unsigned long int cminflt;
unsigned long int cmajflt;
unsigned long long int utime;
unsigned long long int stime;
unsigned long long int cutime;
unsigned long long int cstime;
long m_share;
long m_pss;
long m_swap;
long m_psswp;
long m_trs;
long m_drs;
long m_lrs;
long m_dt;
/* Data read (in kilobytes) */
unsigned long long io_rchar;
/* Data written (in kilobytes) */
unsigned long long io_wchar;
/* Number of read(2) syscalls */
unsigned long long io_syscr;
/* Number of write(2) syscalls */
unsigned long long io_syscw;
/* Storage data read (in kilobytes) */
unsigned long long io_read_bytes;
/* Storage data written (in kilobytes) */
unsigned long long io_write_bytes;
/* Storage data cancelled (in kilobytes) */
unsigned long long io_cancelled_write_bytes;
/* Point in time of last io scan (in seconds elapsed since the Epoch) */
unsigned long long io_last_scan_time;
double io_rate_read_bps;
double io_rate_write_bps;
char* cgroup;
unsigned int oom;
char* ttyDevice;
unsigned long long int delay_read_time;
unsigned long long cpu_delay_total;
unsigned long long blkio_delay_total;
unsigned long long swapin_delay_total;
float cpu_delay_percent;
float blkio_delay_percent;
float swapin_delay_percent;
unsigned long ctxt_total;
unsigned long ctxt_diff;
char* secattr;
unsigned long long int last_mlrs_calctime;
} PCPProcess;
static inline void Process_setKernelThread(Process* this, bool truth) {
((PCPProcess*)this)->isKernelThread = truth;
}
static inline bool Process_isKernelThread(const Process* this) {
return ((const PCPProcess*)this)->isKernelThread;
}
static inline bool Process_isUserlandThread(const Process* this) {
return this->pid != this->tgid;
}
extern const ProcessFieldData Process_fields[LAST_PROCESSFIELD];
extern const ProcessClass PCPProcess_class;
Process* PCPProcess_new(const Settings* settings);
void Process_delete(Object* cast);
/* This function constructs the string that is displayed by
* PCPProcess_writeCommand and also returned by PCPProcess_getCommandStr */
void PCPProcess_makeCommandStr(Process *this);
bool Process_isThread(const Process* this);
#endif

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/*
htop - PCPProcessList.c
(C) 2014 Hisham H. Muhammad
(C) 2020 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "config.h" // IWYU pragma: keep
#include "PCPProcessList.h"
#include <math.h>
#include "CRT.h"
#include "Macros.h"
#include "Object.h"
#include "PCPProcess.h"
#include "Process.h"
#include "Settings.h"
#include "XUtils.h"
static int PCPProcessList_computeCPUcount(void) {
int cpus;
if ((cpus = Platform_getMaxCPU()) <= 0)
cpus = Metric_instanceCount(PCP_PERCPU_SYSTEM);
return cpus > 1 ? cpus : 1;
}
static void PCPProcessList_updateCPUcount(PCPProcessList* this) {
ProcessList* pl = &(this->super);
int cpus = PCPProcessList_computeCPUcount();
if (cpus == pl->cpuCount)
return;
pl->cpuCount = cpus;
free(this->percpu);
free(this->values);
this->percpu = xCalloc(cpus, sizeof(pmAtomValue *));
for (int i = 0; i < cpus; i++)
this->percpu[i] = xCalloc(CPU_METRIC_COUNT, sizeof(pmAtomValue));
this->values = xCalloc(cpus, sizeof(pmAtomValue));
}
static char* setUser(UsersTable* this, unsigned int uid, int pid, int offset) {
char* name = Hashtable_get(this->users, uid);
if (name)
return name;
pmAtomValue value;
if (Metric_instance(PCP_PROC_ID_USER, pid, offset, &value, PM_TYPE_STRING)) {
Hashtable_put(this->users, uid, value.cp);
name = value.cp;
}
return name;
}
ProcessList* ProcessList_new(UsersTable* usersTable, Hashtable* pidMatchList, uid_t userId) {
PCPProcessList* this = xCalloc(1, sizeof(PCPProcessList));
ProcessList* super = &(this->super);
ProcessList_init(super, Class(PCPProcess), usersTable, pidMatchList, userId);
struct timeval timestamp;
gettimeofday(&timestamp, NULL);
this->timestamp = pmtimevalToReal(&timestamp);
this->cpu = xCalloc(CPU_METRIC_COUNT, sizeof(pmAtomValue));
PCPProcessList_updateCPUcount(this);
return super;
}
void ProcessList_delete(ProcessList* pl) {
PCPProcessList* this = (PCPProcessList*) pl;
ProcessList_done(pl);
free(this->values);
for (int i = 0; i < pl->cpuCount; i++)
free(this->percpu[i]);
free(this->percpu);
free(this->cpu);
free(this);
}
static inline unsigned long long PCPProcessList_adjustTime(unsigned long long t) {
return t / 10;
}
static void PCPProcessList_updateID(Process* process, int pid, int offset) {
pmAtomValue value;
if (Metric_instance(PCP_PROC_TGID, pid, offset, &value, PM_TYPE_U32))
process->tgid = value.ul;
else
process->tgid = 1;
if (Metric_instance(PCP_PROC_PPID, pid, offset, &value, PM_TYPE_U32))
process->ppid = value.ul;
else
process->ppid = 1;
if (Metric_instance(PCP_PROC_STATE, pid, offset, &value, PM_TYPE_STRING)) {
process->state = value.cp[0];
free(value.cp);
} else {
process->state = 'X';
}
}
static void PCPProcessList_updateInfo(Process* process, int pid, int offset, char* command, size_t commLen) {
PCPProcess* pp = (PCPProcess*) process;
pmAtomValue value;
if (!Metric_instance(PCP_PROC_CMD, pid, offset, &value, PM_TYPE_STRING))
value.cp = xStrdup("<unknown>");
String_safeStrncpy(command, value.cp, commLen);
free(value.cp);
if (Metric_instance(PCP_PROC_PGRP, pid, offset, &value, PM_TYPE_U32))
process->pgrp = value.ul;
else
process->pgrp = 0;
if (Metric_instance(PCP_PROC_SESSION, pid, offset, &value, PM_TYPE_U32))
process->session = value.ul;
else
process->session = 0;
if (Metric_instance(PCP_PROC_TTY, pid, offset, &value, PM_TYPE_U32))
process->tty_nr = value.ul;
else
process->tty_nr = 0;
if (Metric_instance(PCP_PROC_TTYPGRP, pid, offset, &value, PM_TYPE_U32))
process->tpgid = value.ul;
else
process->tpgid = 0;
if (Metric_instance(PCP_PROC_MINFLT, pid, offset, &value, PM_TYPE_U32))
process->minflt = value.ul;
else
process->minflt = 0;
if (Metric_instance(PCP_PROC_CMINFLT, pid, offset, &value, PM_TYPE_U32))
pp->cminflt = value.ul;
else
pp->cminflt = 0;
if (Metric_instance(PCP_PROC_MAJFLT, pid, offset, &value, PM_TYPE_U32))
process->majflt = value.ul;
else
process->majflt = 0;
if (Metric_instance(PCP_PROC_CMAJFLT, pid, offset, &value, PM_TYPE_U32))
pp->cmajflt = value.ul;
else
pp->cmajflt = 0;
if (Metric_instance(PCP_PROC_UTIME, pid, offset, &value, PM_TYPE_U64))
pp->utime = PCPProcessList_adjustTime(value.ull);
else
pp->utime = 0;
if (Metric_instance(PCP_PROC_STIME, pid, offset, &value, PM_TYPE_U64))
pp->stime = PCPProcessList_adjustTime(value.ull);
else
pp->stime = 0;
if (Metric_instance(PCP_PROC_CUTIME, pid, offset, &value, PM_TYPE_U64))
pp->cutime = PCPProcessList_adjustTime(value.ull);
else
pp->cutime = 0;
if (Metric_instance(PCP_PROC_CSTIME, pid, offset, &value, PM_TYPE_U64))
pp->cstime = PCPProcessList_adjustTime(value.ull);
else
pp->cstime = 0;
if (Metric_instance(PCP_PROC_PRIORITY, pid, offset, &value, PM_TYPE_U32))
process->priority = value.ul;
else
process->priority = 0;
if (Metric_instance(PCP_PROC_NICE, pid, offset, &value, PM_TYPE_32))
process->nice = value.l;
else
process->nice = 0;
if (Metric_instance(PCP_PROC_THREADS, pid, offset, &value, PM_TYPE_U32))
process->nlwp = value.ul;
else
process->nlwp = 0;
if (Metric_instance(PCP_PROC_STARTTIME, pid, offset, &value, PM_TYPE_U64))
process->starttime_ctime = PCPProcessList_adjustTime(value.ull);
else
process->starttime_ctime = 0;
if (Metric_instance(PCP_PROC_PROCESSOR, pid, offset, &value, PM_TYPE_U32))
process->processor = value.ul;
else
process->processor = 0;
process->time = pp->utime + pp->stime;
}
