// Import the utility functionality. import jobs.generation.* // The input project name (e.g. dotnet/coreclr) def project = GithubProject // The input branch name (e.g. master) def branch = GithubBranchName def projectFolder = Utilities.getFolderName(project) + '/' + Utilities.getFolderName(branch) // Create a folder for JIT stress jobs and associated folder views folder('jitstress') Utilities.addStandardFolderView(this, 'jitstress', project) // Create a folder for testing via illink folder('illink') Utilities.addStandardFolderView(this, 'illink', project) def static getOSGroup(def os) { def osGroupMap = ['Ubuntu':'Linux', 'RHEL7.2': 'Linux', 'Ubuntu16.04': 'Linux', 'Ubuntu16.10': 'Linux', 'Debian8.4':'Linux', 'Fedora24':'Linux', 'OSX10.12':'OSX', 'Windows_NT':'Windows_NT', 'CentOS7.1': 'Linux', 'Tizen': 'Linux'] def osGroup = osGroupMap.get(os, null) assert osGroup != null : "Could not find os group for ${os}" return osGroupMap[os] } def static getCrossArchitecture(def os, def architecture, def scenario) { switch (architecture) { case 'arm': return 'x86' case 'arm64': return 'x64' } assert false } // We use this class (vs variables) so that the static functions can access data here. class Constants { // We have very limited ARM64 hardware (used for ARM/ARM64 testing). So only allow certain branches to use it. def static LimitedHardwareBranches = [ 'master'] // Innerloop build OS's // The Windows_NT_BuildOnly OS is a way to speed up the Non-Windows builds by avoiding // test execution in the build flow runs. It generates the exact same build // as Windows_NT but without running the tests. def static osList = [ 'Ubuntu', 'Debian8.4', 'OSX10.12', 'Windows_NT', 'Windows_NT_BuildOnly', 'CentOS7.1', 'RHEL7.2', 'Ubuntu16.04', 'Ubuntu16.10', 'Fedora24', 'Tizen'] def static crossList = [ 'Ubuntu', 'Debian8.4', 'OSX10.12', 'Windows_NT', 'CentOS7.1', 'RHEL7.2'] // This is a set of JIT stress modes combined with the set of variables that // need to be set to actually enable that stress mode. The key of the map is the stress mode and // the values are the environment variables def static jitStressModeScenarios = [ 'minopts' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JITMinOpts' : '1'], 'tieredcompilation' : ['COMPlus_TieredCompilation' : '1'], // this can be removed once tiered compilation is on by default 'no_tiered_compilation' : ['COMPlus_TieredCompilation' : '0'], 'no_tiered_compilation_innerloop': ['COMPlus_TieredCompilation' : '0'], 'forcerelocs' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_ForceRelocs' : '1'], 'jitstress1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '1'], 'jitstress2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2'], 'jitstress1_tiered' : ['COMPlus_TieredCompilation' : '1', 'COMPlus_JitStress' : '1'], 'jitstress2_tiered' : ['COMPlus_TieredCompilation' : '1', 'COMPlus_JitStress' : '2'], 'jitstressregs1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '1'], 'jitstressregs2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '2'], 'jitstressregs3' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '3'], 'jitstressregs4' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '4'], 'jitstressregs8' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '8'], 'jitstressregs0x10' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x10'], 'jitstressregs0x80' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x80'], 'jitstressregs0x1000' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x1000'], 'jitstress2_jitstressregs1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '1'], 'jitstress2_jitstressregs2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '2'], 'jitstress2_jitstressregs3' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '3'], 'jitstress2_jitstressregs4' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '4'], 'jitstress2_jitstressregs8' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '8'], 'jitstress2_jitstressregs0x10' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '0x10'], 'jitstress2_jitstressregs0x80' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '0x80'], 'jitstress2_jitstressregs0x1000' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2', 'COMPlus_JitStressRegs' : '0x1000'], 'tailcallstress' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_TailcallStress' : '1'], 'jitsse2only' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableAVX' : '0', 'COMPlus_EnableSSE3_4' : '0'], 'jitnosimd' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_FeatureSIMD' : '0'], 'jitincompletehwintrinsic' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableIncompleteISAClass' : '1'], 'jitx86hwintrinsicnoavx' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableIncompleteISAClass' : '1', 'COMPlus_EnableAVX' : '0'], // testing the legacy SSE encoding 'jitx86hwintrinsicnoavx2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableIncompleteISAClass' : '1', 'COMPlus_EnableAVX2' : '0'], // testing SNB/IVB 'jitx86hwintrinsicnosimd' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableIncompleteISAClass' : '1', 'COMPlus_FeatureSIMD' : '0'], // match "jitnosimd", may need to remove after decoupling HW intrinsic from FeatureSIMD 'jitnox86hwintrinsic' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_EnableIncompleteISAClass' : '1', 'COMPlus_EnableSSE' : '0' , 'COMPlus_EnableSSE2' : '0' , 'COMPlus_EnableSSE3' : '0' , 'COMPlus_EnableSSSE3' : '0' , 'COMPlus_EnableSSE41' : '0' , 'COMPlus_EnableSSE42' : '0' , 'COMPlus_EnableAVX' : '0' , 'COMPlus_EnableAVX2' : '0' , 'COMPlus_EnableAES' : '0' , 'COMPlus_EnableBMI1' : '0' , 'COMPlus_EnableBMI2' : '0' , 'COMPlus_EnableFMA' : '0' , 'COMPlus_EnableLZCNT' : '0' , 'COMPlus_EnablePCLMULQDQ' : '0' , 'COMPlus_EnablePOPCNT' : '0'], 'corefx_baseline' : ['COMPlus_TieredCompilation' : '0'], // corefx baseline 'corefx_minopts' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JITMinOpts' : '1'], 'corefx_tieredcompilation' : ['COMPlus_TieredCompilation' : '1'], // this can be removed once tiered compilation is on by default 'corefx_jitstress1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '1'], 'corefx_jitstress2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStress' : '2'], 'corefx_jitstressregs1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '1'], 'corefx_jitstressregs2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '2'], 'corefx_jitstressregs3' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '3'], 'corefx_jitstressregs4' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '4'], 'corefx_jitstressregs8' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '8'], 'corefx_jitstressregs0x10' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x10'], 'corefx_jitstressregs0x80' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x80'], 'corefx_jitstressregs0x1000' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_JitStressRegs' : '0x1000'], 'gcstress0x3' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0x3'], 'gcstress0xc' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC'], 'zapdisable' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_ZapDisable' : '1', 'COMPlus_ReadyToRun' : '0'], 'heapverify1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_HeapVerify' : '1'], 'gcstress0xc_zapdisable' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_ZapDisable' : '1', 'COMPlus_ReadyToRun' : '0'], 'gcstress0xc_zapdisable_jitstress2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_ZapDisable' : '1', 'COMPlus_ReadyToRun' : '0', 'COMPlus_JitStress' : '2'], 'gcstress0xc_zapdisable_heapverify1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_ZapDisable' : '1', 'COMPlus_ReadyToRun' : '0', 'COMPlus_HeapVerify' : '1'], 'gcstress0xc_jitstress1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_JitStress' : '1'], 'gcstress0xc_jitstress2' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_JitStress' : '2'], 'gcstress0xc_minopts_heapverify1' : ['COMPlus_TieredCompilation' : '0', 'COMPlus_GCStress' : '0xC', 'COMPlus_JITMinOpts' : '1', 'COMPlus_HeapVerify' : '1'] ] // This is a set of ReadyToRun stress scenarios def static r2rStressScenarios = [ 'r2r_jitstress1' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStress": "1"], 'r2r_jitstress2' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStress": "2"], 'r2r_jitstress1_tiered' : ['COMPlus_TieredCompilation' : '1', "COMPlus_JitStress": "1"], 'r2r_jitstress2_tiered' : ['COMPlus_TieredCompilation' : '1', "COMPlus_JitStress": "2"], 'r2r_jitstressregs1' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "1"], 'r2r_jitstressregs2' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "2"], 'r2r_jitstressregs3' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "3"], 'r2r_jitstressregs4' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "4"], 'r2r_jitstressregs8' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "8"], 'r2r_jitstressregs0x10' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "0x10"], 'r2r_jitstressregs0x80' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "0x80"], 'r2r_jitstressregs0x1000' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JitStressRegs": "0x1000"], 'r2r_jitminopts' : ['COMPlus_TieredCompilation' : '0', "COMPlus_JITMinOpts": "1"], 'r2r_jitforcerelocs' : ['COMPlus_TieredCompilation' : '0', "COMPlus_ForceRelocs": "1"], 'r2r_gcstress15' : ['COMPlus_TieredCompilation' : '0', "COMPlus_GCStress": "0xF"], 'r2r_no_tiered_compilation' : ['COMPlus_TieredCompilation' : '0'], ] // This is the basic set of scenarios def static basicScenarios = [ 'innerloop', 'normal', 'ilrt', 'r2r', 'longgc', 'formatting', 'gcsimulator', // 'jitdiff', // jitdiff is currently disabled, until someone spends the effort to make it fully work 'standalone_gc', 'gc_reliability_framework', 'illink', 'corefx_innerloop', 'crossgen_comparison'] def static allScenarios = basicScenarios + r2rStressScenarios.keySet() + jitStressModeScenarios.keySet() // Valid PR trigger combinations. def static prTriggeredValidInnerLoopCombos = [ 'Windows_NT': [ 'x64': [ 'Checked' ], 'x86': [ 'Checked', 'Release' ], 'arm': [ 'Debug', 'Checked' ], 'arm64': [ 'Debug', 'Checked' ] ], 'Windows_NT_BuildOnly': [ 'x64': [ 'Checked', 'Release' ], 'x86': [ 'Checked', 'Release' ], 'arm': [ 'Checked' ], ], 'Ubuntu': [ 'x64': [ 'Checked' ], 'arm64': [ 'Debug' ], 'arm': [ 'Checked' ] ], 'CentOS7.1': [ 'x64': [ 'Debug', 'Checked' ] ], 'OSX10.12': [ 'x64': [ 'Checked' ] ], 'Tizen': [ 'armem': [ 'Checked' ] ] ] // A set of scenarios that are valid for arm/arm64 tests run on hardware. This is a map from valid scenario name // to Tests.lst file categories to exclude. // // This list should contain a subset of the scenarios from `allScenarios`. Please keep this in the same order as that, // and with the same values, with some commented out, for easier maintenance. // // Note that some scenarios that are commented out should be enabled, but haven't yet been. // def static validArmWindowsScenarios = [ 'innerloop': [], 'normal': [], // 'ilrt' 'r2r': ["R2R_FAIL", "R2R_EXCLUDE"], // 'longgc' // 'formatting' // 'gcsimulator' // 'jitdiff' // 'standalone_gc' // 'gc_reliability_framework' // 'illink' // 'corefx_innerloop' // 'crossgen_comparison' 'r2r_jitstress1': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstress2': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstress1_tiered': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstress2_tiered': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs1': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs2': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs3': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs4': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs8': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs0x10': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs0x80': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitstressregs0x1000': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_jitminopts': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE", "MINOPTS_FAIL", "MINOPTS_EXCLUDE"], 'r2r_jitforcerelocs': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'r2r_gcstress15': ["R2R_FAIL", "R2R_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE", "GCSTRESS_FAIL", "GCSTRESS_EXCLUDE"], 'r2r_no_tiered_compilation': ["R2R_FAIL", "R2R_EXCLUDE"], 'minopts': ["MINOPTS_FAIL", "MINOPTS_EXCLUDE"], 'tieredcompilation': [], 'no_tiered_compilation': [], 'no_tiered_compilation_innerloop': [], 'forcerelocs': [], 'jitstress1': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress1_tiered': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_tiered': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs1': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs2': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs3': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs4': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs8': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs0x10': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs0x80': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstressregs0x1000': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs1': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs2': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs3': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs4': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs8': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs0x10': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs0x80': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'jitstress2_jitstressregs0x1000': ["JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'tailcallstress': ["TAILCALLSTRESS_FAIL", "TAILCALLSTRESS_EXCLUDE"], // 'jitsse2only' // Only relevant to xarch 'jitnosimd': [], // Only interesting on platforms where SIMD support exists. // 'jitincompletehwintrinsic' // 'jitx86hwintrinsicnoavx' // 'jitx86hwintrinsicnoavx2' // 'jitx86hwintrinsicnosimd' // 'jitnox86hwintrinsic' 'corefx_baseline': [], // corefx tests don't use smarty 'corefx_minopts': [], // corefx tests don't use smarty 'corefx_tieredcompilation': [], // corefx tests don't use smarty 'corefx_jitstress1': [], // corefx tests don't use smarty 'corefx_jitstress2': [], // corefx tests don't use smarty 'corefx_jitstressregs1': [], // corefx tests don't use smarty 'corefx_jitstressregs2': [], // corefx tests don't use smarty 'corefx_jitstressregs3': [], // corefx tests don't use smarty 'corefx_jitstressregs4': [], // corefx tests don't use smarty 'corefx_jitstressregs8': [], // corefx tests don't use smarty 'corefx_jitstressregs0x10': [], // corefx tests don't use smarty 'corefx_jitstressregs0x80': [], // corefx tests don't use smarty 'corefx_jitstressregs0x1000': [], // corefx tests don't use smarty 'gcstress0x3': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE"], 'gcstress0xc': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE"], 'zapdisable': ["ZAPDISABLE_FAIL", "ZAPDISABLE_EXCLUDE"], 'heapverify1': [], 'gcstress0xc_zapdisable': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "ZAPDISABLE_FAIL", "ZAPDISABLE_EXCLUDE"], 'gcstress0xc_zapdisable_jitstress2': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "ZAPDISABLE_FAIL", "ZAPDISABLE_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_zapdisable_heapverify1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "ZAPDISABLE_FAIL", "ZAPDISABLE_EXCLUDE"], 'gcstress0xc_jitstress1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstress2': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_minopts_heapverify1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "MINOPTS_FAIL", "MINOPTS_EXCLUDE"], // // NOTE: the following scenarios are not defined in the 'allScenarios' list! Is this a bug? // 'minopts_zapdisable': ["ZAPDISABLE_FAIL", "ZAPDISABLE_EXCLUDE", "MINOPTS_FAIL", "MINOPTS_EXCLUDE"], 'gcstress0x3_jitstress1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstress2': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs2': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs3': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs4': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs8': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs0x10': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs0x80': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0x3_jitstressregs0x1000': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs1': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs2': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs3': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs4': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs8': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs0x10': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs0x80': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"], 'gcstress0xc_jitstressregs0x1000': ["GCSTRESS_FAIL", "GCSTRESS_EXCLUDE", "JITSTRESS_FAIL", "JITSTRESS_EXCLUDE"] ] def static validLinuxArmScenarios = [ 'innerloop', 'normal', // 'ilrt' 'r2r', // 'longgc' // 'formatting' // 'gcsimulator' // 'jitdiff' // 'standalone_gc' // 'gc_reliability_framework' // 'illink' // 'corefx_innerloop' 'crossgen_comparison', 'r2r_jitstress1', 'r2r_jitstress2', 'r2r_jitstress1_tiered', 'r2r_jitstress2_tiered', 'r2r_jitstressregs1', 'r2r_jitstressregs2', 'r2r_jitstressregs3', 'r2r_jitstressregs4', 'r2r_jitstressregs8', 'r2r_jitstressregs0x10', 'r2r_jitstressregs0x80', 'r2r_jitstressregs0x1000', 'r2r_jitminopts', 'r2r_jitforcerelocs', 'r2r_gcstress15', 'r2r_no_tiered_compilation', 'minopts', 'tieredcompilation', 'no_tiered_compilation', 'no_tiered_compilation_innerloop', 'forcerelocs', 'jitstress1', 'jitstress2', 'jitstress1_tiered', 'jitstress2_tiered', 'jitstressregs1', 'jitstressregs2', 'jitstressregs3', 'jitstressregs4', 'jitstressregs8', 'jitstressregs0x10', 'jitstressregs0x80', 'jitstressregs0x1000', 'jitstress2_jitstressregs1', 'jitstress2_jitstressregs2', 'jitstress2_jitstressregs3', 'jitstress2_jitstressregs4', 'jitstress2_jitstressregs8', 'jitstress2_jitstressregs0x10', 'jitstress2_jitstressregs0x80', 'jitstress2_jitstressregs0x1000', 'tailcallstress', // 'jitsse2only' // Only relevant to xarch // 'jitnosimd' // Only interesting on platforms where SIMD support exists. // 'jitincompletehwintrinsic' // 'jitx86hwintrinsicnoavx' // 'jitx86hwintrinsicnoavx2' // 'jitx86hwintrinsicnosimd' // 'jitnox86hwintrinsic' 'corefx_baseline', 'corefx_minopts', 'corefx_tieredcompilation', 'corefx_jitstress1', 'corefx_jitstress2', 'corefx_jitstressregs1', 'corefx_jitstressregs2', 'corefx_jitstressregs3', 'corefx_jitstressregs4', 'corefx_jitstressregs8', 'corefx_jitstressregs0x10', 'corefx_jitstressregs0x80', 'corefx_jitstressregs0x1000', 'gcstress0x3', 'gcstress0xc', 'zapdisable', 'heapverify1', 'gcstress0xc_zapdisable', 'gcstress0xc_zapdisable_jitstress2', 'gcstress0xc_zapdisable_heapverify1', 'gcstress0xc_jitstress1', 'gcstress0xc_jitstress2', 'gcstress0xc_minopts_heapverify1' ] def static validLinuxArm64Scenarios = [ 'innerloop', 'normal', // 'ilrt' 'r2r', // 'longgc' // 'formatting' // 'gcsimulator' // 'jitdiff' // 'standalone_gc' // 'gc_reliability_framework' // 'illink' // 'corefx_innerloop' // 'crossgen_comparison' 'r2r_jitstress1', 'r2r_jitstress2', 'r2r_jitstress1_tiered', 'r2r_jitstress2_tiered', 'r2r_jitstressregs1', 'r2r_jitstressregs2', 'r2r_jitstressregs3', 'r2r_jitstressregs4', 'r2r_jitstressregs8', 'r2r_jitstressregs0x10', 'r2r_jitstressregs0x80', 'r2r_jitstressregs0x1000', 'r2r_jitminopts', 'r2r_jitforcerelocs', 'r2r_gcstress15', 'minopts', 'tieredcompilation', 'forcerelocs', 'jitstress1', 'jitstress2', 'jitstress1_tiered', 'jitstress2_tiered', 'jitstressregs1', 'jitstressregs2', 'jitstressregs3', 'jitstressregs4', 'jitstressregs8', 'jitstressregs0x10', 'jitstressregs0x80', 'jitstressregs0x1000', 'jitstress2_jitstressregs1', 'jitstress2_jitstressregs2', 'jitstress2_jitstressregs3', 'jitstress2_jitstressregs4', 'jitstress2_jitstressregs8', 'jitstress2_jitstressregs0x10', 'jitstress2_jitstressregs0x80', 'jitstress2_jitstressregs0x1000', 'tailcallstress', // 'jitsse2only' // Only relevant to xarch 'jitnosimd', // Only interesting on platforms where SIMD support exists. // 'jitincompletehwintrinsic' // 'jitx86hwintrinsicnoavx' // 'jitx86hwintrinsicnoavx2' // 'jitx86hwintrinsicnosimd' // 'jitnox86hwintrinsic' 'corefx_baseline', 'corefx_minopts', 'corefx_tieredcompilation', 'corefx_jitstress1', 'corefx_jitstress2', 'corefx_jitstressregs1', 'corefx_jitstressregs2', 'corefx_jitstressregs3', 'corefx_jitstressregs4', 'corefx_jitstressregs8', 'corefx_jitstressregs0x10', 'corefx_jitstressregs0x80', 'corefx_jitstressregs0x1000', 'gcstress0x3', 'gcstress0xc', 'zapdisable', 'heapverify1', 'gcstress0xc_zapdisable', 'gcstress0xc_zapdisable_jitstress2', 'gcstress0xc_zapdisable_heapverify1', 'gcstress0xc_jitstress1', 'gcstress0xc_jitstress2', 'gcstress0xc_minopts_heapverify1' ] def static configurationList = ['Debug', 'Checked', 'Release'] // This is the set of architectures // Some of these are pseudo-architectures: // armem -- ARM builds/runs using an emulator. Used for Tizen runs. // x86_arm_altjit -- ARM runs on x86 using the ARM altjit // x64_arm64_altjit -- ARM64 runs on x64 using the ARM64 altjit def static architectureList = ['arm', 'armem', 'x86_arm_altjit', 'x64_arm64_altjit', 'arm64', 'x64', 'x86'] // This set of architectures that cross build on Windows and run on Windows ARM64 hardware. def static armWindowsCrossArchitectureList = ['arm', 'arm64'] } // ************************************************************** // Create some specific views // // These aren't using the Utilities.addStandardFolderView() function, because that creates // views based on a single regular expression. These views will be generated by adding a // specific set of jobs to them. // // Utilities.addStandardFolderView() also creates a lot of additional stuff around the // view, like "Build Statistics", "Job Statistics", "Unstable Jobs". Until it is determined // those are required, don't add them (which simplifies the view pages, as well). // ************************************************************** class Views { def static MergeJobView = null def static PeriodicJobView = null def static ArchitectureViews = [:] def static OSViews = [:] } // MergeJobView: include all jobs that execute when a PR change is merged. Views.MergeJobView = listView('Merge') { recurse() columns { status() weather() name() lastSuccess() lastFailure() lastDuration() buildButton() } } // PeriodicJobView: include all jobs that execute on a schedule Views.PeriodicJobView = listView('Periodic') { recurse() columns { status() weather() name() lastSuccess() lastFailure() lastDuration() buildButton() } } // Create a view for non-PR jobs for each architecture. Constants.architectureList.each { architecture -> Views.ArchitectureViews[architecture] = listView(architecture) { recurse() columns { status() weather() name() lastSuccess() lastFailure() lastDuration() buildButton() } } } // Create a view for non-PR jobs for each OS. Constants.osList.each { os -> // Don't create one for the special 'Windows_NT_BuildOnly' if (os == 'Windows_NT_BuildOnly') { return } Views.OSViews[os] = listView(os) { recurse() columns { status() weather() name() lastSuccess() lastFailure() lastDuration() buildButton() } } } def static addToMergeView(def job) { Views.MergeJobView.with { jobs { name(job.name) } } } def static addToPeriodicView(def job) { Views.PeriodicJobView.with { jobs { name(job.name) } } } def static addToViews(def job, def isPR, def architecture, def os) { if (isPR) { // No views want PR jobs currently. return } // Add to architecture view. Views.ArchitectureViews[architecture].with { jobs { name(job.name) } } // Add to OS view. Views.OSViews[os].with { jobs { name(job.name) } } } def static addPeriodicTriggerHelper(def job, String cronString, boolean alwaysRuns = false) { addToPeriodicView(job) Utilities.addPeriodicTrigger(job, cronString, alwaysRuns) } def static addGithubPushTriggerHelper(def job) { addToMergeView(job) Utilities.addGithubPushTrigger(job) } def static setMachineAffinity(def job, def os, def architecture, def options = null) { assert os instanceof String assert architecture instanceof String def armArches = ['arm', 'armem', 'arm64'] if (!(architecture in armArches)) { assert options == null Utilities.setMachineAffinity(job, os, 'latest-or-auto') return } // This is an arm(64) job. // // There are several options. // // Windows_NT // // Arm32 (Build) -> latest-arm64 // |-> os == "Windows_NT" && (architecture == "arm") && options['use_arm64_build_machine'] == true // Arm32 (Test) -> arm64-windows_nt // |-> os == "Windows_NT" && (architecture == "arm") && options['use_arm64_build_machine'] == false // // Arm64 (Build) -> latest-arm64 // |-> os == "Windows_NT" && architecture == "arm64" && options['use_arm64_build_machine'] == true // Arm64 (Test) -> arm64-windows_nt // |-> os == "Windows_NT" && architecture == "arm64" && options['use_arm64_build_machine'] == false // // Ubuntu // // Arm32 emulator (Build, Test) -> arm-cross-latest // |-> os == "Tizen" && (architecture == "armem") // // Arm32 hardware (Flow) -> Ubuntu 16.04 latest-or-auto (don't use limited arm hardware) // |-> os == "Ubuntu" && (architecture == "arm") && options['is_flow_job'] == true // Arm32 hardware (Build) -> Ubuntu 16.04 latest-or-auto // |-> os == "Ubuntu" && (architecture == "arm") && options['is_build_job'] == true // Arm32 hardware (Test) -> ubuntu.1404.arm32.open // |-> os == "Ubuntu" && (architecture == "arm") // // Arm64 (Build) -> arm64-cross-latest // |-> os != "Windows_NT" && architecture == "arm64" && options['is_build_only'] == true // Arm64 Small Page Size (Test) -> arm64-small-page-size // |-> os != "Windows_NT" && architecture == "arm64" && options['large_pages'] == false // Arm64 Large Page Size (Test) -> arm64-huge-page-size // |-> os != "Windows_NT" && architecture == "arm64" && options['large_pages'] == true // This has to be a arm arch assert architecture in armArches if (os == "Windows_NT") { // arm32/arm64 Windows jobs share the same machines for now def isBuild = options['use_arm64_build_machine'] == true if (isBuild == true) { // Current set of machines with private Windows arm64 toolset: // Utilities.setMachineAffinity(job, os, 'latest-arm64') // // New set of machines with public Windows arm64 toolset, coming from Helix: job.with { label('Windows.10.Amd64.ClientRS4.DevEx.Open') } } else { Utilities.setMachineAffinity(job, os, 'arm64-windows_nt') } } else { assert os != 'Windows_NT' if (architecture == 'arm64') { assert os == 'Ubuntu' def isFlow = (options != null) && (options['is_flow_job'] == true) def isBuild = (options != null) && (options['is_build_job'] == true) if (isFlow || isBuild) { // Arm64 Ubuntu build machine. Build uses docker, so the actual host OS is not // very important. Therefore, use latest or auto. Flow jobs don't need to use // Arm64 hardware. Utilities.setMachineAffinity(job, 'Ubuntu16.04', 'latest-or-auto') } else { // Arm64 Linux test machines if ((options != null) && (options['large_pages'] == true)) { Utilities.setMachineAffinity(job, os, 'arm64-huge-page-size') } else { Utilities.setMachineAffinity(job, os, 'arm64-small-page-size') } } } else if (architecture == 'armem') { // arm emulator (Tizen). Build and test on same machine, // using Docker. assert os == 'Tizen' Utilities.setMachineAffinity(job, 'Ubuntu', 'arm-cross-latest') } else { // arm Ubuntu on hardware. assert architecture == 'arm' assert os == 'Ubuntu' def isFlow = (options != null) && (options['is_flow_job'] == true) def isBuild = (options != null) && (options['is_build_job'] == true) if (isFlow || isBuild) { // arm Ubuntu build machine. Build uses docker, so the actual host OS is not // very important. Therefore, use latest or auto. Flow jobs don't need to use // arm hardware. Utilities.setMachineAffinity(job, 'Ubuntu16.04', 'latest-or-auto') } else { // arm Ubuntu test machine // There is no tag (like, e.g., "arm-latest") for this, so don't call // Utilities.setMachineAffinity. Just add the machine affinity // manually. We specify the Helix queue name here. job.with { label('ubuntu.1404.arm32.open') } } } } } // setJobMachineAffinity: compute the machine affinity options for a job, // then set the job with those affinity options. def static setJobMachineAffinity(def architecture, def os, def isBuildJob, def isTestJob, def isFlowJob, def job) { assert (isBuildJob && !isTestJob && !isFlowJob) || (!isBuildJob && isTestJob && !isFlowJob) || (!isBuildJob && !isTestJob && isFlowJob) def affinityOptions = null def affinityArchitecture = architecture if (os == "Windows_NT") { if (architecture in Constants.armWindowsCrossArchitectureList) { if (isBuildJob) { affinityOptions = [ "use_arm64_build_machine" : true ] } else if (isTestJob) { affinityOptions = [ "use_arm64_build_machine" : false ] } else if (isFlowJob) { // For the flow jobs set the machine affinity as x64 affinityArchitecture = 'x64' } } } else { if (architecture == 'arm64') { if (isBuildJob) { affinityOptions = ['is_build_job': true] } else if (isFlowJob) { affinityOptions = ['is_flow_job': true] } else if (isTestJob) { affinityOptions = [ "large_pages" : false ] } } else if (architecture == 'arm') { if (isBuildJob) { affinityOptions = ['is_build_job': true] } else if (isFlowJob) { affinityOptions = ['is_flow_job': true] } } } setMachineAffinity(job, os, affinityArchitecture, affinityOptions) } def static isGCStressRelatedTesting(def scenario) { // The 'r2r_gcstress15' scenario is a basic scenario. // Detect it and make it a GCStress related. if (scenario == 'r2r_gcstress15') { return true; } def gcStressTestEnvVars = [ 'COMPlus_GCStress', 'COMPlus_ZapDisable', 'COMPlus_HeapVerify'] def scenarioName = scenario.toLowerCase() def isGCStressTesting = false Constants.jitStressModeScenarios[scenario].each{ k, v -> if (k in gcStressTestEnvVars) { isGCStressTesting = true; } } return isGCStressTesting } def static isCoreFxScenario(def scenario) { def corefx_prefix = 'corefx_' if (scenario.length() < corefx_prefix.length()) { return false } return scenario.substring(0,corefx_prefix.length()) == corefx_prefix } def static isR2RBaselineScenario(def scenario) { return (scenario == 'r2r') } def static isR2RStressScenario(def scenario) { return Constants.r2rStressScenarios.containsKey(scenario) } def static isR2RScenario(def scenario) { return isR2RBaselineScenario(scenario) || isR2RStressScenario(scenario) } def static isJitStressScenario(def scenario) { return Constants.jitStressModeScenarios.containsKey(scenario) } def static isLongGc(def scenario) { return (scenario == 'longgc' || scenario == 'gcsimulator') } def static isJitDiff(def scenario) { return (scenario == 'jitdiff') } def static isGcReliabilityFramework(def scenario) { return (scenario == 'gc_reliability_framework') } def static isArmWindowsScenario(def scenario) { return Constants.validArmWindowsScenarios.containsKey(scenario) } def static isValidPrTriggeredInnerLoopJob(os, architecture, configuration, isBuildOnly) { if (isBuildOnly == true) { os = 'Windows_NT_BuildOnly' } def validOsPrTriggerArchConfigs = Constants.prTriggeredValidInnerLoopCombos[os] if (validOsPrTriggerArchConfigs != null) { def validOsPrTriggerConfigs = validOsPrTriggerArchConfigs[architecture] if (validOsPrTriggerConfigs != null) { if (configuration in validOsPrTriggerConfigs) { return true } } } return false } // This means the job builds and runs the 'innerloop' test set. This does not mean the job is // scheduled with a default PR trigger despite the correlation being true at the moment. def static isInnerloopTestScenario(def scenario) { return (scenario == 'innerloop' || scenario == 'no_tiered_compilation_innerloop') } def static isCrossGenComparisonScenario(def scenario) { return (scenario == 'crossgen_comparison') } def static shouldGenerateCrossGenComparisonJob(def os, def architecture, def configuration, def scenario) { assert isCrossGenComparisonScenario(scenario) return (os == 'Ubuntu' && architecture == 'arm' && configuration == 'Checked') } def static getFxBranch(def branch) { def fxBranch = branch // Map 'dev/unix_test_workflow' to 'master' so we can test CoreFX jobs in the CoreCLR dev/unix_test_workflow // branch even though CoreFX doesn't have such a branch. if (branch == 'dev/unix_test_workflow') { fxBranch = 'master' } return fxBranch } def static setJobTimeout(newJob, isPR, architecture, configuration, scenario, isBuildOnly) { // 2 hours (120 minutes) is the default timeout def timeout = 120 if (!isInnerloopTestScenario(scenario)) { // Pri-1 test builds take a long time (see calculateBuildCommands()). So up the Pri-1 build jobs timeout. timeout = 240 } if (!isBuildOnly) { // Note that these can only increase, never decrease, the Pri-1 timeout possibly set above. if (isGCStressRelatedTesting(scenario)) { timeout = 4320 } else if (isCoreFxScenario(scenario)) { timeout = 360 } else if (isJitStressScenario(scenario)) { timeout = 300 } else if (isR2RBaselineScenario(scenario)) { timeout = 240 } else if (isLongGc(scenario)) { timeout = 1440 } else if (isJitDiff(scenario)) { timeout = 240 } else if (isGcReliabilityFramework(scenario)) { timeout = 1440 } else if (architecture == 'armem' || architecture == 'arm64') { timeout = 240 } if (architecture == 'arm') { // ARM32 machines are particularly slow. timeout += 120 } } if (configuration == 'Debug') { // Debug runs can be very slow. Add an hour. timeout += 60 } if (architecture == 'x86_arm_altjit' || architecture == 'x64_arm64_altjit') { // AltJit runs compile all methods twice. timeout *= 2 } // If we've changed the timeout from the default, set it in the job. if (timeout != 120) { Utilities.setJobTimeout(newJob, timeout) } } def static getJobFolder(def scenario) { if (isJitStressScenario(scenario) || isR2RStressScenario(scenario)) { return 'jitstress' } if (scenario == 'illink') { return 'illink' } return '' } def static getStressModeDisplayName(def scenario) { def displayStr = '' Constants.jitStressModeScenarios[scenario].each{ k, v -> def prefixLength = 'COMPlus_'.length() if (k.length() >= prefixLength) { def modeName = k.substring(prefixLength, k.length()) displayStr += ' ' + modeName + '=' + v } } if (isCoreFxScenario(scenario)) { displayStr = ('CoreFx ' + displayStr).trim() } return displayStr } def static getR2RDisplayName(def scenario) { // Assume the scenario name is one from the r2rStressScenarios dict, and remove its "r2r_" prefix. def displayStr = scenario def prefixLength = 'r2r_'.length() if (displayStr.length() >= prefixLength) { displayStr = "R2R " + displayStr.substring(prefixLength, displayStr.length()) } else if (scenario == 'r2r') { displayStr = "R2R" } return displayStr } def static getScenarioDisplayString(def scenario) { switch (scenario) { case 'innerloop': return "Innerloop Build and Test" case 'no_tiered_compilation_innerloop': def displayStr = getStressModeDisplayName(scenario) return "Innerloop Build and Test (Jit - ${displayStr})" case 'corefx_innerloop': return "CoreFX Tests" case 'normal': return "Build and Test" case 'jitdiff': return "Jit Diff Build and Test" case 'ilrt': return "IL RoundTrip Build and Test" case 'longgc': return "Long-Running GC Build & Test" case 'gcsimulator': return "GC Simulator" case 'standalone_gc': return "Standalone GC" case 'gc_reliability_framework': return "GC Reliability Framework" case 'illink': return "via ILLink" default: if (isJitStressScenario(scenario)) { def displayStr = getStressModeDisplayName(scenario) return "Build and Test (Jit - ${displayStr})" } else if (isR2RScenario(scenario)) { def displayStr = getR2RDisplayName(scenario) return "${displayStr} Build and Test" } else { return "${scenario}" } break } println("Unknown scenario: ${scenario}"); assert false } // // Functions to create an environment script. // envScriptCreate -- initialize the script (call first) // envScriptFinalize -- finalize the script (call last) // envScriptSetStressModeVariables -- set stress mode variables in the env script // envScriptAppendExistingScript -- append an existing script to the generated script // // Each script returns a string of commands. Concatenate all the strings together before // adding them to the builds commands, to make sure they get executed as one Jenkins script. // // Initialize the environment setting script. def static envScriptCreate(def os, def stepScriptLocation) { def stepScript = '' if (os == 'Windows_NT') { stepScript += "echo Creating TestEnv script\r\n" stepScript += "if exist ${stepScriptLocation} del ${stepScriptLocation}\r\n" // Create at least an empty script. stepScript += "echo. > ${stepScriptLocation}\r\n" } else { stepScript += "echo Creating environment setting script\n" stepScript += "echo \\#\\!/usr/bin/env bash > ${stepScriptLocation}\n" } return stepScript } // Generates the string for setting stress mode variables. def static envScriptSetStressModeVariables(def os, def stressModeVars, def stepScriptLocation) { def stepScript = '' if (os == 'Windows_NT') { stressModeVars.each{ k, v -> // Write out what we are writing to the script file stepScript += "echo Setting ${k}=${v}\r\n" // Write out the set itself to the script file` stepScript += "echo set ${k}=${v} >> ${stepScriptLocation}\r\n" } } else { stressModeVars.each{ k, v -> // Write out what we are writing to the script file stepScript += "echo Setting ${k}=${v}\n" // Write out the set itself to the script file` stepScript += "echo export ${k}=${v} >> ${stepScriptLocation}\n" } } return stepScript } // Append an existing script to an environment script. // Returns string of commands to do this. def static envScriptAppendExistingScript(def os, def appendScript, def stepScriptLocation) { assert (os == 'Windows_NT') def stepScript = '' stepScript += "echo Appending ${appendScript} to ${stepScriptLocation}\r\n" stepScript += "type ${appendScript} >> ${stepScriptLocation}\r\n" return stepScript } // Finalize an environment setting script. // Returns string of commands to do this. def static envScriptFinalize(def os, def stepScriptLocation) { def stepScript = '' if (os == 'Windows_NT') { // Display the resulting script. This is useful when looking at the output log file. stepScript += "echo Display the total script ${stepScriptLocation}\r\n" stepScript += "type ${stepScriptLocation}\r\n" } else { stepScript += "chmod +x ${stepScriptLocation}\n" } return stepScript } def static isNeedDocker(def architecture, def os, def isBuild) { if (isBuild) { if (architecture == 'x86' && os == 'Ubuntu') { return true } else if (architecture == 'armem') { return true } else if (architecture == 'arm') { if (os == 'Ubuntu') { return true } } else if (architecture == 'arm64') { if (os == 'Ubuntu') { return true } } } else { if (architecture == 'x86' && os == 'Ubuntu') { return true } } return false } def static getDockerImageName(def architecture, def os, def isBuild) { // We must change some docker private images to official later if (isBuild) { if (architecture == 'x86' && os == 'Ubuntu') { return "hseok82/dotnet-buildtools-prereqs:ubuntu-16.04-crossx86-ef0ac75-20175511035548" } else if (architecture == 'armem') { if (os == 'Tizen') { return "tizendotnet/dotnet-buildtools-prereqs:ubuntu-16.04-cross-e435274-20180426002255-tizen-rootfs-5.0m1" } } else if (architecture == 'arm') { if (os == 'Ubuntu') { return "microsoft/dotnet-buildtools-prereqs:ubuntu-14.04-cross-e435274-20180426002420" } } else if (architecture == 'arm64') { if (os == 'Ubuntu') { return "microsoft/dotnet-buildtools-prereqs:ubuntu-16.04-cross-arm64-a3ae44b-20180315221921" } } } else { if (architecture == 'x86' && os == 'Ubuntu') { return "hseok82/dotnet-buildtools-prereqs:ubuntu1604_x86_test" } } println("Unknown architecture to use docker: ${architecture} ${os}"); assert false } // We have a limited amount of some hardware. For these, scale back the periodic testing we do, // and only allowing using this hardware in some specific branches. def static jobRequiresLimitedHardware(def architecture, def os) { if (((architecture == 'arm64') || (architecture == 'arm')) && (os == 'Windows_NT')) { // These test jobs require ARM64 hardware return true } else if ((architecture == 'arm') && (os == 'Ubuntu')) { // These test jobs require Linux/arm32 hardware return true } else if ((architecture == 'arm64') && (os == 'Ubuntu')) { // These test jobs require Linux/arm64 hardware return true } else { return false } } // Calculates the name of the build job based on some typical parameters. // def static getJobName(def configuration, def architecture, def os, def scenario, def isBuildOnly) { // If the architecture is x64, do not add that info into the build name. // Need to change around some systems and other builds to pick up the right builds // to do that. def suffix = scenario != 'normal' ? "_${scenario}" : ''; if (isBuildOnly) { suffix += '_bld' } def baseName = '' switch (architecture) { case 'x64': if (scenario == 'normal') { // For now we leave x64 off of the name for compatibility with other jobs baseName = configuration.toLowerCase() + '_' + os.toLowerCase() } else if (scenario == 'formatting') { // we don't care about the configuration for the formatting job. It runs all configs baseName = architecture.toLowerCase() + '_' + os.toLowerCase() } else { baseName = architecture.toLowerCase() + '_' + configuration.toLowerCase() + '_' + os.toLowerCase() } break case 'arm64': if (os.toLowerCase() == "windows_nt") { // These are cross builds baseName = architecture.toLowerCase() + '_cross_' + configuration.toLowerCase() + '_' + os.toLowerCase() } else { // Defaults to a small page size set of machines. baseName = architecture.toLowerCase() + '_' + configuration.toLowerCase() + '_' + "small_page_size" } break case 'armem': // These are cross builds assert os == 'Tizen' baseName = 'armel_cross_' + configuration.toLowerCase() + '_' + os.toLowerCase() break case 'arm': baseName = architecture.toLowerCase() + '_cross_' + configuration.toLowerCase() + '_' + os.toLowerCase() break case 'x86': case 'x86_arm_altjit': case 'x64_arm64_altjit': baseName = architecture.toLowerCase() + '_' + configuration.toLowerCase() + '_' + os.toLowerCase() break default: println("Unknown architecture: ${architecture}"); assert false break } return baseName + suffix } def static addNonPRTriggers(def job, def branch, def isPR, def architecture, def os, def configuration, def scenario, def isFlowJob, def isWindowsBuildOnlyJob, def bidailyCrossList) { def isNormalOrInnerloop = (scenario == "normal" || scenario == "innerloop") // Limited hardware is restricted for non-PR triggers to certain branches. if (jobRequiresLimitedHardware(architecture, os) && (!(branch in Constants.LimitedHardwareBranches))) { return } // No arm64 Ubuntu cron jobs for now: we don't have enough hardware. if ((architecture == 'arm64') && (os != 'Windows_NT')) { return } // Ubuntu x86 CI jobs are failing. Disable non-PR triggered jobs to avoid these constant failures // until this is fixed. Tracked by https://github.com/dotnet/coreclr/issues/19003. if (architecture == 'x86' && os == 'Ubuntu') { return } // Check scenario. switch (scenario) { case 'innerloop': case 'no_tiered_compilation_innerloop': case 'crossgen_comparison': break case 'normal': switch (architecture) { case 'x64': case 'x86': if (isFlowJob && architecture == 'x86' && os == 'Ubuntu') { addPeriodicTriggerHelper(job, '@daily') } else if (isFlowJob || os == 'Windows_NT' || !(os in Constants.crossList)) { addGithubPushTriggerHelper(job) } break case 'arm64': if (os == 'Windows_NT') { if (isFlowJob || (isNormalOrInnerloop && (configuration == 'Debug'))) { // We would normally want a per-push trigger, but with limited hardware we can't keep up. // Do the builds daily. addPeriodicTriggerHelper(job, '@daily') } } else { // Only the flow jobs get push triggers; the build and test jobs are triggered by the flow job. if (isFlowJob) { addPeriodicTriggerHelper(job, '@daily') } } break case 'arm': if (os == 'Windows_NT') { if (isFlowJob || (isNormalOrInnerloop && (configuration == 'Debug'))) { // We would normally want a push trigger, but with limited hardware we can't keep up. // Do the builds daily. addPeriodicTriggerHelper(job, '@daily') } } else { assert os == 'Ubuntu' // Only the flow jobs get push triggers; the build and test jobs are triggered by the flow job. if (isFlowJob) { // Currently no push triggers, with limited arm Linux hardware. // TODO: If we have enough machine capacity, add some arm Linux push triggers. addPeriodicTriggerHelper(job, '@daily') } } break case 'armem': addGithubPushTriggerHelper(job) break case 'x86_arm_altjit': case 'x64_arm64_altjit': // Only do altjit push triggers for Checked; don't waste time on Debug or Release. if (configuration == 'Checked') { addGithubPushTriggerHelper(job) } break default: println("Unknown architecture: ${architecture}"); assert false break } break case 'r2r': assert !(os in bidailyCrossList) // r2r gets a push trigger for checked/release if (configuration == 'Checked' || configuration == 'Release') { assert (os == 'Windows_NT') || (os in Constants.crossList) if (architecture == 'x64' && os != 'OSX10.12') { //Flow jobs should be Windows, Ubuntu, OSX0.12, or CentOS if (isFlowJob || os == 'Windows_NT') { addGithubPushTriggerHelper(job) } // OSX10.12 r2r jobs should only run every 12 hours, not daily. } else if (architecture == 'x64' && os == 'OSX10.12'){ if (isFlowJob) { addPeriodicTriggerHelper(job, 'H H/12 * * *') } } // For x86, only add per-commit jobs for Windows else if (architecture == 'x86') { if (os == 'Windows_NT') { addGithubPushTriggerHelper(job) } } // arm64 r2r jobs should only run weekly. // arm64 r2r jobs are only run on Windows (Q: should they run on non-Windows?) else if (architecture == 'arm64') { if (os == 'Windows_NT') { if (isFlowJob) { addPeriodicTriggerHelper(job, '@weekly') } } } // arm r2r jobs should only run weekly. else if (architecture == 'arm') { if (isFlowJob) { addPeriodicTriggerHelper(job, '@weekly') } } } break case 'r2r_jitstress1': case 'r2r_jitstress2': case 'r2r_jitstress1_tiered': case 'r2r_jitstress2_tiered': case 'r2r_jitstressregs1': case 'r2r_jitstressregs2': case 'r2r_jitstressregs3': case 'r2r_jitstressregs4': case 'r2r_jitstressregs8': case 'r2r_jitstressregs0x10': case 'r2r_jitstressregs0x80': case 'r2r_jitstressregs0x1000': case 'r2r_jitminopts': case 'r2r_jitforcerelocs': case 'r2r_gcstress15': case 'r2r_no_tiered_compilation': assert !