htop/linux/Platform.c

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/*
htop - linux/Platform.c
(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 "linux/Platform.h"
#include <assert.h>
#include <ctype.h>
#include <dirent.h>
#include <fcntl.h>
#include <inttypes.h>
#include <math.h>
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#include <stdint.h>
#include <stdio.h>
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#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.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 "HugePageMeter.h"
#include "LoadAverageMeter.h"
#include "Macros.h"
#include "MainPanel.h"
#include "Meter.h"
#include "MemoryMeter.h"
#include "MemorySwapMeter.h"
#include "NetworkIOMeter.h"
#include "Object.h"
#include "Panel.h"
#include "PressureStallMeter.h"
#include "ProcessList.h"
#include "ProvideCurses.h"
#include "linux/SELinuxMeter.h"
#include "Settings.h"
#include "SwapMeter.h"
#include "SysArchMeter.h"
#include "TasksMeter.h"
#include "UptimeMeter.h"
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#include "XUtils.h"
#include "linux/IOPriority.h"
#include "linux/IOPriorityPanel.h"
#include "linux/LinuxProcess.h"
#include "linux/LinuxProcessList.h"
#include "linux/SystemdMeter.h"
#include "linux/ZramMeter.h"
#include "linux/ZramStats.h"
#include "zfs/ZfsArcMeter.h"
#include "zfs/ZfsArcStats.h"
#include "zfs/ZfsCompressedArcMeter.h"
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#ifdef HAVE_LIBCAP
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#include <errno.h>
#include <sys/capability.h>
#endif
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#ifdef HAVE_SENSORS_SENSORS_H
#include "LibSensors.h"
#endif
#ifndef O_PATH
#define O_PATH 010000000 // declare for ancient glibc versions
#endif
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#ifdef HAVE_LIBCAP
enum CapMode {
CAP_MODE_OFF,
CAP_MODE_BASIC,
CAP_MODE_STRICT
};
#endif
bool Running_containerized = false;
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const ScreenDefaults Platform_defaultScreens[] = {
{
.name = "Main",
.columns = "PID USER PRIORITY NICE M_VIRT M_RESIDENT M_SHARE STATE PERCENT_CPU PERCENT_MEM TIME Command",
.sortKey = "PERCENT_CPU",
},
{
.name = "I/O",
.columns = "PID USER IO_PRIORITY IO_RATE IO_READ_RATE IO_WRITE_RATE PERCENT_SWAP_DELAY PERCENT_IO_DELAY Command",
.sortKey = "IO_RATE",
},
};
const unsigned int Platform_numberOfDefaultScreens = ARRAYSIZE(Platform_defaultScreens);
const SignalItem Platform_signals[] = {
{ .name = " 0 Cancel", .number = 0 },
{ .name = " 1 SIGHUP", .number = 1 },
{ .name = " 2 SIGINT", .number = 2 },
{ .name = " 3 SIGQUIT", .number = 3 },
{ .name = " 4 SIGILL", .number = 4 },
{ .name = " 5 SIGTRAP", .number = 5 },
{ .name = " 6 SIGABRT", .number = 6 },
{ .name = " 6 SIGIOT", .number = 6 },
{ .name = " 7 SIGBUS", .number = 7 },
{ .name = " 8 SIGFPE", .number = 8 },
{ .name = " 9 SIGKILL", .number = 9 },
{ .name = "10 SIGUSR1", .number = 10 },
{ .name = "11 SIGSEGV", .number = 11 },
{ .name = "12 SIGUSR2", .number = 12 },
{ .name = "13 SIGPIPE", .number = 13 },
{ .name = "14 SIGALRM", .number = 14 },
{ .name = "15 SIGTERM", .number = 15 },
{ .name = "16 SIGSTKFLT", .number = 16 },
{ .name = "17 SIGCHLD", .number = 17 },
{ .name = "18 SIGCONT", .number = 18 },
{ .name = "19 SIGSTOP", .number = 19 },
{ .name = "20 SIGTSTP", .number = 20 },
{ .name = "21 SIGTTIN", .number = 21 },
{ .name = "22 SIGTTOU", .number = 22 },
{ .name = "23 SIGURG", .number = 23 },
{ .name = "24 SIGXCPU", .number = 24 },
{ .name = "25 SIGXFSZ", .number = 25 },
{ .name = "26 SIGVTALRM", .number = 26 },
{ .name = "27 SIGPROF", .number = 27 },
