575 lines
15 KiB
Go
575 lines
15 KiB
Go
package main
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import (
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"bytes"
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"encoding/json"
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"errors"
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"fmt"
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"io"
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"net/http"
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"os"
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"os/signal"
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"sort"
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"strconv"
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"strings"
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"sync"
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"text/tabwriter"
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"time"
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"github.com/urfave/cli/v2"
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)
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var rpcCmd = &cli.Command{
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Name: "rpc",
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Usage: "Runs a concurrent stress test on one or more rpc methods and prints the performance metrics including latency distribution and histogram",
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Description: `This benchmark is designed to stress test the rpc methods of a lotus node so that we can simulate real world usage and measure the performance of rpc methods on the node.
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This benchmark has the following features:
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* Can query each method both sequentially and concurrently
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* Supports rate limiting
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* Can query multiple different endpoints at once (supporting different concurrency level and rate limiting for each method)
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* Gives a nice reporting summary of the stress testing of each method (including latency distribution, histogram and more)
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* Easy to use
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To use this benchmark you must specify the rpc methods you want to test using the --method options, the format of it is:
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--method=NAME[:CONCURRENCY][:QPS][:PARAMS] where only NAME is required.
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Here are some real examples:
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lotus-bench rpc --method='eth_chainId' // run eth_chainId with default concurrency and qps
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lotus-bench rpc --method='eth_chainId:3' // override concurrency to 3
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lotus-bench rpc --method='eth_chainId::100' // override to 100 qps while using default concurrency
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lotus-bench rpc --method='eth_chainId:3:100' // run using 3 workers but limit to 100 qps
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lotus-bench rpc --method='eth_getTransactionCount:::["0xd4c70007F3F502f212c7e6794b94C06F36173B36", "latest"]' // run using optional params while using default concurrency and qps
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lotus-bench rpc --method='eth_chainId' --method='eth_getTransactionCount:10:0:["0xd4c70007F3F502f212c7e6794b94C06F36173B36", "latest"]' // run multiple methods at once`,
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Flags: []cli.Flag{
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&cli.StringFlag{
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Name: "endpoint",
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Value: "http://127.0.0.1:1234/rpc/v1",
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Usage: "The rpc endpoint to benchmark",
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},
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&cli.DurationFlag{
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Name: "duration",
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Value: 60 * time.Second,
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Usage: "Duration of benchmark in seconds",
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},
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&cli.IntFlag{
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Name: "concurrency",
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Value: 10,
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Usage: "How many workers should be used per rpc method (can be overridden per method)",
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},
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&cli.IntFlag{
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Name: "qps",
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Value: 0,
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Usage: "How many requests per second should be sent per rpc method (can be overridden per method), a value of 0 means no limit",
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},
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&cli.StringSliceFlag{
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Name: "method",
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Usage: `Method to benchmark, you can specify multiple methods by repeating this flag. You can also specify method specific options to set the concurrency and qps for each method (see usage).
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`,
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},
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&cli.DurationFlag{
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Name: "watch",
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Value: 0 * time.Second,
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Usage: "If >0 then generates reports every N seconds (only supports linux/unix)",
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},
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&cli.BoolFlag{
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Name: "print-response",
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Value: false,
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Usage: "print the response of each request",
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},
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},
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Action: func(cctx *cli.Context) error {
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if len(cctx.StringSlice("method")) == 0 {
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return errors.New("you must specify and least one method to benchmark")
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}
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var rpcMethods []*RPCMethod
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for _, str := range cctx.StringSlice("method") {
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entries := strings.SplitN(str, ":", 4)
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if len(entries) == 0 {
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return errors.New("invalid method format")
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}
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// check if concurrency was specified
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concurrency := cctx.Int("concurrency")
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if len(entries) > 1 {
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if len(entries[1]) > 0 {
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var err error
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concurrency, err = strconv.Atoi(entries[1])
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if err != nil {
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return fmt.Errorf("could not parse concurrency value from method %s: %v", entries[0], err)
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}
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}
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}
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// check if qps was specified
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qps := cctx.Int("qps")
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if len(entries) > 2 {
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if len(entries[2]) > 0 {
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var err error
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qps, err = strconv.Atoi(entries[2])
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if err != nil {
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return fmt.Errorf("could not parse qps value from method %s: %v", entries[0], err)
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}
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}
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}
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// check if params was specified
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params := "[]"
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if len(entries) > 3 {
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params = entries[3]
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}
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rpcMethods = append(rpcMethods, &RPCMethod{
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w: os.Stdout,
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uri: cctx.String("endpoint"),
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method: entries[0],
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concurrency: concurrency,
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qps: qps,
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params: params,
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printResp: cctx.Bool("print-response"),
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})
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}
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// terminate early on ctrl+c
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c := make(chan os.Signal, 1)
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signal.Notify(c, os.Interrupt)
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go func() {
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<-c
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fmt.Println("Received interrupt, stopping...")