static void PCPProcessList_updateIO(PCPProcess* process, int pid, int offset, unsigned long long now) {
pmAtomValue value;
if (Metric_instance(PCP_PROC_IO_RCHAR, pid, offset, &value, PM_TYPE_U64))
process->io_rchar = value.ull / ONE_K;
else
process->io_rchar = ULLONG_MAX;
if (Metric_instance(PCP_PROC_IO_WCHAR, pid, offset, &value, PM_TYPE_U64))
process->io_wchar = value.ull / ONE_K;
else
process->io_wchar = ULLONG_MAX;
if (Metric_instance(PCP_PROC_IO_SYSCR, pid, offset, &value, PM_TYPE_U64))
process->io_syscr = value.ull;
else
process->io_syscr = ULLONG_MAX;
if (Metric_instance(PCP_PROC_IO_SYSCW, pid, offset, &value, PM_TYPE_U64))
process->io_syscw = value.ull;
else
process->io_syscw = ULLONG_MAX;
if (Metric_instance(PCP_PROC_IO_CANCELLED, pid, offset, &value, PM_TYPE_U64))
process->io_cancelled_write_bytes = value.ull / ONE_K;
else
process->io_cancelled_write_bytes = ULLONG_MAX;
if (Metric_instance(PCP_PROC_IO_READB, pid, offset, &value, PM_TYPE_U64)) {
unsigned long long last_read = process->io_read_bytes;
process->io_read_bytes = value.ull / ONE_K;
process->io_rate_read_bps =
ONE_K * (process->io_read_bytes - last_read) /
(now - process->io_last_scan_time);
} else {
process->io_read_bytes = ULLONG_MAX;
process->io_rate_read_bps = NAN;
}
if (Metric_instance(PCP_PROC_IO_WRITEB, pid, offset, &value, PM_TYPE_U64)) {
unsigned long long last_write = process->io_write_bytes;
process->io_write_bytes = value.ull;
process->io_rate_write_bps =
ONE_K * (process->io_write_bytes - last_write) /
(now - process->io_last_scan_time);
} else {
process->io_write_bytes = ULLONG_MAX;
process->io_rate_write_bps = NAN;
}
process->io_last_scan_time = now;
}
static void PCPProcessList_updateMemory(PCPProcess* process, int pid, int offset) {
pmAtomValue value;
if (Metric_instance(PCP_PROC_MEM_SIZE, pid, offset, &value, PM_TYPE_U32))
process->super.m_virt = value.ul;
else
process->super.m_virt = 0;
if (Metric_instance(PCP_PROC_MEM_RSS, pid, offset, &value, PM_TYPE_U32))
process->super.m_resident = value.ul;
else
process->super.m_resident = 0;
if (Metric_instance(PCP_PROC_MEM_SHARE, pid, offset, &value, PM_TYPE_U32))
process->m_share = value.ul;
else
process->m_share = 0;
if (Metric_instance(PCP_PROC_MEM_TEXTRS, pid, offset, &value, PM_TYPE_U32))
process->m_trs = value.ul;
else
process->m_trs = 0;
if (Metric_instance(PCP_PROC_MEM_LIBRS, pid, offset, &value, PM_TYPE_U32))
process->m_lrs = value.ul;
else
process->m_lrs = 0;
if (Metric_instance(PCP_PROC_MEM_DATRS, pid, offset, &value, PM_TYPE_U32))
process->m_drs = value.ul;
else
process->m_drs = 0;
if (Metric_instance(PCP_PROC_MEM_DIRTY, pid, offset, &value, PM_TYPE_U32))
process->m_dt = value.ul;
else
process->m_dt = 0;
}
static void PCPProcessList_updateSmaps(PCPProcess* process, pid_t pid, int offset) {
pmAtomValue value;
if (Metric_instance(PCP_PROC_SMAPS_PSS, pid, offset, &value, PM_TYPE_U64))
process->m_pss = value.ull;
else
process->m_pss = 0LL;
if (Metric_instance(PCP_PROC_SMAPS_SWAP, pid, offset, &value, PM_TYPE_U64))
process->m_swap = value.ull;
else
process->m_swap = 0LL;
if (Metric_instance(PCP_PROC_SMAPS_SWAPPSS, pid, offset, &value, PM_TYPE_U64))
process->m_psswp = value.ull;
else
process->m_psswp = 0LL;
}
static void PCPProcessList_readOomData(PCPProcess* process, int pid, int offset) {
pmAtomValue value;
if (Metric_instance(PCP_PROC_OOMSCORE, pid, offset, &value, PM_TYPE_U32))
process->oom = value.ul;
else
process->oom = 0;
}
static void PCPProcessList_readCtxtData(PCPProcess* process, int pid, int offset) {
pmAtomValue value;
unsigned long ctxt = 0;
if (Metric_instance(PCP_PROC_VCTXSW, pid, offset, &value, PM_TYPE_U32))
ctxt += value.ul;
if (Metric_instance(PCP_PROC_NVCTXSW, pid, offset, &value, PM_TYPE_U32))
ctxt += value.ul;
if (ctxt > process->ctxt_total)
process->ctxt_diff = ctxt - process->ctxt_total;
else
process->ctxt_diff = 0;
process->ctxt_total = ctxt;
}
static char* setString(Metric metric, int pid, int offset, char* string) {
if (string)
free(string);
pmAtomValue value;
if (Metric_instance(metric, pid, offset, &value, PM_TYPE_STRING))
string = value.cp;
else
string = NULL;
return string;
}
static void PCPProcessList_updateTTY(PCPProcess* process, int pid, int offset) {
process->ttyDevice = setString(PCP_PROC_TTYNAME, pid, offset, process->ttyDevice);
}
static void PCPProcessList_readCGroups(PCPProcess* process, int pid, int offset) {
process->cgroup = setString(PCP_PROC_CGROUPS, pid, offset, process->cgroup);
}
static void PCPProcessList_readSecattrData(PCPProcess* process, int pid, int offset) {
process->secattr = setString(PCP_PROC_LABELS, pid, offset, process->secattr);
}
static void PCPProcessList_updateUsername(Process* process, int pid, int offset, UsersTable* users) {
unsigned int uid = 0;
pmAtomValue value;
if (Metric_instance(PCP_PROC_ID_UID, pid, offset, &value, PM_TYPE_U32))
uid = value.ul;
process->st_uid = uid;
process->user = setUser(users, uid, pid, offset);
}
static void PCPProcessList_updateCmdline(Process* process, int pid, int offset, const char* comm) {
pmAtomValue value;
if (!Metric_instance(PCP_PROC_PSARGS, pid, offset, &value, PM_TYPE_STRING)) {
if (process->state != 'Z')
Process_setKernelThread(process, true);
else
process->basenameOffset = 0;
return;
}
char *command = value.cp;
int length = strlen(command);
if (command[0] != '(') {
Process_setKernelThread(process, false);
} else {
++command;
--length;
if (command[length-1] == ')')
command[length-1] = '\0';
Process_setKernelThread(process, true);
}
int tokenEnd = 0;
int tokenStart = 0;
int lastChar = 0;
for (int i = 0; i < length; i++) {
/* htop considers the next character after the last / that is before
* basenameOffset, as the start of the basename in cmdline - see
* Process_writeCommand */
if (command[i] == '/')
tokenStart = i + 1;
lastChar = i;
}
tokenEnd = length;
PCPProcess *pp = (PCPProcess *)process;
pp->mergedCommand.maxLen = lastChar + 1; /* accommodate cmdline */
if (!process->comm || !String_eq(command, process->comm)) {
process->basenameOffset = tokenEnd;
free_and_xStrdup(&process->comm, command);
pp->procCmdlineBasenameOffset = tokenStart;
pp->procCmdlineBasenameEnd = tokenEnd;
pp->mergedCommand.cmdlineChanged = true;
}
/* comm could change, so should be updated */
if ((length = strlen(comm)) > 0) {
pp->mergedCommand.maxLen += length;
if (!pp->procComm || !String_eq(command, pp->procComm)) {
free_and_xStrdup(&pp->procComm, command);
pp->mergedCommand.commChanged = true;
}
} else if (pp->procComm) {
free(pp->procComm);
pp->procComm = NULL;
pp->mergedCommand.commChanged = true;
}
free(value.cp);
}
static bool PCPProcessList_updateProcesses(PCPProcessList* this, double period, struct timeval* tv) {
ProcessList* pl = (ProcessList*) this;
const Settings* settings = pl->settings;
bool hideKernelThreads = settings->hideKernelThreads;
bool hideUserlandThreads = settings->hideUserlandThreads;
unsigned long long now = tv->tv_sec * 1000LL + tv->tv_usec / 1000LL;
int pid = -1, offset = -1;
/* for every process ... */
while (Metric_iterate(PCP_PROC_PID, &pid, &offset)) {
bool preExisting;
Process* proc = ProcessList_getProcess(pl, pid, &preExisting, PCPProcess_new);
PCPProcess* pp = (PCPProcess*) proc;
PCPProcessList_updateID(proc, pid, offset);
/*
* These conditions will not trigger on first occurrence, cause we need to
* add the process to the ProcessList and do all one time scans
* (e.g. parsing the cmdline to detect a kernel thread)
* But it will short-circuit subsequent scans.