(os in bidailyCrossList) // GCStress=C is currently not supported on OS X if (os == 'OSX10.12' && isGCStressRelatedTesting(scenario)) { break } // GC Stress 15 r2r gets a push trigger for checked/release if (configuration == 'Checked' || configuration == 'Release') { assert (os == 'Windows_NT') || (os in Constants.crossList) if (architecture == 'x64') { //Flow jobs should be Windows, Ubuntu, OSX10.12, or CentOS if (isFlowJob || os == 'Windows_NT') { // Add a weekly periodic trigger addPeriodicTriggerHelper(job, 'H H * * 3,6') // some time every Wednesday and Saturday } } // For x86, only add periodic jobs for Windows else if (architecture == 'x86') { if (os == 'Windows_NT') { addPeriodicTriggerHelper(job, 'H H * * 3,6') // some time every Wednesday and Saturday } } // arm64 r2r jobs are only run on Windows (Q: should they run on non-Windows?) else if (architecture == 'arm64') { if (os == 'Windows_NT') { if (isFlowJob) { addPeriodicTriggerHelper(job, '@weekly') } } } else if (architecture == 'arm') { if (isFlowJob) { addPeriodicTriggerHelper(job, '@weekly') } } } break case 'longgc': assert (os == 'Ubuntu' || os == 'Windows_NT' || os == 'OSX10.12') assert configuration == 'Release' assert architecture == 'x64' addPeriodicTriggerHelper(job, '@daily') // TODO: Add once external email sending is available again // addEmailPublisher(job, 'dotnetgctests@microsoft.com') break case 'gcsimulator': assert (os == 'Ubuntu' || os == 'Windows_NT' || os == 'OSX10.12') assert configuration == 'Release' assert architecture == 'x64' addPeriodicTriggerHelper(job, 'H H * * 3,6') // some time every Wednesday and Saturday // TODO: Add once external email sending is available again // addEmailPublisher(job, 'dotnetgctests@microsoft.com') break case 'standalone_gc': assert (os == 'Ubuntu' || os == 'Windows_NT' || os == 'OSX10.12') assert (configuration == 'Release' || configuration == 'Checked') // TODO: Add once external email sending is available again // addEmailPublisher(job, 'dotnetgctests@microsoft.com') addPeriodicTriggerHelper(job, '@daily') break case 'gc_reliability_framework': assert (os == 'Ubuntu' || os == 'Windows_NT' || os == 'OSX10.12') assert (configuration == 'Release' || configuration == 'Checked') // Only triggered by phrase. break case 'ilrt': assert !(os in bidailyCrossList) // ILASM/ILDASM roundtrip one gets a daily build, and only for release if (architecture == 'x64' && configuration == 'Release') { // We don't expect to see a job generated except in these scenarios assert (os == 'Windows_NT') || (os in Constants.crossList) if (isFlowJob || os == 'Windows_NT') { addPeriodicTriggerHelper(job, '@daily') } } break case 'jitdiff': assert (os == 'Ubuntu' || os == 'Windows_NT' || os == 'OSX10.12') assert configuration == 'Checked' assert (architecture == 'x64' || architecture == 'x86') addGithubPushTriggerHelper(job) break case 'formatting': assert (os == 'Windows_NT' || os == "Ubuntu") assert architecture == 'x64' addGithubPushTriggerHelper(job) break case 'jitstressregs1': case 'jitstressregs2': case 'jitstressregs3': case 'jitstressregs4': case 'jitstressregs8': case 'jitstressregs0x10': case 'jitstressregs0x80': case 'jitstressregs0x1000': case 'minopts': case 'tieredcompilation': case 'no_tiered_compilation': case 'forcerelocs': case 'jitstress1': case 'jitstress2': case 'jitstress1_tiered': case 'jitstress2_tiered': case 'jitstress2_jitstressregs1': case 'jitstress2_jitstressregs2': case 'jitstress2_jitstressregs3': case 'jitstress2_jitstressregs4': case 'jitstress2_jitstressregs8': case 'jitstress2_jitstressregs0x10': case 'jitstress2_jitstressregs0x80': case 'jitstress2_jitstressregs0x1000': case 'tailcallstress': case 'jitsse2only': case 'jitnosimd': case 'jitnox86hwintrinsic': case 'jitincompletehwintrinsic': case 'jitx86hwintrinsicnoavx': case 'jitx86hwintrinsicnoavx2': case 'jitx86hwintrinsicnosimd': case 'corefx_baseline': case 'corefx_minopts': case 'corefx_tieredcompilation': case 'corefx_jitstress1': case 'corefx_jitstress2': case 'corefx_jitstressregs1': case 'corefx_jitstressregs2': case 'corefx_jitstressregs3': case 'corefx_jitstressregs4': case 'corefx_jitstressregs8': case 'corefx_jitstressregs0x10': case 'corefx_jitstressregs0x80': case 'corefx_jitstressregs0x1000': case 'zapdisable': if (os == 'CentOS7.1') { break } if (os in bidailyCrossList) { break } // ARM corefx testing uses non-flow jobs to provide the configuration-specific // build for the flow job. We don't need cron jobs for these. Note that the // Windows ARM jobs depend on a Windows "build only" job that exits the trigger // function very early, so only non-Windows gets here. if ((architecture == 'arm') && isCoreFxScenario(scenario) && !isFlowJob) { break } if ((architecture == 'arm64') && isCoreFxScenario(scenario) && !isFlowJob) { break } assert (os == 'Windows_NT') || (os in Constants.crossList) if (jobRequiresLimitedHardware(architecture, os)) { addPeriodicTriggerHelper(job, '@weekly') } else { addPeriodicTriggerHelper(job, '@daily') } break case 'heapverify1': case 'gcstress0x3': if (os == 'CentOS7.1') { break } if (os in bidailyCrossList) { break } if ((architecture == 'arm64') && (os != 'Windows_NT')) { // TODO: should we have cron jobs for arm64 Linux GCStress? break } assert (os == 'Windows_NT') || (os in Constants.crossList) addPeriodicTriggerHelper(job, '@weekly') break case 'gcstress0xc': case 'gcstress0xc_zapdisable': case 'gcstress0xc_zapdisable_jitstress2': case 'gcstress0xc_zapdisable_heapverify1': case 'gcstress0xc_jitstress1': case 'gcstress0xc_jitstress2': case 'gcstress0xc_minopts_heapverify1': if (os == 'CentOS7.1') { break } if (os == 'OSX10.12') { // GCStress=C is currently not supported on OS X break } if (os in bidailyCrossList) { break } if ((architecture == 'arm64') && (os != 'Windows_NT')) { // TODO: should we have cron jobs for arm64 Linux GCStress? break } assert (os == 'Windows_NT') || (os in Constants.crossList) addPeriodicTriggerHelper(job, '@weekly') break case 'illink': // Testing on other operating systems TBD assert (os == 'Windows_NT' || os == 'Ubuntu') if (architecture == 'x64' || architecture == 'x86') { if (configuration == 'Checked') { addPeriodicTriggerHelper(job, '@daily') } } break default: println("Unknown scenario: ${scenario}"); assert false break } return } // ************************** // Define the basic inner loop builds for PR and commit. This is basically just the set // of coreclr builds over linux/osx 10.12/windows and debug/release/checked. In addition, the windows // builds will do a couple extra steps. // ************************** // Adds a trigger for the PR build if one is needed. If isFlowJob is true, then this is the // flow job that rolls up the build and test for non-windows OS's. // If the job is a windows build only job, // it's just used for internal builds // If you add a job with a trigger phrase, please add that phrase to coreclr/Documentation/project-docs/ci-trigger-phrases.md def static addTriggers(def job, def branch, def isPR, def architecture, def os, def configuration, def scenario, def isFlowJob, def isWindowsBuildOnlyJob) { def isNormalOrInnerloop = (scenario == "normal" || scenario == "innerloop") if (isWindowsBuildOnlyJob) { return } def bidailyCrossList = ['RHEL7.2', 'Debian8.4'] // Non pull request builds. if (!isPR) { addNonPRTriggers(job, branch, isPR, architecture, os, configuration, scenario, isFlowJob, isWindowsBuildOnlyJob, bidailyCrossList) return } def arm64Users = [ 'adityamandaleeka', 'AndyAyersMS', 'briansull', 'BruceForstall', 'CarolEidt', 'davidwrighton', 'echesakovMSFT', 'erozenfeld', 'janvorli', 'jashook', 'pgodeq', 'RussKeldorph', 'sandreenko', 'sdmaclea', 'swaroop-sridhar', 'jkotas', 'markwilkie', 'weshaggard' ] // Pull request builds. Generally these fall into two categories: default triggers and on-demand triggers // We generally only have a distinct set of default triggers but a bunch of on-demand ones. def contextString = "" def triggerString = "" def needsTrigger = true def isDefaultTrigger = false def isArm64PrivateJob = false def scenarioString = "" // Set up default context string and trigger phrases. This is overridden in places, sometimes just to keep // the existing non-standard descriptions and phrases. In some cases, the scenarios are asymmetric, as for // some jobs where the Debug configuration just does builds, no tests. // // Some configurations, like arm32/arm64, always use the exact scenario name as part of the context string. // This makes it possible to copy/paste the displayed context string as "@dotnet-bot test " // to invoke the trigger. Any "fancy" context string makes that impossible, requiring the user to either // remember the mapping from context string to trigger string, or use "@dotnet-bot help" to look it up. if (architecture == 'armem') { assert os == 'Tizen' architecture = 'armel' } switch (architecture) { case 'x64_arm64_altjit': case 'x86_arm_altjit': // TODO: for consistency, add "Build and Test" at end. contextString = "${os} ${architecture} ${configuration} ${scenario}" triggerString = "(?i).*test\\W+${os}\\W+${architecture}\\W+${configuration}\\W+${scenario}.*" break case 'armel': case 'arm': case 'arm64': contextString = "${os} ${architecture} Cross ${configuration}" triggerString = "(?i).*test\\W+${os}\\W+${architecture}\\W+Cross\\W+${configuration}" if (scenario == 'innerloop') { contextString += " Innerloop" triggerString += "\\W+Innerloop" } else { contextString += " ${scenario}" triggerString += "\\W+${scenario}" } if (configuration == 'Debug') { contextString += " Build" triggerString += "\\W+Build" } else { contextString += " Build and Test" triggerString += "\\W+Build and Test" } triggerString += ".*" break default: scenarioString = getScenarioDisplayString(scenario) contextString = "${os} ${architecture} ${configuration} ${scenarioString}" triggerString = "(?i).*test\\W+${os}\\W+${architecture}\\W+${configuration}" switch (scenario) { case 'normal': triggerString += "\\W+Build and Test.*" break case 'corefx_innerloop': // maintain this asymmetry triggerString += "\\W+CoreFX Tests.*" break default: triggerString += "\\W+${scenario}.*" break } triggerString += ".*" break } // Now determine what kind of trigger this job needs, if any. Any job should be triggerable, except for // non-flow jobs that are only used as part of flow jobs. switch (architecture) { case 'x64': // editor brace matching: { if (scenario == 'formatting') { assert configuration == 'Checked' if (os == 'Windows_NT' || os == 'Ubuntu') { isDefaultTrigger = true contextString = "${os} ${architecture} Formatting" } break } switch (os) { // OpenSUSE, Debian & RedHat get trigger phrases for pri 0 build, and pri 1 build & test case 'Debian8.4': case 'RHEL7.2': if (scenario == 'innerloop') { assert !isFlowJob contextString = "${os} ${architecture} ${configuration} Innerloop Build" isDefaultTrigger = true break } // fall through case 'Fedora24': case 'Ubuntu16.04': case 'Ubuntu16.10': assert !isFlowJob assert scenario != 'innerloop' contextString = "${os} ${architecture} ${configuration} Build" triggerString = "(?i).*test\\W+${os}\\W+${architecture}\\W+${configuration}\\W+Build.*" break case 'Ubuntu': if (scenario == 'illink') { break } else if (scenario == 'corefx_innerloop') { if (configuration == 'Checked') { isDefaultTrigger = true } break } // fall through case 'OSX10.12': // Triggers on the non-flow jobs aren't necessary here // Corefx testing uses non-flow jobs. if (!isFlowJob && !isCoreFxScenario(scenario)) { needsTrigger = false break } switch (scenario) { case 'innerloop': isDefaultTrigger = true break case 'no_tiered_compilation_innerloop': if (os == 'Ubuntu') { isDefaultTrigger = true } break default: break } break case 'CentOS7.1': switch (scenario) { case 'innerloop': // CentOS uses checked for default PR tests while debug is build only if (configuration == 'Debug') { isDefaultTrigger = true contextString = "${os} ${architecture} ${configuration} Innerloop Build" break } // Make sure this is a flow job to get build and test. if (!isFlowJob) { needsTrigger = false break } if (configuration == 'Checked') { assert job.name.contains("flow") isDefaultTrigger = true contextString = "${os} ${architecture} ${configuration} Innerloop Build and Test" } break case 'normal': // Make sure this is a flow job to get build and test. if (!isFlowJob) { needsTrigger = false break } break default: break } break case 'Windows_NT': switch (scenario) { case 'innerloop': case 'no_tiered_compilation_innerloop': isDefaultTrigger = true break case 'corefx_innerloop': if (configuration == 'Checked' || configuration == 'Release') { isDefaultTrigger = true } break default: break } break default: println("Unknown os: ${os}"); assert false break } // switch (os) break // editor brace matching: } case 'armel': // editor brace matching: { job.with { publishers { azureVMAgentPostBuildAction { agentPostBuildAction('Delete agent if the build was not successful (when idle).') } } } switch (os) { case 'Tizen': if (scenario == 'innerloop') { if (configuration == 'Checked') { isDefaultTrigger = true } } break } break // editor brace matching: } case 'arm': case 'arm64': // editor brace matching: { switch (os) { case 'Ubuntu': // TODO: make arm and arm64 Ubuntu more alike if (architecture == 'arm') { // Triggers on the non-flow jobs aren't necessary if (!isFlowJob) { needsTrigger = false break } switch (scenario) { case 'innerloop': case 'no_tiered_compilation_innerloop': if (configuration == 'Checked') { isDefaultTrigger = true } break } } else { assert architecture == 'arm64' switch (scenario) { case 'innerloop': if (configuration == 'Debug' && !isFlowJob) { isDefaultTrigger = true } break } } break case 'Windows_NT': assert isArmWindowsScenario(scenario) // For Debug normal/innerloop scenario, we don't do test runs, so we don't use flow jobs. That means we need a trigger for // the non-flow Build job. All others need a trigger on the flow job. def needsFlowJobTrigger = !(isNormalOrInnerloop && (configuration == 'Debug')) if (isFlowJob != needsFlowJobTrigger) { needsTrigger = false break } switch (scenario) { case 'innerloop': if (configuration == 'Debug') { // Add default PR trigger for Windows arm64 Debug builds. This is a build only -- no tests are run -- // so the private test hardware is not used. Thus, it can be run by all users, not just arm64Users. // People in arm64Users will get both this and the Checked Build and Test job. isDefaultTrigger = true } else if (configuration == 'Checked') { isDefaultTrigger = true isArm64PrivateJob = true } break default: isArm64PrivateJob = true break } break default: println("NYI os: ${os}"); assert false break } break // editor brace matching: } case 'x86': // editor brace matching: { assert ((os == 'Windows_NT') || ((os == 'Ubuntu') && isNormalOrInnerloop)) if (os == 'Ubuntu') { // Triggers on the non-flow jobs aren't necessary here if (!isFlowJob) { needsTrigger = false break } // on-demand only for ubuntu x86 contextString = "${os} ${architecture} ${configuration} Build" triggerString = "(?i).*test\\W+${os}\\W+${architecture}\\W+${configuration}.