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for _, method := range rpcMethods {
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method.Stop()
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}
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}()
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// stop all threads after duration
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go func() {
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time.Sleep(cctx.Duration("duration"))
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for _, e := range rpcMethods {
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e.Stop()
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}
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}()
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// start all threads
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var wg sync.WaitGroup
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wg.Add(len(rpcMethods))
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for _, e := range rpcMethods {
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go func(e *RPCMethod) {
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defer wg.Done()
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err := e.Run()
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if err != nil {
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fmt.Printf("error running rpc method: %v\n", err)
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}
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}(e)
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}
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// if watch is set then print a report every N seconds
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var progressCh chan struct{}
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if cctx.Duration("watch") > 0 {
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progressCh = make(chan struct{}, 1)
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go func(progressCh chan struct{}) {
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ticker := time.NewTicker(cctx.Duration("watch"))
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for {
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clearAndPrintReport := func() {
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// clear the screen move the curser to the top left
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fmt.Print("\033[2J")
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fmt.Printf("\033[%d;%dH", 1, 1)
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for i, e := range rpcMethods {
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e.Report()
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if i < len(rpcMethods)-1 {
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fmt.Println()
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}
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}
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}
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select {
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case <-ticker.C:
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clearAndPrintReport()
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case <-progressCh:
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clearAndPrintReport()
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return
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}
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}
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}(progressCh)
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}
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wg.Wait()
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if progressCh != nil {
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// wait for the watch go routine to return
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progressCh <- struct{}{}
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// no need to print the report again
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return nil
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}
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// print the report for each endpoint
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for i, e := range rpcMethods {
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e.Report()
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if i < len(rpcMethods)-1 {
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fmt.Println()
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}
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}
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return nil
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},
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}
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// RPCMethod handles the benchmarking of a single endpoint method.
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type RPCMethod struct {
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w io.Writer
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// the endpoint uri
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uri string
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// the rpc method we want to benchmark
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method string
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// the number of concurrent requests to make to this endpoint
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concurrency int
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// if >0 then limit to qps is the max number of requests per second to make to this endpoint (0 = no limit)
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qps int
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// many endpoints require specific parameters to be passed
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params string
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// whether or not to print the response of each request (useful for debugging)
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printResp bool
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// instruct the worker go routines to stop
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stopCh chan struct{}
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// when the endpoint bencharking started
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start time.Time
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// results channel is used by the workers to send results to the reporter
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results chan *result
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// reporter handles reading the results from workers and printing the report statistics
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reporter *Reporter
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}
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// result is the result of a single rpc method request.
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type result struct {
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err error
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statusCode *int
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duration time.Duration
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}
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func (rpc *RPCMethod) Run() error {
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client := &http.Client{
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Timeout: 0,
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}
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var wg sync.WaitGroup
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wg.Add(rpc.concurrency)
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rpc.results = make(chan *result, rpc.concurrency*1_000)
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rpc.stopCh = make(chan struct{}, rpc.concurrency)
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go func() {
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rpc.reporter = NewReporter(rpc.results, rpc.w)
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rpc.reporter.Run()
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}()
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rpc.start = time.Now()
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// throttle the number of requests per second
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var qpsTicker *time.Ticker
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if rpc.qps > 0 {
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qpsTicker = time.NewTicker(time.Second / time.Duration(rpc.qps))
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}
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for i := 0; i < rpc.concurrency; i++ {
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go func() {
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rpc.startWorker(client, qpsTicker)
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wg.Done()
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}()
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}
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wg.Wait()
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// close the results channel so reporter will stop
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close(rpc.results)
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// wait until the reporter is done
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<-rpc.reporter.doneCh
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return nil
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}
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func (rpc *RPCMethod) startWorker(client *http.Client, qpsTicker *time.Ticker) {
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for {
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// check if we should stop
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select {
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case <-rpc.stopCh:
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return
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default:
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}
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// wait for the next tick if we are rate limiting this endpoint
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if qpsTicker != nil {
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<-qpsTicker.C
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}
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req, err := rpc.buildRequest()
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if err != nil {
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log.Fatalln(err)
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}
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start := time.Now()
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var statusCode *int
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// send request the endpoint
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resp, err := client.Do(req)
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if err != nil {
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err = fmt.Errorf("HTTP error: %s", err.Error())
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} else {
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statusCode = &resp.StatusCode
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// there was not a HTTP error but we need to still check the json response for errrors
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var data []byte
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data, err = io.ReadAll(resp.Body)
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if err != nil {
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log.Fatalln(err)
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}
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// we are only interested if it has the error field in the response
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type respData struct {
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Error struct {
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Code int `json:"code"`
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Message string `json:"message"`
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} `json:"error"`
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}
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// unmarshal the response into a struct so we can check for errors
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var d respData
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err = json.Unmarshal(data, &d)
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if err != nil {
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log.Fatalln(err)
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}
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// if the response has an error json message then it should be considered an error just like any http error
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if len(d.Error.Message) > 0 {
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// truncate the error message if it is too long
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if len(d.Error.Message) > 1000 {
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d.Error.Message = d.Error.Message[:1000] + "..."