{ .name = "28 SIGWINCH", .number = 28 },
{ .name = "29 SIGIO", .number = 29 },
{ .name = "29 SIGPOLL", .number = 29 },
{ .name = "30 SIGPWR", .number = 30 },
{ .name = "31 SIGSYS", .number = 31 },
};
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const unsigned int Platform_numberOfSignals = ARRAYSIZE(Platform_signals);
static enum { BAT_PROC, BAT_SYS, BAT_ERR } Platform_Battery_method = BAT_PROC;
static time_t Platform_Battery_cacheTime;
static double Platform_Battery_cachePercent = NAN;
static ACPresence Platform_Battery_cacheIsOnAC;
#ifdef HAVE_LIBCAP
static enum CapMode Platform_capabilitiesMode = CAP_MODE_BASIC;
#endif
static Htop_Reaction Platform_actionSetIOPriority(State* st) {
if (Settings_isReadonly())
return HTOP_OK;
const LinuxProcess* p = (const LinuxProcess*) Panel_getSelected((Panel*)st->mainPanel);
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if (!p)
return HTOP_OK;
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IOPriority ioprio1 = p->ioPriority;
Panel* ioprioPanel = IOPriorityPanel_new(ioprio1);
const void* set = Action_pickFromVector(st, ioprioPanel, 20, true);
if (set) {
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IOPriority ioprio2 = IOPriorityPanel_getIOPriority(ioprioPanel);
bool ok = MainPanel_foreachProcess(st->mainPanel, LinuxProcess_setIOPriority, (Arg) { .i = ioprio2 }, NULL);
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if (!ok) {
beep();
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}
}
Panel_delete((Object*)ioprioPanel);
return HTOP_REFRESH | HTOP_REDRAW_BAR | HTOP_UPDATE_PANELHDR;
}
static bool Platform_changeAutogroupPriority(MainPanel* panel, int delta) {
if (LinuxProcess_isAutogroupEnabled() == false) {
beep();
return false;
}
bool anyTagged;
bool ok = MainPanel_foreachProcess(panel, LinuxProcess_changeAutogroupPriorityBy, (Arg) { .i = delta }, &anyTagged);
if (!ok)
beep();
return anyTagged;
}
static Htop_Reaction Platform_actionHigherAutogroupPriority(State* st) {
if (Settings_isReadonly())
return HTOP_OK;
bool changed = Platform_changeAutogroupPriority(st->mainPanel, -1);
return changed ? HTOP_REFRESH : HTOP_OK;
}
static Htop_Reaction Platform_actionLowerAutogroupPriority(State* st) {
if (Settings_isReadonly())
return HTOP_OK;
bool changed = Platform_changeAutogroupPriority(st->mainPanel, 1);
return changed ? HTOP_REFRESH : HTOP_OK;
}
void Platform_setBindings(Htop_Action* keys) {
keys['i'] = Platform_actionSetIOPriority;
keys['{'] = Platform_actionLowerAutogroupPriority;
keys['}'] = Platform_actionHigherAutogroupPriority;
keys[KEY_F(19)] = Platform_actionLowerAutogroupPriority; // Shift-F7
keys[KEY_F(20)] = Platform_actionHigherAutogroupPriority; // Shift-F8
}
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const MeterClass* const Platform_meterTypes[] = {
&CPUMeter_class,
&ClockMeter_class,
&DateMeter_class,
&DateTimeMeter_class,
&LoadAverageMeter_class,
&LoadMeter_class,
&MemoryMeter_class,
&SwapMeter_class,
&MemorySwapMeter_class,
&SysArchMeter_class,
&HugePageMeter_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,
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&PressureStallCPUSomeMeter_class,
&PressureStallIOSomeMeter_class,
&PressureStallIOFullMeter_class,
&PressureStallMemorySomeMeter_class,
&PressureStallMemoryFullMeter_class,
&ZfsArcMeter_class,
&ZfsCompressedArcMeter_class,
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&ZramMeter_class,
&DiskIOMeter_class,
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&NetworkIOMeter_class,
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&SELinuxMeter_class,
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&SystemdMeter_class,