*" break } switch (scenario) { case 'innerloop': case 'no_tiered_compilation_innerloop': isDefaultTrigger = true break default: break } break // editor brace matching: } case 'x64_arm64_altjit': case 'x86_arm_altjit': // Everything default break default: println("Unknown architecture: ${architecture}"); assert false break } if (needsTrigger) { if (isArm64PrivateJob) { if (isDefaultTrigger) { Utilities.addDefaultPrivateGithubPRTriggerForBranch(job, branch, contextString, null, arm64Users) } else { Utilities.addPrivateGithubPRTriggerForBranch(job, branch, contextString, triggerString, null, arm64Users) } } else { if (isDefaultTrigger) { Utilities.addGithubPRTriggerForBranch(job, branch, contextString) } else { Utilities.addGithubPRTriggerForBranch(job, branch, contextString, triggerString) } } } } def static calculateBuildCommands(def newJob, def scenario, def branch, def isPR, def architecture, def configuration, def os, def isBuildOnly) { def buildCommands = [] def osGroup = getOSGroup(os) def lowerConfiguration = configuration.toLowerCase() def priority = '1' if (isInnerloopTestScenario(scenario)) { priority = '0' } def doCoreFxTesting = isCoreFxScenario(scenario) // Calculate the build steps, archival, and xunit results switch (os) { case 'Windows_NT': // editor brace matching: { switch (architecture) { case 'x64': case 'x86': case 'x86_arm_altjit': case 'x64_arm64_altjit': def arch = architecture def buildOpts = '' if (architecture == 'x86_arm_altjit') { arch = 'x86' } else if (architecture == 'x64_arm64_altjit') { arch = 'x64' } if (scenario == 'formatting') { buildCommands += "python -u tests\\scripts\\format.py -c %WORKSPACE% -o Windows_NT -a ${arch}" Utilities.addArchival(newJob, "format.patch", "", true, false) break } if (scenario == 'illink') { buildCommands += "tests\\scripts\\build_illink.cmd clone ${arch}" } // If it is a release build for Windows, ensure PGO is used, else fail the build. if ((lowerConfiguration == 'release') && (scenario in Constants.basicScenarios) && (architecture != 'x86_arm_altjit') && (architecture != 'x64_arm64_altjit')) { buildOpts += ' -enforcepgo' } if (doCoreFxTesting) { buildOpts += ' skiptests'; } else { buildOpts += " -priority=${priority}" } // Set __TestIntermediateDir to something short. If __TestIntermediateDir is already set, build-test.cmd will // output test binaries to that directory. If it is not set, the binaries are sent to a default directory whose name is about // 35 characters long. buildCommands += "set __TestIntermediateDir=int&&build.cmd ${lowerConfiguration} ${arch} ${buildOpts}" if (!isBuildOnly) { def runtestArguments = '' def testOpts = 'collectdumps' if (isR2RScenario(scenario)) { // If this is a ReadyToRun scenario, pass 'crossgen' or 'crossgenaltjit' // to cause framework assemblies to be crossgen'ed. Pass 'runcrossgentests' // to cause the tests to be crossgen'ed. if ((architecture == 'x86_arm_altjit') || (architecture == 'x64_arm64_altjit')) { testOpts += ' crossgenaltjit protononjit.dll' } else { testOpts += ' crossgen' } testOpts += ' runcrossgentests' } else if (scenario == 'jitdiff') { testOpts += ' jitdisasm crossgen' } else if (scenario == 'ilrt') { testOpts += ' ilasmroundtrip' } else if (isLongGc(scenario)) { testOpts += " ${scenario} sequential" } else if (scenario == 'standalone_gc') { testOpts += ' gcname clrgc.dll' } else if (scenario == 'illink') { testOpts += " link %WORKSPACE%\\linker\\linker\\bin\\netcore_Release\\netcoreapp2.0\\win10-${arch}\\publish\\illink.exe" } // Default per-test timeout is 10 minutes. For stress modes and Debug scenarios, increase this // to 30 minutes (30 * 60 * 1000 = 180000). The "timeout" argument to runtest.cmd sets this, by // taking a timeout value in milliseconds. (Note that it sets the __TestTimeout environment variable, // which is read by the xunit harness.) if (isJitStressScenario(scenario) || isR2RStressScenario(scenario) || (lowerConfiguration == 'debug')) { def timeout = 1800000 testOpts += " timeout ${timeout}" } // If we are running a stress mode, we should write out the set of key // value env pairs to a file at this point and then we'll pass that to runtest.cmd def envScriptPath = '' if (isJitStressScenario(scenario) || isR2RStressScenario(scenario)) { def buildCommandsStr = '' envScriptPath = "%WORKSPACE%\\SetStressModes.bat" buildCommandsStr += envScriptCreate(os, envScriptPath) if (isJitStressScenario(scenario)) { buildCommandsStr += envScriptSetStressModeVariables(os, Constants.jitStressModeScenarios[scenario], envScriptPath) } else if (isR2RStressScenario(scenario)) { buildCommandsStr += envScriptSetStressModeVariables(os, Constants.r2rStressScenarios[scenario], envScriptPath) } if (architecture == 'x86_arm_altjit') { buildCommandsStr += envScriptAppendExistingScript(os, "%WORKSPACE%\\tests\\x86_arm_altjit.cmd", envScriptPath) } else if (architecture == 'x64_arm64_altjit') { buildCommandsStr += envScriptAppendExistingScript(os, "%WORKSPACE%\\tests\\x64_arm64_altjit.cmd", envScriptPath) } envScriptFinalize(os, envScriptPath) // Note that buildCommands is an array of individually executed commands; we want all the commands used to // create the SetStressModes.bat script to be executed together, hence we accumulate them as strings // into a single script. buildCommands += buildCommandsStr } else if (architecture == 'x86_arm_altjit') { envScriptPath = "%WORKSPACE%\\tests\\x86_arm_altjit.cmd" } else if (architecture == 'x64_arm64_altjit') { envScriptPath = "%WORKSPACE%\\tests\\x64_arm64_altjit.cmd" } if (envScriptPath != '') { testOpts += " TestEnv ${envScriptPath}" } runtestArguments = "${lowerConfiguration} ${arch} ${testOpts}" if (doCoreFxTesting) { if (scenario == 'corefx_innerloop') { // Create CORE_ROOT and testhost buildCommands += "build-test.cmd ${lowerConfiguration} ${arch} buildtesthostonly" buildCommands += "tests\\runtest.cmd ${runtestArguments} CoreFXTestsAll" // Archive and process (only) the test results Utilities.addArchival(newJob, "bin/Logs/**/testResults.xml") Utilities.addXUnitDotNETResults(newJob, "bin/Logs/**/testResults.xml") } else { def workspaceRelativeFxRoot = "_/fx" def absoluteFxRoot = "%WORKSPACE%\\_\\fx" def fxBranch = getFxBranch(branch) buildCommands += "python -u %WORKSPACE%\\tests\\scripts\\run-corefx-tests.py -arch ${arch} -ci_arch ${architecture} -build_type ${configuration} -fx_root ${absoluteFxRoot} -fx_branch ${fxBranch} -env_script ${envScriptPath}" // Archive and process (only) the test results Utilities.addArchival(newJob, "${workspaceRelativeFxRoot}/bin/**/testResults.xml") Utilities.addXUnitDotNETResults(newJob, "${workspaceRelativeFxRoot}/bin/**/testResults.xml") //Archive additional build stuff to diagnose why my attempt at fault injection isn't causing CI to fail Utilities.addArchival(newJob, "SetStressModes.bat", "", true, false) Utilities.addArchival(newJob, "${workspaceRelativeFxRoot}/bin/testhost/**", "", true, false) } } else if (isGcReliabilityFramework(scenario)) { buildCommands += "tests\\runtest.cmd ${runtestArguments} GenerateLayoutOnly" buildCommands += "tests\\scripts\\run-gc-reliability-framework.cmd ${arch} ${configuration}" } else { buildCommands += "tests\\runtest.cmd ${runtestArguments}" } } // end if (!isBuildOnly) if (!doCoreFxTesting) { // Run the rest of the build // Build the mscorlib for the other OS's buildCommands += "build.cmd ${lowerConfiguration} ${arch} linuxmscorlib" buildCommands += "build.cmd ${lowerConfiguration} ${arch} osxmscorlib" if (arch == 'x64') { buildCommands += "build.cmd ${lowerConfiguration} arm64 linuxmscorlib" } // Zip up the tests directory so that we don't use so much space/time copying // 10s of thousands of files around. buildCommands += "powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::CreateFromDirectory('.\\bin\\tests\\${osGroup}.${arch}.${configuration}', '.\\bin\\tests\\tests.zip')\""; if (!isJitStressScenario(scenario)) { // For Windows, pull full test results and test drops for x86/x64. // No need to pull for stress mode scenarios (downstream builds use the default scenario) Utilities.addArchival(newJob, "bin/Product/**,bin/tests/tests.zip", "bin/Product/**/.nuget/**") } if (scenario == 'jitdiff') { // retrieve jit-dasm output for base commit, and run jit-diff if (!isBuildOnly) { // if this is a build only job, we want to keep the default (build) artifacts for the flow job Utilities.addArchival(newJob, "bin/tests/${osGroup}.${arch}.${configuration}/dasm/**") } } if (!isBuildOnly) { Utilities.addXUnitDotNETResults(newJob, 'bin/**/TestRun*.xml', true) } } break case 'arm': case 'arm64': assert isArmWindowsScenario(scenario) def buildOpts = '' if (doCoreFxTesting) { buildOpts += ' skiptests' } else { buildOpts += " -priority=${priority}" } // This is now a build only job. Do not run tests. Use the flow job. buildCommands += "set __TestIntermediateDir=int&&build.cmd ${lowerConfiguration} ${architecture} ${buildOpts}" if (doCoreFxTesting) { assert isBuildOnly // Set the stress mode variables; this is incorporated into the generated CoreFx RunTests.cmd files. def envScriptPath = '' def buildCommandsStr = '' envScriptPath = "%WORKSPACE%\\SetStressModes.bat" buildCommandsStr += envScriptCreate(os, envScriptPath) buildCommandsStr += envScriptSetStressModeVariables(os, Constants.jitStressModeScenarios[scenario], envScriptPath) envScriptFinalize(os, envScriptPath) buildCommands += buildCommandsStr def workspaceRelativeFxRootLinux = "_/fx" def workspaceRelativeFxRootWin = "_\\fx" def absoluteFxRoot = "%WORKSPACE%\\_\\fx" def fxBranch = getFxBranch(branch) buildCommands += "python -u %WORKSPACE%\\tests\\scripts\\run-corefx-tests.py -arch ${architecture} -ci_arch ${architecture} -build_type ${configuration} -fx_root ${absoluteFxRoot} -fx_branch ${fxBranch} -env_script ${envScriptPath} -no_run_tests" // Zip up the CoreFx runtime and tests. We don't need the CoreCLR binaries; they have been copied to the CoreFX tree. buildCommands += "powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::CreateFromDirectory('${workspaceRelativeFxRootWin}\\bin\\testhost\\netcoreapp-Windows_NT-Release-${architecture}', '${workspaceRelativeFxRootWin}\\fxruntime.zip')\""; buildCommands += "powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::CreateFromDirectory('${workspaceRelativeFxRootWin}\\bin\\tests', '${workspaceRelativeFxRootWin}\\fxtests.zip')\""; Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/fxruntime.zip") Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/fxtests.zip") } else { // Zip up the tests directory so that we don't use so much space/time copying // 10s of thousands of files around. buildCommands += "powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::CreateFromDirectory('.\\bin\\tests\\${osGroup}.${architecture}.${configuration}', '.\\bin\\tests\\tests.zip')\""; // Add archival. Utilities.addArchival(newJob, "bin/Product/**,bin/tests/tests.zip", "bin/Product/**/.nuget/**") } break default: println("Unknown architecture: ${architecture}"); assert false break } break // end case 'Windows_NT'; editor brace matching: } case 'Ubuntu': case 'Ubuntu16.04': case 'Ubuntu16.10': case 'Debian8.4': case 'OSX10.12': case 'CentOS7.1': case 'RHEL7.2': case 'Tizen': case 'Fedora24': // editor brace matching: { switch (architecture) { case 'x64': case 'x86': if (architecture == 'x86' && os == 'Ubuntu') { // build and PAL test def dockerImage = getDockerImageName(architecture, os, true) buildCommands += "docker run -i --rm -v \${WORKSPACE}:/opt/code -w /opt/code -e ROOTFS_DIR=/crossrootfs/x86 ${dockerImage} ./build.sh ${architecture} cross ${lowerConfiguration}" dockerImage = getDockerImageName(architecture, os, false) buildCommands += "docker run -i --rm -v \${WORKSPACE}:/opt/code -w /opt/code ${dockerImage} ./src/pal/tests/palsuite/runpaltests.sh /opt/code/bin/obj/${osGroup}.${architecture}.${configuration} /opt/code/bin/paltestout" Utilities.addArchival(newJob, "bin/Product/**,bin/obj/*/tests/**/*.so", "bin/Product/**/.nuget/**") Utilities.addXUnitDotNETResults(newJob, '**/pal_tests.xml') break } if (scenario == 'formatting') { buildCommands += "python tests/scripts/format.py -c \${WORKSPACE} -o Linux -a ${architecture}" Utilities.addArchival(newJob, "format.patch", "", true, false) break } if (scenario == 'illink') { assert(os == 'Ubuntu') buildCommands += "./tests/scripts/build_illink.sh --clone --arch=${architecture}" } if (!doCoreFxTesting) { // We run pal tests on all OS but generate mscorlib (and thus, nuget packages) // only on supported OS platforms. def bootstrapRid = Utilities.getBoostrapPublishRid(os) def bootstrapRidEnv = bootstrapRid != null ? "__PUBLISH_RID=${bootstrapRid} " : '' buildCommands += "${bootstrapRidEnv}./build.sh ${lowerConfiguration} ${architecture}" buildCommands += "src/pal/tests/palsuite/runpaltests.sh \${WORKSPACE}/bin/obj/${osGroup}.${architecture}.${configuration} \${WORKSPACE}/bin/paltestout" // Basic archiving of the build Utilities.addArchival(newJob, "bin/Product/**,bin/obj/*/tests/**/*.dylib,bin/obj/*/tests/**/*.so", "bin/Product/**/.nuget/**") // And pal tests Utilities.addXUnitDotNETResults(newJob, '**/pal_tests.xml') } else { if (scenario == 'corefx_innerloop') { assert os == 'Ubuntu' || 'OSX10.12' assert architecture == 'x64' buildCommands += "./build.sh ${lowerConfiguration} ${architecture} skiptests" buildCommands += "./build-test.sh ${lowerConfiguration} ${architecture} generatetesthostonly" buildCommands += "./tests/runtest.sh --corefxtestsall --testHostDir=\${WORKSPACE}/bin/tests/${osGroup}.${architecture}.${configuration}/testhost/ --coreclr-src=\${WORKSPACE}" break // Archive and process (only) the test results Utilities.addArchival(newJob, "bin/Logs/**/testResults.xml") Utilities.addXUnitDotNETResults(newJob, "bin/Logs/**/testResults.xml") } else { // Corefx stress testing assert os == 'Ubuntu' assert architecture == 'x64' assert lowerConfiguration == 'checked' assert isJitStressScenario(scenario) // Build coreclr buildCommands += "./build.sh ${lowerConfiguration} ${architecture}" def scriptFileName = "\$WORKSPACE/set_stress_test_env.sh" def envScriptCmds = envScriptCreate(os, scriptFileName) envScriptCmds += envScriptSetStressModeVariables(os, Constants.jitStressModeScenarios[scenario], scriptFileName) envScriptCmds += envScriptFinalize(os, scriptFileName) buildCommands += envScriptCmds // Build and text corefx def workspaceRelativeFxRoot = "_/fx" def absoluteFxRoot = "\$WORKSPACE/${workspaceRelativeFxRoot}" def fxBranch = getFxBranch(branch) buildCommands += "python -u \$WORKSPACE/tests/scripts/run-corefx-tests.py -arch ${architecture} -ci_arch ${architecture} -build_type ${configuration} -fx_root ${absoluteFxRoot} -fx_branch ${fxBranch} -env_script ${scriptFileName}" // Archive and process (only) the test results Utilities.addArchival(newJob, "${workspaceRelativeFxRoot}/bin/**/testResults.xml") Utilities.addXUnitDotNETResults(newJob, "${workspaceRelativeFxRoot}/bin/**/testResults.xml") } } break case 'armem': // Emulator cross builds for ARM runs on Tizen currently assert os == 'Tizen' def arm_abi = "armel" def linuxCodeName = "tizen" // Unzip the Windows test binaries first. Exit with 0 buildCommands += "unzip -q -o ./bin/tests/tests.zip -d ./bin/tests/Windows_NT.x64.${configuration} || exit 0" // Unpack the corefx binaries buildCommands += "mkdir ./bin/CoreFxBinDir" buildCommands += "tar -xf ./bin/build.tar.gz -C ./bin/CoreFxBinDir" // Call the ARM CI script to cross build and test using docker buildCommands += """./tests/scripts/arm32_ci_script.sh \\ --mode=docker \\ --${arm_abi} \\ --linuxCodeName=${linuxCodeName} \\ --buildConfig=${lowerConfiguration} \\ --testRootDir=./bin/tests/Windows_NT.x64.