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}
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// remove newlines from the error message so we don't screw up the report
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d.Error.Message = strings.ReplaceAll(d.Error.Message, "\n", "")
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err = fmt.Errorf("JSON error: code:%d, message:%s", d.Error.Code, d.Error.Message)
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}
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if rpc.printResp {
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fmt.Printf("[%s] %s", rpc.method, string(data))
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}
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resp.Body.Close() //nolint:errcheck
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}
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rpc.results <- &result{
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statusCode: statusCode,
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err: err,
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duration: time.Since(start),
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}
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}
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}
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func (rpc *RPCMethod) buildRequest() (*http.Request, error) {
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jreq, err := json.Marshal(struct {
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Jsonrpc string `json:"jsonrpc"`
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ID int `json:"id"`
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Method string `json:"method"`
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Params json.RawMessage `json:"params"`
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}{
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Jsonrpc: "2.0",
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Method: rpc.method,
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Params: json.RawMessage(rpc.params),
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ID: 0,
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})
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if err != nil {
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return nil, err
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}
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req, err := http.NewRequest("POST", rpc.uri, bytes.NewReader(jreq))
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if err != nil {
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return nil, err
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}
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req.Header.Set("Accept", "application/json")
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return req, nil
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}
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func (rpc *RPCMethod) Stop() {
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for i := 0; i < rpc.concurrency; i++ {
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rpc.stopCh <- struct{}{}
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}
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}
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func (rpc *RPCMethod) Report() {
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total := time.Since(rpc.start)
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fmt.Fprintf(rpc.w, "[%s]:\n", rpc.method)
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fmt.Fprintf(rpc.w, "- Options:\n")
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fmt.Fprintf(rpc.w, " - concurrency: %d\n", rpc.concurrency)
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fmt.Fprintf(rpc.w, " - params: %s\n", rpc.params)
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fmt.Fprintf(rpc.w, " - qps: %d\n", rpc.qps)
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rpc.reporter.Print(total, rpc.w)
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}
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// Reporter reads the results from the workers through the results channel and aggregates the results.
