xmtop/main.go
Jaron Swab 7ff732e06e Added sigterm options to "d" command.
This should satisfy issue #13 (at least in part).
`main.go` now has cases for "dd", "d3", and "d9".
"d3" is "sigquit" and "d9" is "sigkill".

`KillProc()` now takes a string as an arugment to perferm desired kill
action using `--signal`.

`help.go` also has been update to reflect the additions.
2019-10-03 20:59:22 -04:00

472 lines
11 KiB
Go

package main
import (
"encoding/json"
"fmt"
"io/ioutil"
"log"
"os"
"os/signal"
"path/filepath"
"sort"
"strconv"
"syscall"
"time"
docopt "github.com/docopt/docopt.go"
ui "github.com/gizak/termui/v3"
"github.com/cjbassi/gotop/colorschemes"
"github.com/cjbassi/gotop/src/logging"
"github.com/cjbassi/gotop/src/utils"
w "github.com/cjbassi/gotop/src/widgets"
)
const (
appName = "gotop"
version = "3.0.0"
graphHorizontalScaleDelta = 3
)
var (
configDir = utils.GetConfigDir(appName)
logDir = utils.GetLogDir(appName)
logPath = filepath.Join(logDir, "errors.log")
stderrLogger = log.New(os.Stderr, "", 0)
graphHorizontalScale = 7
helpVisible = false
colorscheme = colorschemes.Default
updateInterval = time.Second
minimalMode = false
averageLoad = false
percpuLoad = false
tempScale = w.Celcius
battery = false
statusbar = false
netInterface = w.NET_INTERFACE_ALL
cpu *w.CpuWidget
batt *w.BatteryWidget
mem *w.MemWidget
proc *w.ProcWidget
net *w.NetWidget
disk *w.DiskWidget
temp *w.TempWidget
help *w.HelpMenu
grid *ui.Grid
bar *w.StatusBar
)
func parseArgs() error {
usage := `
Usage: gotop [options]
Options:
-c, --color=NAME Set a colorscheme.
-h, --help Show this screen.
-m, --minimal Only show CPU, Mem and Process widgets.
-r, --rate=RATE Number of times per second to update CPU and Mem widgets [default: 1].
-V, --version Print version and exit.
-p, --percpu Show each CPU in the CPU widget.
-a, --averagecpu Show average CPU in the CPU widget.
-f, --fahrenheit Show temperatures in fahrenheit.
-s, --statusbar Show a statusbar with the time.
-b, --battery Show battery level widget ('minimal' turns off).
-i, --interface=NAME Select network interface [default: all].
Colorschemes:
default
default-dark (for white background)
solarized
monokai
vice
`
args, err := docopt.ParseArgs(usage, os.Args[1:], version)
if err != nil {
return err
}
if val, _ := args["--color"]; val != nil {
if err := handleColorscheme(val.(string)); err != nil {
return err
}
}
averageLoad, _ = args["--averagecpu"].(bool)
percpuLoad, _ = args["--percpu"].(bool)
battery, _ = args["--battery"].(bool)
minimalMode, _ = args["--minimal"].(bool)
statusbar, _ = args["--statusbar"].(bool)
rateStr, _ := args["--rate"].(string)
rate, err := strconv.ParseFloat(rateStr, 64)
if err != nil {
return fmt.Errorf("invalid rate parameter")
}
if rate < 1 {
updateInterval = time.Second * time.Duration(1/rate)
} else {
updateInterval = time.Second / time.Duration(rate)
}
fahrenheit, _ := args["--fahrenheit"].(bool)
if fahrenheit {
tempScale = w.Fahrenheit
}
netInterface, _ = args["--interface"].(string)
return nil
}
func handleColorscheme(cs string) error {
switch cs {
case "default":
colorscheme = colorschemes.Default
case "solarized":
colorscheme = colorschemes.Solarized
case "monokai":
colorscheme = colorschemes.Monokai
case "vice":
colorscheme = colorschemes.Vice
case "default-dark":
colorscheme = colorschemes.DefaultDark
default:
custom, err := getCustomColorscheme(cs)
if err != nil {
return err
}
colorscheme = custom
}