NULL
};
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int Platform_getUptime() {
double uptime = 0;
FILE* fd = fopen(PROCDIR "/uptime", "r");
if (fd) {
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int n = fscanf(fd, "%64lf", &uptime);
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fclose(fd);
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if (n <= 0) {
return 0;
}
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}
return floor(uptime);
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}
void Platform_getLoadAverage(double* one, double* five, double* fifteen) {
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FILE* fd = fopen(PROCDIR "/loadavg", "r");
if (!fd)
goto err;
double scanOne, scanFive, scanFifteen;
int r = fscanf(fd, "%lf %lf %lf", &scanOne, &scanFive, &scanFifteen);
fclose(fd);
if (r != 3)
goto err;
*one = scanOne;
*five = scanFive;
*fifteen = scanFifteen;
return;
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err:
*one = NAN;
*five = NAN;
*fifteen = NAN;
}
int Platform_getMaxPid() {
FILE* file = fopen(PROCDIR "/sys/kernel/pid_max", "r");
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if (!file)
return -1;
int maxPid = 4194303;
int match = fscanf(file, "%32d", &maxPid);
(void) match;
fclose(file);
return maxPid;
}
double Platform_setCPUValues(Meter* this, unsigned int cpu) {
const LinuxProcessList* pl = (const LinuxProcessList*) this->pl;
const CPUData* cpuData = &(pl->cpuData[cpu]);
double total = (double) ( cpuData->totalPeriod == 0 ? 1 : cpuData->totalPeriod);
double percent;
double* v = this->values;
if (!cpuData->online) {
this->curItems = 0;
return NAN;
}
v[CPU_METER_NICE] = cpuData->nicePeriod / total * 100.0;
v[CPU_METER_NORMAL] = cpuData->userPeriod / total * 100.0;
if (this->pl->settings->detailedCPUTime) {
v[CPU_METER_KERNEL] = cpuData->systemPeriod / total * 100.0;
v[CPU_METER_IRQ] = cpuData->irqPeriod / total * 100.0;
v[CPU_METER_SOFTIRQ] = cpuData->softIrqPeriod / total * 100.0;
v[CPU_METER_STEAL] = cpuData->stealPeriod / total * 100.0;
v[CPU_METER_GUEST] = cpuData->guestPeriod / total * 100.0;
v[CPU_METER_IOWAIT] = cpuData->ioWaitPeriod / total * 100.0;
this->curItems = 8;
if (this->pl->settings->accountGuestInCPUMeter) {
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percent = v[0] + v[1] + v[2] + v[3] + v[4] + v[5] + v[6];
} else {
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percent = v[0] + v[1] + v[2] + v[3] + v[4];
}
} else {
v[2] = cpuData->systemAllPeriod / total * 100.0;
v[3] = (cpuData->stealPeriod + cpuData->guestPeriod) / total * 100.0;
this->curItems = 4;
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percent = v[0] + v[1] + v[2] + v[3];
}
percent = CLAMP(percent, 0.0, 100.0);
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if (isnan(percent)) {
percent = 0.0;
}
v[CPU_METER_FREQUENCY] = cpuData->frequency;
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#ifdef HAVE_SENSORS_SENSORS_H
v[CPU_METER_TEMPERATURE] = cpuData->temperature;
#else
v[CPU_METER_TEMPERATURE] = NAN;
#endif
return percent;
}
void Platform_setMemoryValues(Meter* this) {
const ProcessList* pl = this->pl;
const LinuxProcessList* lpl = (const LinuxProcessList*) pl;
this->total = pl->totalMem;
this->values[0] = pl->usedMem;
this->values[1] = pl->buffersMem;
this->values[2] = pl->sharedMem;
this->values[3] = pl->cachedMem;
this->values[4] = pl->availableMem;
if (lpl->zfs.enabled != 0 && !Running_containerized) {
this->values[0] -= lpl->zfs.size;
this->values[3] += lpl->zfs.size;
}
}
void Platform_setSwapValues(Meter* this) {
const ProcessList* pl = this->pl;
this->total = pl->totalSwap;