*/
if (preExisting && hideKernelThreads && Process_isKernelThread(proc)) {
proc->updated = true;
proc->show = false;
if (proc->state == 'R')
pl->runningTasks++;
pl->kernelThreads++;
pl->totalTasks++;
continue;
}
if (preExisting && hideUserlandThreads && Process_isUserlandThread(proc)) {
proc->updated = true;
proc->show = false;
if (proc->state == 'R')
pl->runningTasks++;
pl->userlandThreads++;
pl->totalTasks++;
continue;
}
if (settings->flags & PROCESS_FLAG_IO)
PCPProcessList_updateIO(pp, pid, offset, now);
PCPProcessList_updateMemory(pp, pid, offset);
if ((settings->flags & PROCESS_FLAG_LINUX_SMAPS) &&
(Process_isKernelThread(proc) == false)) {
if (Metric_enabled(PCP_PROC_SMAPS_PSS))
PCPProcessList_updateSmaps(pp, pid, offset);
}
char command[MAX_NAME + 1];
unsigned int tty_nr = proc->tty_nr;
unsigned long long int lasttimes = pp->utime + pp->stime;
PCPProcessList_updateInfo(proc, pid, offset, command, sizeof(command));
proc->starttime_ctime += Platform_getBootTime();
if (tty_nr != proc->tty_nr)
PCPProcessList_updateTTY(pp, pid, offset);
float percent_cpu = (pp->utime + pp->stime - lasttimes) / period * 100.0;
proc->percent_cpu = isnan(percent_cpu) ?
0.0 : CLAMP(percent_cpu, 0.0, pl->cpuCount * 100.0);
proc->percent_mem = proc->m_resident / (double)pl->totalMem * 100.0;
if (!preExisting) {
PCPProcessList_updateUsername(proc, pid, offset, pl->usersTable);
PCPProcessList_updateCmdline(proc, pid, offset, command);
Process_fillStarttimeBuffer(proc);
ProcessList_add(pl, proc);
} else if (settings->updateProcessNames && proc->state != 'Z') {
PCPProcessList_updateCmdline(proc, pid, offset, command);
}
/* (Re)Generate the Command string, but only if the process is:
* - not a kernel thread, and
* - not a zombie or it became zombie under htop's watch, and
* - not a user thread or if showThreadNames is not set */
if (!Process_isKernelThread(proc) &&
(proc->state != 'Z' || pp->mergedCommand.str) &&
(!Process_isUserlandThread(proc) || !settings->showThreadNames)) {
PCPProcess_makeCommandStr(proc);
}
if (settings->flags & PROCESS_FLAG_LINUX_CGROUP)
PCPProcessList_readCGroups(pp, pid, offset);
if (settings->flags & PROCESS_FLAG_LINUX_OOM)
PCPProcessList_readOomData(pp, pid, offset);
if (settings->flags & PROCESS_FLAG_LINUX_CTXT)
PCPProcessList_readCtxtData(pp, pid, offset);
if (settings->flags & PROCESS_FLAG_LINUX_SECATTR)
PCPProcessList_readSecattrData(pp, pid, offset);
if (proc->state == 'Z' && proc->basenameOffset == 0) {
proc->basenameOffset = -1;
free_and_xStrdup(&proc->comm, command);
pp->procCmdlineBasenameOffset = 0;
pp->procCmdlineBasenameEnd = 0;
pp->mergedCommand.commChanged = true;
} else if (Process_isThread(proc)) {
if (settings->showThreadNames || Process_isKernelThread(proc)) {
proc->basenameOffset = -1;
free_and_xStrdup(&proc->comm, command);
pp->procCmdlineBasenameOffset = 0;
pp->procCmdlineBasenameEnd = 0;
pp->mergedCommand.commChanged = true;
}
if (Process_isKernelThread(proc)) {
pl->kernelThreads++;
} else {
pl->userlandThreads++;
}
}
/* Set at the end when we know if a new entry is a thread */
proc->show = ! ((hideKernelThreads && Process_isKernelThread(proc)) ||
(hideUserlandThreads && Process_isUserlandThread(proc)));
//fprintf(stderr, "Updated PID %d [%s] show=%d user=%d[%d] kern=%d[%d]\n", pid, command, proc->show, Process_isUserlandThread(proc), hideUserlandThreads, Process_isKernelThread(proc), hideKernelThreads);
pl->totalTasks++;
if (proc->state == 'R')
pl->runningTasks++;
proc->updated = true;
}
//fprintf(stderr, "Total tasks %d, running=%d\n", pl->totalTasks, pl->runningTasks);
return true;
}
static void PCPProcessList_updateMemoryInfo(ProcessList* super) {
unsigned long long int freeMem = 0;
unsigned long long int swapFreeMem = 0;
unsigned long long int sreclaimableMem = 0;
super->totalMem = super->usedMem = super->cachedMem = 0;
super->usedSwap = super->totalSwap = 0;
pmAtomValue value;
if (Metric_values(PCP_MEM_TOTAL, &value, 1, PM_TYPE_U64) != NULL)
super->totalMem = value.ull;
if (Metric_values(PCP_MEM_FREE, &value, 1, PM_TYPE_U64) != NULL)
freeMem = value.ull;
if (Metric_values(PCP_MEM_BUFFERS, &value, 1, PM_TYPE_U64) != NULL)
super->buffersMem = value.ull;
if (Metric_values(PCP_MEM_SRECLAIM, &value, 1, PM_TYPE_U64) != NULL)
sreclaimableMem = value.ull;
if (Metric_values(PCP_MEM_CACHED, &value, 1, PM_TYPE_U64) != NULL) {
super->cachedMem = value.ull;
super->cachedMem += sreclaimableMem;
}
unsigned long long int usedDiff;
usedDiff = freeMem + super->cachedMem + super->buffersMem;
super->usedMem = (super->totalMem >= usedDiff) ?
super->totalMem - usedDiff : super->totalMem - freeMem;
if (Metric_values(PCP_MEM_AVAILABLE, &value, 1, PM_TYPE_U64) != NULL)
super->availableMem = MINIMUM(value.ull, super->totalMem);
else
super->availableMem = freeMem;
if (Metric_values(PCP_MEM_SWAPFREE, &value, 1, PM_TYPE_U64) != NULL)
swapFreeMem = value.ull;
if (Metric_values(PCP_MEM_SWAPTOTAL, &value, 1, PM_TYPE_U64) != NULL)
super->totalSwap = value.ull;
if (Metric_values(PCP_MEM_SWAPCACHED, &value, 1, PM_TYPE_U64) != NULL)
super->cachedSwap = value.ull;
super->usedSwap = super->totalSwap - swapFreeMem - super->cachedSwap;
}
/* make copies of previously sampled values to avoid overwrite */
static inline void PCPProcessList_backupCPUTime(pmAtomValue* values) {
/* the PERIOD fields (must) mirror the TIME fields */
for (int metric = CPU_TOTAL_TIME; metric < CPU_TOTAL_PERIOD; metric++) {
values[metric + CPU_TOTAL_PERIOD] = values[metric];
}
}
static inline void PCPProcessList_saveCPUTimePeriod(pmAtomValue* values, CPUMetric previous, pmAtomValue* latest) {
pmAtomValue *value;
/* new value for period */
value = &values[previous];
if (latest->ull > value->ull)
value->ull = latest->ull - value->ull;
else
value->ull = 0;
/* new value for time */
value = &values[previous - CPU_TOTAL_PERIOD];
value->ull = latest->ull;
}
/* using copied sampled values and new values, calculate derivations */
static void PCPProcessList_deriveCPUTime(pmAtomValue* values) {
pmAtomValue* usertime = &values[CPU_USER_TIME];
pmAtomValue* guesttime = &values[CPU_GUEST_TIME];
usertime->ull -= guesttime->ull;
pmAtomValue* nicetime = &values[CPU_NICE_TIME];
pmAtomValue* guestnicetime = &values[CPU_GUESTNICE_TIME];
nicetime->ull -= guestnicetime->ull;
pmAtomValue* idletime = &values[CPU_IDLE_TIME];
pmAtomValue* iowaittime = &values[CPU_IOWAIT_TIME];
pmAtomValue* idlealltime = &values[CPU_IDLE_ALL_TIME];
idlealltime->ull = idletime->ull + iowaittime->ull;
pmAtomValue* systemtime = &values[CPU_SYSTEM_TIME];
pmAtomValue* irqtime = &values[CPU_IRQ_TIME];
pmAtomValue* softirqtime = &values[CPU_SOFTIRQ_TIME];
pmAtomValue* systalltime = &values[CPU_SYSTEM_ALL_TIME];
systalltime->ull = systemtime->ull + irqtime->ull + softirqtime->ull;
pmAtomValue* virtalltime = &values[CPU_GUEST_TIME];
virtalltime->ull = guesttime->ull + guestnicetime->ull;
pmAtomValue* stealtime = &values[CPU_STEAL_TIME];
pmAtomValue* totaltime = &values[CPU_TOTAL_TIME];
totaltime->ull = usertime->ull + nicetime->ull + systalltime->ull +
idlealltime->ull + stealtime->ull + virtalltime->ull;
PCPProcessList_saveCPUTimePeriod(values, CPU_USER_PERIOD, usertime);
PCPProcessList_saveCPUTimePeriod(values, CPU_NICE_PERIOD, nicetime);
PCPProcessList_saveCPUTimePeriod(values, CPU_SYSTEM_PERIOD, systemtime);
PCPProcessList_saveCPUTimePeriod(values, CPU_SYSTEM_ALL_PERIOD, systalltime);
PCPProcessList_saveCPUTimePeriod(values, CPU_IDLE_ALL_PERIOD, idlealltime);
PCPProcessList_saveCPUTimePeriod(values, CPU_IDLE_PERIOD, idletime);
PCPProcessList_saveCPUTimePeriod(values, CPU_IOWAIT_PERIOD, iowaittime);
PCPProcessList_saveCPUTimePeriod(values, CPU_IRQ_PERIOD, irqtime);
PCPProcessList_saveCPUTimePeriod(values, CPU_SOFTIRQ_PERIOD, softirqtime);
PCPProcessList_saveCPUTimePeriod(values, CPU_STEAL_PERIOD, stealtime);
PCPProcessList_saveCPUTimePeriod(values, CPU_GUEST_PERIOD, virtalltime);
