// Copyright 2020 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package tools import ( "fmt" "regexp" "strconv" "testing" ) // Sysbench represents a 'sysbench' command. type Sysbench interface { // MakeCmd constructs the relevant command line. MakeCmd(*testing.B) []string // Report reports relevant custom metrics. Report(*testing.B, string) } // SysbenchBase is the top level struct for sysbench and holds top-level arguments // for sysbench. See: 'sysbench --help' type SysbenchBase struct { // Threads is the number of threads for the test. Threads int } // baseFlags returns top level flags. func (s *SysbenchBase) baseFlags(b *testing.B) []string { var ret []string if s.Threads > 0 { ret = append(ret, fmt.Sprintf("--threads=%d", s.Threads)) } ret = append(ret, "--time=0") // Ensure events is used. ret = append(ret, fmt.Sprintf("--events=%d", b.N)) return ret } // SysbenchCPU is for 'sysbench [flags] cpu run' and holds CPU specific arguments. type SysbenchCPU struct { SysbenchBase } // MakeCmd makes commands for SysbenchCPU. func (s *SysbenchCPU) MakeCmd(b *testing.B) []string { cmd := []string{"sysbench"} cmd = append(cmd, s.baseFlags(b)...) cmd = append(cmd, "cpu", "run") return cmd } // Report reports the relevant metrics for SysbenchCPU. func (s *SysbenchCPU) Report(b *testing.B, output string) { b.Helper() result, err := s.parseEvents(output) if err != nil { b.Fatalf("parsing CPU events from %s failed: %v", output, err) } ReportCustomMetric(b, result, "cpu_events" /*metric name*/, "events_per_second" /*unit*/) } var cpuEventsPerSecondRE = regexp.MustCompile(`events per second:\s*(\d*.?\d*)\n`) // parseEvents parses cpu events per second. func (s *SysbenchCPU) parseEvents(data string) (float64, error) { match := cpuEventsPerSecondRE.FindStringSubmatch(data) if len(match) < 2 { return 0.0, fmt.Errorf("could not find events per second: %s", data) } return strconv.ParseFloat(match[1], 64) } // SysbenchMemory is for 'sysbench [FLAGS] memory run' and holds Memory specific arguments. type SysbenchMemory struct { SysbenchBase BlockSize int // size of test memory block in megabytes [1]. TotalSize int // size of data to transfer in gigabytes [100]. Scope string // memory access scope {global, local} [global]. HugeTLB bool // allocate memory from HugeTLB [off]. OperationType string // type of memory ops {read, write, none} [write]. AccessMode string // access mode {seq, rnd} [seq]. } // MakeCmd makes commands for SysbenchMemory. func (s *SysbenchMemory) MakeCmd(b *testing.B) []string { cmd := []string{"sysbench"} cmd = append(cmd, s.flags(b)...) cmd = append(cmd, "memory", "run") return cmd } // flags makes flags for SysbenchMemory cmds. func (s *SysbenchMemory) flags(b *testing.B) []string { cmd := s.baseFlags(b) if s.BlockSize != 0 { cmd = append(cmd, fmt.Sprintf("--memory-block-size=%dM", s.BlockSize)) } if s.TotalSize != 0 { cmd = append(cmd, fmt.Sprintf("--memory-total-size=%dG", s.TotalSize)) } if s.Scope != "" { cmd = append(cmd, fmt.Sprintf("--memory-scope=%s", s.Scope)) } if s.HugeTLB { cmd = append(cmd, "--memory-hugetlb=on") } if s.OperationType != "" { cmd = append(cmd, fmt.Sprintf("--memory-oper=%s", s.OperationType)) } if s.AccessMode != "" { cmd = append(cmd, fmt.Sprintf("--memory-access-mode=%s", s.AccessMode)) } return cmd } // Report reports the relevant metrics for SysbenchMemory. func (s *SysbenchMemory) Report(b *testing.B, output string) { b.Helper() result, err := s.parseOperations(output) if err != nil { b.Fatalf("parsing result %s failed with err: %v", output, err) } ReportCustomMetric(b, result, "memory_operations" /*metric name*/, "ops_per_second" /*unit*/) } var memoryOperationsRE = regexp.MustCompile(`Total\s+operations:\s+\d+\s+\((\s*\d+\.