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type Reporter struct {
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// write the report to this writer
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w io.Writer
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// the reporter read the results from this channel
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results chan *result
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// doneCh is used to signal that the reporter has finished reading the results (channel has closed)
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doneCh chan bool
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// lock protect the following fields during critical sections (if --watch was specified)
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lock sync.Mutex
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// the latencies of all requests
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latencies []int64
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// the number of requests that returned each status code
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statusCodes map[int]int
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// the number of errors that occurred
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errors map[string]int
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}
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func NewReporter(results chan *result, w io.Writer) *Reporter {
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return &Reporter{
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w: w,
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results: results,
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doneCh: make(chan bool, 1),
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statusCodes: make(map[int]int),
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errors: make(map[string]int),
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}
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}
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func (r *Reporter) Run() {
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for res := range r.results {
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r.lock.Lock()
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r.latencies = append(r.latencies, res.duration.Milliseconds())
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if res.statusCode != nil {
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r.statusCodes[*res.statusCode]++
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}
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if res.err != nil {
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if len(r.errors) < 1_000_000 {
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r.errors[res.err.Error()]++
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} else {
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// we don't want to store too many errors in memory
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r.errors["hidden"]++
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}
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} else {
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r.errors["nil"]++
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}
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r.lock.Unlock()
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}
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r.doneCh <- true
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}
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func (r *Reporter) Print(elapsed time.Duration, w io.Writer) {
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r.lock.Lock()
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defer r.lock.Unlock()
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nrReq := int64(len(r.latencies))
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if nrReq == 0 {
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fmt.Println("No requests were made")
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return
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}
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// we need to sort the latencies slice to calculate the percentiles
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sort.Slice(r.latencies, func(i, j int) bool {
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return r.latencies[i] < r.latencies[j]
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})
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var totalLatency int64 = 0
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for _, latency := range r.latencies {
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totalLatency += latency
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}
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fmt.Fprintf(w, "- Total Requests: %d\n", nrReq)
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fmt.Fprintf(w, "- Total Duration: %dms\n", elapsed.Milliseconds())
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fmt.Fprintf(w, "- Requests/sec: %f\n", float64(nrReq)/elapsed.Seconds())
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fmt.Fprintf(w, "- Avg latency: %dms\n", totalLatency/nrReq)
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fmt.Fprintf(w, "- Median latency: %dms\n", r.latencies[nrReq/2])
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fmt.Fprintf(w, "- Latency distribution:\n")
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percentiles := []float64{0.1, 0.5, 0.9, 0.95, 0.99, 0.999}
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for _, p := range percentiles {
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idx := int64(p * float64(nrReq))
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fmt.Fprintf(w, " %s%% in %dms\n", fmt.Sprintf("%.2f", p*100.0), r.latencies[idx])
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}
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// create a simple histogram with 10 buckets spanning the range of latency
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// into equal ranges
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//
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nrBucket := 10
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buckets := make([]Bucket, nrBucket)
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latencyRange := r.latencies[len(r.latencies)-1]
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bucketRange := latencyRange / int64(nrBucket)
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// mark the end of each bucket
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for i := 0; i < nrBucket; i++ {
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buckets[i].start = int64(i) * bucketRange
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buckets[i].end = buckets[i].start + bucketRange
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// extend the last bucked by any remaning range caused by the integer division
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if i == nrBucket-1 {
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buckets[i].end = latencyRange
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}
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}
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// count the number of requests in each bucket
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currBucket := 0
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for i := 0; i < len(r.latencies); {
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if r.latencies[i] <= buckets[currBucket].end {
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buckets[currBucket].cnt++
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i++
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} else {
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currBucket++
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}
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}
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// print the histogram using a tabwriter which will align the columns nicely
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fmt.Fprintf(w, "- Histogram:\n")
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const padding = 2
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tabWriter := tabwriter.NewWriter(w, 0, 0, padding, ' ', tabwriter.AlignRight|tabwriter.Debug)
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for i := 0; i < nrBucket; i++ {
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ratio := float64(buckets[i].cnt) / float64(nrReq)
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bars := strings.Repeat("#", int(ratio*100))
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fmt.Fprintf(tabWriter, " %d-%dms\t%d\t%s (%s%%)\n", buckets[i].start, buckets[i].end, buckets[i].cnt, bars, fmt.Sprintf("%.2f", ratio*100))
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}
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tabWriter.Flush() //nolint:errcheck
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fmt.Fprintf(w, "- Status codes:\n")
|
|
for code, cnt := range r.statusCodes {
|
|
fmt.Fprintf(w, " [%d]: %d\n", code, cnt)
|
|
}
|
|
|
|
// print the 10 most occurring errors (in case error values are not unique)
|
|
//
|
|
type kv struct {
|
|
err string
|
|
cnt int
|
|
}
|
|
var sortedErrors []kv
|
|
for err, cnt := range r.errors {
|
|
sortedErrors = append(sortedErrors, kv{err, cnt})
|
|
}
|
|
sort.Slice(sortedErrors, func(i, j int) bool {
|
|
return sortedErrors[i].cnt > sortedErrors[j].cnt
|
|
})
|
|
fmt.Fprintf(w, "- Errors (top 10):\n")
|
|
for i, se := range sortedErrors {
|
|
if i > 10 {
|
|
break
|
|
}
|
|
fmt.Fprintf(w, " [%s]: %d\n", se.err, se.cnt)
|
|
}
|
|
}
|
|
|
|
type Bucket struct {
|
|
start int64
|
|
// the end value of the bucket
|
|
end int64
|
|
// how many entries are in the bucket
|
|
cnt int
|
|
}
|