PCPProcessList_saveCPUTimePeriod(values, CPU_TOTAL_PERIOD, totaltime);
}
static void PCPProcessList_updateAllCPUTime(PCPProcessList* this, Metric metric, CPUMetric cpumetric)
{
pmAtomValue* value = &this->cpu[cpumetric];
if (Metric_values(metric, value, 1, PM_TYPE_U64) == NULL)
memset(&value, 0, sizeof(pmAtomValue));
}
static void PCPProcessList_updatePerCPUTime(PCPProcessList* this, Metric metric, CPUMetric cpumetric)
{
int cpus = this->super.cpuCount;
if (Metric_values(metric, this->values, cpus, PM_TYPE_U64) == NULL)
memset(this->values, 0, cpus * sizeof(pmAtomValue));
for (int i = 0; i < cpus; i++)
this->percpu[i][cpumetric].ull = this->values[i].ull;
}
static void PCPProcessList_updatePerCPUReal(PCPProcessList* this, Metric metric, CPUMetric cpumetric)
{
int cpus = this->super.cpuCount;
if (Metric_values(metric, this->values, cpus, PM_TYPE_DOUBLE) == NULL)
memset(this->values, 0, cpus * sizeof(pmAtomValue));
for (int i = 0; i < cpus; i++)
this->percpu[i][cpumetric].d = this->values[i].d;
}
static void PCPProcessList_updateHeader(ProcessList* super, const Settings* settings) {
PCPProcessList_updateMemoryInfo(super);
PCPProcessList* this = (PCPProcessList*) super;
PCPProcessList_updateCPUcount(this);
PCPProcessList_backupCPUTime(this->cpu);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_USER, CPU_USER_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_NICE, CPU_NICE_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_SYSTEM, CPU_SYSTEM_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_IDLE, CPU_IDLE_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_IOWAIT, CPU_IOWAIT_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_IRQ, CPU_IRQ_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_SOFTIRQ, CPU_SOFTIRQ_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_STEAL, CPU_STEAL_TIME);
PCPProcessList_updateAllCPUTime(this, PCP_CPU_GUEST, CPU_GUEST_TIME);
PCPProcessList_deriveCPUTime(this->cpu);
for (int i = 0; i < super->cpuCount; i++)
PCPProcessList_backupCPUTime(this->percpu[i]);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_USER, CPU_USER_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_NICE, CPU_NICE_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_SYSTEM, CPU_SYSTEM_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_IDLE, CPU_IDLE_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_IOWAIT, CPU_IOWAIT_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_IRQ, CPU_IRQ_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_SOFTIRQ, CPU_SOFTIRQ_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_STEAL, CPU_STEAL_TIME);
PCPProcessList_updatePerCPUTime(this, PCP_PERCPU_GUEST, CPU_GUEST_TIME);
for (int i = 0; i < super->cpuCount; i++)
PCPProcessList_deriveCPUTime(this->percpu[i]);
if (settings->showCPUFrequency)
PCPProcessList_updatePerCPUReal(this, PCP_HINV_CPUCLOCK, CPU_FREQUENCY);
}
void ProcessList_goThroughEntries(ProcessList* super, bool pauseProcessUpdate) {
PCPProcessList* this = (PCPProcessList*) super;
const Settings* settings = super->settings;
bool enabled = !pauseProcessUpdate;
bool flagged = settings->showCPUFrequency;
Metric_enable(PCP_HINV_CPUCLOCK, flagged);
/* In pause mode do not sample per-process metric values at all */
for (int metric = PCP_PROC_PID; metric < PCP_METRIC_COUNT; metric++)
Metric_enable(metric, enabled);
flagged = settings->flags & PROCESS_FLAG_LINUX_CGROUP;
Metric_enable(PCP_PROC_CGROUPS, flagged && enabled);
flagged = settings->flags & PROCESS_FLAG_LINUX_OOM;
Metric_enable(PCP_PROC_OOMSCORE, flagged && enabled);
flagged = settings->flags & PROCESS_FLAG_LINUX_CTXT;
Metric_enable(PCP_PROC_VCTXSW, flagged && enabled);
Metric_enable(PCP_PROC_NVCTXSW, flagged && enabled);
flagged = settings->flags & PROCESS_FLAG_LINUX_SECATTR;
Metric_enable(PCP_PROC_LABELS, flagged && enabled);
/* Sample smaps metrics on every second pass to improve performance */
static int smaps_flag;
smaps_flag = !!smaps_flag;
Metric_enable(PCP_PROC_SMAPS_PSS, smaps_flag && enabled);
Metric_enable(PCP_PROC_SMAPS_SWAP, smaps_flag && enabled);
Metric_enable(PCP_PROC_SMAPS_SWAPPSS, smaps_flag && enabled);
struct timeval timestamp;
Metric_fetch(&timestamp);
double sample = this->timestamp;
this->timestamp = pmtimevalToReal(&timestamp);
PCPProcessList_updateHeader(super, settings);
/* In pause mode only update global data for meters (CPU, memory, etc) */
if (pauseProcessUpdate)
return;
double period = (this->timestamp - sample) * 100;
PCPProcessList_updateProcesses(this, period, &timestamp);
}

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#ifndef HEADER_PCPProcessList
#define HEADER_PCPProcessList
/*
htop - PCPProcessList.h
(C) 2014 Hisham H. Muhammad
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "config.h"
#include <stdbool.h>
#include <sys/types.h>
#include "Hashtable.h"
#include "ProcessList.h"
#include "pcp/Platform.h"
#include "UsersTable.h"
typedef enum CPUMetric_ {
CPU_TOTAL_TIME,
CPU_USER_TIME,
CPU_SYSTEM_TIME,
CPU_SYSTEM_ALL_TIME,
CPU_IDLE_ALL_TIME,
CPU_IDLE_TIME,
CPU_NICE_TIME,
CPU_IOWAIT_TIME,
CPU_IRQ_TIME,
CPU_SOFTIRQ_TIME,
CPU_STEAL_TIME,
CPU_GUEST_TIME,
CPU_GUESTNICE_TIME,
CPU_TOTAL_PERIOD,
CPU_USER_PERIOD,
CPU_SYSTEM_PERIOD,
CPU_SYSTEM_ALL_PERIOD,
CPU_IDLE_ALL_PERIOD,
CPU_IDLE_PERIOD,
CPU_NICE_PERIOD,
CPU_IOWAIT_PERIOD,
CPU_IRQ_PERIOD,
CPU_SOFTIRQ_PERIOD,
CPU_STEAL_PERIOD,
CPU_GUEST_PERIOD,
CPU_GUESTNICE_PERIOD,
CPU_FREQUENCY,
CPU_METRIC_COUNT
} CPUMetric;
typedef struct PCPProcessList_ {
ProcessList super;
double timestamp; /* previous sample timestamp */
pmAtomValue* cpu; /* aggregate values for each metric */
pmAtomValue** percpu; /* per-processor values for each metric */
pmAtomValue* values; /* per-processor buffer for just one metric */
} PCPProcessList;
ProcessList* ProcessList_new(UsersTable* usersTable, Hashtable* pidMatchList, uid_t userId);
void ProcessList_delete(ProcessList* pl);
void ProcessList_goThroughEntries(ProcessList* super, bool pauseProcessUpdate);
#endif

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/*
htop - linux/Platform.c
(C) 2014 Hisham H. Muhammad
(C) 2020 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "config.h"
#include "Platform.h"
#include <math.h>
#include "BatteryMeter.h"
#include "ClockMeter.h"
#include "Compat.h"
#include "CPUMeter.h"
#include "DateMeter.h"
#include "DateTimeMeter.h"
#include "DiskIOMeter.h"
#include "HostnameMeter.h"
#include "LoadAverageMeter.h"
#include "Macros.h"
#include "MainPanel.h"
#include "MemoryMeter.h"
#include "Meter.h"
#include "NetworkIOMeter.h"
#include "Object.h"
#include "Panel.h"
#include "PCPProcess.h"
#include "PCPProcessList.h"
#include "ProcessList.h"
#include "ProvideCurses.h"
#include "Settings.h"
#include "SwapMeter.h"
#include "TasksMeter.h"
#include "UptimeMeter.h"
#include "XUtils.h"
#include "linux/PressureStallMeter.h"
#include "linux/ZramMeter.h"
#include "linux/ZramStats.h"
typedef struct Platform_ {
int context; /* PMAPI(3) context identifier */
unsigned int total; /* total number of all metrics */
const char** names; /* name array indexed by Metric */
pmID* pmids; /* all known metric identifiers */
pmID* fetch; /* enabled identifiers for sampling */
pmDesc* descs; /* metric desc array indexed by Metric */
pmResult* result; /* sample values result indexed by Metric */
long long btime; /* boottime in seconds since the epoch */
int pidmax; /* maximum platform process identifier */
int ncpu; /* maximum processor count configured */
} Platform;
Platform* pcp;
ProcessField Platform_defaultFields[] = { PID, USER, PRIORITY, NICE, M_VIRT, M_RESIDENT, (int)M_SHARE, STATE, PERCENT_CPU, PERCENT_MEM, TIME, COMM, 0 };
int Platform_numberOfFields = LAST_PROCESSFIELD;
const SignalItem Platform_signals[] = {
{ .name = " 0 Cancel", .number = 0 },
};
const unsigned int Platform_numberOfSignals = ARRAYSIZE(Platform_signals);
const MeterClass* const Platform_meterTypes[] = {