${configuration} \\ --coreFxBinDir=./bin/CoreFxBinDir \\ --testDirFile=./tests/testsRunningInsideARM.txt""" // Basic archiving of the build, no pal tests Utilities.addArchival(newJob, "bin/Product/**,bin/obj/*/tests/**/*.dylib,bin/obj/*/tests/**/*.so", "bin/Product/**/.nuget/**") break case 'arm64': case 'arm': // Non-Windows ARM cross builds on hardware run on Ubuntu only assert (os == 'Ubuntu') // Add some useful information to the log file. Ignore return codes. buildCommands += "uname -a || true" def additionalOpts = "" if (architecture == 'arm') { additionalOpts = "-e CAC_ROOTFS_DIR=/crossrootfs/x86" } // Cross build the Ubuntu/arm product using docker with a docker image that contains the correct // Ubuntu cross-compilation toolset (running on a Ubuntu x64 host). // For CoreFX testing, we only need the product build; we don't need to generate the layouts. The product // build is then copied into the corefx layout by the run-corefx-test.py script. For CoreFX testing, we // ZIP up the generated CoreFX runtime and tests. def dockerImage = getDockerImageName(architecture, os, true) def dockerCmd = "docker run -i --rm -v \${WORKSPACE}:\${WORKSPACE} -w \${WORKSPACE} -e ROOTFS_DIR=/crossrootfs/${architecture} ${additionalOpts} ${dockerImage} " buildCommands += "${dockerCmd}\${WORKSPACE}/build.sh ${lowerConfiguration} ${architecture} cross crosscomponent" if (doCoreFxTesting) { def scriptFileName = "\$WORKSPACE/set_stress_test_env.sh" def envScriptCmds = envScriptCreate(os, scriptFileName) envScriptCmds += envScriptSetStressModeVariables(os, Constants.jitStressModeScenarios[scenario], scriptFileName) envScriptCmds += envScriptFinalize(os, scriptFileName) buildCommands += envScriptCmds // Build and text corefx def workspaceRelativeFxRootLinux = "_/fx" def absoluteFxRoot = "\$WORKSPACE/${workspaceRelativeFxRootLinux}" def fxBranch = getFxBranch(branch) buildCommands += "${dockerCmd}python -u \$WORKSPACE/tests/scripts/run-corefx-tests.py -arch ${architecture} -ci_arch ${architecture} -build_type ${configuration} -fx_root ${absoluteFxRoot} -fx_branch ${fxBranch} -env_script ${scriptFileName} -no_run_tests" // Docker creates files with root permission, so we need to zip in docker also, or else we'll get permission errors. buildCommands += "${dockerCmd}zip -r ${workspaceRelativeFxRootLinux}/fxruntime.zip ${workspaceRelativeFxRootLinux}/bin/testhost/netcoreapp-Linux-Release-${architecture}" buildCommands += "${dockerCmd}zip -r ${workspaceRelativeFxRootLinux}/fxtests.zip ${workspaceRelativeFxRootLinux}/bin/tests" Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/fxruntime.zip") Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/fxtests.zip") Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/run-test.sh") } else if (isCrossGenComparisonScenario(scenario)) { buildCommands += "${dockerCmd}\${WORKSPACE}/build-test.sh ${lowerConfiguration} ${architecture} cross generatelayoutonly" def crossArchitecture = getCrossArchitecture(os, architecture, scenario) def workspaceRelativeProductBinDir = "bin/Product/${osGroup}.${architecture}.${configuration}" def workspaceRelativeCoreLib = "${workspaceRelativeProductBinDir}/IL/System.Private.CoreLib.dll" def workspaceRelativeCoreRootDir = "bin/tests/${osGroup}.${architecture}.${configuration}/Tests/Core_Root" def workspaceRelativeCrossGenComparisonScript = "tests/scripts/crossgen_comparison.py" def workspaceRelativeCrossResultDir = "_/${osGroup}.${crossArchitecture}_${architecture}.${configuration}" def workspaceRelativeArtifactsArchive = "${os}.${architecture}.${configuration}.${scenario}.zip" def crossGenComparisonCmd = "python -u \${WORKSPACE}/${workspaceRelativeCrossGenComparisonScript} " def crossGenExecutable = "\${WORKSPACE}/${workspaceRelativeProductBinDir}/${crossArchitecture}/crossgen" buildCommands += "${dockerCmd}mkdir -p \${WORKSPACE}/${workspaceRelativeCrossResultDir}" buildCommands += "${dockerCmd}${crossGenComparisonCmd}crossgen_corelib --crossgen ${crossGenExecutable} --il_corelib \${WORKSPACE}/${workspaceRelativeCoreLib} --result_dir \${WORKSPACE}/${workspaceRelativeCrossResultDir}" buildCommands += "${dockerCmd}${crossGenComparisonCmd}crossgen_framework --crossgen ${crossGenExecutable} --core_root \${WORKSPACE}/${workspaceRelativeCoreRootDir} --result_dir \${WORKSPACE}/${workspaceRelativeCrossResultDir}" buildCommands += "${dockerCmd}zip -r ${workspaceRelativeArtifactsArchive} ${workspaceRelativeCoreLib} ${workspaceRelativeCoreRootDir} ${workspaceRelativeCrossGenComparisonScript} ${workspaceRelativeCrossResultDir}" Utilities.addArchival(newJob, "${workspaceRelativeArtifactsArchive}") } else { // Then, using the same docker image, generate the CORE_ROOT layout using build-test.sh to // download the appropriate CoreFX packages. // Note that docker should not be necessary here, for the "generatelayoutonly" case, but we use it // just to be consistent with the "build.sh" case -- so both are run with the same environment. buildCommands += "${dockerCmd}\${WORKSPACE}/build-test.sh ${lowerConfiguration} ${architecture} cross generatelayoutonly" // ZIP up for the test job (created in the flow job code): // (1) the built CORE_ROOT, /home/user/coreclr/bin/tests/Linux.arm.Checked/Tests/Core_Root, // used by runtest.sh as the "--coreOverlayDir" argument. // (2) the native parts of the test build: /home/user/coreclr/bin/obj/Linux.arm.Checked/tests, // used by runtest.sh as the "--testNativeBinDir" argument. // These commands are assumed to be run from the root of the workspace. buildCommands += "zip -r coreroot.${lowerConfiguration}.zip ./bin/tests/Linux.${architecture}.${configuration}/Tests/Core_Root" buildCommands += "zip -r testnativebin.${lowerConfiguration}.zip ./bin/obj/Linux.${architecture}.${configuration}/tests" Utilities.addArchival(newJob, "coreroot.${lowerConfiguration}.zip,testnativebin.${lowerConfiguration}.zip", "") } // We need to clean up the build machines; the docker build leaves newly built files with root permission, which // the cleanup task in Jenkins can't remove. newJob.with { publishers { azureVMAgentPostBuildAction { agentPostBuildAction('Delete agent after build execution (when idle).') } } } break default: println("Unknown architecture: ${architecture}"); assert false break } break // editor brace matching: } default: println("Unknown os: ${os}"); assert false break } // os return buildCommands } // Determine if we should generate a job for the given parameters. This is for non-flow jobs: either build and test, or build only. // Returns true if the job should be generated. def static shouldGenerateJob(def scenario, def isPR, def architecture, def configuration, def os, def isBuildOnly) { // The "innerloop" (Pri-0 testing) scenario is only available as PR triggered. if (scenario == 'innerloop' && !isPR) { return false } // Run basic corefx tests only on PR-triggered jobs // Runs under Release and Checked if (scenario == 'corefx_innerloop' && !isPR) { return false } // Tizen is only supported for armem architecture if (os == 'Tizen' && architecture != 'armem') { return false } // Filter based on architecture. switch (architecture) { case 'arm64': case 'arm': if ((os != 'Windows_NT') && (os != 'Ubuntu')) { return false } break case 'armem': if (os != 'Tizen') { return false } break case 'x86_arm_altjit': case 'x64_arm64_altjit': if (os != 'Windows_NT') { return false } break case 'x86': if ((os != 'Windows_NT') && (os != 'Ubuntu')) { return false } break case 'x64': // Everything implemented break default: println("Unknown architecture: ${architecture}") assert false break } // Which (Windows) build only jobs are required? def isNormalOrInnerloop = (scenario == 'innerloop' || scenario == 'normal') if (isBuildOnly) { switch (architecture) { case 'arm': case 'arm64': // We use build only jobs for Windows arm/arm64 cross-compilation corefx testing, so we need to generate builds for that. if (!isCoreFxScenario(scenario)) { return false } break case 'x64': case 'x86': if (!isNormalOrInnerloop) { return false } break default: return false } } // Filter based on scenario. if (isJitStressScenario(scenario)) { if (configuration != 'Checked') { return false } def isEnabledOS = (os == 'Windows_NT') || (os == 'Ubuntu' && (isCoreFxScenario(scenario) || architecture == 'arm' || architecture == 'arm64')) if (!isEnabledOS) { return false } switch (architecture) { case 'x64': case 'x86_arm_altjit': case 'x64_arm64_altjit': break case 'x86': // x86 ubuntu: no stress modes if (os == 'Ubuntu') { return false } break case 'arm': // We use build only jobs for Windows arm/arm64 cross-compilation corefx testing, so we need to generate builds for that. // No "regular" Windows arm corefx jobs, e.g. // For Ubuntu arm corefx testing, we use regular jobs (not "build only" since only Windows has "build only", and // the Ubuntu arm "regular" jobs don't run tests anyway). if (os == 'Windows_NT') { if (! (isBuildOnly && isCoreFxScenario(scenario)) ) { return false } } else { if (!isCoreFxScenario(scenario)) { return false } } break case 'arm64': if (os == 'Windows_NT') { if (! (isBuildOnly && isCoreFxScenario(scenario)) ) { return false } } else { if (!isCoreFxScenario(scenario)) { return false } } break default: // arm64: stress is handled through flow jobs. // armem: no stress jobs for ARM emulator. return false } } else if (isR2RScenario(scenario)) { if (os != 'Windows_NT') { return false } if (isR2RBaselineScenario(scenario)) { // no need for Debug scenario; Checked is sufficient if (configuration != 'Checked' && configuration != 'Release') { return false } } else if (isR2RStressScenario(scenario)) { // Stress scenarios only run with Checked builds, not Release (they would work with Debug, but be slow). if (configuration != 'Checked') { return false } } switch (architecture) { case 'arm': case 'arm64': // Windows arm/arm64 ready-to-run jobs use flow jobs and test jobs, but depend on "normal" (not R2R specific) build jobs. return false default: break } } else if (isCrossGenComparisonScenario(scenario)) { return shouldGenerateCrossGenComparisonJob(os, architecture, configuration, scenario) } else { // Skip scenarios switch (scenario) { case 'ilrt': // The ilrt build isn't necessary except for Windows_NT2003. Non-Windows NT uses // the default scenario build if (os != 'Windows_NT') { return false } // Only x64 for now if (architecture != 'x64') { return false } // Release only if (configuration != 'Release') { return false } break case 'jitdiff': if (os != 'Windows_NT' && os != 'Ubuntu' && os != 'OSX10.12') { return false } if (architecture != 'x64') { return false } if (configuration != 'Checked') { return false } break case 'longgc': case 'gcsimulator': if (os != 'Windows_NT' && os != 'Ubuntu' && os != 'OSX10.12') { return false } if (architecture != 'x64') { return false } if (configuration != 'Release') { return false } break case 'gc_reliability_framework': case 'standalone_gc': if (os != 'Windows_NT' && os != 'Ubuntu' && os != 'OSX10.12') { return false } if (architecture != 'x64') { return false } if (configuration != 'Release' && configuration != 'Checked') { return false } break // We only run Windows and Ubuntu x64 Checked for formatting right now case 'formatting': if (os != 'Windows_NT' && os != 'Ubuntu') { return false } if (architecture != 'x64') { return false } if (configuration != 'Checked') { return false } break case 'illink': if (os != 'Windows_NT' && (os != 'Ubuntu' || architecture != 'x64')) { return false } if (architecture != 'x64' && architecture != 'x86') { return false } break case 'normal': // Nothing skipped break case 'innerloop': if (!isValidPrTriggeredInnerLoopJob(os, architecture, configuration, isBuildOnly)) { return false } break case 'corefx_innerloop': if (os != 'Windows_NT' && os != 'Ubuntu' && os != 'OSX10.12') { return false } if (architecture != 'x64') { return false } break default: println("Unknown scenario: ${scenario}") assert false break } } // For altjit, don't do any scenarios that don't change compilation. That is, scenarios that only change // runtime behavior, not compile-time behavior, are not interesting. switch (architecture) { case 'x86_arm_altjit': case 'x64_arm64_altjit': if (isGCStressRelatedTesting(scenario)) { return false } break default: break } // The job was not filtered out, so we should generate it! return true } Constants.allScenarios.each { scenario -> [true, false].each { isPR -> Constants.architectureList.each { architecture -> Constants.configurationList.each { configuration -> Constants.osList.each { os -> // If the OS is Windows_NT_BuildOnly, set the isBuildOnly flag to true // and reset the os to Windows_NT def isBuildOnly = false if (os == 'Windows_NT_BuildOnly') { isBuildOnly = true os = 'Windows_NT' } if (!shouldGenerateJob(scenario, isPR, architecture, configuration, os, isBuildOnly)) { return } // Calculate names def jobName = getJobName(configuration, architecture, os, scenario, isBuildOnly) def folderName = getJobFolder(scenario) // Create the new job def newJob = job(Utilities.getFullJobName(project, jobName, isPR, folderName)) {} // We don't want to include in view any job that is only used by a flow job (because we want the views to have only the // "top-level" jobs. Build only jobs are such jobs. if (!isBuildOnly) { addToViews(newJob, isPR, architecture, os) } setJobMachineAffinity(architecture, os, true, false, false, newJob) // isBuildJob = true, isTestJob = false, isFlowJob = false Utilities.standardJobSetup(newJob, project, isPR, "*/${branch}") addTriggers(newJob, branch, isPR, architecture, os, configuration, scenario, false, isBuildOnly) // isFlowJob==false setJobTimeout(newJob, isPR, architecture, configuration, scenario, isBuildOnly) // Copy Windows build test binaries and corefx build artifacts for Linux cross build for armem. // We don't use a flow job for this, but we do depend on there being existing builds with these // artifacts produced. if ((architecture == 'armem') && (os == 'Tizen')) { // Define the Windows Tests and Corefx build job names def lowerConfiguration = configuration.toLowerCase() def WindowsTestsName = projectFolder + '/' + Utilities.getFullJobName(project, getJobName(lowerConfiguration, 'x64' , 'windows_nt', 'normal', true), false) def fxBranch = getFxBranch(branch) def corefxFolder = Utilities.getFolderName('dotnet/corefx') + '/' + Utilities.getFolderName(fxBranch) def arm_abi = 'armel' def corefx_os = 'tizen' // Let's use release CoreFX to test checked CoreCLR, // because we do not generate checked CoreFX in CoreFX CI yet. def corefx_lowerConfiguration = lowerConfiguration if (lowerConfiguration == 'checked') { corefx_lowerConfiguration = 'release' } // Copy the Windows test binaries and the Corefx build binaries newJob.with { steps { copyArtifacts(WindowsTestsName) { includePatterns('bin/tests/tests.zip') buildSelector { latestSuccessful(true) } } copyArtifacts("${corefxFolder}/${corefx_os}_${arm_abi}_cross_${corefx_lowerConfiguration}") { includePatterns('bin/build.tar.gz') buildSelector { latestSuccessful(true) } } } // steps } // newJob.with } def buildCommands = calculateBuildCommands(newJob, scenario, branch, isPR, architecture, configuration, os, isBuildOnly) newJob.with { steps { if (os == 'Windows_NT') { buildCommands.each { buildCommand -> batchFile(buildCommand) } } else { buildCommands.each { buildCommand -> shell(buildCommand) } } } // steps } // newJob.with } // os } // configuration } // architecture } // isPR } // scenario // Create a Windows ARM/ARM64 test job that will be used by a flow job. // Returns the newly created job. def static CreateWindowsArmTestJob(def dslFactory, def project, def architecture, def os, def configuration, def scenario, def isPR, def inputCoreCLRBuildName) { def osGroup = getOSGroup(os) def jobName = getJobName(configuration, architecture, os, scenario, false) + "_tst" def jobFolder = getJobFolder(scenario) def newJob = dslFactory.job(Utilities.getFullJobName(project, jobName, isPR, jobFolder)) { parameters { stringParam('CORECLR_BUILD', '', "Build number to copy CoreCLR ${osGroup} binaries from") } steps { // Set up the copies // Coreclr build we are trying to test // // ** NOTE ** This will, correctly, overwrite the CORE_ROOT from the Windows test archive copyArtifacts(inputCoreCLRBuildName) { excludePatterns('**/testResults.xml', '**/*.ni.dll') buildSelector { buildNumber('${CORECLR_BUILD}') } } if (isCoreFxScenario(scenario)) { // Only arm/arm64 supported for corefx testing now. assert architecture == 'arm' || architecture == 'arm64' // Unzip CoreFx runtime batchFile("powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::ExtractToDirectory('_\\fx\\fxruntime.zip', '_\\fx\\bin\\testhost\\netcoreapp-Windows_NT-Release-${architecture}')\"") // Unzip CoreFx tests. batchFile("powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::ExtractToDirectory('_\\fx\\fxtests.zip', '_\\fx\\bin\\tests')\"") // Add the script to run the corefx tests def corefx_runtime_path = "%WORKSPACE%\\_\\fx\\bin\\testhost\\netcoreapp-Windows_NT-Release-${architecture}" def corefx_tests_dir = "%WORKSPACE%\\_\\fx\\bin\\tests" def corefx_exclusion_file = "%WORKSPACE%\\tests\\${architecture}\\corefx_test_exclusions.txt" batchFile("call %WORKSPACE%\\tests\\scripts\\run-corefx-tests.bat ${corefx_runtime_path} ${corefx_tests_dir} ${corefx_exclusion_file} ${architecture}") } else { // !isCoreFxScenario(scenario) // Unzip tests. batchFile("powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::ExtractToDirectory('bin\\tests\\tests.zip', 'bin\\tests\\${osGroup}.