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khenaidooab1f7bd2019-11-14 14:00:27 -05001// Copyright 2018 The Prometheus Authors
2// Licensed under the Apache License, Version 2.0 (the "License");
3// you may not use this file except in compliance with the License.
4// You may obtain a copy of the License at
5//
6// http://www.apache.org/licenses/LICENSE-2.0
7//
8// Unless required by applicable law or agreed to in writing, software
9// distributed under the License is distributed on an "AS IS" BASIS,
10// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
11// See the License for the specific language governing permissions and
12// limitations under the License.
13
14package procfs
15
16import (
17 "bytes"
18 "fmt"
19 "io/ioutil"
20 "os"
21
22 "github.com/prometheus/procfs/internal/fs"
23)
24
25// Originally, this USER_HZ value was dynamically retrieved via a sysconf call
26// which required cgo. However, that caused a lot of problems regarding
27// cross-compilation. Alternatives such as running a binary to determine the
28// value, or trying to derive it in some other way were all problematic. After
29// much research it was determined that USER_HZ is actually hardcoded to 100 on
30// all Go-supported platforms as of the time of this writing. This is why we
31// decided to hardcode it here as well. It is not impossible that there could
32// be systems with exceptions, but they should be very exotic edge cases, and
33// in that case, the worst outcome will be two misreported metrics.
34//
35// See also the following discussions:
36//
37// - https://github.com/prometheus/node_exporter/issues/52
38// - https://github.com/prometheus/procfs/pull/2
39// - http://stackoverflow.com/questions/17410841/how-does-user-hz-solve-the-jiffy-scaling-issue
40const userHZ = 100
41
42// ProcStat provides status information about the process,
43// read from /proc/[pid]/stat.
44type ProcStat struct {
45 // The process ID.
46 PID int
47 // The filename of the executable.
48 Comm string
49 // The process state.
50 State string
51 // The PID of the parent of this process.
52 PPID int
53 // The process group ID of the process.
54 PGRP int
55 // The session ID of the process.
56 Session int
57 // The controlling terminal of the process.
58 TTY int
59 // The ID of the foreground process group of the controlling terminal of
60 // the process.
61 TPGID int
62 // The kernel flags word of the process.
63 Flags uint
64 // The number of minor faults the process has made which have not required
65 // loading a memory page from disk.
66 MinFlt uint
67 // The number of minor faults that the process's waited-for children have
68 // made.
69 CMinFlt uint
70 // The number of major faults the process has made which have required
71 // loading a memory page from disk.
72 MajFlt uint
73 // The number of major faults that the process's waited-for children have
74 // made.
75 CMajFlt uint
76 // Amount of time that this process has been scheduled in user mode,
77 // measured in clock ticks.
78 UTime uint
79 // Amount of time that this process has been scheduled in kernel mode,
80 // measured in clock ticks.
81 STime uint
82 // Amount of time that this process's waited-for children have been
83 // scheduled in user mode, measured in clock ticks.
84 CUTime uint
85 // Amount of time that this process's waited-for children have been
86 // scheduled in kernel mode, measured in clock ticks.
87 CSTime uint
88 // For processes running a real-time scheduling policy, this is the negated
89 // scheduling priority, minus one.
90 Priority int
91 // The nice value, a value in the range 19 (low priority) to -20 (high
92 // priority).
93 Nice int
94 // Number of threads in this process.
95 NumThreads int
96 // The time the process started after system boot, the value is expressed
97 // in clock ticks.
98 Starttime uint64
99 // Virtual memory size in bytes.
100 VSize uint
101 // Resident set size in pages.
102 RSS int
103
104 proc fs.FS
105}
106
107// NewStat returns the current status information of the process.
108//
109// Deprecated: use NewStat() instead
110func (p Proc) NewStat() (ProcStat, error) {
111 return p.Stat()
112}
113
114// Stat returns the current status information of the process.
115func (p Proc) Stat() (ProcStat, error) {
116 f, err := os.Open(p.path("stat"))
117 if err != nil {
118 return ProcStat{}, err
119 }
120 defer f.Close()
121
122 data, err := ioutil.ReadAll(f)
123 if err != nil {
124 return ProcStat{}, err
125 }
126
127 var (
128 ignore int
129
130 s = ProcStat{PID: p.PID, proc: p.fs}
131 l = bytes.Index(data, []byte("("))
132 r = bytes.LastIndex(data, []byte(")"))
133 )
134
135 if l < 0 || r < 0 {
136 return ProcStat{}, fmt.Errorf(
137 "unexpected format, couldn't extract comm: %s",
138 data,
139 )
140 }
141
142 s.Comm = string(data[l+1 : r])
143 _, err = fmt.Fscan(
144 bytes.NewBuffer(data[r+2:]),
145 &s.State,
146 &s.PPID,
147 &s.PGRP,
148 &s.Session,
149 &s.TTY,
150 &s.TPGID,
151 &s.Flags,
152 &s.MinFlt,
153 &s.CMinFlt,
154 &s.MajFlt,
155 &s.CMajFlt,
156 &s.UTime,
157 &s.STime,
158 &s.CUTime,
159 &s.CSTime,
160 &s.Priority,
161 &s.Nice,
162 &s.NumThreads,
163 &ignore,
164 &s.Starttime,
165 &s.VSize,
166 &s.RSS,
167 )
168 if err != nil {
169 return ProcStat{}, err
170 }
171
172 return s, nil
173}
174
175// VirtualMemory returns the virtual memory size in bytes.
176func (s ProcStat) VirtualMemory() uint {
177 return s.VSize
178}
179
180// ResidentMemory returns the resident memory size in bytes.
181func (s ProcStat) ResidentMemory() int {
182 return s.RSS * os.Getpagesize()
183}
184
185// StartTime returns the unix timestamp of the process in seconds.
186func (s ProcStat) StartTime() (float64, error) {
187 fs := FS{proc: s.proc}
188 stat, err := fs.Stat()
189 if err != nil {
190 return 0, err
191 }
192 return float64(stat.BootTime) + (float64(s.Starttime) / userHZ), nil
193}
194
195// CPUTime returns the total CPU user and system time in seconds.
196func (s ProcStat) CPUTime() float64 {
197 return float64(s.UTime+s.STime) / userHZ
198}