&CPUMeter_class,
&ClockMeter_class,
&DateMeter_class,
&DateTimeMeter_class,
&LoadAverageMeter_class,
&LoadMeter_class,
&MemoryMeter_class,
&SwapMeter_class,
&TasksMeter_class,
&UptimeMeter_class,
&BatteryMeter_class,
&HostnameMeter_class,
&AllCPUsMeter_class,
&AllCPUs2Meter_class,
&AllCPUs4Meter_class,
&AllCPUs8Meter_class,
&LeftCPUsMeter_class,
&RightCPUsMeter_class,
&LeftCPUs2Meter_class,
&RightCPUs2Meter_class,
&LeftCPUs4Meter_class,
&RightCPUs4Meter_class,
&LeftCPUs8Meter_class,
&RightCPUs8Meter_class,
&BlankMeter_class,
&PressureStallCPUSomeMeter_class,
&PressureStallIOSomeMeter_class,
&PressureStallIOFullMeter_class,
&PressureStallMemorySomeMeter_class,
&PressureStallMemoryFullMeter_class,
&ZramMeter_class,
&DiskIOMeter_class,
&NetworkIOMeter_class,
NULL
};
static const char *Platform_metricNames[] = {
[PCP_CONTROL_THREADS] = "proc.control.perclient.threads",
[PCP_HINV_NCPU] = "hinv.ncpu",
[PCP_HINV_CPUCLOCK] = "hinv.cpu.clock",
[PCP_UNAME_SYSNAME] = "kernel.uname.sysname",
[PCP_UNAME_RELEASE] = "kernel.uname.release",
[PCP_UNAME_MACHINE] = "kernel.uname.machine",
[PCP_LOAD_AVERAGE] = "kernel.all.load",
[PCP_PID_MAX] = "kernel.all.pid_max",
[PCP_UPTIME] = "kernel.all.uptime",
[PCP_BOOTTIME] = "kernel.all.boottime",
[PCP_CPU_USER] = "kernel.all.cpu.user",
[PCP_CPU_NICE] = "kernel.all.cpu.nice",
[PCP_CPU_SYSTEM] = "kernel.all.cpu.sys",
[PCP_CPU_IDLE] = "kernel.all.cpu.idle",
[PCP_CPU_IOWAIT] = "kernel.all.cpu.wait.total",
[PCP_CPU_IRQ] = "kernel.all.cpu.intr",
[PCP_CPU_SOFTIRQ] = "kernel.all.cpu.irq.soft",
[PCP_CPU_STEAL] = "kernel.all.cpu.steal",
[PCP_CPU_GUEST] = "kernel.all.cpu.guest",
[PCP_CPU_GUESTNICE] = "kernel.all.cpu.guest_nice",
[PCP_PERCPU_USER] = "kernel.percpu.cpu.user",
[PCP_PERCPU_NICE] = "kernel.percpu.cpu.nice",
[PCP_PERCPU_SYSTEM] = "kernel.percpu.cpu.sys",
[PCP_PERCPU_IDLE] = "kernel.percpu.cpu.idle",
[PCP_PERCPU_IOWAIT] = "kernel.percpu.cpu.wait.total",
[PCP_PERCPU_IRQ] = "kernel.percpu.cpu.intr",
[PCP_PERCPU_SOFTIRQ] = "kernel.percpu.cpu.irq.soft",
[PCP_PERCPU_STEAL] = "kernel.percpu.cpu.steal",
[PCP_PERCPU_GUEST] = "kernel.percpu.cpu.guest",
[PCP_PERCPU_GUESTNICE] = "kernel.percpu.cpu.guest_nice",
[PCP_MEM_TOTAL] = "mem.physmem",
[PCP_MEM_FREE] = "mem.util.free",
[PCP_MEM_AVAILABLE] = "mem.util.available",
[PCP_MEM_BUFFERS] = "mem.util.bufmem",
[PCP_MEM_CACHED] = "mem.util.cached",
[PCP_MEM_SRECLAIM] = "mem.util.slabReclaimable",
[PCP_MEM_SWAPCACHED] = "mem.util.swapCached",
[PCP_MEM_SWAPTOTAL] = "mem.util.swapTotal",
[PCP_MEM_SWAPFREE] = "mem.util.swapFree",
[PCP_DISK_READB] = "disk.all.read_bytes",
[PCP_DISK_WRITEB] = "disk.all.write_bytes",
[PCP_DISK_ACTIVE] = "disk.all.avactive",
[PCP_NET_RECVB] = "network.all.in.bytes",
[PCP_NET_SENDB] = "network.all.out.bytes",
[PCP_NET_RECVP] = "network.all.in.packets",
[PCP_NET_SENDP] = "network.all.out.packets",
[PCP_PSI_CPUSOME] = "kernel.all.pressure.cpu.some.avg",
[PCP_PSI_IOSOME] = "kernel.all.pressure.io.some.avg",
[PCP_PSI_IOFULL] = "kernel.all.pressure.io.full.avg",
[PCP_PSI_MEMSOME] = "kernel.all.pressure.memory.some.avg",
[PCP_PSI_MEMFULL] = "kernel.all.pressure.memory.full.avg",
[PCP_ZRAM_CAPACITY] = "zram.capacity",
[PCP_ZRAM_ORIGINAL] = "zram.mm_stat.data_size.original",
[PCP_ZRAM_COMPRESSED] = "zram.mm_stat.data_size.compressed",
[PCP_PROC_PID] = "proc.psinfo.pid",
[PCP_PROC_PPID] = "proc.psinfo.ppid",
[PCP_PROC_TGID] = "proc.psinfo.tgid",
[PCP_PROC_PGRP] = "proc.psinfo.pgrp",
[PCP_PROC_SESSION] = "proc.psinfo.session",
[PCP_PROC_STATE] = "proc.psinfo.sname",
[PCP_PROC_TTY] = "proc.psinfo.tty",
[PCP_PROC_TTYPGRP] = "proc.psinfo.tty_pgrp",
[PCP_PROC_MINFLT] = "proc.psinfo.minflt",
[PCP_PROC_MAJFLT] = "proc.psinfo.maj_flt",
[PCP_PROC_CMINFLT] = "proc.psinfo.cmin_flt",
[PCP_PROC_CMAJFLT] = "proc.psinfo.cmaj_flt",
[PCP_PROC_UTIME] = "proc.psinfo.utime",
[PCP_PROC_STIME] = "proc.psinfo.stime",
[PCP_PROC_CUTIME] = "proc.psinfo.cutime",
[PCP_PROC_CSTIME] = "proc.psinfo.cstime",
[PCP_PROC_PRIORITY] = "proc.psinfo.priority",
[PCP_PROC_NICE] = "proc.psinfo.nice",
[PCP_PROC_THREADS] = "proc.psinfo.threads",
[PCP_PROC_STARTTIME] = "proc.psinfo.start_time",
[PCP_PROC_PROCESSOR] = "proc.psinfo.processor",
[PCP_PROC_CMD] = "proc.psinfo.cmd",
[PCP_PROC_PSARGS] = "proc.psinfo.psargs",
[PCP_PROC_CGROUPS] = "proc.psinfo.cgroups",
[PCP_PROC_OOMSCORE] = "proc.psinfo.oom_score",
[PCP_PROC_VCTXSW] = "proc.psinfo.vctxsw",
[PCP_PROC_NVCTXSW] = "proc.psinfo.nvctxsw",
[PCP_PROC_LABELS] = "proc.psinfo.labels",
[PCP_PROC_ENVIRON] = "proc.psinfo.environ",
[PCP_PROC_TTYNAME] = "proc.psinfo.ttyname",
[PCP_PROC_ID_UID] = "proc.id.uid",
[PCP_PROC_ID_USER] = "proc.id.uid_nm",
[PCP_PROC_IO_RCHAR] = "proc.io.rchar",
[PCP_PROC_IO_WCHAR] = "proc.io.wchar",
[PCP_PROC_IO_SYSCR] = "proc.io.syscr",
[PCP_PROC_IO_SYSCW] = "proc.io.syscw",
[PCP_PROC_IO_READB] = "proc.io.read_bytes",
[PCP_PROC_IO_WRITEB] = "proc.io.write_bytes",
[PCP_PROC_IO_CANCELLED] = "proc.io.cancelled_write_bytes",
[PCP_PROC_MEM_SIZE] = "proc.memory.size",
[PCP_PROC_MEM_RSS] = "proc.memory.rss",
[PCP_PROC_MEM_SHARE] = "proc.memory.share",
[PCP_PROC_MEM_TEXTRS] = "proc.memory.textrss",
[PCP_PROC_MEM_LIBRS] = "proc.memory.librss",
[PCP_PROC_MEM_DATRS] = "proc.memory.datrss",
[PCP_PROC_MEM_DIRTY] = "proc.memory.dirty",
[PCP_PROC_SMAPS_PSS] = "proc.smaps.pss",
[PCP_PROC_SMAPS_SWAP] = "proc.smaps.swap",
[PCP_PROC_SMAPS_SWAPPSS] = "proc.smaps.swappss",
[PCP_METRIC_COUNT] = NULL
};
pmAtomValue* Metric_values(Metric metric, pmAtomValue *atom, int count, int type) {
pmValueSet* vset = pcp->result->vset[metric];
if (!vset || vset->numval <= 0)
return NULL;
/* allocate space for atom if needed */
if (!atom || !count) {
if (!count)
count = vset->numval;
atom = xCalloc(count, sizeof(pmAtomValue));
}
/* extract requested number of values as requested type */
const pmDesc* desc = &pcp->descs[metric];
for (int i = 0; i < vset->numval; i++) {
if (i == count)
break;
const pmValue *value = &vset->vlist[i];
int sts = pmExtractValue(vset->valfmt, value, desc->type, &atom[i], type);
if (sts < 0) {
if (pmDebugOptions.appl0)
fprintf(stderr, "Error: cannot extract metric value: %s\n",
pmErrStr(sts));
memset(&atom[i], 0, sizeof(pmAtomValue));
}
}
return atom;
}
int Metric_instanceCount(Metric metric) {
pmValueSet* vset = pcp->result->vset[metric];
if (vset)
return vset->numval;
return 0;
}
int Metric_instanceOffset(Metric metric, int inst) {
pmValueSet* vset = pcp->result->vset[metric];
if (!vset || vset->numval <= 0)
return 0;
/* search for optimal offset for subsequent inst lookups to begin */
for (int i = 0; i < vset->numval; i++) {
if (inst == vset->vlist[i].inst)
return i;
}
return 0;
}
static pmAtomValue *Metric_extract(Metric metric, int inst, int offset, pmValueSet *vset, pmAtomValue *atom, int type) {
/* extract value (using requested type) of given metric instance */
const pmDesc* desc = &pcp->descs[metric];
const pmValue *value = &vset->vlist[offset];
int sts = pmExtractValue(vset->valfmt, value, desc->type, atom, type);
if (sts < 0) {
if (pmDebugOptions.appl0)
fprintf(stderr, "Error: cannot extract %s instance %d value: %s\n",
pcp->names[metric], inst, pmErrStr(sts));
memset(atom, 0, sizeof(pmAtomValue));
}
return atom;
}
pmAtomValue *Metric_instance(Metric metric, int inst, int offset, pmAtomValue *atom, int type) {
pmValueSet* vset = pcp->result->vset[metric];
if (!vset || vset->numval <= 0)
return NULL;
/* fast-path using heuristic offset based on expected location */
if (offset >= 0 && offset < vset->numval && inst == vset->vlist[offset].inst)
return Metric_extract(metric, inst, offset, vset, atom, type);
/* slow-path using a linear search for the requested instance */
for (int i = 0; i < vset->numval; i++) {
if (inst == vset->vlist[i].inst)
return Metric_extract(metric, inst, i, vset, atom, type);
}
return NULL;
}
/*
* Iterate over a set of instances (incl PM_IN_NULL)
* returning the next instance identifier and offset.