${architecture}.${configuration}')\"") def buildCommands = "" def coreRootLocation = "%WORKSPACE%\\bin\\tests\\Windows_NT.${architecture}.${configuration}\\Tests\\Core_Root" def addEnvVariable = { variable, value -> buildCommands += "set ${variable}=${value}\r\n"} def addCommand = { cmd -> buildCommands += "${cmd}\r\n"} // Make sure Command Extensions are enabled. Used so %ERRORLEVEL% is available. addCommand("SETLOCAL ENABLEEXTENSIONS") // For all jobs addEnvVariable("CORE_ROOT", coreRootLocation) addEnvVariable("COMPlus_NoGuiOnAssert", "1") addEnvVariable("COMPlus_ContinueOnAssert", "0") // If we are running a stress mode, we'll set those variables as well if (isJitStressScenario(scenario) || isR2RStressScenario(scenario)) { def stressValues = null if (isJitStressScenario(scenario)) { stressValues = Constants.jitStressModeScenarios[scenario] } else { stressValues = Constants.r2rStressScenarios[scenario] } stressValues.each { key, value -> addEnvVariable(key, value) } } if (isR2RScenario(scenario)) { // Crossgen the framework assemblies. buildCommands += """ @for %%F in (%CORE_ROOT%\\*.dll) do @call :PrecompileAssembly "%CORE_ROOT%" "%%F" %%~nxF @goto skip_PrecompileAssembly :PrecompileAssembly @REM Skip mscorlib since it is already precompiled. @if /I "%3" == "mscorlib.dll" exit /b 0 @if /I "%3" == "mscorlib.ni.dll" exit /b 0 "%CORE_ROOT%\\crossgen.exe" /Platform_Assemblies_Paths "%CORE_ROOT%" %2 >nul 2>nul @if "%errorlevel%" == "-2146230517" ( echo %2 is not a managed assembly. ) else if "%errorlevel%" == "-2146234344" ( echo %2 is not a managed assembly. ) else if %errorlevel% neq 0 ( echo Unable to precompile %2 ) else ( echo Precompiled %2 ) @exit /b 0 :skip_PrecompileAssembly """ // Set RunCrossGen variable to cause test wrappers to invoke their logic to run // crossgen on tests before running them. addEnvVariable("RunCrossGen", "true") } // isR2RScenario(scenario) // Create the smarty command def smartyCommand = "C:\\Tools\\Smarty.exe /noecid /noie /workers 9 /inc EXPECTED_PASS " def addSmartyFlag = { flag -> smartyCommand += flag + " "} def addExclude = { exclude -> addSmartyFlag("/exc " + exclude)} def addArchSpecificExclude = { architectureToExclude, exclude -> addExclude(exclude) } // Exclude tests based on scenario. Constants.validArmWindowsScenarios[scenario].each { excludeTag -> addArchSpecificExclude(architecture, excludeTag) } if (isInnerloopTestScenario(scenario)) { addExclude("pri1") } // Exclude any test marked LONG_RUNNING; these often exceed the standard timeout and fail as a result. // TODO: We should create a "long running" job that runs these with a longer timeout. addExclude("LONG_RUNNING") smartyCommand += "/lstFile Tests.lst" def testListArch = [ 'arm64': 'arm64', 'arm': 'arm' ] def archLocation = testListArch[architecture] addCommand("copy %WORKSPACE%\\tests\\${archLocation}\\Tests.lst bin\\tests\\${osGroup}.${architecture}.${configuration}") addCommand("pushd bin\\tests\\${osGroup}.${architecture}.${configuration}") addCommand("${smartyCommand}") // Save the errorlevel from the smarty command to be used as the errorlevel of this batch file. // However, we also need to remove all the variables that were set during this batch file, so we // can run the ZIP powershell command (below) in a clean environment. (We can't run the powershell // command with the COMPlus_AltJit variables set, for example.) To do that, we do ENDLOCAL as well // as save the current errorlevel on the same line. This works because CMD evaluates the %errorlevel% // variable expansion (or any variable expansion on the line) BEFORE it executes the ENDLOCAL command. // Note that the ENDLOCAL also undoes the pushd command, but we add the popd here for clarity. addCommand("popd & ENDLOCAL & set __save_smarty_errorlevel=%errorlevel%") // ZIP up the smarty output, no matter what the smarty result. addCommand("powershell -NoProfile -Command \"Add-Type -Assembly 'System.IO.Compression.FileSystem'; [System.IO.Compression.ZipFile]::CreateFromDirectory('.\\bin\\tests\\${osGroup}.${architecture}.${configuration}\\Smarty.run.0', '.\\bin\\tests\\${osGroup}.${architecture}.${configuration}\\Smarty.run.0.zip')\"") addCommand("echo %errorlevel%") addCommand("dir .\\bin\\tests\\${osGroup}.${architecture}.${configuration}") // Use the smarty errorlevel as the script errorlevel. addCommand("exit /b %__save_smarty_errorlevel%") batchFile(buildCommands) } // non-corefx testing } // steps } // job if (!isCoreFxScenario(scenario)) { Utilities.addArchival(newJob, "bin/tests/${osGroup}.${architecture}.${configuration}/Smarty.run.0/*.smrt", '', true, false) // Archive a ZIP file of the entire Smarty.run.0 directory. This is possibly a little too much, // but there is no easy way to only archive the HTML/TXT files of the failing tests, so we get // all the passing test info as well. Not necessarily a bad thing, but possibly somewhat large. Utilities.addArchival(newJob, "bin/tests/${osGroup}.${architecture}.${configuration}/Smarty.run.0.zip", '', true, false) } return newJob } // Create a test job not covered by the "Windows ARM" case that will be used by a flow job. // E.g., non-Windows tests. // Returns the newly created job. def static CreateOtherTestJob(def dslFactory, def project, def branch, def architecture, def os, def configuration, def scenario, def isPR, def inputCoreCLRBuildName, def inputTestsBuildName) { def isUbuntuArmJob = (os == "Ubuntu") && ((architecture == 'arm') || (architecture == 'arm64')) // ARM Ubuntu running on hardware (not emulator) def doCoreFxTesting = isCoreFxScenario(scenario) def workspaceRelativeFxRootLinux = "_/fx" // only used for CoreFX testing def osGroup = getOSGroup(os) def jobName = getJobName(configuration, architecture, os, scenario, false) + "_tst" def testOpts = '' def useServerGC = false // Enable Server GC for Ubuntu PR builds // REVIEW: why? Does this apply to all architectures? Why only PR? if (os == 'Ubuntu' && isPR) { testOpts += ' --useServerGC' useServerGC = true } if (isR2RScenario(scenario)) { testOpts += ' --crossgen --runcrossgentests' if (scenario == 'r2r_jitstress1') { testOpts += ' --jitstress=1' } else if (scenario == 'r2r_jitstress2') { testOpts += ' --jitstress=2' } else if (scenario == 'r2r_jitstress1_tiered') { testOpts += ' --jitstress=1' } else if (scenario == 'r2r_jitstress2_tiered') { testOpts += ' --jitstress=2' } else if (scenario == 'r2r_jitstressregs1') { testOpts += ' --jitstressregs=1' } else if (scenario == 'r2r_jitstressregs2') { testOpts += ' --jitstressregs=2' } else if (scenario == 'r2r_jitstressregs3') { testOpts += ' --jitstressregs=3' } else if (scenario == 'r2r_jitstressregs4') { testOpts += ' --jitstressregs=4' } else if (scenario == 'r2r_jitstressregs8') { testOpts += ' --jitstressregs=8' } else if (scenario == 'r2r_jitstressregs0x10') { testOpts += ' --jitstressregs=0x10' } else if (scenario == 'r2r_jitstressregs0x80') { testOpts += ' --jitstressregs=0x80' } else if (scenario == 'r2r_jitstressregs0x1000') { testOpts += ' --jitstressregs=0x1000' } else if (scenario == 'r2r_jitminopts') { testOpts += ' --jitminopts' } else if (scenario == 'r2r_jitforcerelocs') { testOpts += ' --jitforcerelocs' } else if (scenario == 'r2r_gcstress15') { testOpts += ' --gcstresslevel=0xF' } } else if (scenario == 'jitdiff') { testOpts += ' --jitdisasm --crossgen' } else if (scenario == 'illink') { testOpts += ' --link=\$WORKSPACE/linker/linker/bin/netcore_Release/netcoreapp2.0/ubuntu-x64/publish/illink' } else if (isLongGc(scenario)) { // Long GC tests behave very poorly when they are not // the only test running (many of them allocate until OOM). testOpts += ' --sequential' // A note - runtest.sh does have "--long-gc" and "--gcsimulator" options // for running long GC and GCSimulator tests, respectively. We don't use them // here because using a playlist file produces much more readable output on the CI machines // and reduces running time. // // The Long GC playlist contains all of the tests that are // going to be run. The GCSimulator playlist contains all of // the GC simulator tests. if (scenario == 'longgc') { testOpts += ' --long-gc --playlist=./tests/longRunningGcTests.txt' } else if (scenario == 'gcsimulator') { testOpts += ' --gcsimulator --playlist=./tests/gcSimulatorTests.txt' } } else if (isGcReliabilityFramework(scenario)) { testOpts += ' --build-overlay-only' } else if (scenario == 'standalone_gc') { if (osGroup == 'OSX') { testOpts += ' --gcname=libclrgc.dylib' } else if (osGroup == 'Linux') { testOpts += ' --gcname=libclrgc.so' } else { println("Unexpected OS group: ${osGroup} for os ${os}") assert false } } // The ARM Ubuntu corefx test job doesn't depend on a Windows test build, and hence inputTestsBuildName // will be null in this case. def jobFolder = getJobFolder(scenario) def newJob = dslFactory.job(Utilities.getFullJobName(project, jobName, isPR, jobFolder)) { parameters { if (inputTestsBuildName != null) { stringParam('CORECLR_WINDOWS_BUILD', '', 'Build number to copy CoreCLR Windows test binaries from') } stringParam('CORECLR_BUILD', '', "Build number to copy CoreCLR ${osGroup} binaries from") } steps { // Set up the copies // Coreclr build containing the tests and mscorlib // pri1 jobs still need to copy windows_nt built tests if (inputTestsBuildName != null) { copyArtifacts(inputTestsBuildName) { excludePatterns('**/testResults.xml', '**/*.ni.dll') buildSelector { buildNumber('${CORECLR_WINDOWS_BUILD}') } } } // Coreclr build we are trying to test // // ** NOTE ** This will, correctly, overwrite the CORE_ROOT from the Windows test archive copyArtifacts(inputCoreCLRBuildName) { excludePatterns('**/testResults.xml', '**/*.ni.dll') buildSelector { buildNumber('${CORECLR_BUILD}') } } if (isUbuntuArmJob) { // Add some useful information to the log file. Ignore return codes. shell("uname -a || true") } if (architecture == 'x86') { shell("mkdir ./bin/CoreFxNative") def fxBranch = getFxBranch(branch) def corefxFolder = Utilities.getFolderName('dotnet/corefx') + '/' + Utilities.getFolderName(fxBranch) copyArtifacts("${corefxFolder}/ubuntu16.04_x86_release") { includePatterns('bin/build.tar.gz') targetDirectory('bin/CoreFxNative') buildSelector { latestSuccessful(true) } } shell("mkdir ./bin/CoreFxBinDir") shell("tar -xf ./bin/CoreFxNative/bin/build.tar.gz -C ./bin/CoreFxBinDir") } // CoreFX testing downloads the CoreFX tests, not the coreclr tests. Also, unzip the built CoreFX layout/runtime directories. if (doCoreFxTesting) { shell("unzip -o ${workspaceRelativeFxRootLinux}/fxtests.zip || exit 0") shell("unzip -o ${workspaceRelativeFxRootLinux}/fxruntime.zip || exit 0") } else { // Unzip the tests first. Exit with 0 shell("unzip -q -o ./bin/tests/tests.zip -d ./bin/tests/${osGroup}.${architecture}.${configuration} || exit 0") shell("rm -r ./bin/tests/${osGroup}.${architecture}.${configuration}/Tests/Core_Root || exit 0") } // For arm Ubuntu (on hardware), we do the "build-test" step on the build machine, not on the test // machine. The arm Ubuntu test machines do no building -- they have no CLI, for example. // We should probably do the "generatelayoutonly" step on the build machine for all architectures. // However, it's believed that perhaps there's an issue with executable permission bits not getting // copied correctly. if (!doCoreFxTesting) { if (isUbuntuArmJob) { def lowerConfiguration = configuration.toLowerCase() shell("unzip -o ./coreroot.${lowerConfiguration}.zip || exit 0") // unzips to ./bin/tests/Linux.${architecture}.${configuration}/Tests/Core_Root shell("unzip -o ./testnativebin.${lowerConfiguration}.zip || exit 0") // unzips to ./bin/obj/Linux.${architecture}.${configuration}/tests } else { shell("./build-test.sh ${architecture} ${configuration} generatelayoutonly") } } // Execute the tests def runDocker = isNeedDocker(architecture, os, false) def dockerPrefix = "" def dockerCmd = "" if (runDocker) { def dockerImage = getDockerImageName(architecture, os, false) dockerPrefix = "docker run -i --rm -v \${WORKSPACE}:\${WORKSPACE} -w \${WORKSPACE} " dockerCmd = dockerPrefix + "${dockerImage} " } // If we are running a stress mode, we'll set those variables first. // For CoreFX, the stress variables are already built into the CoreFX test build per-test wrappers. if (!doCoreFxTesting && isJitStressScenario(scenario)) { def scriptFileName = "\${WORKSPACE}/set_stress_test_env.sh" def envScriptCmds = envScriptCreate(os, scriptFileName) envScriptCmds += envScriptSetStressModeVariables(os, Constants.jitStressModeScenarios[scenario], scriptFileName) envScriptCmds += envScriptFinalize(os, scriptFileName) shell("${envScriptCmds}") testOpts += " --test-env=${scriptFileName}" } // setup-stress-dependencies.sh, invoked by runtest.sh to download the coredistools package, depends on the "dotnet" // tool downloaded by the "init-tools.sh" script. However, it only invokes setup-stress-dependencies.sh for x64. The // coredistools package is used by GCStress on x86 and x64 to disassemble code to determine instruction boundaries. // On arm/arm64, it is not required as determining instruction boundaries is trivial. if (isGCStressRelatedTesting(scenario)) { if (architecture == 'x64') { shell('./init-tools.sh') } } if (doCoreFxTesting) { shell("""\ \${WORKSPACE}/${workspaceRelativeFxRootLinux}/run-test.sh --sequential --test-exclude-file \${WORKSPACE}/tests/${architecture}/corefx_linux_test_exclusions.txt --runtime \${WORKSPACE}/${workspaceRelativeFxRootLinux}/bin/testhost/netcoreapp-Linux-Release-${architecture} --arch ${architecture} --corefx-tests \${WORKSPACE}/${workspaceRelativeFxRootLinux}/bin --configurationGroup Release""") } else { def runScript = "${dockerCmd}./tests/runtest.sh" shell("""\ ${runScript} \\ --testRootDir=\"\${WORKSPACE}/bin/tests/${osGroup}.${architecture}.${configuration}\" \\ --coreOverlayDir=\"\${WORKSPACE}/bin/tests/${osGroup}.${architecture}.${configuration}/Tests/Core_Root\" \\ --testNativeBinDir=\"\${WORKSPACE}/bin/obj/${osGroup}.${architecture}.