this->values[0] = pl->usedSwap;
this->values[1] = pl->cachedSwap;
}
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void Platform_setZramValues(Meter* this) {
const LinuxProcessList* lpl = (const LinuxProcessList*) this->pl;
this->total = lpl->zram.totalZram;
this->values[0] = lpl->zram.usedZramComp;
this->values[1] = lpl->zram.usedZramOrig;
}
void Platform_setZfsArcValues(Meter* this) {
const LinuxProcessList* lpl = (const LinuxProcessList*) this->pl;
ZfsArcMeter_readStats(this, &(lpl->zfs));
}
void Platform_setZfsCompressedArcValues(Meter* this) {
const LinuxProcessList* lpl = (const LinuxProcessList*) this->pl;
ZfsCompressedArcMeter_readStats(this, &(lpl->zfs));
}
char* Platform_getProcessEnv(pid_t pid) {
char procname[128];
xSnprintf(procname, sizeof(procname), PROCDIR "/%d/environ", pid);
FILE* fd = fopen(procname, "r");
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if (!fd)
return NULL;
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char* env = NULL;
size_t capacity = 0;
size_t size = 0;
ssize_t bytes = 0;
do {
size += bytes;
capacity += 4096;
env = xRealloc(env, capacity);
} while ((bytes = fread(env + size, 1, capacity - size, fd)) > 0);
fclose(fd);
if (bytes < 0) {
free(env);
return NULL;
}
size += bytes;
env = xRealloc(env, size + 2);
env[size] = '\0';
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env[size + 1] = '\0';
return env;
}
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/*
* Return the absolute path of a file given its pid&inode number
*
* Based on implementation of lslocks from util-linux:
* https://sources.debian.org/src/util-linux/2.36-3/misc-utils/lslocks.c/#L162
*/
char* Platform_getInodeFilename(pid_t pid, ino_t inode) {
struct stat sb;
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const struct dirent* de;
DIR* dirp;
ssize_t len;
int fd;
char path[PATH_MAX];
char sym[PATH_MAX];
char* ret = NULL;
memset(path, 0, sizeof(path));
memset(sym, 0, sizeof(sym));
xSnprintf(path, sizeof(path), "%s/%d/fd/", PROCDIR, pid);
if (strlen(path) >= (sizeof(path) - 2))
return NULL;
if (!(dirp = opendir(path)))
return NULL;
if ((fd = dirfd(dirp)) < 0 )
goto out;
while ((de = readdir(dirp))) {
if (String_eq(de->d_name, ".") || String_eq(de->d_name, ".."))
continue;
/* care only for numerical descriptors */
if (!strtoull(de->d_name, (char **) NULL, 10))
continue;
if (!Compat_fstatat(fd, path, de->d_name, &sb, 0) && inode != sb.st_ino)
continue;
if ((len = Compat_readlinkat(fd, path, de->d_name, sym, sizeof(sym) - 1)) < 1)
goto out;
sym[len] = '\0';
ret = xStrdup(sym);
break;
}
out:
closedir(dirp);
return ret;
}
FileLocks_ProcessData* Platform_getProcessLocks(pid_t pid) {
FileLocks_ProcessData* pdata = xCalloc(1, sizeof(FileLocks_ProcessData));
FILE* f = fopen(PROCDIR "/locks", "r");
if (!f) {
pdata->error = true;
return pdata;
}
char buffer[1024];
FileLocks_LockData** data_ref = &pdata->locks;
while(fgets(buffer, sizeof(buffer), f)) {
if (!strchr(buffer, '\n'))
continue;
int lock_id;
char lock_type[16];
char lock_excl[16];
char lock_rw[16];
pid_t lock_pid;
unsigned int lock_dev[2];
uint64_t lock_inode;
char lock_start[25];
char lock_end[25];
if (10 != sscanf(buffer, "%d: %15s %15s %15s %d %x:%x:%"PRIu64" %24s %24s",
&lock_id, lock_type, lock_excl, lock_rw, &lock_pid,
&lock_dev[0], &lock_dev[1], &lock_inode,
lock_start, lock_end))
continue;
if (pid != lock_pid)
continue;
FileLocks_LockData* ldata = xCalloc(1, sizeof(FileLocks_LockData));
FileLocks_Data* data = &ldata->data;
data->id = lock_id;
data->locktype = xStrdup(lock_type);
data->exclusive = xStrdup(lock_excl);
data->readwrite = xStrdup(lock_rw);
data->filename = Platform_getInodeFilename(lock_pid, lock_inode);