*
* Start it off by passing offset -1 into the routine.
*/
bool Metric_iterate(Metric metric, int* instp, int* offsetp) {
pmValueSet* vset = pcp->result->vset[metric];
if (!vset || vset->numval <= 0)
return false;
int offset = *offsetp;
offset = (offset < 0) ? 0 : offset + 1;
if (offset > vset->numval - 1)
return false;
*offsetp = offset;
*instp = vset->vlist[offset].inst;
return true;
}
/* Switch on/off a metric for value fetching (sampling) */
void Metric_enable(Metric metric, bool enable) {
pcp->fetch[metric] = enable ? pcp->pmids[metric] : PM_ID_NULL;
}
bool Metric_enabled(Metric metric) {
return pcp->fetch[metric] != PM_ID_NULL;
}
void Metric_enableThreads(void) {
pmValueSet* vset = xCalloc(1, sizeof(pmValueSet));
vset->vlist[0].inst = PM_IN_NULL;
vset->vlist[0].value.lval = 1;
vset->valfmt = PM_VAL_INSITU;
vset->numval = 1;
vset->pmid = pcp->pmids[PCP_CONTROL_THREADS];
pmResult* result = xCalloc(1, sizeof(pmResult));
result->vset[0] = vset;
result->numpmid = 1;
int sts = pmStore(result);
if (sts < 0 && pmDebugOptions.appl0)
fprintf(stderr, "Error: cannot enable threads: %s\n", pmErrStr(sts));
pmFreeResult(result);
}
bool Metric_fetch(struct timeval *timestamp) {
int sts = pmFetch(pcp->total, pcp->fetch, &pcp->result);
if (sts < 0) {
if (pmDebugOptions.appl0)
fprintf(stderr, "Error: cannot fetch metric values): %s\n",
pmErrStr(sts));
return false;
}
if (timestamp)
*timestamp = pcp->result->timestamp;
return true;
}
static int Platform_addMetric(Metric id, const char *name) {
unsigned int i = (unsigned int)id;
if (i >= PCP_METRIC_COUNT && i >= pcp->total) {
/* added via configuration files */
unsigned int j = pcp->total + 1;
pcp->fetch = xRealloc(pcp->fetch, j * sizeof(pmID));
pcp->pmids = xRealloc(pcp->pmids, j * sizeof(pmID));
pcp->names = xRealloc(pcp->names, j * sizeof(char*));
pcp->descs = xRealloc(pcp->descs, j * sizeof(pmDesc));
memset(&pcp->descs[i], 0, sizeof(pmDesc));
}
pcp->pmids[i] = pcp->fetch[i] = PM_ID_NULL;
pcp->names[i] = name;
return ++pcp->total;
}
void Platform_init(void) {
int sts = pmNewContext(PM_CONTEXT_HOST, "local:");
if (sts < 0)
sts = pmNewContext(PM_CONTEXT_LOCAL, NULL);
if (sts < 0) {
fprintf(stderr, "Cannot setup PCP metric source: %s\n", pmErrStr(sts));
exit(1);
}
pcp = xCalloc(1, sizeof(Platform));
pcp->context = sts;
pcp->fetch = xCalloc(PCP_METRIC_COUNT, sizeof(pmID));
pcp->pmids = xCalloc(PCP_METRIC_COUNT, sizeof(pmID));
pcp->names = xCalloc(PCP_METRIC_COUNT, sizeof(char*));
pcp->descs = xCalloc(PCP_METRIC_COUNT, sizeof(pmDesc));
for (unsigned int i = 0; i < PCP_METRIC_COUNT; i++)
Platform_addMetric(i, Platform_metricNames[i]);
sts = pmLookupName(pcp->total, pcp->names, pcp->pmids);
if (sts < 0) {
fprintf(stderr, "Error: cannot lookup metric names: %s\n", pmErrStr(sts));
exit(1);
}
for (unsigned int i = 0; i < pcp->total; i++) {
pcp->fetch[i] = PM_ID_NULL; /* default is to not sample */
/* expect some metrics to be missing - e.g. PMDA not available */
if (pcp->pmids[i] == PM_ID_NULL)
continue;
sts = pmLookupDesc(pcp->pmids[i], &pcp->descs[i]);
if (sts < 0) {
if (pmDebugOptions.appl0)
fprintf(stderr, "Error: cannot lookup metric %s(%s): %s\n",
pcp->names[i], pmIDStr(pcp->pmids[i]), pmErrStr(sts));
pcp->pmids[i] = PM_ID_NULL;
continue;
}
}
/* set proc.control.perclient.threads to 1 for live contexts */
Metric_enableThreads();
/* extract values needed for setup - e.g. cpu count, pid_max */
Metric_enable(PCP_PID_MAX, true);
Metric_enable(PCP_BOOTTIME, true);
Metric_enable(PCP_HINV_NCPU, true);
Metric_enable(PCP_PERCPU_SYSTEM, true);
Metric_enable(PCP_UNAME_SYSNAME, true);
Metric_enable(PCP_UNAME_RELEASE, true);
Metric_enable(PCP_UNAME_MACHINE, true);
Metric_fetch(NULL);
for (Metric metric = 0; metric < PCP_PROC_PID; metric++)
Metric_enable(metric, true);
Metric_enable(PCP_PID_MAX, false); /* needed one time only */
Metric_enable(PCP_BOOTTIME, false);
Metric_enable(PCP_UNAME_SYSNAME, false);
Metric_enable(PCP_UNAME_RELEASE, false);
Metric_enable(PCP_UNAME_MACHINE, false);
/* first sample (fetch) performed above, save constants */
Platform_getBootTime();
Platform_getMaxCPU();
Platform_getMaxPid();
}
void Platform_done(void) {
pmDestroyContext(pcp->context);
free(pcp->fetch);
free(pcp->pmids);
free(pcp->names);
free(pcp->descs);
free(pcp);
}
void Platform_setBindings(Htop_Action* keys) {
/* no platform-specific key bindings */
(void)keys;
}
int Platform_getUptime(void) {
pmAtomValue value;
if (Metric_values(PCP_UPTIME, &value, 1, PM_TYPE_32) == NULL)
return 0;
return value.l;
}
void Platform_getLoadAverage(double* one, double* five, double* fifteen) {
*one = *five = *fifteen = 0.0;
pmAtomValue values[3] = {0};
if (Metric_values(PCP_LOAD_AVERAGE, values, 3, PM_TYPE_DOUBLE) != NULL) {
*one = values[0].d;
*five = values[1].d;
*fifteen = values[2].d;
}
}
int Platform_getMaxCPU(void) {
if (pcp->ncpu)
return pcp->ncpu;
pmAtomValue value;
if (Metric_values(PCP_HINV_NCPU, &value, 1, PM_TYPE_32) != NULL)
pcp->ncpu = value.l;
else
pcp->ncpu = -1;
return pcp->ncpu;
}
int Platform_getMaxPid(void) {
if (pcp->pidmax)
return pcp->pidmax;
pmAtomValue value;
if (Metric_values(PCP_PID_MAX, &value, 1, PM_TYPE_32) == NULL)
return -1;
pcp->pidmax = value.l;
return pcp->pidmax;
}
long long Platform_getBootTime(void) {
if (pcp->btime)
return pcp->btime;
pmAtomValue value;
if (Metric_values(PCP_BOOTTIME, &value, 1, PM_TYPE_64) != NULL)
pcp->btime = value.ll;
return pcp->btime;
}
static double Platform_setOneCPUValues(Meter* this, pmAtomValue* values) {
unsigned long long value = values[CPU_TOTAL_PERIOD].ull;
double total = (double) (value == 0 ? 1 : value);
double percent;
double* v = this->values;
v[CPU_METER_NICE] = values[CPU_NICE_PERIOD].ull / total * 100.0;
v[CPU_METER_NORMAL] = values[CPU_USER_PERIOD].ull / total * 100.0;
if (this->pl->settings->detailedCPUTime) {
v[CPU_METER_KERNEL] = values[CPU_SYSTEM_PERIOD].ull / total * 100.0;
v[CPU_METER_IRQ] = values[CPU_IRQ_PERIOD].ull / total * 100.0;
v[CPU_METER_SOFTIRQ] = values[CPU_SOFTIRQ_PERIOD].ull / total * 100.0;
v[CPU_METER_STEAL] = values[CPU_STEAL_PERIOD].ull / total * 100.0;
v[CPU_METER_GUEST] = values[CPU_GUEST_PERIOD].ull / total * 100.0;
