termui/_examples/dashboard2.go

371 lines
7.8 KiB
Go

// Copyright 2017 Zack Guo <zack.y.guo@gmail.com>. All rights reserved.
// Use of this source code is governed by a MIT license that can
// be found in the LICENSE file.
// +build ignore
package main
import (
"bufio"
"errors"
"fmt"
"image"
"io"
"log"
"os"
"regexp"
"runtime"
"sort"
"strconv"
"strings"
"time"
ui "github.com/gizak/termui"
"github.com/gizak/termui/widgets"
)
const statFilePath = "/proc/stat"
const meminfoFilePath = "/proc/meminfo"
type CpuStat struct {
user float32
nice float32
system float32
idle float32
}
type CpusStats struct {
stat map[string]CpuStat
proc map[string]CpuStat
}
func NewCpusStats(s map[string]CpuStat) *CpusStats {
return &CpusStats{stat: s, proc: make(map[string]CpuStat)}
}
func (cs *CpusStats) String() (ret string) {
for key, _ := range cs.proc {
ret += fmt.Sprintf("%s: %.2f %.2f %.2f %.2f\n", key, cs.proc[key].user, cs.proc[key].nice, cs.proc[key].system, cs.proc[key].idle)
}
return
}
func subCpuStat(m CpuStat, s CpuStat) CpuStat {
return CpuStat{user: m.user - s.user,
nice: m.nice - s.nice,
system: m.system - s.system,
idle: m.idle - s.idle}
}
func procCpuStat(c CpuStat) CpuStat {
sum := c.user + c.nice + c.system + c.idle
return CpuStat{user: c.user / sum * 100,
nice: c.nice / sum * 100,
system: c.system / sum * 100,
idle: c.idle / sum * 100}
}
func (cs *CpusStats) tick(ns map[string]CpuStat) {
for key, _ := range cs.stat {
proc := subCpuStat(ns[key], cs.stat[key])
cs.proc[key] = procCpuStat(proc)
cs.stat[key] = ns[key]
}
}
type errIntParser struct {
err error
}
func (eip *errIntParser) parse(s string) (ret int64) {
if eip.err != nil {
return 0
}
ret, eip.err = strconv.ParseInt(s, 10, 0)
return
}
type LineProcessor interface {
process(string) error
finalize() interface{}
}
type CpuLineProcessor struct {
m map[string]CpuStat
}
func (clp *CpuLineProcessor) process(line string) (err error) {
r := regexp.MustCompile("^cpu([0-9]*)")
if r.MatchString(line) {
tab := strings.Fields(line)
if len(tab) < 5 {
err = errors.New("cpu info line has not enough fields")
return
}
parser := errIntParser{}
cs := CpuStat{user: float32(parser.parse(tab[1])),
nice: float32(parser.parse(tab[2])),
system: float32(parser.parse(tab[3])),
idle: float32(parser.parse(tab[4]))}
clp.m[tab[0]] = cs
err = parser.err
if err != nil {
return
}
}
return
}
func (clp *CpuLineProcessor) finalize() interface{} {
return clp.m
}
type MemStat struct {
total int64
free int64
}
func (ms MemStat) String() (ret string) {
ret = fmt.Sprintf("TotalMem: %d, FreeMem: %d\n", ms.total, ms.free)
return
}
func (ms *MemStat) process(line string) (err error) {
rtotal := regexp.MustCompile("^MemTotal:")
rfree := regexp.MustCompile("^MemFree:")
var aux int64
if rtotal.MatchString(line) || rfree.MatchString(line) {
tab := strings.Fields(line)
if len(tab) < 3 {
err = errors.New("mem info line has not enough fields")
return
}
aux, err = strconv.ParseInt(tab[1], 10, 0)
}
if err != nil {
return
}
if rtotal.MatchString(line) {
ms.total = aux
}
if rfree.MatchString(line) {
ms.free = aux
}
return
}
func (ms *MemStat) finalize() interface{} {
return *ms
}
func processFileLines(filePath string, lp LineProcessor) (ret interface{}, err error) {
var statFile *os.File
statFile, err = os.Open(filePath)
if err != nil {
fmt.Printf("open: %v\n", err)
}
defer statFile.Close()
statFileReader := bufio.NewReader(statFile)
for {
var line string
line, err = statFileReader.ReadString('\n')
if err == io.EOF {
err = nil
break
}
if err != nil {
fmt.Printf("open: %v\n", err)
break
}
line = strings.TrimSpace(line)
err = lp.process(line)
}
ret = lp.finalize()
return
}
func getCpusStatsMap() (m map[string]CpuStat, err error) {
var aux interface{}
aux, err = processFileLines(statFilePath, &CpuLineProcessor{m: make(map[string]CpuStat)})