data->dev[0] = lock_dev[0];
data->dev[1] = lock_dev[1];
data->inode = lock_inode;
data->start = strtoull(lock_start, NULL, 10);
if (!String_eq(lock_end, "EOF")) {
data->end = strtoull(lock_end, NULL, 10);
} else {
data->end = ULLONG_MAX;
}
*data_ref = ldata;
data_ref = &ldata->next;
}
fclose(f);
return pdata;
}
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void Platform_getPressureStall(const char* file, bool some, double* ten, double* sixty, double* threehundred) {
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*ten = *sixty = *threehundred = 0;
char procname[128];
xSnprintf(procname, sizeof(procname), PROCDIR "/pressure/%s", file);
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FILE* fd = fopen(procname, "r");
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if (!fd) {
*ten = *sixty = *threehundred = NAN;
return;
}
int total = fscanf(fd, "some avg10=%32lf avg60=%32lf avg300=%32lf total=%*f ", ten, sixty, threehundred);
if (!some) {
total = fscanf(fd, "full avg10=%32lf avg60=%32lf avg300=%32lf total=%*f ", ten, sixty, threehundred);
}
(void) total;
assert(total == 3);
fclose(fd);
}
bool Platform_getDiskIO(DiskIOData* data) {
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FILE* fd = fopen(PROCDIR "/diskstats", "r");
if (!fd)
return false;
char lastTopDisk[32] = { '\0' };
unsigned long long int read_sum = 0, write_sum = 0, timeSpend_sum = 0;
char lineBuffer[256];
while (fgets(lineBuffer, sizeof(lineBuffer), fd)) {
char diskname[32];
unsigned long long int read_tmp, write_tmp, timeSpend_tmp;
if (sscanf(lineBuffer, "%*d %*d %31s %*u %*u %llu %*u %*u %*u %llu %*u %*u %llu", diskname, &read_tmp, &write_tmp, &timeSpend_tmp) == 4) {
if (String_startsWith(diskname, "dm-"))
continue;
if (String_startsWith(diskname, "zram"))
continue;
/* only count root disks, e.g. do not count IO from sda and sda1 twice */
if (lastTopDisk[0] && String_startsWith(diskname, lastTopDisk))
continue;
/* This assumes disks are listed directly before any of their partitions */
String_safeStrncpy(lastTopDisk, diskname, sizeof(lastTopDisk));
read_sum += read_tmp;
write_sum += write_tmp;
timeSpend_sum += timeSpend_tmp;
}
}
fclose(fd);
/* multiply with sector size */
data->totalBytesRead = 512 * read_sum;
data->totalBytesWritten = 512 * write_sum;
data->totalMsTimeSpend = timeSpend_sum;
return true;
}
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bool Platform_getNetworkIO(NetworkIOData* data) {
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FILE* fd = fopen(PROCDIR "/net/dev", "r");
if (!fd)
return false;
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memset(data, 0, sizeof(NetworkIOData));
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char lineBuffer[512];
while (fgets(lineBuffer, sizeof(lineBuffer), fd)) {
char interfaceName[32];
unsigned long long int bytesReceived, packetsReceived, bytesTransmitted, packetsTransmitted;
if (sscanf(lineBuffer, "%31s %llu %llu %*u %*u %*u %*u %*u %*u %llu %llu",
interfaceName,
&bytesReceived,
&packetsReceived,
&bytesTransmitted,
&packetsTransmitted) != 5)
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continue;
if (String_eq(interfaceName, "lo:"))
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continue;
data->bytesReceived += bytesReceived;
data->packetsReceived += packetsReceived;
data->bytesTransmitted += bytesTransmitted;
data->packetsTransmitted += packetsTransmitted;
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}
fclose(fd);
return true;
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}
// Linux battery reading by Ian P. Hands (iphands@gmail.com, ihands@redhat.com).
