## @file # build a platform or a module # # Copyright (c) 2007 - 2013, Intel Corporation. All rights reserved.
# # This program and the accompanying materials # are licensed and made available under the terms and conditions of the BSD License # which accompanies this distribution. The full text of the license may be found at # http://opensource.org/licenses/bsd-license.php # # THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, # WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. # ## # Import Modules # import os import re import StringIO import sys import glob import time import platform import traceback import encodings.ascii from struct import * from threading import * from optparse import OptionParser from subprocess import * from Common import Misc as Utils from Common.TargetTxtClassObject import * from Common.ToolDefClassObject import * from Common.DataType import * from Common.BuildVersion import gBUILD_VERSION from AutoGen.AutoGen import * from Common.BuildToolError import * from Workspace.WorkspaceDatabase import * from BuildReport import BuildReport from GenPatchPcdTable.GenPatchPcdTable import * from PatchPcdValue.PatchPcdValue import * import Common.EdkLogger import Common.GlobalData as GlobalData # Version and Copyright VersionNumber = "0.51" + ' ' + gBUILD_VERSION __version__ = "%prog Version " + VersionNumber __copyright__ = "Copyright (c) 2007 - 2013, Intel Corporation All rights reserved." ## standard targets of build command gSupportedTarget = ['all', 'genc', 'genmake', 'modules', 'libraries', 'fds', 'clean', 'cleanall', 'cleanlib', 'run'] ## build configuration file gBuildConfiguration = "Conf/target.txt" gBuildCacheDir = "Conf/.cache" gToolsDefinition = "Conf/tools_def.txt" TemporaryTablePattern = re.compile(r'^_\d+_\d+_[a-fA-F0-9]+$') TmpTableDict = {} ## Check environment PATH variable to make sure the specified tool is found # # If the tool is found in the PATH, then True is returned # Otherwise, False is returned # def IsToolInPath(tool): if os.environ.has_key('PATHEXT'): extns = os.environ['PATHEXT'].split(os.path.pathsep) else: extns = ('',) for pathDir in os.environ['PATH'].split(os.path.pathsep): for ext in extns: if os.path.exists(os.path.join(pathDir, tool + ext)): return True return False ## Check environment variables # # Check environment variables that must be set for build. Currently they are # # WORKSPACE The directory all packages/platforms start from # EDK_TOOLS_PATH The directory contains all tools needed by the build # PATH $(EDK_TOOLS_PATH)/Bin/ must be set in PATH # # If any of above environment variable is not set or has error, the build # will be broken. # def CheckEnvVariable(): # check WORKSPACE if "WORKSPACE" not in os.environ: EdkLogger.error("build", ATTRIBUTE_NOT_AVAILABLE, "Environment variable not found", ExtraData="WORKSPACE") WorkspaceDir = os.path.normcase(os.path.normpath(os.environ["WORKSPACE"])) if not os.path.exists(WorkspaceDir): EdkLogger.error("build", FILE_NOT_FOUND, "WORKSPACE doesn't exist", ExtraData="%s" % WorkspaceDir) elif ' ' in WorkspaceDir: EdkLogger.error("build", FORMAT_NOT_SUPPORTED, "No space is allowed in WORKSPACE path", ExtraData=WorkspaceDir) os.environ["WORKSPACE"] = WorkspaceDir # # Check EFI_SOURCE (Edk build convention). EDK_SOURCE will always point to ECP # if "ECP_SOURCE" not in os.environ: os.environ["ECP_SOURCE"] = os.path.join(WorkspaceDir, GlobalData.gEdkCompatibilityPkg) if "EFI_SOURCE" not in os.environ: os.environ["EFI_SOURCE"] = os.environ["ECP_SOURCE"] if "EDK_SOURCE" not in os.environ: os.environ["EDK_SOURCE"] = os.environ["ECP_SOURCE"] # # Unify case of characters on case-insensitive systems # EfiSourceDir = os.path.normcase(os.path.normpath(os.environ["EFI_SOURCE"])) EdkSourceDir = os.path.normcase(os.path.normpath(os.environ["EDK_SOURCE"])) EcpSourceDir = os.path.normcase(os.path.normpath(os.environ["ECP_SOURCE"])) os.environ["EFI_SOURCE"] = EfiSourceDir os.environ["EDK_SOURCE"] = EdkSourceDir os.environ["ECP_SOURCE"] = EcpSourceDir os.environ["EDK_TOOLS_PATH"] = os.path.normcase(os.environ["EDK_TOOLS_PATH"]) if not os.path.exists(EcpSourceDir): EdkLogger.verbose("ECP_SOURCE = %s doesn't exist. Edk modules could not be built." % EcpSourceDir) elif ' ' in EcpSourceDir: EdkLogger.error("build", FORMAT_NOT_SUPPORTED, "No space is allowed in ECP_SOURCE path", ExtraData=EcpSourceDir) if not os.path.exists(EdkSourceDir): if EdkSourceDir == EcpSourceDir: EdkLogger.verbose("EDK_SOURCE = %s doesn't exist. Edk modules could not be built." % EdkSourceDir) else: EdkLogger.error("build", PARAMETER_INVALID, "EDK_SOURCE does not exist", ExtraData=EdkSourceDir) elif ' ' in EdkSourceDir: EdkLogger.error("build", FORMAT_NOT_SUPPORTED, "No space is allowed in EDK_SOURCE path", ExtraData=EdkSourceDir) if not os.path.exists(EfiSourceDir): if EfiSourceDir == EcpSourceDir: EdkLogger.verbose("EFI_SOURCE = %s doesn't exist. Edk modules could not be built." % EfiSourceDir) else: EdkLogger.error("build", PARAMETER_INVALID, "EFI_SOURCE does not exist", ExtraData=EfiSourceDir) elif ' ' in EfiSourceDir: EdkLogger.error("build", FORMAT_NOT_SUPPORTED, "No space is allowed in EFI_SOURCE path", ExtraData=EfiSourceDir) # change absolute path to relative path to WORKSPACE if EfiSourceDir.upper().find(WorkspaceDir.upper()) != 0: EdkLogger.error("build", PARAMETER_INVALID, "EFI_SOURCE is not under WORKSPACE", ExtraData="WORKSPACE = %s\n EFI_SOURCE = %s" % (WorkspaceDir, EfiSourceDir)) if EdkSourceDir.upper().find(WorkspaceDir.upper()) != 0: EdkLogger.error("build", PARAMETER_INVALID, "EDK_SOURCE is not under WORKSPACE", ExtraData="WORKSPACE = %s\n EDK_SOURCE = %s" % (WorkspaceDir, EdkSourceDir)) if EcpSourceDir.upper().find(WorkspaceDir.upper()) != 0: EdkLogger.error("build", PARAMETER_INVALID, "ECP_SOURCE is not under WORKSPACE", ExtraData="WORKSPACE = %s\n ECP_SOURCE = %s" % (WorkspaceDir, EcpSourceDir)) # check EDK_TOOLS_PATH if "EDK_TOOLS_PATH" not in os.environ: EdkLogger.error("build", ATTRIBUTE_NOT_AVAILABLE, "Environment variable not found", ExtraData="EDK_TOOLS_PATH") # check PATH if "PATH" not in os.environ: EdkLogger.error("build", ATTRIBUTE_NOT_AVAILABLE, "Environment variable not found", ExtraData="PATH") GlobalData.gWorkspace = WorkspaceDir GlobalData.gEfiSource = EfiSourceDir GlobalData.gEdkSource = EdkSourceDir GlobalData.gEcpSource = EcpSourceDir GlobalData.gGlobalDefines["WORKSPACE"] = WorkspaceDir GlobalData.gGlobalDefines["EFI_SOURCE"] = EfiSourceDir GlobalData.gGlobalDefines["EDK_SOURCE"] = EdkSourceDir GlobalData.gGlobalDefines["ECP_SOURCE"] = EcpSourceDir GlobalData.gGlobalDefines["EDK_TOOLS_PATH"] = os.environ["EDK_TOOLS_PATH"] ## Get normalized