v[CPU_METER_IOWAIT] = values[CPU_IOWAIT_PERIOD].ull / total * 100.0;
this->curItems = 8;
if (this->pl->settings->accountGuestInCPUMeter)
percent = v[0] + v[1] + v[2] + v[3] + v[4] + v[5] + v[6];
else
percent = v[0] + v[1] + v[2] + v[3] + v[4];
} else {
v[2] = values[CPU_SYSTEM_ALL_PERIOD].ull / total * 100.0;
value = values[CPU_STEAL_PERIOD].ull + values[CPU_GUEST_PERIOD].ull;
v[3] = value / total * 100.0;
this->curItems = 4;
percent = v[0] + v[1] + v[2] + v[3];
}
percent = CLAMP(percent, 0.0, 100.0);
if (isnan(percent))
percent = 0.0;
v[CPU_METER_FREQUENCY] = values[CPU_FREQUENCY].d;
v[CPU_METER_TEMPERATURE] = NAN;
return percent;
}
double Platform_setCPUValues(Meter* this, int cpu) {
const PCPProcessList* pl = (const PCPProcessList*) this->pl;
if (cpu <= 0) /* use aggregate values */
return Platform_setOneCPUValues(this, pl->cpu);
return Platform_setOneCPUValues(this, pl->percpu[cpu - 1]);
}
void Platform_setMemoryValues(Meter* this) {
const ProcessList* pl = this->pl;
long int usedMem = pl->usedMem;
long int buffersMem = pl->buffersMem;
long int cachedMem = pl->cachedMem;
usedMem -= buffersMem + cachedMem;
this->total = pl->totalMem;
this->values[0] = usedMem;
this->values[1] = buffersMem;
this->values[2] = cachedMem;
}
void Platform_setSwapValues(Meter* this) {
const ProcessList* pl = this->pl;
this->total = pl->totalSwap;
this->values[0] = pl->usedSwap;
this->values[1] = pl->cachedSwap;
}
void Platform_setZramValues(Meter* this) {
(void)this;
int i, count = Metric_instanceCount(PCP_ZRAM_CAPACITY);
pmAtomValue *values = xCalloc(count, sizeof(pmAtomValue));
ZramStats stats = {0};
if (Metric_values(PCP_ZRAM_CAPACITY, values, count, PM_TYPE_U64)) {
for (i = 0; i < count; i++)
stats.totalZram += values[i].ull;
}
if (Metric_values(PCP_ZRAM_ORIGINAL, values, count, PM_TYPE_U64)) {
for (i = 0; i < count; i++)
stats.usedZramOrig += values[i].ull;
}
if (Metric_values(PCP_ZRAM_COMPRESSED, values, count, PM_TYPE_U64)) {
for (i = 0; i < count; i++)
stats.usedZramComp += values[i].ull;
}
free(values);
this->total = stats.totalZram;
this->values[0] = stats.usedZramComp;
this->values[1] = stats.usedZramOrig;
}
char* Platform_getProcessEnv(pid_t pid) {
pmAtomValue value;
if (!Metric_instance(PCP_PROC_ENVIRON, pid, 0, &value, PM_TYPE_STRING))
return NULL;
return value.cp;
}
char* Platform_getInodeFilename(pid_t pid, ino_t inode) {
(void)pid;
(void)inode;
return NULL;
}
FileLocks_ProcessData* Platform_getProcessLocks(pid_t pid) {
(void)pid;
return NULL;
}
void Platform_getPressureStall(const char* file, bool some, double* ten, double* sixty, double* threehundred) {
*ten = *sixty = *threehundred = 0;
Metric metric;
if (String_eq(file, "cpu"))
metric = PCP_PSI_CPUSOME;
else if (String_eq(file, "io"))
metric = some ? PCP_PSI_IOSOME : PCP_PSI_IOFULL;
else if (String_eq(file, "mem"))
metric = some ? PCP_PSI_MEMSOME : PCP_PSI_MEMFULL;
else
return;
pmAtomValue values[3] = {0};
if (Metric_values(metric, values, 3, PM_TYPE_DOUBLE) != NULL) {
*ten = values[0].d;
*sixty = values[1].d;
*threehundred = values[2].d;
}
}
bool Platform_getDiskIO(DiskIOData* data) {
data->totalBytesRead = 0;
data->totalBytesWritten = 0;
data->totalMsTimeSpend = 0;
pmAtomValue value;
if (Metric_values(PCP_DISK_READB, &value, 1, PM_TYPE_U64) != NULL)
data->totalBytesRead = value.ull;
if (Metric_values(PCP_DISK_WRITEB, &value, 1, PM_TYPE_U64) != NULL)
data->totalBytesWritten = value.ull;
if (Metric_values(PCP_DISK_ACTIVE, &value, 1, PM_TYPE_U64) != NULL)
data->totalMsTimeSpend = value.ull;
return true;
}
bool Platform_getNetworkIO(unsigned long int* bytesReceived,
unsigned long int* packetsReceived,
unsigned long int* bytesTransmitted,
unsigned long int* packetsTransmitted) {
*bytesReceived = 0;
*packetsReceived = 0;
*bytesTransmitted = 0;
*packetsTransmitted = 0;
pmAtomValue value;
if (Metric_values(PCP_NET_RECVB, &value, 1, PM_TYPE_U64) != NULL)
*bytesReceived = value.ull;
if (Metric_values(PCP_NET_SENDB, &value, 1, PM_TYPE_U64) != NULL)
*bytesTransmitted = value.ull;
if (Metric_values(PCP_NET_RECVP, &value, 1, PM_TYPE_U64) != NULL)
*packetsReceived = value.ull;
if (Metric_values(PCP_NET_SENDP, &value, 1, PM_TYPE_U64) != NULL)
*packetsTransmitted = value.ull;
return true;
}
void Platform_getBattery(double* level, ACPresence* isOnAC) {
*level = NAN;
*isOnAC = AC_ERROR;
}

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#ifndef HEADER_Platform
#define HEADER_Platform
/*
htop - pcp/Platform.h
(C) 2014 Hisham H. Muhammad
(C) 2020 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include <ctype.h>
#include <stdbool.h>
#include <pcp/pmapi.h>
#undef PACKAGE_URL
#undef PACKAGE_NAME
#undef PACKAGE_STRING
#undef PACKAGE_TARNAME
#undef PACKAGE_VERSION
#undef PACKAGE_BUGREPORT
#include "Action.h"
#include "BatteryMeter.h"
#include "DiskIOMeter.h"
#include "Meter.h"
#include "Process.h"
#include "ProcessLocksScreen.h"
#include "SignalsPanel.h"
extern ProcessField Platform_defaultFields[];
extern int Platform_numberOfFields;
extern const SignalItem Platform_signals[];
extern const unsigned int Platform_numberOfSignals;
extern const MeterClass* const Platform_meterTypes[];
void Platform_init(void);
void Platform_done(void);
void Platform_setBindings(Htop_Action* keys);
int Platform_getUptime(void);
void Platform_getLoadAverage(double* one, double* five, double* fifteen);
long long Platform_getBootTime(void);
int Platform_getMaxCPU(void);
int Platform_getMaxPid(void);
double Platform_setCPUValues(Meter* this, int cpu);
void Platform_setMemoryValues(Meter* this);
void Platform_setSwapValues(Meter* this);
void Platform_setZramValues(Meter* this);
char* Platform_getProcessEnv(pid_t pid);
char* Platform_getInodeFilename(pid_t pid, ino_t inode);
FileLocks_ProcessData* Platform_getProcessLocks(pid_t pid);
void Platform_getPressureStall(const char *file, bool some, double* ten, double* sixty, double* threehundred);
bool Platform_getDiskIO(DiskIOData* data);
bool Platform_getNetworkIO(unsigned long int* bytesReceived,
unsigned long int* packetsReceived,
unsigned long int* bytesTransmitted,
unsigned long int* packetsTransmitted);
void Platform_getBattery(double *percent, ACPresence *isOnAC);