return nil
}
// getCustomColorscheme tries to read a custom json colorscheme from <configDir>/<name>.json
func getCustomColorscheme(name string) (colorschemes.Colorscheme, error) {
var colorscheme colorschemes.Colorscheme
filePath := filepath.Join(configDir, name+".json")
dat, err := ioutil.ReadFile(filePath)
if err != nil {
return colorscheme, fmt.Errorf("failed to read colorscheme file: %v", err)
}
err = json.Unmarshal(dat, &colorscheme)
if err != nil {
return colorscheme, fmt.Errorf("failed to parse colorscheme file: %v", err)
}
return colorscheme, nil
}
func setupGrid() {
grid = ui.NewGrid()
if minimalMode {
grid.Set(
ui.NewRow(1.0/2, cpu),
ui.NewRow(1.0/2,
ui.NewCol(1.0/2, mem),
ui.NewCol(1.0/2, proc),
),
)
} else {
var cpuRow ui.GridItem
if battery {
cpuRow = ui.NewRow(1.0/3,
ui.NewCol(2.0/3, cpu),
ui.NewCol(1.0/3, batt),
)
} else {
cpuRow = ui.NewRow(1.0/3, cpu)
}
grid.Set(
cpuRow,
ui.NewRow(1.0/3,
ui.NewCol(1.0/3,
ui.NewRow(1.0/2, disk),
ui.NewRow(1.0/2, temp),
),
ui.NewCol(2.0/3, mem),
),
ui.NewRow(1.0/3,
ui.NewCol(1.0/2, net),
ui.NewCol(1.0/2, proc),
),
)
}
}
func setDefaultTermuiColors() {
ui.Theme.Default = ui.NewStyle(ui.Color(colorscheme.Fg), ui.Color(colorscheme.Bg))
ui.Theme.Block.Title = ui.NewStyle(ui.Color(colorscheme.BorderLabel), ui.Color(colorscheme.Bg))
ui.Theme.Block.Border = ui.NewStyle(ui.Color(colorscheme.BorderLine), ui.Color(colorscheme.Bg))
}
func setWidgetColors() {
mem.LineColors["Main"] = ui.Color(colorscheme.MainMem)
mem.LineColors["Swap"] = ui.Color(colorscheme.SwapMem)
proc.CursorColor = ui.Color(colorscheme.ProcCursor)
var keys []string
for key := range cpu.Data {
keys = append(keys, key)
}
sort.Strings(keys)
i := 0
for _, v := range keys {
if i >= len(colorscheme.CPULines) {
// assuming colorscheme for CPU lines is not empty
i = 0
}
c := colorscheme.CPULines[i]
cpu.LineColors[v] = ui.Color(c)
i++
}
if !minimalMode {
if battery {
var battKeys []string
for key := range batt.Data {
battKeys = append(battKeys, key)
}
sort.Strings(battKeys)
i = 0 // Re-using variable from CPU
for _, v := range battKeys {
if i >= len(colorscheme.BattLines) {
// assuming colorscheme for battery lines is not empty
i = 0
}
c := colorscheme.BattLines[i]
batt.LineColors[v] = ui.Color(c)
i++
}
}
temp.TempLowColor = ui.Color(colorscheme.TempLow)
temp.TempHighColor = ui.Color(colorscheme.TempHigh)
net.Lines[0].LineColor = ui.Color(colorscheme.Sparkline)
net.Lines[0].TitleColor = ui.Color(colorscheme.BorderLabel)
net.Lines[1].LineColor = ui.Color(colorscheme.Sparkline)
net.Lines[1].TitleColor = ui.Color(colorscheme.BorderLabel)
}
}
func initWidgets() {
cpu = w.NewCpuWidget(updateInterval, graphHorizontalScale, averageLoad, percpuLoad)
mem = w.NewMemWidget(updateInterval, graphHorizontalScale)
proc = w.NewProcWidget()
help = w.NewHelpMenu()
if !minimalMode {
if battery {
batt = w.NewBatteryWidget(graphHorizontalScale)
}
net = w.NewNetWidget(netInterface)
disk = w.NewDiskWidget()
temp = w.NewTempWidget(tempScale)
}
if statusbar {
bar = w.NewStatusBar()
}
}
func eventLoop() {
drawTicker := time.NewTicker(updateInterval).C
// handles kill signal sent to gotop
sigTerm := make(chan os.Signal, 2)
signal.Notify(sigTerm, os.Interrupt, syscall.SIGTERM)
uiEvents := ui.PollEvents()
previousKey := ""
for {
select {
case <-sigTerm:
return
case <-drawTicker:
if !helpVisible {
ui.Render(grid)
if statusbar {
ui.Render(bar)
}
}
case e := <-uiEvents:
switch e.ID {