file path # # Convert the path to be local format, and remove the WORKSPACE path at the # beginning if the file path is given in full path. # # @param FilePath File path to be normalized # @param Workspace Workspace path which the FilePath will be checked against # # @retval string The normalized file path # def NormFile(FilePath, Workspace): # check if the path is absolute or relative if os.path.isabs(FilePath): FileFullPath = os.path.normpath(FilePath) else: FileFullPath = os.path.normpath(os.path.join(Workspace, FilePath)) # check if the file path exists or not if not os.path.isfile(FileFullPath): EdkLogger.error("build", FILE_NOT_FOUND, ExtraData="\t%s (Please give file in absolute path or relative to WORKSPACE)" % FileFullPath) # remove workspace directory from the beginning part of the file path if Workspace[-1] in ["\\", "/"]: return FileFullPath[len(Workspace):] else: return FileFullPath[(len(Workspace) + 1):] ## Get the output of an external program # # This is the entrance method of thread reading output of an external program and # putting them in STDOUT/STDERR of current program. # # @param From The stream message read from # @param To The stream message put on # @param ExitFlag The flag used to indicate stopping reading # def ReadMessage(From, To, ExitFlag): while True: # read one line a time Line = From.readline() # empty string means "end" if Line != None and Line != "": To(Line.rstrip()) else: break if ExitFlag.isSet(): break ## Launch an external program # # This method will call subprocess.Popen to execute an external program with # given options in specified directory. Because of the dead-lock issue during # redirecting output of the external program, threads are used to to do the # redirection work. # # @param Command A list or string containing the call of the program # @param WorkingDir The directory in which the program will be running # def LaunchCommand(Command, WorkingDir): # if working directory doesn't exist, Popen() will raise an exception if not os.path.isdir(WorkingDir): EdkLogger.error("build", FILE_NOT_FOUND, ExtraData=WorkingDir) Proc = None EndOfProcedure = None try: # launch the command Proc = Popen(Command, stdout=PIPE, stderr=PIPE, env=os.environ, cwd=WorkingDir, bufsize=-1) # launch two threads to read the STDOUT and STDERR EndOfProcedure = Event() EndOfProcedure.clear() if Proc.stdout: StdOutThread = Thread(target=ReadMessage, args=(Proc.stdout, EdkLogger.info, EndOfProcedure)) StdOutThread.setName("STDOUT-Redirector") StdOutThread.setDaemon(False) StdOutThread.start() if Proc.stderr: StdErrThread = Thread(target=ReadMessage, args=(Proc.stderr, EdkLogger.quiet, EndOfProcedure)) StdErrThread.setName("STDERR-Redirector") StdErrThread.setDaemon(False) StdErrThread.start() # waiting for program exit Proc.wait() except: # in case of aborting # terminate the threads redirecting the program output if EndOfProcedure != None: EndOfProcedure.set() if Proc == None: if type(Command) != type(""): Command = " ".join(Command) EdkLogger.error("build", COMMAND_FAILURE, "Failed to start command", ExtraData="%s [%s]" % (Command, WorkingDir)) if Proc.stdout: StdOutThread.join() if Proc.stderr: StdErrThread.join() # check the return code of the program if Proc.returncode != 0: if type(Command) != type(""): Command = " ".join(Command) EdkLogger.error("build", COMMAND_FAILURE, ExtraData="%s [%s]" % (Command, WorkingDir)) ## The smallest unit that can be built in multi-thread build mode # # This is the base class of build unit. The "Obj" parameter must provide # __str__(), __eq__() and __hash__() methods. Otherwise there could be build units # missing build. # # Currently the "Obj" should be only ModuleAutoGen or PlatformAutoGen objects. # class BuildUnit: ## The constructor # # @param self The object pointer # @param Obj The object the build is working on # @param Target The build target name, one of gSupportedTarget # @param Dependency The BuildUnit(s) which must be completed in advance # @param WorkingDir The directory build command starts in # def __init__(self, Obj, BuildCommand, Target, Dependency, WorkingDir="."): self.BuildObject = Obj self.Dependency = Dependency self.WorkingDir = WorkingDir self.Target = Target self.BuildCommand = BuildCommand if not BuildCommand: EdkLogger.error("build", OPTION_MISSING, "No build command found for this module. " "Please check your setting of %s_%s_%s_MAKE_PATH in Conf/tools_def.txt file." % (Obj.BuildTarget, Obj.ToolChain, Obj.Arch), ExtraData=str(Obj)) ## str() method # # It just returns the string representation of self.BuildObject # # @param self The object pointer # def __str__(self): return str(self.BuildObject) ## "==" operator method # # It just compares self.BuildObject with "Other". So self.BuildObject must # provide its own __eq__() method. # # @param self The object pointer # @param Other The other BuildUnit object compared to # def __eq__(self, Other): return Other != None and self.BuildObject == Other.BuildObject \ and self.BuildObject.Arch == Other.BuildObject.Arch ## hash() method # # It just returns the hash value of self.BuildObject which must be hashable. # # @param self The object pointer # def __hash__(self): return hash(self.BuildObject) + hash(self.BuildObject.Arch) def __repr__(self): return repr(self.BuildObject) ## The smallest module unit that can be built by nmake/make command in multi-thread build mode # # This class is for module build by nmake/make build system. The "Obj" parameter # must provide __str__(), __eq__() and __hash__() methods. Otherwise there could # be make units missing build. # # Currently the "Obj" should be only ModuleAutoGen object. # class ModuleMakeUnit(BuildUnit): ## The constructor # # @param self The object pointer # @param Obj The ModuleAutoGen object the build is working on # @param Target The build target name, one of gSupportedTarget # def __init__(self, Obj, Target): Dependency = [ModuleMakeUnit(La, Target) for La in Obj.LibraryAutoGenList] BuildUnit.__init__(self, Obj, Obj.BuildCommand, Target, Dependency, Obj.MakeFileDir) if Target in [None, "", "all"]: self.Target = "tbuild" ## The smallest platform unit that can be built by nmake/make command in multi-thread build mode # # This class is for platform build by nmake/make build system. The "Obj" parameter # must provide __str__(), __eq__() and __hash__() methods. Otherwise there could # be make units missing build. # # Currently the "Obj" should be only PlatformAutoGen object. # class PlatformMakeUnit(BuildUnit): ## The constructor # # @param self The object pointer # @param Obj The PlatformAutoGen object the build is working on # @param Target The build target name, one of gSupportedTarget # def __init__(self, Obj, Target): Dependency = [ModuleMakeUnit(Lib, Target) for Lib in self.BuildObject.LibraryAutoGenList] Dependency.extend([ModuleMakeUnit(Mod, Target) for Mod in self.BuildObject.ModuleAutoGenList]) BuildUnit.