return aux.(map[string]CpuStat), err
}
func getMemStats() (ms MemStat, err error) {
var aux interface{}
aux, err = processFileLines(meminfoFilePath, &MemStat{})
return aux.(MemStat), err
}
type CpuTabElems struct {
GMap map[string]*widgets.Gauge
LChart *widgets.LineChart
}
func NewCpuTabElems(width int) *CpuTabElems {
lc := widgets.NewLineChart()
lc.SetRect(0, 0, width, 12)
lc.LineType = widgets.DotLine
lc.Title = "CPU"
return &CpuTabElems{
GMap: make(map[string]*widgets.Gauge),
LChart: lc,
}
}
func (cte *CpuTabElems) AddGauge(key string, Y int, width int) *widgets.Gauge {
cte.GMap[key] = widgets.NewGauge()
cte.GMap[key].SetRect(0, Y, width, Y+3)
cte.GMap[key].Title = key
cte.GMap[key].Percent = 0 //int(val.user + val.nice + val.system)
return cte.GMap[key]
}
func (cte *CpuTabElems) Update(cs CpusStats) {
for key, val := range cs.proc {
p := int(val.user + val.nice + val.system)
cte.GMap[key].Percent = p
if key == "cpu" {
cte.LChart.Data = append(cte.LChart.Data, []float64{})
cte.LChart.Data[0] = append(cte.LChart.Data[0], 0)
copy(cte.LChart.Data[0][1:], cte.LChart.Data[0][0:])
cte.LChart.Data[0][0] = float64(p)
}
}
}
type MemTabElems struct {
Gauge *widgets.Gauge
SLines *widgets.SparklineGroup
}
func NewMemTabElems(width int) *MemTabElems {
g := widgets.NewGauge()
g.SetRect(0, 5, width, 10)
sline := widgets.NewSparkline()
sline.Title = "MEM"
sls := widgets.NewSparklineGroup(sline)
sls.SetRect(0, 10, width, 25)
return &MemTabElems{Gauge: g, SLines: sls}
}
func (mte *MemTabElems) Update(ms MemStat) {
used := (ms.total - ms.free) * 100 / ms.total
mte.Gauge.Percent = int(used)
mte.SLines.Sparklines[0].Data = append(mte.SLines.Sparklines[0].Data, 0)
copy(mte.SLines.Sparklines[0].Data[1:], mte.SLines.Sparklines[0].Data[0:])
mte.SLines.Sparklines[0].Data[0] = float64(used)
if len(mte.SLines.Sparklines[0].Data) > mte.SLines.Dx()-2 {
mte.SLines.Sparklines[0].Data = mte.SLines.Sparklines[0].Data[0 : mte.SLines.Dx()-2]
}
}
func main() {
if runtime.GOOS != "linux" {
log.Fatalf("Currently only works on Linux")
}
if err := ui.Init(); err != nil {
log.Fatalf("failed to initialize termui: %v", err)
}
defer ui.Close()
termWidth := 70
header := widgets.NewParagraph()
header.Text = "Press q to quit, Press h or l to switch tabs"
header.SetRect(0, 0, 50, 1)
header.Border = false
header.TextStyle.Bg = ui.ColorBlue
cs, errcs := getCpusStatsMap()
cpusStats := NewCpusStats(cs)
if errcs != nil {
panic("error")
}
cpuTabElems := NewCpuTabElems(termWidth)
Y := 5
cpuKeys := make([]string, 0, len(cs))
for key := range cs {
cpuKeys = append(cpuKeys, key)
}
sort.Strings(cpuKeys)
for _, key := range cpuKeys {
cpuTabElems.AddGauge(key, Y, termWidth)
Y += 3
}
cpuTabElems.LChart.Rectangle = cpuTabElems.LChart.GetRect().Add(image.Pt(0, Y))
memTabElems := NewMemTabElems(termWidth)
ms, errm := getMemStats()
if errm != nil {
panic(errm)
}
memTabElems.Update(ms)
tabpane := widgets.NewTabPane("CPU", "MEM")
tabpane.SetRect(0, 1, 30, 30)
tabpane.Border = false
renderTab := func() {
switch tabpane.ActiveTabIndex {
case 0:
ui.Render(cpuTabElems.LChart)
for _, gauge := range cpuTabElems.GMap {
ui.Render(gauge)
}
case 1:
ui.Render(memTabElems.Gauge, memTabElems.SLines)
}
}
ui.Render(header, tabpane)
renderTab()
tickerCount := 1
uiEvents := ui.PollEvents()
ticker := time.NewTicker(time.Second).C
for {
select {
case e := <-uiEvents:
switch e.ID {
case "q", "<C-c>":
return
case "h":
tabpane.FocusLeft()
ui.Render(header, tabpane)
renderTab()
case "l":
tabpane.FocusRight()
ui.Render(header, tabpane)
renderTab()
}
case <-ticker:
cs, errcs := getCpusStatsMap()
if errcs != nil {
panic(errcs)
}
cpusStats.tick(cs)
cpuTabElems.Update(*cpusStats)
ms, errm := getMemStats()
if errm != nil {
panic(errm)
}
memTabElems.Update(ms)
ui.Render(header, tabpane)
renderTab()
tickerCount++
}
}
}