${configuration}/tests\" \\ --copyNativeTestBin --limitedDumpGeneration ${testOpts}""") } if (isGcReliabilityFramework(scenario)) { // runtest.sh doesn't actually execute the reliability framework - do it here. if (useServerGC) { if (runDocker) { dockerCmd = dockerPrefix + "-e COMPlus_gcServer=1 ${dockerImage} " } else { shell("export COMPlus_gcServer=1") } } shell("${dockerCmd}./tests/scripts/run-gc-reliability-framework.sh ${architecture} ${configuration}") } } // steps } // job // Experimental: If on Ubuntu 14.04, then attempt to pull in crash dump links if (os in ['Ubuntu']) { SummaryBuilder summaries = new SummaryBuilder() summaries.addLinksSummaryFromFile('Crash dumps from this run:', 'dumplings.txt') summaries.emit(newJob) } if (doCoreFxTesting) { Utilities.addArchival(newJob, "${workspaceRelativeFxRootLinux}/bin/**/testResults.xml") if ((os == "Ubuntu") && (architecture == 'arm')) { // We have a problem with the xunit plug-in, where it is consistently failing on Ubuntu arm32 test result uploading with this error: // // [xUnit] [ERROR] - The plugin hasn't been performed correctly: remote file operation failed: /ssd/j/workspace/dotnet_coreclr/master/jitstress/arm_cross_checked_ubuntu_corefx_baseline_tst at hudson.remoting.Channel@3697f46d:JNLP4-connect connection from 131.107.159.149/131.107.159.149:58529: java.io.IOException: Remote call on JNLP4-connect connection from 131.107.159.149/131.107.159.149:58529 failed // // We haven't been able to identify the reason. So, do not add xunit parsing of the test data in this scenario. // This is tracked by: https://github.com/dotnet/coreclr/issues/19447. } else { Utilities.addXUnitDotNETResults(newJob, "${workspaceRelativeFxRootLinux}/bin/**/testResults.xml") } } else { Utilities.addXUnitDotNETResults(newJob, '**/coreclrtests.xml') } return newJob } def static CreateNonWindowsCrossGenComparisonTestJob(def dslFactory, def project, def architecture, def os, def configuration, def scenario, def isPR, def inputCoreCLRBuildName) { assert isCrossGenComparisonScenario(scenario) def osGroup = getOSGroup(os) def jobName = getJobName(configuration, architecture, os, scenario, false) + "_tst" def crossArchitecture = getCrossArchitecture(os, architecture, scenario) def workspaceRelativeCrossResultDir = "_/${osGroup}.${crossArchitecture}_${architecture}.${configuration}" def workspaceRelativeNativeResultDir = "_/${osGroup}.${architecture}_${architecture}.${configuration}" def jobFolder = getJobFolder(scenario) def newJob = dslFactory.job(Utilities.getFullJobName(project, jobName, isPR, jobFolder)) { parameters { stringParam('CORECLR_BUILD', '', "Build number to copy CoreCLR ${osGroup} binaries from") } def workspaceRelativeArtifactsArchive = "${os}.${architecture}.${configuration}.${scenario}.zip" steps { copyArtifacts(inputCoreCLRBuildName) { includePatterns("${workspaceRelativeArtifactsArchive}") buildSelector { buildNumber('${CORECLR_BUILD}') } } shell("unzip -o ${workspaceRelativeArtifactsArchive} || exit 0") def workspaceRelativeCoreLib = "bin/Product/${osGroup}.${architecture}.${configuration}/IL/System.Private.CoreLib.dll" def workspaceRelativeCoreRootDir = "bin/tests/${osGroup}.${architecture}.${configuration}/Tests/Core_Root" def workspaceRelativeCrossGenComparisonScript = "tests/scripts/crossgen_comparison.py" def workspaceRelativeCrossGenExecutable = "${workspaceRelativeCoreRootDir}/crossgen" def crossGenComparisonCmd = "python -u \${WORKSPACE}/${workspaceRelativeCrossGenComparisonScript} " def crossGenExecutable = "\${WORKSPACE}/${workspaceRelativeCrossGenExecutable}" shell("mkdir -p ${workspaceRelativeNativeResultDir}") shell("${crossGenComparisonCmd}crossgen_corelib --crossgen ${crossGenExecutable} --il_corelib \${WORKSPACE}/${workspaceRelativeCoreLib} --result_dir \${WORKSPACE}/${workspaceRelativeNativeResultDir}") shell("${crossGenComparisonCmd}crossgen_framework --crossgen ${crossGenExecutable} --core_root \${WORKSPACE}/${workspaceRelativeCoreRootDir} --result_dir \${WORKSPACE}/${workspaceRelativeNativeResultDir}") shell("${crossGenComparisonCmd}compare --base_dir \${WORKSPACE}/${workspaceRelativeNativeResultDir} --diff_dir \${WORKSPACE}/${workspaceRelativeCrossResultDir}") } // steps } // job Utilities.addArchival(newJob, "${workspaceRelativeCrossResultDir}/**") Utilities.addArchival(newJob, "${workspaceRelativeNativeResultDir}/**") return newJob } // Create a test job that will be used by a flow job. // Returns the newly created job. // Note that we don't add tests jobs to the various views, since they are always used by a flow job, which is in the views, // and we want the views to be the minimal set of "top-level" jobs that represent all work. def static CreateTestJob(def dslFactory, def project, def branch, def architecture, def os, def configuration, def scenario, def isPR, def inputCoreCLRBuildName, def inputTestsBuildName) { def windowsArmJob = ((os == "Windows_NT") && (architecture in Constants.armWindowsCrossArchitectureList)) def newJob = null if (windowsArmJob) { assert inputTestsBuildName == null newJob = CreateWindowsArmTestJob(dslFactory, project, architecture, os, configuration, scenario, isPR, inputCoreCLRBuildName) } else if (isCrossGenComparisonScenario(scenario)) { assert inputTestsBuildName == null newJob = CreateNonWindowsCrossGenComparisonTestJob(dslFactory, project, architecture, os, configuration, scenario, isPR, inputCoreCLRBuildName) } else { newJob = CreateOtherTestJob(dslFactory, project, branch, architecture, os, configuration, scenario, isPR, inputCoreCLRBuildName, inputTestsBuildName) } setJobMachineAffinity(architecture, os, false, true, false, newJob) // isBuildJob = false, isTestJob = true, isFlowJob = false if (scenario == 'jitdiff') { def osGroup = getOSGroup(os) Utilities.addArchival(newJob, "bin/tests/${osGroup}.${architecture}.${configuration}/dasm/**") } Utilities.standardJobSetup(newJob, project, isPR, "*/${branch}") setJobTimeout(newJob, isPR, architecture, configuration, scenario, false) return newJob } // Create a flow job to tie together a build job with the given test job. // The 'inputTestsBuildName' argument might be null if the flow job doesn't depend on a Windows build job. // Returns the new flow job. def static CreateFlowJob(def dslFactory, def project, def branch, def architecture, def os, def configuration, def scenario, def isPR, def fullTestJobName, def inputCoreCLRBuildName, def inputTestsBuildName) { // Windows CoreCLR build and Linux CoreCLR build (in parallel) -> // Linux CoreCLR test def flowJobName = getJobName(configuration, architecture, os, scenario, false) + "_flow" def jobFolder = getJobFolder(scenario) def newFlowJob = null if (inputTestsBuildName == null) { newFlowJob = dslFactory.buildFlowJob(Utilities.getFullJobName(project, flowJobName, isPR, jobFolder)) { buildFlow("""\ coreclrBuildJob = build(params, '${inputCoreCLRBuildName}') // And then build the test build build(params + [CORECLR_BUILD: coreclrBuildJob.build.number], '${fullTestJobName}') """) } JobReport.Report.addReference(inputCoreCLRBuildName) JobReport.Report.addReference(fullTestJobName) } else { newFlowJob = dslFactory.buildFlowJob(Utilities.getFullJobName(project, flowJobName, isPR, jobFolder)) { buildFlow("""\ // Build the input jobs in parallel parallel ( { coreclrBuildJob = build(params, '${inputCoreCLRBuildName}') }, { windowsBuildJob = build(params, '${inputTestsBuildName}') } ) // And then build the test build build(params + [CORECLR_BUILD: coreclrBuildJob.build.number, CORECLR_WINDOWS_BUILD: windowsBuildJob.build.number], '${fullTestJobName}') """) } JobReport.Report.addReference(inputCoreCLRBuildName) JobReport.Report.addReference(inputTestsBuildName) JobReport.Report.addReference(fullTestJobName) } addToViews(newFlowJob, isPR, architecture, os) setJobMachineAffinity(architecture, os, false, false, true, newFlowJob) // isBuildJob = false, isTestJob = false, isFlowJob = true Utilities.standardJobSetup(newFlowJob, project, isPR, "*/${branch}") addTriggers(newFlowJob, branch, isPR, architecture, os, configuration, scenario, true, false) // isFlowJob==true, isWindowsBuildOnlyJob==false return newFlowJob } // Determine if we should generate a flow job for the given parameters. // Returns true if the job should be generated. def static shouldGenerateFlowJob(def scenario, def isPR, def architecture, def configuration, def os) { // The "innerloop" (Pri-0 testing) scenario is only available as PR triggered. if (scenario == 'innerloop' && !isPR) { return false } if (scenario == 'corefx_innerloop') { return false } // Filter based on OS and architecture. switch (architecture) { case 'arm64': case 'arm': if (os != "Ubuntu" && os != "Windows_NT") { return false } break case 'x86': if (os != "Ubuntu") { return false } break case 'x64': if (!(os in Constants.crossList)) { return false } if (os == "Windows_NT") { return false } break case 'armem': case 'x86_arm_altjit': case 'x64_arm64_altjit': // No flow jobs return false default: println("Unknown architecture: ${architecture}") assert false break } def isNormalOrInnerloop = (scenario == 'innerloop' || scenario == 'normal') // Filter based on scenario in OS. if (os == 'Windows_NT') { assert architecture == 'arm' || architecture == 'arm64' if (!isArmWindowsScenario(scenario)) { return false } if (isNormalOrInnerloop && (configuration == 'Debug')) { // The arm32/arm64 Debug configuration for innerloop/normal scenario is a special case: it does a build only, and no test run. // To do that, it doesn't require a flow job. return false } } else { // Non-Windows if (architecture == 'arm64') { if (!(scenario in Constants.validLinuxArm64Scenarios)) { return false } if (isNormalOrInnerloop && (configuration == 'Debug')) { // The arm32/arm64 Debug configuration for innerloop/normal scenario is a special case: it does a build only, and no test run. // To do that, it doesn't require a flow job. return false } } else if (architecture == 'arm') { if (!(scenario in Constants.validLinuxArmScenarios)) { return false } } else if (architecture == 'x86') { // Linux/x86 only want innerloop and default test if (!isNormalOrInnerloop) { return false } } else if (architecture == 'x64') { // Linux/x64 corefx testing doesn't need a flow job; the "build" job runs run-corefx-tests.py which // builds and runs the corefx tests. Other Linux/x64 flow jobs are required to get the test // build from a Windows machine. if (isCoreFxScenario(scenario)) { return false } } } // For CentOS, we only want Checked/Release builds. if (os == 'CentOS7.1') { if (configuration != 'Checked' && configuration != 'Release') { return false } if (!isNormalOrInnerloop && !isR2RScenario(scenario)) { return false } } // For RedHat and Debian, we only do Release builds. else if (os == 'RHEL7.2' || os == 'Debian8.4') { if (configuration != 'Release') { return false } if (!isNormalOrInnerloop) { return false } } // Next, filter based on scenario. if (isJitStressScenario(scenario)) { if (configuration != 'Checked') { return false } } else if (isR2RBaselineScenario(scenario)) { if (configuration != 'Checked' && configuration != 'Release') { return false } } else if (isR2RStressScenario(scenario)) { if (configuration != 'Checked') { return false } } else if (isCrossGenComparisonScenario(scenario)) { return shouldGenerateCrossGenComparisonJob(os, architecture, configuration, scenario) } else { // Skip scenarios switch (scenario) { case 'ilrt': case 'longgc': case 'gcsimulator': // Long GC tests take a long time on non-Release builds // ilrt is also Release only if (configuration != 'Release') { return false } break case 'jitdiff': if (configuration != 'Checked') { return false } break case 'gc_reliability_framework': case 'standalone_gc': if (configuration != 'Release' && configuration != 'Checked') { return false } break case 'formatting': return false case 'illink': if (os != 'Windows_NT' && os != 'Ubuntu') { return false } break case 'normal': // Nothing skipped break case 'innerloop': if (!isValidPrTriggeredInnerLoopJob(os, architecture, configuration, false)) { return false } break default: println("Unknown scenario: ${scenario}") assert false break } } // The job was not filtered out, so we should generate it! return true } // Create jobs requiring flow jobs. This includes x64 non-Windows, arm/arm64 Ubuntu, and arm/arm64 Windows. Constants.allScenarios.each { scenario -> [true, false].each { isPR -> Constants.architectureList.each { architecture -> Constants.configurationList.each { configuration -> Constants.osList.each { os -> if (!shouldGenerateFlowJob(scenario, isPR, architecture, configuration, os)) { return } def windowsArmJob = ((os == "Windows_NT") && (architecture in Constants.armWindowsCrossArchitectureList)) def doCoreFxTesting = isCoreFxScenario(scenario) def doCrossGenComparison = isCrossGenComparisonScenario(scenario) // Figure out the job name of the CoreCLR build the test will depend on. def inputCoreCLRBuildScenario = isInnerloopTestScenario(scenario) ? 'innerloop' : 'normal' def inputCoreCLRBuildIsBuildOnly = false if (doCoreFxTesting) { // Every CoreFx test depends on its own unique build. inputCoreCLRBuildScenario = scenario if (windowsArmJob) { // Only Windows ARM corefx jobs use "build only" jobs. Others, such as Ubuntu ARM corefx, use "regular" jobs. inputCoreCLRBuildIsBuildOnly = true } } if (doCrossGenComparison) { inputCoreCLRBuildScenario = scenario } def inputCoreCLRFolderName = getJobFolder(inputCoreCLRBuildScenario) def inputCoreCLRBuildName = projectFolder + '/' + Utilities.getFullJobName(project, getJobName(configuration, architecture, os, inputCoreCLRBuildScenario, inputCoreCLRBuildIsBuildOnly), isPR, inputCoreCLRFolderName) // Figure out the name of the build job that the test job will depend on. // For Windows ARM tests, this is not used, as the CoreCLR build creates the tests. For other // tests (e.g., Linux ARM), we depend on a Windows build to get the tests. // For CoreFX tests, however, Linux doesn't need the Windows build for the tests, since the // CoreFX build creates the tests. def inputTestsBuildName = null if (!windowsArmJob && !doCoreFxTesting & !doCrossGenComparison) { def testBuildScenario = isInnerloopTestScenario(scenario) ? 'innerloop' : 'normal' def inputTestsBuildArch = architecture if (architecture == "arm64") { // Use the x64 test build for arm64 unix inputTestsBuildArch = "x64" } else if (architecture == "arm") { // Use the x86 test build for arm unix inputTestsBuildArch = "x86" } def inputTestsBuildIsBuildOnly = true inputTestsBuildName = projectFolder + '/' + Utilities.getFullJobName(project, getJobName(configuration, inputTestsBuildArch, 'windows_nt', testBuildScenario, inputTestsBuildIsBuildOnly), isPR) } // ============================================================================================= // Create the test job // ============================================================================================= def testJob = CreateTestJob(this, project, branch, architecture, os, configuration, scenario, isPR, inputCoreCLRBuildName, inputTestsBuildName) // ============================================================================================= // Create a build flow to join together the build and tests required to run this test. // ============================================================================================= if (os == 'RHEL7.2' || os == 'Debian8.4') { // Do not create the flow job for RHEL jobs. return } def fullTestJobName = projectFolder + '/' + testJob.name def flowJob = CreateFlowJob(this, project, branch, architecture, os, configuration, scenario, isPR, fullTestJobName, inputCoreCLRBuildName, inputTestsBuildName) } // os } // configuration } // architecture } // isPR } // scenario JobReport.Report.generateJobReport(out) // Make the call to generate the help job Utilities.createHelperJob(this, project, branch, "Welcome to the ${project} Repository", // This is prepended to the help message "Have a nice day!") // This is appended to the help message. You might put known issues here. Utilities.addCROSSCheck(this, project, branch)