__init__(self, Obj, Obj.BuildCommand, Target, Dependency, Obj.MakeFileDir) ## The class representing the task of a module build or platform build # # This class manages the build tasks in multi-thread build mode. Its jobs include # scheduling thread running, catching thread error, monitor the thread status, etc. # class BuildTask: # queue for tasks waiting for schedule _PendingQueue = sdict() _PendingQueueLock = threading.Lock() # queue for tasks ready for running _ReadyQueue = sdict() _ReadyQueueLock = threading.Lock() # queue for run tasks _RunningQueue = sdict() _RunningQueueLock = threading.Lock() # queue containing all build tasks, in case duplicate build _TaskQueue = sdict() # flag indicating error occurs in a running thread _ErrorFlag = threading.Event() _ErrorFlag.clear() _ErrorMessage = "" # BoundedSemaphore object used to control the number of running threads _Thread = None # flag indicating if the scheduler is started or not _SchedulerStopped = threading.Event() _SchedulerStopped.set() ## Start the task scheduler thread # # @param MaxThreadNumber The maximum thread number # @param ExitFlag Flag used to end the scheduler # @staticmethod def StartScheduler(MaxThreadNumber, ExitFlag): SchedulerThread = Thread(target=BuildTask.Scheduler, args=(MaxThreadNumber, ExitFlag)) SchedulerThread.setName("Build-Task-Scheduler") SchedulerThread.setDaemon(False) SchedulerThread.start() # wait for the scheduler to be started, especially useful in Linux while not BuildTask.IsOnGoing(): time.sleep(0.01) ## Scheduler method # # @param MaxThreadNumber The maximum thread number # @param ExitFlag Flag used to end the scheduler # @staticmethod def Scheduler(MaxThreadNumber, ExitFlag): BuildTask._SchedulerStopped.clear() try: # use BoundedSemaphore to control the maximum running threads BuildTask._Thread = BoundedSemaphore(MaxThreadNumber) # # scheduling loop, which will exits when no pending/ready task and # indicated to do so, or there's error in running thread # while (len(BuildTask._PendingQueue) > 0 or len(BuildTask._ReadyQueue) > 0 \ or not ExitFlag.isSet()) and not BuildTask._ErrorFlag.isSet(): EdkLogger.debug(EdkLogger.DEBUG_8, "Pending Queue (%d), Ready Queue (%d)" % (len(BuildTask._PendingQueue), len(BuildTask._ReadyQueue))) # get all pending tasks BuildTask._PendingQueueLock.acquire() BuildObjectList = BuildTask._PendingQueue.keys() # # check if their dependency is resolved, and if true, move them # into ready queue # for BuildObject in BuildObjectList: Bt = BuildTask._PendingQueue[BuildObject] if Bt.IsReady(): BuildTask._ReadyQueue[BuildObject] = BuildTask._PendingQueue.pop(BuildObject) BuildTask._PendingQueueLock.release() # launch build thread until the maximum number of threads is reached while not BuildTask._ErrorFlag.isSet(): # empty ready queue, do nothing further if len(BuildTask._ReadyQueue) == 0: break # wait for active thread(s) exit BuildTask._Thread.acquire(True) # start a new build thread Bo = BuildTask._ReadyQueue.keys()[0] Bt = BuildTask._ReadyQueue.pop(Bo) # move into running queue BuildTask._RunningQueueLock.acquire() BuildTask._RunningQueue[Bo] = Bt BuildTask._RunningQueueLock.release() Bt.Start() # avoid tense loop time.sleep(0.01) # avoid tense loop time.sleep(0.01) # wait for all running threads exit if BuildTask._ErrorFlag.isSet(): EdkLogger.quiet("\nWaiting for all build threads exit...") # while not BuildTask._ErrorFlag.isSet() and \ while len(BuildTask._RunningQueue) > 0: EdkLogger.verbose("Waiting for thread ending...(%d)" % len(BuildTask._RunningQueue)) EdkLogger.debug(EdkLogger.DEBUG_8, "Threads [%s]" % ", ".join([Th.getName() for Th in threading.enumerate()])) # avoid tense loop time.sleep(0.1) except BaseException, X: # # TRICK: hide the output of threads left runing, so that the user can # catch the error message easily # EdkLogger.SetLevel(EdkLogger.ERROR) BuildTask._ErrorFlag.set() BuildTask._ErrorMessage = "build thread scheduler error\n\t%s" % str(X) BuildTask._PendingQueue.clear() BuildTask._ReadyQueue.clear() BuildTask._RunningQueue.clear() BuildTask._TaskQueue.clear() BuildTask._SchedulerStopped.set() ## Wait for all running method exit # @staticmethod def WaitForComplete(): BuildTask._SchedulerStopped.wait() ## Check if the scheduler is running or not # @staticmethod def IsOnGoing(): return not BuildTask._SchedulerStopped.isSet() ## Abort the build @staticmethod def Abort(): if BuildTask.IsOnGoing(): BuildTask._ErrorFlag.set() BuildTask.WaitForComplete() ## Check if there's error in running thread # # Since the main thread cannot catch exceptions in other thread, we have to # use threading.Event to communicate this formation to main thread. # @staticmethod def HasError(): return BuildTask._ErrorFlag.isSet() ## Get error message in running thread # # Since the main thread cannot catch exceptions in other thread, we have to # use a static variable to communicate this message to main thread. # @staticmethod def GetErrorMessage(): return BuildTask._ErrorMessage ## Factory method to create a BuildTask object # # This method will check if a module is building or has been built. And if # true, just return the associated BuildTask object in the _TaskQueue. If # not, create and return a new BuildTask object. The new BuildTask object # will be appended to the _PendingQueue for scheduling later. # # @param BuildItem A BuildUnit object representing a build object # @param Dependency The dependent build object of BuildItem # @staticmethod def New(BuildItem, Dependency=None): if BuildItem in BuildTask._TaskQueue: Bt = BuildTask._TaskQueue[BuildItem] return Bt Bt = BuildTask() Bt._Init(BuildItem, Dependency) BuildTask._TaskQueue[BuildItem] = Bt BuildTask._PendingQueueLock.acquire() BuildTask._PendingQueue[BuildItem] = Bt BuildTask._PendingQueueLock.release() return Bt ## The real constructor of BuildTask # # @param BuildItem A BuildUnit object representing a build object # @param Dependency The dependent build object of BuildItem # def _Init(self, BuildItem, Dependency=None): self.BuildItem = BuildItem self.DependencyList = [] if Dependency == None: Dependency = BuildItem.Dependency else: Dependency.extend(BuildItem.Dependency) self.AddDependency(Dependency) # flag indicating build completes, used to avoid unnecessary re-build self.CompleteFlag = False ## Check if all dependent build tasks are completed or not # def IsReady(self): ReadyFlag = True for Dep