case "q", "<C-c>":
return
case "?":
helpVisible = !helpVisible
case "<Resize>":
payload := e.Payload.(ui.Resize)
termWidth, termHeight := payload.Width, payload.Height
if statusbar {
grid.SetRect(0, 0, termWidth, termHeight-1)
bar.SetRect(0, termHeight-1, termWidth, termHeight)
} else {
grid.SetRect(0, 0, payload.Width, payload.Height)
}
help.Resize(payload.Width, payload.Height)
ui.Clear()
}
if helpVisible {
switch e.ID {
case "?":
ui.Clear()
ui.Render(help)
case "<Escape>":
helpVisible = false
ui.Render(grid)
case "<Resize>":
ui.Render(help)
}
} else {
switch e.ID {
case "?":
ui.Render(grid)
case "h":
graphHorizontalScale += graphHorizontalScaleDelta
cpu.HorizontalScale = graphHorizontalScale
mem.HorizontalScale = graphHorizontalScale
ui.Render(cpu, mem)
case "l":
if graphHorizontalScale > graphHorizontalScaleDelta {
graphHorizontalScale -= graphHorizontalScaleDelta
cpu.HorizontalScale = graphHorizontalScale
mem.HorizontalScale = graphHorizontalScale
ui.Render(cpu, mem)
}
case "<Resize>":
ui.Render(grid)
if statusbar {
ui.Render(bar)
}
case "<MouseLeft>":
payload := e.Payload.(ui.Mouse)
proc.HandleClick(payload.X, payload.Y)
ui.Render(proc)
case "k", "<Up>", "<MouseWheelUp>":
proc.ScrollUp()
ui.Render(proc)
case "j", "<Down>", "<MouseWheelDown>":
proc.ScrollDown()
ui.Render(proc)
case "<Home>":
proc.ScrollTop()
ui.Render(proc)
case "g":
if previousKey == "g" {
proc.ScrollTop()
ui.Render(proc)
}
case "G", "<End>":
proc.ScrollBottom()
ui.Render(proc)
case "<C-d>":
proc.ScrollHalfPageDown()
ui.Render(proc)
case "<C-u>":
proc.ScrollHalfPageUp()
ui.Render(proc)
case "<C-f>":
proc.ScrollPageDown()
ui.Render(proc)
case "<C-b>":
proc.ScrollPageUp()
ui.Render(proc)
case "d":
if previousKey == "d" {
proc.KillProc("SIGTERM")
}
case "3":
if previousKey == "d" {
proc.KillProc("SIGQUIT")
}
case "9":
if previousKey == "d" {
proc.KillProc("SIGKILL")
}
case "<Tab>":
proc.ToggleShowingGroupedProcs()
ui.Render(proc)
case "m", "c", "p":
proc.ChangeProcSortMethod(w.ProcSortMethod(e.ID))
ui.Render(proc)
}
if previousKey == e.ID {
previousKey = ""
} else {
previousKey = e.ID
}
}
}
}
}
func setupLogfile() (*os.File, error) {
// create the log directory
if err := os.MkdirAll(logDir, 0755); err != nil {
return nil, fmt.Errorf("failed to make the log directory: %v", err)
}
// open the log file
logfile, err := os.OpenFile(logPath, os.O_CREATE|os.O_WRONLY|os.O_TRUNC, 0660)
if err != nil {
return nil, fmt.Errorf("failed to open log file: %v", err)
}
// log time, filename, and line number
log.SetFlags(log.Ltime | log.Lshortfile)
// log to file
log.SetOutput(logfile)
return logfile, nil
}
func main() {
if err := parseArgs(); err != nil {
stderrLogger.Fatalf("failed to parse cli args: %v", err)
}
logfile, err := setupLogfile()
if err != nil {
stderrLogger.Fatalf("failed to setup log file: %v", err)
}
defer logfile.Close()
if err := ui.Init(); err != nil {
stderrLogger.Fatalf("failed to initialize termui: %v", err)
}
defer ui.Close()
logging.StderrToLogfile(logfile)
setDefaultTermuiColors() // done before initializing widgets to allow inheriting colors
initWidgets()
setWidgetColors()
setupGrid()
termWidth, termHeight := ui.TerminalDimensions()
if statusbar {
grid.SetRect(0, 0, termWidth, termHeight-1)
} else {
grid.SetRect(0, 0, termWidth, termHeight)
}
help.Resize(termWidth, termHeight)
ui.Render(grid)
if statusbar {
bar.SetRect(0, termHeight-1, termWidth, termHeight)
ui.Render(bar)
}
eventLoop()
}