typedef enum Metric_ {
PCP_CONTROL_THREADS, /* proc.control.perclient.threads */
PCP_HINV_NCPU, /* hinv.ncpu */
PCP_HINV_CPUCLOCK, /* hinv.cpu.clock */
PCP_UNAME_SYSNAME, /* kernel.uname.sysname */
PCP_UNAME_RELEASE, /* kernel.uname.release */
PCP_UNAME_MACHINE, /* kernel.uname.machine */
PCP_LOAD_AVERAGE, /* kernel.all.load */
PCP_PID_MAX, /* kernel.all.pid_max */
PCP_UPTIME, /* kernel.all.uptime */
PCP_BOOTTIME, /* kernel.all.boottime */
PCP_CPU_USER, /* kernel.all.cpu.user */
PCP_CPU_NICE, /* kernel.all.cpu.nice */
PCP_CPU_SYSTEM, /* kernel.all.cpu.sys */
PCP_CPU_IDLE, /* kernel.all.cpu.idle */
PCP_CPU_IOWAIT, /* kernel.all.cpu.wait.total */
PCP_CPU_IRQ, /* kernel.all.cpu.intr */
PCP_CPU_SOFTIRQ, /* kernel.all.cpu.irq.soft */
PCP_CPU_STEAL, /* kernel.all.cpu.steal */
PCP_CPU_GUEST, /* kernel.all.cpu.guest */
PCP_CPU_GUESTNICE, /* kernel.all.cpu.guest_nice */
PCP_PERCPU_USER, /* kernel.percpu.cpu.user */
PCP_PERCPU_NICE, /* kernel.percpu.cpu.nice */
PCP_PERCPU_SYSTEM, /* kernel.percpu.cpu.sys */
PCP_PERCPU_IDLE, /* kernel.percpu.cpu.idle */
PCP_PERCPU_IOWAIT, /* kernel.percpu.cpu.wait.total */
PCP_PERCPU_IRQ, /* kernel.percpu.cpu.intr */
PCP_PERCPU_SOFTIRQ, /* kernel.percpu.cpu.irq.soft */
PCP_PERCPU_STEAL, /* kernel.percpu.cpu.steal */
PCP_PERCPU_GUEST, /* kernel.percpu.cpu.guest */
PCP_PERCPU_GUESTNICE, /* kernel.percpu.cpu.guest_nice */
PCP_MEM_TOTAL, /* mem.physmem */
PCP_MEM_FREE, /* mem.util.free */
PCP_MEM_BUFFERS, /* mem.util.bufmem */
PCP_MEM_CACHED, /* mem.util.cached */
PCP_MEM_AVAILABLE, /* mem.util.available */
PCP_MEM_SRECLAIM, /* mem.util.slabReclaimable */
PCP_MEM_SWAPCACHED, /* mem.util.swapCached */
PCP_MEM_SWAPTOTAL, /* mem.util.swapTotal */
PCP_MEM_SWAPFREE, /* mem.util.swapFree */
PCP_DISK_READB, /* disk.all.read_bytes */
PCP_DISK_WRITEB, /* disk.all.write_bytes */
PCP_DISK_ACTIVE, /* disk.all.avactive */
PCP_NET_RECVB, /* network.all.in.bytes */
PCP_NET_SENDB, /* network.all.out.bytes */
PCP_NET_RECVP, /* network.all.in.packets */
PCP_NET_SENDP, /* network.all.out.packets */
PCP_PSI_CPUSOME, /* kernel.all.pressure.cpu.some.avg */
PCP_PSI_IOSOME, /* kernel.all.pressure.io.some.avg */
PCP_PSI_IOFULL, /* kernel.all.pressure.io.full.avg */
PCP_PSI_MEMSOME, /* kernel.all.pressure.memory.some.avg */
PCP_PSI_MEMFULL, /* kernel.all.pressure.memory.full.avg */
PCP_ZRAM_CAPACITY, /* zram.capacity */
PCP_ZRAM_ORIGINAL, /* zram.mm_stat.data_size.original */
PCP_ZRAM_COMPRESSED, /* zram.mm_stat.data_size.compressed */
PCP_PROC_PID, /* proc.psinfo.pid */
PCP_PROC_PPID, /* proc.psinfo.ppid */
PCP_PROC_TGID, /* proc.psinfo.tgid */
PCP_PROC_PGRP, /* proc.psinfo.pgrp */
PCP_PROC_SESSION, /* proc.psinfo.session */
PCP_PROC_STATE, /* proc.psinfo.sname */
PCP_PROC_TTY, /* proc.psinfo.tty */
PCP_PROC_TTYPGRP, /* proc.psinfo.tty_pgrp */
PCP_PROC_MINFLT, /* proc.psinfo.minflt */
PCP_PROC_MAJFLT, /* proc.psinfo.maj_flt */
PCP_PROC_CMINFLT, /* proc.psinfo.cmin_flt */
PCP_PROC_CMAJFLT, /* proc.psinfo.cmaj_flt */
PCP_PROC_UTIME, /* proc.psinfo.utime */
PCP_PROC_STIME, /* proc.psinfo.stime */
PCP_PROC_CUTIME, /* proc.psinfo.cutime */
PCP_PROC_CSTIME, /* proc.psinfo.cstime */
PCP_PROC_PRIORITY, /* proc.psinfo.priority */
PCP_PROC_NICE, /* proc.psinfo.nice */
PCP_PROC_THREADS, /* proc.psinfo.threads */
PCP_PROC_STARTTIME, /* proc.psinfo.start_time */
PCP_PROC_PROCESSOR, /* proc.psinfo.processor */
PCP_PROC_CMD, /* proc.psinfo.cmd */
PCP_PROC_PSARGS, /* proc.psinfo.psargs */
PCP_PROC_CGROUPS, /* proc.psinfo.cgroups */
PCP_PROC_OOMSCORE, /* proc.psinfo.oom_score */
PCP_PROC_VCTXSW, /* proc.psinfo.vctxsw */
PCP_PROC_NVCTXSW, /* proc.psinfo.nvctxsw */
PCP_PROC_LABELS, /* proc.psinfo.labels */
PCP_PROC_ENVIRON, /* proc.psinfo.environ */
PCP_PROC_TTYNAME, /* proc.psinfo.ttyname */
PCP_PROC_ID_UID, /* proc.id.uid */
PCP_PROC_ID_USER, /* proc.id.uid_nm */
PCP_PROC_IO_RCHAR, /* proc.io.rchar */
PCP_PROC_IO_WCHAR, /* proc.io.wchar */
PCP_PROC_IO_SYSCR, /* proc.io.syscr */
PCP_PROC_IO_SYSCW, /* proc.io.syscw */
PCP_PROC_IO_READB, /* proc.io.read_bytes */
PCP_PROC_IO_WRITEB, /* proc.io.write_bytes */
PCP_PROC_IO_CANCELLED, /* proc.io.cancelled_write_bytes */
PCP_PROC_MEM_SIZE, /* proc.memory.size */
PCP_PROC_MEM_RSS, /* proc.memory.rss */
PCP_PROC_MEM_SHARE, /* proc.memory.share */
PCP_PROC_MEM_TEXTRS, /* proc.memory.textrss */
PCP_PROC_MEM_LIBRS, /* proc.memory.librss */
PCP_PROC_MEM_DATRS, /* proc.memory.datrss */
PCP_PROC_MEM_DIRTY, /* proc.memory.dirty */
PCP_PROC_SMAPS_PSS, /* proc.smaps.pss */
PCP_PROC_SMAPS_SWAP, /* proc.smaps.swap */
PCP_PROC_SMAPS_SWAPPSS, /* proc.smaps.swappss */
PCP_METRIC_COUNT /* total metric count */
} Metric;
void Metric_enable(Metric metric, bool enable);
bool Metric_enabled(Metric metric);
void Metric_enableThreads(void);
bool Metric_fetch(struct timeval *timestamp);
bool Metric_iterate(Metric metric, int* instp, int* offsetp);
pmAtomValue* Metric_values(Metric metric, pmAtomValue *atom, int count, int type);
int Metric_instanceCount(Metric metric);
int Metric_instanceOffset(Metric metric, int inst);
pmAtomValue *Metric_instance(Metric metric, int inst, int offset, pmAtomValue *atom, int type);
#endif

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pcp/ProcessField.h Normal file
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#ifndef HEADER_PCPProcessField
#define HEADER_PCPProcessField
/*
htop - pcp/ProcessField.h
(C) 2014 Hisham H. Muhammad
(C) 2021 htop dev team
(C) 2020-2021 Red Hat, Inc. All Rights Reserved.
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#define PLATFORM_PROCESS_FIELDS \
CMINFLT = 11, \
CMAJFLT = 13, \
UTIME = 14, \
STIME = 15, \
CUTIME = 16, \
CSTIME = 17, \
M_SHARE = 41, \
M_TRS = 42, \
M_DRS = 43, \
M_LRS = 44, \
M_DT = 45, \
CTID = 100, \
RCHAR = 103, \
WCHAR = 104, \
SYSCR = 105, \
SYSCW = 106, \
RBYTES = 107, \
WBYTES = 108, \
CNCLWB = 109, \
IO_READ_RATE = 110, \
IO_WRITE_RATE = 111, \
IO_RATE = 112, \
CGROUP = 113, \
OOM = 114, \
PERCENT_CPU_DELAY = 116, \
PERCENT_IO_DELAY = 117, \
PERCENT_SWAP_DELAY = 118, \
M_PSS = 119, \
M_SWAP = 120, \
M_PSSWP = 121, \
CTXT = 122, \
SECATTR = 123, \
PROC_COMM = 124, \
// End of list
#endif /* HEADER_PCPProcessField */