in self.DependencyList: if Dep.CompleteFlag == True: continue ReadyFlag = False break return ReadyFlag ## Add dependent build task # # @param Dependency The list of dependent build objects # def AddDependency(self, Dependency): for Dep in Dependency: self.DependencyList.append(BuildTask.New(Dep)) # BuildTask list ## The thread wrapper of LaunchCommand function # # @param Command A list or string contains the call of the command # @param WorkingDir The directory in which the program will be running # def _CommandThread(self, Command, WorkingDir): try: LaunchCommand(Command, WorkingDir) self.CompleteFlag = True except: # # TRICK: hide the output of threads left runing, so that the user can # catch the error message easily # if not BuildTask._ErrorFlag.isSet(): GlobalData.gBuildingModule = "%s [%s, %s, %s]" % (str(self.BuildItem.BuildObject), self.BuildItem.BuildObject.Arch, self.BuildItem.BuildObject.ToolChain, self.BuildItem.BuildObject.BuildTarget ) EdkLogger.SetLevel(EdkLogger.ERROR) BuildTask._ErrorFlag.set() BuildTask._ErrorMessage = "%s broken\n %s [%s]" % \ (threading.currentThread().getName(), Command, WorkingDir) # indicate there's a thread is available for another build task BuildTask._RunningQueueLock.acquire() BuildTask._RunningQueue.pop(self.BuildItem) BuildTask._RunningQueueLock.release() BuildTask._Thread.release() ## Start build task thread # def Start(self): EdkLogger.quiet("Building ... %s" % repr(self.BuildItem)) Command = self.BuildItem.BuildCommand + [self.BuildItem.Target] self.BuildTread = Thread(target=self._CommandThread, args=(Command, self.BuildItem.WorkingDir)) self.BuildTread.setName("build thread") self.BuildTread.setDaemon(False) self.BuildTread.start() ## The class contains the information related to EFI image # class PeImageInfo(): ## Constructor # # Constructor will load all required image information. # # @param BaseName The full file path of image. # @param Guid The GUID for image. # @param Arch Arch of this image. # @param OutputDir The output directory for image. # @param DebugDir The debug directory for image. # @param ImageClass PeImage Information # def __init__(self, BaseName, Guid, Arch, OutputDir, DebugDir, ImageClass): self.BaseName = BaseName self.Guid = Guid self.Arch = Arch self.OutputDir = OutputDir self.DebugDir = DebugDir self.Image = ImageClass self.Image.Size = (self.Image.Size / 0x1000 + 1) * 0x1000 ## The class implementing the EDK2 build process # # The build process includes: # 1. Load configuration from target.txt and tools_def.txt in $(WORKSPACE)/Conf # 2. Parse DSC file of active platform # 3. Parse FDF file if any # 4. Establish build database, including parse all other files (module, package) # 5. Create AutoGen files (C code file, depex file, makefile) if necessary # 6. Call build command # class Build(): ## Constructor # # Constructor will load all necessary configurations, parse platform, modules # and packages and the establish a database for AutoGen. # # @param Target The build command target, one of gSupportedTarget # @param WorkspaceDir The directory of workspace # @param BuildOptions Build options passed from command line # def __init__(self, Target, WorkspaceDir, BuildOptions): self.WorkspaceDir = WorkspaceDir self.Target = Target self.PlatformFile = BuildOptions.PlatformFile self.ModuleFile = BuildOptions.ModuleFile self.ArchList = BuildOptions.TargetArch self.ToolChainList = BuildOptions.ToolChain self.BuildTargetList= BuildOptions.BuildTarget self.Fdf = BuildOptions.FdfFile self.FdList = BuildOptions.RomImage self.FvList = BuildOptions.FvImage self.CapList = BuildOptions.CapName self.SilentMode = BuildOptions.SilentMode self.ThreadNumber = BuildOptions.ThreadNumber self.SkipAutoGen = BuildOptions.SkipAutoGen self.Reparse = BuildOptions.Reparse self.SkuId = BuildOptions.SkuId self.SpawnMode = True self.BuildReport = BuildReport(BuildOptions.ReportFile, BuildOptions.ReportType) self.TargetTxt = TargetTxtClassObject() self.ToolDef = ToolDefClassObject() if BuildOptions.DisableCache: self.Db = WorkspaceDatabase(":memory:") else: self.Db = WorkspaceDatabase(None, self.Reparse) self.BuildDatabase = self.Db.BuildObject self.Platform = None self.LoadFixAddress = 0 self.UniFlag = BuildOptions.Flag # print dot character during doing some time-consuming work self.Progress = Utils.Progressor() self.InitBuild() # print current build environment and configuration EdkLogger.quiet("%-16s = %s" % ("WORKSPACE", os.environ["WORKSPACE"])) EdkLogger.quiet("%-16s = %s" % ("ECP_SOURCE", os.environ["ECP_SOURCE"])) EdkLogger.quiet("%-16s = %s" % ("EDK_SOURCE", os.environ["EDK_SOURCE"])) EdkLogger.quiet("%-16s = %s" % ("EFI_SOURCE", os.environ["EFI_SOURCE"])) EdkLogger.quiet("%-16s = %s" % ("EDK_TOOLS_PATH", os.environ["EDK_TOOLS_PATH"])) EdkLogger.info("") os.chdir(self.WorkspaceDir) ## Load configuration # # This method will parse target.txt and get the build configurations. # def LoadConfiguration(self): # # Check target.txt and tools_def.txt and Init them # BuildConfigurationFile = os.path.normpath(os.path.join(self.WorkspaceDir, gBuildConfiguration)) if os.path.isfile(BuildConfigurationFile) == True: StatusCode = self.TargetTxt.LoadTargetTxtFile(BuildConfigurationFile) ToolDefinitionFile = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_TOOL_CHAIN_CONF] if ToolDefinitionFile == '': ToolDefinitionFile = gToolsDefinition ToolDefinitionFile = os.path.normpath(os.path.join(self.WorkspaceDir, ToolDefinitionFile)) if os.path.isfile(ToolDefinitionFile) == True: StatusCode = self.ToolDef.LoadToolDefFile(ToolDefinitionFile) else: EdkLogger.error("build", FILE_NOT_FOUND, ExtraData=ToolDefinitionFile) else: EdkLogger.error("build", FILE_NOT_FOUND, ExtraData=BuildConfigurationFile) # if no ARCH given in command line, get it from target.txt if not self.ArchList: self.ArchList = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_TARGET_ARCH] self.ArchList = tuple(self.ArchList) # if no build target given in command line, get it from target.txt if not self.BuildTargetList: self.BuildTargetList = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_TARGET] # if no tool chain given in command line, get it from target.txt if not self.ToolChainList: self.ToolChainList = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_TOOL_CHAIN_TAG] if self.ToolChainList == None or len(self.ToolChainList) == 0: EdkLogger.error("build", RESOURCE_NOT_AVAILABLE, ExtraData="No toolchain given. Don't know how to build.