#define PROC_BATTERY_DIR PROCDIR "/acpi/battery"
#define PROC_POWERSUPPLY_DIR PROCDIR "/acpi/ac_adapter"
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#define PROC_POWERSUPPLY_ACSTATE_FILE PROC_POWERSUPPLY_DIR "/AC/state"
#define SYS_POWERSUPPLY_DIR "/sys/class/power_supply"
// ----------------------------------------
// READ FROM /proc
// ----------------------------------------
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static double Platform_Battery_getProcBatInfo(void) {
DIR* batteryDir = opendir(PROC_BATTERY_DIR);
if (!batteryDir)
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return NAN;
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uint64_t totalFull = 0;
uint64_t totalRemain = 0;
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struct dirent* dirEntry = NULL;
while ((dirEntry = readdir(batteryDir))) {
const char* entryName = dirEntry->d_name;
if (!String_startsWith(entryName, "BAT"))
continue;
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char filePath[256];
char bufInfo[1024] = {0};
xSnprintf(filePath, sizeof(filePath), "%s/%s/info", PROC_BATTERY_DIR, entryName);
ssize_t r = xReadfile(filePath, bufInfo, sizeof(bufInfo));
if (r < 0)
continue;
char bufState[1024] = {0};
xSnprintf(filePath, sizeof(filePath), "%s/%s/state", PROC_BATTERY_DIR, entryName);
r = xReadfile(filePath, bufState, sizeof(bufState));
if (r < 0)
continue;
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const char* line;
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//Getting total charge for all batteries
char* buf = bufInfo;
while ((line = strsep(&buf, "\n")) != NULL) {
char field[100] = {0};
int val = 0;
if (2 != sscanf(line, "%99[^:]:%d", field, &val))
continue;
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if (String_eq(field, "last full capacity")) {
totalFull += val;
break;
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}
}
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//Getting remaining charge for all batteries
buf = bufState;
while ((line = strsep(&buf, "\n")) != NULL) {
char field[100] = {0};
int val = 0;
if (2 != sscanf(line, "%99[^:]:%d", field, &val))
continue;
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if (String_eq(field, "remaining capacity")) {
totalRemain += val;
break;
}
}
}
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closedir(batteryDir);
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return totalFull > 0 ? ((double) totalRemain * 100.0) / (double) totalFull : NAN;
}
static ACPresence procAcpiCheck(void) {
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char buffer[1024] = {0};
ssize_t r = xReadfile(PROC_POWERSUPPLY_ACSTATE_FILE, buffer, sizeof(buffer));
if (r < 1)
return AC_ERROR;
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return String_eq(buffer, "on-line") ? AC_PRESENT : AC_ABSENT;
}
static void Platform_Battery_getProcData(double* percent, ACPresence* isOnAC) {
*isOnAC = procAcpiCheck();
*percent = AC_ERROR != *isOnAC ? Platform_Battery_getProcBatInfo() : NAN;
}
// ----------------------------------------
// READ FROM /sys
// ----------------------------------------
static void Platform_Battery_getSysData(double* percent, ACPresence* isOnAC) {
*percent = NAN;
*isOnAC = AC_ERROR;
DIR* dir = opendir(SYS_POWERSUPPLY_DIR);
if (!dir)
return;
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uint64_t totalFull = 0;
uint64_t totalRemain = 0;
const struct dirent* dirEntry;
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while ((dirEntry = readdir(dir))) {
const char* entryName = dirEntry->d_name;
#ifdef HAVE_OPENAT
int entryFd = openat(dirfd(dir), entryName, O_DIRECTORY | O_PATH);
if (entryFd < 0)
continue;
#else
char entryFd[4096];
xSnprintf(entryFd, sizeof(entryFd), SYS_POWERSUPPLY_DIR "/%s", entryName);
#endif
enum { AC, BAT } type;
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if (String_startsWith(entryName, "BAT")) {