\d+\s*)\s+per\s+second\)`) // parseOperations parses memory operations per second form sysbench memory ouput. func (s *SysbenchMemory) parseOperations(data string) (float64, error) { match := memoryOperationsRE.FindStringSubmatch(data) if len(match) < 2 { return 0.0, fmt.Errorf("couldn't find memory operations per second: %s", data) } return strconv.ParseFloat(match[1], 64) } // SysbenchMutex is for 'sysbench [FLAGS] mutex run' and holds Mutex specific arguments. type SysbenchMutex struct { SysbenchBase Num int // total size of mutex array [4096]. Locks int // number of mutex locks per thread [50000]. Loops int // number of loops to do outside mutex lock [10000]. } // MakeCmd makes commands for SysbenchMutex. func (s *SysbenchMutex) MakeCmd(b *testing.B) []string { cmd := []string{"sysbench"} cmd = append(cmd, s.flags(b)...) cmd = append(cmd, "mutex", "run") return cmd } // flags makes flags for SysbenchMutex commands. func (s *SysbenchMutex) flags(b *testing.B) []string { var cmd []string cmd = append(cmd, s.baseFlags(b)...) if s.Num > 0 { cmd = append(cmd, fmt.Sprintf("--mutex-num=%d", s.Num)) } if s.Locks > 0 { cmd = append(cmd, fmt.Sprintf("--mutex-locks=%d", s.Locks)) } if s.Loops > 0 { cmd = append(cmd, fmt.Sprintf("--mutex-loops=%d", s.Loops)) } return cmd } // Report parses and reports relevant sysbench mutex metrics. func (s *SysbenchMutex) Report(b *testing.B, output string) { b.Helper() result, err := s.parseExecutionTime(output) if err != nil { b.Fatalf("parsing result %s failed with err: %v", output, err) } ReportCustomMetric(b, result, "average_execution_time" /*metric name*/, "s" /*unit*/) result, err = s.parseDeviation(output) if err != nil { b.Fatalf("parsing result %s failed with err: %v", output, err) } ReportCustomMetric(b, result, "stddev_execution_time" /*metric name*/, "s" /*unit*/) result, err = s.parseLatency(output) if err != nil { b.Fatalf("parsing result %s failed with err: %v", output, err) } ReportCustomMetric(b, result/1000, "average_latency" /*metric name*/, "s" /*unit*/) } var executionTimeRE = regexp.MustCompile(`execution time \(avg/stddev\):\s*(\d*.?\d*)/(\d*.?\d*)`) // parseExecutionTime parses threads fairness average execution time from sysbench output. func (s *SysbenchMutex) parseExecutionTime(data string) (float64, error) { match := executionTimeRE.FindStringSubmatch(data) if len(match) < 2 { return 0.0, fmt.Errorf("could not find execution time average: %s", data) } return strconv.ParseFloat(match[1], 64) } // parseDeviation parses threads fairness stddev time from sysbench output. func (s *SysbenchMutex) parseDeviation(data string) (float64, error) { match := executionTimeRE.FindStringSubmatch(data) if len(match) < 3 { return 0.0, fmt.Errorf("could not find execution time deviation: %s", data) } return strconv.ParseFloat(match[2], 64) } var averageLatencyRE = regexp.MustCompile(`avg:[^\n^\d]*(\d*\.?\d*)`) // parseLatency parses latency from sysbench output. func (s *SysbenchMutex) parseLatency(data string) (float64, error) { match := averageLatencyRE.FindStringSubmatch(data) if len(match) < 2 { return 0.0, fmt.Errorf("could not find average latency: %s", data) } return strconv.ParseFloat(match[1], 64) }