type = BAT;
} else if (String_startsWith(entryName, "AC")) {
type = AC;
} else {
char buffer[32];
ssize_t ret = xReadfileat(entryFd, "type", buffer, sizeof(buffer));
if (ret <= 0)
goto next;
/* drop optional trailing newlines */
for (char* buf = &buffer[(size_t)ret - 1]; *buf == '\n'; buf--)
*buf = '\0';
if (String_eq(buffer, "Battery"))
type = BAT;
else if (String_eq(buffer, "Mains"))
type = AC;
else
goto next;
}
if (type == BAT) {
char buffer[1024];
ssize_t r = xReadfileat(entryFd, "uevent", buffer, sizeof(buffer));
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if (r < 0)
goto next;
bool full = false;
bool now = false;
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double fullCharge = 0;
double capacityLevel = NAN;
const char* line;
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char* buf = buffer;
while ((line = strsep(&buf, "\n")) != NULL) {
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char field[100] = {0};
int val = 0;
if (2 != sscanf(line, "POWER_SUPPLY_%99[^=]=%d", field, &val))
continue;
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if (String_eq(field, "CAPACITY")) {
capacityLevel = val / 100.0;
continue;
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}
if (String_eq(field, "ENERGY_FULL") || String_eq(field, "CHARGE_FULL")) {
fullCharge = val;
totalFull += fullCharge;
full = true;
if (now)
break;
continue;
}
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if (String_eq(field, "ENERGY_NOW") || String_eq(field, "CHARGE_NOW")) {
totalRemain += val;
now = true;
if (full)
break;
continue;
}
}
if (!now && full && !isnan(capacityLevel))
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totalRemain += capacityLevel * fullCharge;
} else if (type == AC) {
if (*isOnAC != AC_ERROR)
goto next;
char buffer[2];
ssize_t r = xReadfileat(entryFd, "online", buffer, sizeof(buffer));
if (r < 1) {
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*isOnAC = AC_ERROR;
goto next;
}
if (buffer[0] == '0')
*isOnAC = AC_ABSENT;
else if (buffer[0] == '1')
*isOnAC = AC_PRESENT;
}
next:
Compat_openatArgClose(entryFd);
}
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closedir(dir);
*percent = totalFull > 0 ? ((double) totalRemain * 100.0) / (double) totalFull : NAN;
}
void Platform_getBattery(double* percent, ACPresence* isOnAC) {
time_t now = time(NULL);
// update battery reading is slow. Update it each 10 seconds only.
if (now < Platform_Battery_cacheTime + 10) {
*percent = Platform_Battery_cachePercent;
*isOnAC = Platform_Battery_cacheIsOnAC;
return;
}
if (Platform_Battery_method == BAT_PROC) {
Platform_Battery_getProcData(percent, isOnAC);
if (isnan(*percent))
Platform_Battery_method = BAT_SYS;
}
if (Platform_Battery_method == BAT_SYS) {
Platform_Battery_getSysData(percent, isOnAC);
if (isnan(*percent))
Platform_Battery_method = BAT_ERR;
}
if (Platform_Battery_method == BAT_ERR) {
*percent = NAN;
*isOnAC = AC_ERROR;
} else {
*percent = CLAMP(*percent, 0.0, 100.0);
}
Platform_Battery_cachePercent = *percent;
Platform_Battery_cacheIsOnAC = *isOnAC;
Platform_Battery_cacheTime = now;
}
void Platform_longOptionsUsage(const char* name)
{
#ifdef HAVE_LIBCAP
printf(
" --drop-capabilities[=off|basic|strict] Drop Linux capabilities when running as root\n"
" off - do not drop any capabilities\n"
" basic (default) - drop all capabilities not needed by %s\n"
" strict - drop all capabilities except those needed for\n"
" core functionality\n", name);
#else
(void) name;
#endif
}
CommandLineStatus Platform_getLongOption(int opt, int argc, char** argv) {
#ifndef HAVE_LIBCAP
(void) argc;
(void) argv;
#endif
switch (opt) {
#ifdef HAVE_LIBCAP
case 160: {
const char* mode = optarg;
if (!mode && optind < argc && argv[optind] != NULL &&
(argv[optind][0] != '\0' && argv[optind][0] != '-')) {
mode = argv[optind++];
}
if (!mode || String_eq(mode, "basic")) {
Platform_capabilitiesMode = CAP_MODE_BASIC;
} else if (String_eq(mode, "off")) {
Platform_capabilitiesMode = CAP_MODE_OFF;
} else if (String_eq(mode, "strict")) {
Platform_capabilitiesMode = CAP_MODE_STRICT;
} else {
fprintf(stderr, "Error: invalid capabilities mode \"%s\".\n", mode);
return STATUS_ERROR_EXIT;
}
return STATUS_OK;
}
#endif
default:
break;
}
return STATUS_ERROR_EXIT;
}
#ifdef HAVE_LIBCAP
static int dropCapabilities(enum CapMode mode) {
if (mode == CAP_MODE_OFF)
return 0;
/* capabilities we keep to operate */
const cap_value_t keepcapsStrict[] = {
CAP_DAC_READ_SEARCH,
CAP_SYS_PTRACE,
};
const cap_value_t keepcapsBasic[] = {
CAP_DAC_READ_SEARCH, /* read non world-readable process files of other users, like /proc/[pid]/io */
CAP_KILL, /* send signals to processes of other users */
CAP_SYS_NICE, /* lower process nice value / change nice value for arbitrary processes */
CAP_SYS_PTRACE, /* read /proc/[pid]/exe */
#ifdef HAVE_DELAYACCT
CAP_NET_ADMIN, /* communicate over netlink socket for delay accounting */
#endif
};
const cap_value_t* const keepcaps = (mode == CAP_MODE_BASIC) ? keepcapsBasic : keepcapsStrict;
const size_t ncap = (mode == CAP_MODE_BASIC) ? ARRAYSIZE(keepcapsBasic) : ARRAYSIZE(keepcapsStrict);
cap_t caps = cap_init();
if (caps == NULL) {
fprintf(stderr, "Error: can not initialize capabilities: %s\n", strerror(errno));
return -1;
}
if (cap_clear(caps) < 0) {
fprintf(stderr, "Error: can not clear capabilities: %s\n", strerror(errno));
cap_free(caps);
return -1;
}
cap_t currCaps = cap_get_proc();
if (currCaps == NULL) {
fprintf(stderr, "Error: can not get current process capabilities: %s\n", strerror(errno));
cap_free(caps);
return -1;
}
for (size_t i = 0; i < ncap; i++) {
if (!CAP_IS_SUPPORTED(keepcaps[i]))
continue;
cap_flag_value_t current;
if (cap_get_flag(currCaps, keepcaps[i], CAP_PERMITTED, &current) < 0) {
fprintf(stderr, "Error: can not get current value of capability %d: %s\n", keepcaps[i], strerror(errno));
cap_free(currCaps);
cap_free(caps);
return -1;
}
if (current != CAP_SET)
continue;
if (cap_set_flag(caps, CAP_PERMITTED, 1, &keepcaps[i], CAP_SET) < 0) {
fprintf(stderr, "Error: can not set permitted capability %d: %s\n", keepcaps[i], strerror(errno));
cap_free(currCaps);
cap_free(caps);
return -1;
}
if (cap_set_flag(caps, CAP_EFFECTIVE, 1, &keepcaps[i], CAP_SET) < 0) {
fprintf(stderr, "Error: can not set effective capability %d: %s\n", keepcaps[i], strerror(errno));
cap_free(currCaps);
cap_free(caps);
return -1;
}
}
if (cap_set_proc(caps) < 0) {
fprintf(stderr, "Error: can not set process capabilities: %s\n", strerror(errno));
cap_free(currCaps);
cap_free(caps);
return -1;
}
cap_free(currCaps);
cap_free(caps);
return 0;
}
#endif
bool Platform_init(void) {
#ifdef HAVE_LIBCAP
if (dropCapabilities(Platform_capabilitiesMode) < 0)
return false;
#endif
if (access(PROCDIR, R_OK) != 0) {
fprintf(stderr, "Error: could not read procfs (compiled to look in %s).\n", PROCDIR);
return false;
}
#ifdef HAVE_SENSORS_SENSORS_H
LibSensors_init();
#endif
char target[PATH_MAX];
ssize_t ret = readlink(PROCDIR "/self/ns/pid", target, sizeof(target) - 1);
if (ret > 0) {
target[ret] = '\0';
if (!String_eq("pid:[4026531836]", target)) { // magic constant PROC_PID_INIT_INO from include/linux/proc_ns.h#L46
Running_containerized = true;
return true; // early return
}
}
FILE* fd = fopen(PROCDIR "/1/mounts", "r");
if (fd) {
char lineBuffer[256];
while (fgets(lineBuffer, sizeof(lineBuffer), fd)) {
// detect lxc or overlayfs and guess that this means we are running containerized
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if (String_startsWith(lineBuffer, "lxcfs /proc") || String_startsWith(lineBuffer, "overlay ")) {
Running_containerized = true;
break;
}
}
fclose(fd);
} // if (fd)
return true;
}
void Platform_done(void) {
#ifdef HAVE_SENSORS_SENSORS_H
LibSensors_cleanup();
#endif
}