\n") # check if the tool chains are defined or not NewToolChainList = [] for ToolChain in self.ToolChainList: if ToolChain not in self.ToolDef.ToolsDefTxtDatabase[TAB_TOD_DEFINES_TOOL_CHAIN_TAG]: EdkLogger.warn("build", "Tool chain [%s] is not defined" % ToolChain) else: NewToolChainList.append(ToolChain) # if no tool chain available, break the build if len(NewToolChainList) == 0: EdkLogger.error("build", RESOURCE_NOT_AVAILABLE, ExtraData="[%s] not defined. No toolchain available for build!\n" % ", ".join(self.ToolChainList)) else: self.ToolChainList = NewToolChainList if self.ThreadNumber == None: self.ThreadNumber = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_MAX_CONCURRENT_THREAD_NUMBER] if self.ThreadNumber == '': self.ThreadNumber = 0 else: self.ThreadNumber = int(self.ThreadNumber, 0) if self.ThreadNumber == 0: self.ThreadNumber = 1 if not self.PlatformFile: PlatformFile = self.TargetTxt.TargetTxtDictionary[DataType.TAB_TAT_DEFINES_ACTIVE_PLATFORM] if not PlatformFile: # Try to find one in current directory WorkingDirectory = os.getcwd() FileList = glob.glob(os.path.normpath(os.path.join(WorkingDirectory, '*.dsc'))) FileNum = len(FileList) if FileNum >= 2: EdkLogger.error("build", OPTION_MISSING, ExtraData="There are %d DSC files in %s. Use '-p' to specify one.\n" % (FileNum, WorkingDirectory)) elif FileNum == 1: PlatformFile = FileList[0] else: EdkLogger.error("build", RESOURCE_NOT_AVAILABLE, ExtraData="No active platform specified in target.txt or command line! Nothing can be built.\n") self.PlatformFile = PathClass(NormFile(PlatformFile, self.WorkspaceDir), self.WorkspaceDir) ## Initialize build configuration # # This method will parse DSC file and merge the configurations from # command line and target.txt, then get the final build configurations. # def InitBuild(self): # parse target.txt, tools_def.txt, and platform file self.LoadConfiguration() # Allow case-insensitive for those from command line or configuration file ErrorCode, ErrorInfo = self.PlatformFile.Validate(".dsc", False) if ErrorCode != 0: EdkLogger.error("build", ErrorCode, ExtraData=ErrorInfo) # create metafile database self.Db.InitDatabase() ## Build a module or platform # # Create autogen code and makefile for a module or platform, and the launch # "make" command to build it # # @param Target The target of build command # @param Platform The platform file # @param Module The module file # @param BuildTarget The name of build target, one of "DEBUG", "RELEASE" # @param ToolChain The name of toolchain to build # @param Arch The arch of the module/platform # @param CreateDepModuleCodeFile Flag used to indicate creating code # for dependent modules/Libraries # @param CreateDepModuleMakeFile Flag used to indicate creating makefile # for dependent modules/Libraries # def _Build(self, Target, AutoGenObject, CreateDepsCodeFile=True, CreateDepsMakeFile=True): if AutoGenObject == None: return False # skip file generation for cleanxxx targets, run and fds target if Target not in ['clean', 'cleanlib', 'cleanall', 'run', 'fds']: # for target which must generate AutoGen code and makefile if not self.SkipAutoGen or Target == 'genc': self.Progress.Start("Generating code") AutoGenObject.CreateCodeFile(CreateDepsCodeFile) self.Progress.Stop("done!") if Target == "genc": return True if not self.SkipAutoGen or Target == 'genmake': self.Progress.Start("Generating makefile") AutoGenObject.CreateMakeFile(CreateDepsMakeFile) AutoGenObject.CreateAsBuiltInf() self.Progress.Stop("done!") if Target == "genmake": return True else: # always recreate top/platform makefile when clean, just in case of inconsistency AutoGenObject.CreateCodeFile(False) AutoGenObject.CreateMakeFile(False) if EdkLogger.GetLevel() == EdkLogger.QUIET: EdkLogger.quiet("Building ... %s" % repr(AutoGenObject)) BuildCommand = AutoGenObject.BuildCommand if BuildCommand == None or len(BuildCommand) == 0: EdkLogger.error("build", OPTION_MISSING, "No build command found for this module. " "Please check your setting of %s_%s_%s_MAKE_PATH in Conf/tools_def.txt file." % (AutoGenObject.BuildTarget, AutoGenObject.ToolChain, AutoGenObject.Arch), ExtraData=str(AutoGenObject)) BuildCommand = BuildCommand + [Target] LaunchCommand(BuildCommand, AutoGenObject.MakeFileDir) if Target == 'cleanall': try: #os.rmdir(AutoGenObject.BuildDir) RemoveDirectory(AutoGenObject.BuildDir, True) # # First should close DB. # self.Db.Close() RemoveDirectory(gBuildCacheDir, True) except WindowsError, X: EdkLogger.error("build", FILE_DELETE_FAILURE, ExtraData=str(X)) return True ## Rebase module image and Get function address for the input module list. # def _RebaseModule (self, MapBuffer, BaseAddress, ModuleList, AddrIsOffset = True, ModeIsSmm = False): if ModeIsSmm: AddrIsOffset = False InfFileNameList = ModuleList.keys() #InfFileNameList.sort() for InfFile in InfFileNameList: sys.stdout.write (".") sys.stdout.flush() ModuleInfo = ModuleList[InfFile] ModuleName = ModuleInfo.BaseName ModuleOutputImage = ModuleInfo.Image.FileName ModuleDebugImage = os.path.join(ModuleInfo.DebugDir, ModuleInfo.BaseName + '.efi') ## for SMM module in SMRAM, the SMRAM will be allocated from base to top. if not ModeIsSmm: BaseAddress = BaseAddress - ModuleInfo.Image.Size # # Update Image to new BaseAddress by GenFw tool # LaunchCommand(["GenFw", "--rebase", str(BaseAddress), "-r", ModuleOutputImage], ModuleInfo.OutputDir) LaunchCommand(["GenFw", "--rebase", str(BaseAddress), "-r", ModuleDebugImage], ModuleInfo.DebugDir) else: # # Set new address to the section header only for SMM driver. # LaunchCommand(["GenFw", "--address", str(BaseAddress), "-r", ModuleOutputImage], ModuleInfo.OutputDir) LaunchCommand(["GenFw", "--address", str(BaseAddress), "-r", ModuleDebugImage], ModuleInfo.DebugDir) # # Collect funtion address from Map file # ImageMapTable = ModuleOutputImage.replace('.efi', '.map') FunctionList = [] if os.path.exists(ImageMapTable): OrigImageBaseAddress = 0 ImageMap = open (ImageMapTable, 'r') for LinStr in ImageMap: if len (LinStr.strip()) == 0: continue # # Get the preferred address set on link time. # if LinStr.find ('Preferred load address is') != -1: StrList = LinStr.split() OrigImageBaseAddress = int (StrList[len(StrList) - 1], 16) StrList = LinStr.split() if len (StrList) > 4: if StrList[3] == 'f' or StrList[3] =='F': Name = StrList[1] RelativeAddress = int (StrList[2], 16) - OrigImageBaseAddress FunctionList.append ((Name, RelativeAddress)) if ModuleInfo.Arch == 'IPF' and Name.endswith('_ModuleEntryPoint'): # # Get the real entry point address for IPF image. # ModuleInfo.Image.EntryPoint = RelativeAddress ImageMap.close() # # Add general information. # if ModeIsSmm: MapBuffer.write('\n\n%s (Fixed SMRAM Offset, BaseAddress=0x%010X, EntryPoint=0x%010X)\n' % (ModuleName, BaseAddress, BaseAddress + ModuleInfo.Image.EntryPoint)) elif AddrIsOffset: MapBuffer.write('\n\n%s (Fixed Memory Offset, BaseAddress=-0x%010X, EntryPoint=-0x%010X)\n' % (ModuleName, 0 - BaseAddress, 0 - (BaseAddress + ModuleInfo.Image.EntryPoint))) else: MapBuffer.write('\n\n%s (Fixed Memory Address, BaseAddress=0x%010X, EntryPoint=0x%010X)\n' % (ModuleName, BaseAddress, BaseAddress + ModuleInfo.Image.EntryPoint)) # # Add guid and general seciton section. # TextSectionAddress = 0 DataSectionAddress = 0 for SectionHeader in ModuleInfo.Image.SectionHeaderList: if SectionHeader[0] == '.text': TextSectionAddress = SectionHeader[1] elif SectionHeader[0] in ['.data', '.sdata']: DataSectionAddress = SectionHeader[1] if AddrIsOffset: MapBuffer.write('(GUID=%s, .textbaseaddress=-0x%010X, .databaseaddress=-0x%010X)\n' % (ModuleInfo.Guid, 0 - (BaseAddress + TextSectionAddress), 0 - (BaseAddress + DataSectionAddress))) else: MapBuffer.write('(GUID=%s, .textbaseaddress=0x%010X, .databaseaddress=0x%010X)\n' % (ModuleInfo.Guid, BaseAddress + TextSectionAddress, BaseAddress + DataSectionAddress)) # # Add debug image full path. # MapBuffer.write('(IMAGE=%s)\n\n' % (ModuleDebugImage)) # # Add funtion address # for Function in FunctionList: if AddrIsOffset: MapBuffer.write(' -0x%010X %s\n' % (0 - (BaseAddress + Function[1]), Function[0])) else: MapBuffer.write(' 0x%010X %s\n' % (BaseAddress + Function[1], Function[0])) ImageMap.close() # # for SMM module in SMRAM, the SMRAM will be allocated from base to top. # if ModeIsSmm: BaseAddress = BaseAddress + ModuleInfo.Image.Size ## Collect MAP information of all FVs # def _CollectFvMapBuffer (self, MapBuffer, Wa, ModuleList): if self.Fdf: # First get the XIP base address for FV map file. GuidPattern = re.compile("[-a-fA-F0-9]+") GuidName = re.compile("\(GUID=[-a-fA-F0-9]+") for FvName in Wa.FdfProfile.FvDict.keys(): FvMapBuffer = os.path.join(Wa.FvDir, FvName + '.Fv.map') if not os.path.exists(FvMapBuffer): continue FvMap = open (FvMapBuffer, 'r') #skip FV size information FvMap.readline() FvMap.readline() FvMap.readline() FvMap.readline() for Line in FvMap: MatchGuid = GuidPattern.match(Line) if MatchGuid != None: # # Replace GUID with module name # GuidString = MatchGuid.group() if GuidString.upper() in ModuleList: Line = Line.replace(GuidString, ModuleList[GuidString.upper()].Name) MapBuffer.write('%s' % (Line)) # # Add the debug image full path. # MatchGuid = GuidName.match(Line) if MatchGuid != None: GuidString = MatchGuid.group().split("=")[1] if GuidString.upper() in ModuleList: MapBuffer.write('(IMAGE=%s)\n' % (os.path.join(ModuleList[GuidString.upper()].DebugDir, ModuleList[GuidString.upper()].Name + '.efi'))) FvMap.close() ## Collect MAP information of all modules # def _CollectModuleMapBuffer (self, MapBuffer, ModuleList): sys.stdout.write ("Generate Load Module At Fix Address Map") sys.stdout.flush() PatchEfiImageList = [] PeiModuleList = {} BtModuleList = {} RtModuleList = {} SmmModuleList = {} PeiSize = 0 BtSize = 0 RtSize = 0 # reserve 4K size in SMRAM to make SMM module address not from 0. SmmSize = 0x1000 IsIpfPlatform = False if 'IPF' in self.ArchList: IsIpfPlatform = True for ModuleGuid in ModuleList: Module = ModuleList[ModuleGuid] GlobalData.gProcessingFile = "%s [%s, %s, %s]" % (Module.MetaFile, Module.Arch, Module.ToolChain, Module.BuildTarget) OutputImageFile = '' for ResultFile in Module.CodaTargetList: if str(ResultFile.Target).endswith('.efi'): # # module list for PEI, DXE, RUNTIME and SMM # OutputImageFile = os.path.join(Module.OutputDir, Module.Name + '.efi') ImageClass = PeImageClass (OutputImageFile) if not ImageClass.IsValid: EdkLogger.error("build", FILE_PARSE_FAILURE, ExtraData=ImageClass.ErrorInfo) ImageInfo = PeImageInfo(Module.Name, Module.Guid, Module.Arch, Module.OutputDir, Module.DebugDir, ImageClass) if Module.ModuleType in ['PEI_CORE', 'PEIM', 'COMBINED_PEIM_DRIVER','PIC_PEIM', 'RELOCATABLE_PEIM', 'DXE_CORE']: PeiModuleList[Module.MetaFile] = ImageInfo PeiSize += ImageInfo.Image.Size elif Module.ModuleType in ['BS_DRIVER', 'DXE_DRIVER', 'UEFI_DRIVER']: BtModuleList[Module.MetaFile] = ImageInfo BtSize += ImageInfo.Image.Size elif Module.ModuleType in ['DXE_RUNTIME_DRIVER', 'RT_DRIVER', 'DXE_SAL_DRIVER', 'SAL_RT_DRIVER']: RtModuleList[Module.MetaFile] = ImageInfo #IPF runtime driver needs to be at 2 page alignment. if IsIpfPlatform and ImageInfo.Image.Size % 0x2000 != 0: ImageInfo.Image.Size = (ImageInfo.Image.Size / 0x2000 + 1) * 0x2000 RtSize += ImageInfo.Image.Size elif Module.ModuleType in ['SMM_CORE', 'DXE_SMM_DRIVER']: SmmModuleList[Module.MetaFile] = ImageInfo SmmSize += ImageInfo.Image.Size if Module.ModuleType == 'DXE_SMM_DRIVER': PiSpecVersion = '0x00000000' if 'PI_SPECIFICATION_VERSION' in Module.Module.Specification: PiSpecVersion = Module.Module.Specification['PI_SPECIFICATION_VERSION'] # for PI specification < PI1.1, DXE_SMM_DRIVER also runs as BOOT time driver. if int(PiSpecVersion, 16) < 0x0001000A: BtModuleList[Module.MetaFile] = ImageInfo BtSize += ImageInfo.Image.Size break # # EFI image is final target. # Check EFI image contains patchable FixAddress related PCDs. # if OutputImageFile != '': ModuleIsPatch = False for Pcd in Module.ModulePcdList: if Pcd.Type == TAB_PCDS_PATCHABLE_IN_MODULE and Pcd.TokenCName in TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_LIST: ModuleIsPatch = True break if not ModuleIsPatch: for Pcd in Module.LibraryPcdList: if Pcd.Type == TAB_PCDS_PATCHABLE_IN_MODULE and Pcd.TokenCName in TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_LIST: ModuleIsPatch = True break if not ModuleIsPatch: continue # # Module includes the patchable load fix address PCDs. # It will be fixed up later. # PatchEfiImageList.append (OutputImageFile) # # Get Top Memory address # ReservedRuntimeMemorySize = 0 TopMemoryAddress = 0 if self.LoadFixAddress == 0xFFFFFFFFFFFFFFFF: TopMemoryAddress = 0 else: TopMemoryAddress = self.LoadFixAddress if TopMemoryAddress < RtSize + BtSize + PeiSize: EdkLogger.error("build", PARAMETER_INVALID, "FIX_LOAD_TOP_MEMORY_ADDRESS is too low to load driver") # Make IPF runtime driver at 2 page alignment. if IsIpfPlatform: ReservedRuntimeMemorySize = TopMemoryAddress % 0x2000 RtSize = RtSize + ReservedRuntimeMemorySize # # Patch FixAddress related PCDs into EFI image # for EfiImage in PatchEfiImageList: EfiImageMap = EfiImage.replace('.efi', '.map') if not os.path.exists(EfiImageMap): continue # # Get PCD offset in EFI image by GenPatchPcdTable function # PcdTable = parsePcdInfoFromMapFile(EfiImageMap, EfiImage) # # Patch real PCD value by PatchPcdValue tool # for PcdInfo in PcdTable: ReturnValue = 0 if PcdInfo[0] == TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_PEI_PAGE_SIZE: ReturnValue, ErrorInfo = PatchBinaryFile (EfiImage, PcdInfo[1], TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_PEI_PAGE_SIZE_DATA_TYPE, str (PeiSize/0x1000)) elif PcdInfo[0] == TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_DXE_PAGE_SIZE: ReturnValue, ErrorInfo = PatchBinaryFile (EfiImage, PcdInfo[1], TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_DXE_PAGE_SIZE_DATA_TYPE, str (BtSize/0x1000)) elif PcdInfo[0] == TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_RUNTIME_PAGE_SIZE: ReturnValue, ErrorInfo = PatchBinaryFile (EfiImage, PcdInfo[1], TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_RUNTIME_PAGE_SIZE_DATA_TYPE, str (RtSize/0x1000)) elif PcdInfo[0] == TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_SMM_PAGE_SIZE and len (SmmModuleList) > 0: ReturnValue, ErrorInfo = PatchBinaryFile (EfiImage, PcdInfo[1], TAB_PCDS_PATCHABLE_LOAD_FIX_ADDRESS_SMM_PAGE_SIZE_DATA_TYPE, str (SmmSize/0x1000)) if ReturnValue != 0: EdkLogger.error("build", PARAMETER_INVALID, "Patch PCD value failed", ExtraData=ErrorInfo) MapBuffer.write('PEI_CODE_PAGE_NUMBER = 0x%x\n' % (PeiSize/0x1000)) MapBuffer.write('BOOT_CODE_PAGE_NUMBER = 0x%x\n' % (BtSize/0x1000)) MapBuffer.write('RUNTIME_CODE_PAGE_NUMBER = 0x%x\n' % (RtSize/0x1000)) if len (SmmModuleList) > 0: MapBuffer.write('SMM_CODE_PAGE_NUMBER = 0x%x\n' % (SmmSize/0x1000)) PeiBaseAddr = TopMemoryAddress - RtSize - BtSize BtBaseAddr = TopMemoryAddress - RtSize RtBaseAddr = TopMemoryAddress - ReservedRuntimeMemorySize self._RebaseModule (MapBuffer, PeiBaseAddr, PeiModuleList, TopMemoryAddress == 0) self._RebaseModule (MapBuffer, BtBaseAddr, BtModuleList, TopMemoryAddress == 0) self._RebaseModule (MapBuffer, RtBaseAddr, RtModuleList, TopMemoryAddress == 0) self._RebaseModule (MapBuffer, 0x1000, SmmModuleList, AddrIsOffset = False, ModeIsSmm = True) MapBuffer.write('\n\n') sys.stdout.write ("\n") sys.stdout.flush() ## Save platform Map file # def _SaveMapFile (self, MapBuffer, Wa): # # Map file path is got. # MapFilePath = os.path.join(Wa.BuildDir, Wa.Name + '.map') # # Save address map into MAP file. # SaveFileOnChange(MapFilePath, MapBuffer.getvalue(), False) MapBuffer.close() if self.LoadFixAddress != 0: sys.stdout.write ("\nLoad Module At Fix Address Map file can be found at %s\n" %(MapFilePath)) sys.stdout.flush() ## Build active platform for different build targets and different tool chains # def _BuildPlatform(self): for BuildTarget in self.BuildTargetList: GlobalData.gGlobalDefines['TARGET'] = BuildTarget for ToolChain in self.ToolChainList: GlobalData.gGlobalDefines['TOOLCHAIN'] = ToolChain GlobalData.gGlobalDefines['TOOL_CHAIN_TAG'] = ToolChain Wa = WorkspaceAutoGen( self.WorkspaceDir, self.PlatformFile, BuildTarget, ToolChain, self.ArchList, self.BuildDatabase, self.TargetTxt, self.ToolDef, self.Fdf, self.FdList, self.FvList, self.CapList, self.SkuId, self.UniFlag, self.Progress ) self.Fdf = Wa.FdfFile self.LoadFixAddress = Wa.Platform.LoadFixAddress self.BuildReport.AddPlatformReport(Wa) self.Progress.Stop("done!") self._Build(self.Target, Wa) # Create MAP file when Load Fix Address is enabled. if self.Target in ["", "all", "fds"]: for Arch in Wa.ArchList: GlobalData.gGlobalDefines['ARCH'] = Arch # # Check whether the set fix address is above 4G for 32bit image. # if (Arch == 'IA32' or Arch == 'ARM') and self.LoadFixAddress != 0xFFFFFFFFFFFFFFFF and self.LoadFixAddress >= 0x100000000: EdkLogger.error("build", PARAMETER_INVALID, "FIX_LOAD_TOP_MEMORY_ADDRESS can't be set to larger than or equal to 4G for the platform with IA32 or ARM arch modules") # # Get Module List # ModuleList = {} for Pa in Wa.AutoGenObjectList: for Ma in Pa.ModuleAutoGenList: if Ma == None: continue if not Ma.IsLibrary: ModuleList[Ma.Guid.upper()] = Ma MapBuffer = StringIO('') if self.LoadFixAddress != 0: # # Rebase module to the preferred memory address before GenFds # self._CollectModuleMapBuffer(MapBuffer, ModuleList) if self.Fdf: # # create FDS again for the updated EFI image # self._Build("fds", Wa) if self.Fdf: # # Create MAP file for all platform FVs after GenFds. # self._CollectFvMapBuffer(MapBuffer, Wa, ModuleList) # # Save MAP buffer into MAP file. # self._SaveMapFile (MapBuffer, Wa) ## Build active module for different build targets, different tool chains and different archs # def _BuildModule(self): for BuildTarget in self.BuildTargetList: GlobalData.gGlobalDefines['TARGET'] = BuildTarget for ToolChain in self.ToolChainList: GlobalData.gGlobalDefines['TOOLCHAIN'] = ToolChain GlobalData.gGlobalDefines['TOOL_CHAIN_TAG'] = ToolChain # # module build needs platform build information, so get platform # AutoGen first # Wa = WorkspaceAutoGen( self.WorkspaceDir, self.PlatformFile, BuildTarget, ToolChain, self.ArchList, self.BuildDatabase, self.TargetTxt, self.ToolDef, self.Fdf, self.FdList, self.FvList, self.CapList, self.SkuId, self.UniFlag, self.Progress, self.ModuleFile ) self.Fdf = Wa.FdfFile self.LoadFixAddress = Wa.Platform.LoadFixAddress Wa.CreateMakeFile(False) self.Progress.Stop("done!") MaList = [] for Arch in Wa.ArchList: GlobalData.gGlobalDefines['ARCH'] = Arch Ma = ModuleAutoGen(Wa, self.ModuleFile, BuildTarget, ToolChain, Arch, self.PlatformFile) if Ma == None: continue MaList.append(Ma) self._Build(self.Target, Ma) self.BuildReport.AddPlatformReport(Wa, MaList) if MaList == []: EdkLogger.error( 'build', BUILD_ERROR, "Module for [%s] is not a component of active platform."\ " Please make sure that the ARCH and inf file path are"\ " given in the same as in [%s]" %\ (', '.join(Wa.ArchList), self.PlatformFile), ExtraData=self.ModuleFile ) # Create MAP file when Load Fix Address is enabled. if self.Target == "fds" and self.Fdf: for Arch in Wa.ArchList: # # Check whether the set fix address is above 4G for 32bit image. # if (Arch == 'IA32' or Arch == 'ARM') and self.LoadFixAddress != 0xFFFFFFFFFFFFFFFF and self.LoadFixAddress >= 0x100000000: EdkLogger.error("build", PARAMETER_INVALID, "FIX_LOAD_TOP_MEMORY_ADDRESS can't be set to larger than or equal to 4G for the platorm with IA32 or ARM arch modules") # # Get Module List # ModuleList = {} for Pa in Wa.AutoGenObjectList: for Ma in Pa.ModuleAutoGenList: if Ma == None: continue if not Ma.IsLibrary: ModuleList[Ma.Guid.upper()] = Ma MapBuffer = StringIO('') if self.LoadFixAddress != 0: # # Rebase module to the preferred memory address before GenFds # self._CollectModuleMapBuffer(MapBuffer, ModuleList) # # create FDS again for the updated EFI image # self._Build("fds", Wa) # # Create MAP file for all platform FVs after GenFds. # self._CollectFvMapBuffer(MapBuffer, Wa, ModuleList) # # Save MAP buffer into MAP file. # self._SaveMapFile (MapBuffer, Wa) ## Build a platform in multi-thread mode # def _MultiThreadBuildPlatform(self): for BuildTarget in self.BuildTargetList: GlobalData.gGlobalDefines['TARGET'] = BuildTarget for ToolChain in self.ToolChainList: GlobalData.gGlobalDefines['TOOLCHAIN'] = ToolChain GlobalData.gGlobalDefines['TOOL_CHAIN_TAG'] = ToolChain Wa = WorkspaceAutoGen( self.WorkspaceDir, self.PlatformFile, BuildTarget, ToolChain, self.ArchList, self.BuildDatabase, self.TargetTxt, self.ToolDef, self.Fdf, self.FdList, self.FvList, self.CapList, self.SkuId, self.UniFlag, self.Progress ) self.Fdf = Wa.FdfFile self.LoadFixAddress = Wa.Platform.LoadFixAddress self.BuildReport.AddPlatformReport(Wa) Wa.CreateMakeFile(False) # multi-thread exit flag ExitFlag = threading.Event() ExitFlag.clear() for Arch in Wa.ArchList: GlobalData.gGlobalDefines['ARCH'] = Arch Pa = PlatformAutoGen(Wa, self.PlatformFile, BuildTarget, ToolChain, Arch) if Pa == None: continue pModules = [] for Module in Pa.Platform.Modules: # Get ModuleAutoGen object to generate C code file and makefile Ma = ModuleAutoGen(Wa, Module, BuildTarget, ToolChain, Arch, self.PlatformFile) if Ma == None: continue # Not to auto-gen for targets 'clean', 'cleanlib', 'cleanall', 'run', 'fds' if self.Target not in ['clean', 'cleanlib', 'cleanall', 'run', 'fds']: # for target which must generate AutoGen code and makefile if not self.SkipAutoGen or self.Target == 'genc': Ma.CreateCodeFile(True) if self.Target == "genc": continue if not self.SkipAutoGen or self.Target == 'genmake': Ma.CreateMakeFile(True) Ma.CreateAsBuiltInf() if self.Target == "genmake": continue pModules.append(Ma) self.Progress.Stop("done!") for Ma in pModules: # Generate build task for the module Bt = BuildTask.New(ModuleMakeUnit(Ma, self.Target)) # Break build if any build thread has error if BuildTask.HasError(): # we need a full version of makefile for platform ExitFlag.set() BuildTask.WaitForComplete() Pa.CreateMakeFile(False) EdkLogger.error("build", BUILD_ERROR, "Failed to build module", ExtraData=GlobalData.gBuildingModule) # Start task scheduler if not BuildTask.IsOnGoing(): BuildTask.StartScheduler(self.ThreadNumber, ExitFlag) # in case there's an interruption. we need a full version of makefile for platform Pa.CreateMakeFile(False) if BuildTask.HasError(): EdkLogger.error("build", BUILD_ERROR, "Failed to build module", ExtraData=GlobalData.gBuildingModule) # # Save temp tables to a TmpTableDict. # for Key in Wa.BuildDatabase._CACHE_: if Wa.BuildDatabase._CACHE_[Key]._RawData and Wa.BuildDatabase._CACHE_[Key]._RawData._Table and Wa.BuildDatabase._CACHE_[Key]._RawData._Table.Table: if TemporaryTablePattern.match(Wa.BuildDatabase._CACHE_[Key]._RawData._Table.Table): TmpTableDict[Wa.BuildDatabase._CACHE_[Key]._RawData._Table.Table] = Wa.BuildDatabase._CACHE_[Key]._RawData._Table.Cur # # # All modules have been put in build tasks queue. Tell task scheduler # to exit if all tasks are completed # ExitFlag.set() BuildTask.WaitForComplete() # # Check for build error, and raise exception if one # has been signaled. # if BuildTask.HasError(): EdkLogger.error("build", BUILD_ERROR, "Failed to build module", ExtraData=GlobalData.gBuildingModule) # Create MAP file when Load Fix Address is enabled. if self.Target in ["", "all", "fds"]: for Arch in Wa.ArchList: # # Check whether the set fix address is above 4G for 32bit image. # if (Arch == 'IA32' or Arch == 'ARM') and self.LoadFixAddress != 0xFFFFFFFFFFFFFFFF and self.LoadFixAddress >= 0x100000000: EdkLogger.error("build", PARAMETER_INVALID, "FIX_LOAD_TOP_MEMORY_ADDRESS can't be set to larger than or equal to 4G for the platorm with IA32 or ARM arch modules") # # Get Module List # ModuleList = {} for Pa in Wa.AutoGenObjectList: for Ma in Pa.ModuleAutoGenList: if Ma == None: continue if not Ma.IsLibrary: ModuleList[Ma.Guid.upper()] = Ma # # Rebase module to the preferred memory address before GenFds # MapBuffer = StringIO('') if self.LoadFixAddress != 0: self._CollectModuleMapBuffer(MapBuffer, ModuleList) if self.Fdf: # # Generate FD image if there's a FDF file found # LaunchCommand(Wa.BuildCommand + ["fds"], Wa.MakeFileDir) # # Create MAP file for all platform FVs after GenFds. # self._CollectFvMapBuffer(MapBuffer, Wa, ModuleList) # # Save MAP buffer into MAP file. # self._SaveMapFile(MapBuffer, Wa) ## Generate GuidedSectionTools.txt in the FV directories. # def CreateGuidedSectionToolsFile(self): for BuildTarget in self.BuildTargetList: for ToolChain in self.ToolChainList: Wa = WorkspaceAutoGen( self.WorkspaceDir, self.PlatformFile, BuildTarget, ToolChain, self.ArchList, self.BuildDatabase, self.TargetTxt, self.ToolDef, self.Fdf, self.FdList, self.FvList, self.CapList, self.SkuId, self.UniFlag ) FvDir = Wa.FvDir if not os.path.exists(FvDir): continue for Arch in self.ArchList: # Build up the list of supported architectures for this build prefix = '%s_%s_%s_' % (BuildTarget, ToolChain, Arch) # Look through the tool definitions for GUIDed tools guidAttribs = [] for (attrib, value) in self.ToolDef.ToolsDefTxtDictionary.iteritems(): if attrib.upper().endswith('_GUID'): split = attrib.split('_') thisPrefix = '_'.join(split[0:3]) + '_' if thisPrefix == prefix: guid = self.ToolDef.ToolsDefTxtDictionary[attrib] guid = guid.lower() toolName = split[3] path = '_'.join(split[0:4]) + '_PATH' path = self.ToolDef.ToolsDefTxtDictionary[path] path = self.GetFullPathOfTool(path) guidAttribs.append((guid, toolName, path)) # Write out GuidedSecTools.txt toolsFile = os.path.join(FvDir, 'GuidedSectionTools.txt') toolsFile = open(toolsFile, 'wt') for guidedSectionTool in guidAttribs: print >> toolsFile, ' '.join(guidedSectionTool) toolsFile.close() ## Returns the full path of the tool. # def GetFullPathOfTool (self, tool): if os.path.exists(tool): return os.path.realpath(tool) else: # We need to search for the tool using the # PATH environment variable. for dirInPath in os.environ['PATH'].split(os.pathsep): foundPath = os.path.join(dirInPath, tool) if os.path.exists(foundPath): return os.path.realpath(foundPath) # If the tool was not found in the path then we just return # the input tool. return tool ## Launch the module or platform build # def Launch(self): if not self.ModuleFile: if not self.SpawnMode or self.Target not in ["", "all"]: self.SpawnMode = False self._BuildPlatform() else: self._MultiThreadBuildPlatform() self.CreateGuidedSectionToolsFile() else: self.SpawnMode = False self._BuildModule() ## Do some clean-up works when error occurred def Relinquish(self): OldLogLevel = EdkLogger.GetLevel() EdkLogger.SetLevel(EdkLogger.ERROR) #self.DumpBuildData() Utils.Progressor.Abort() if self.SpawnMode == True: BuildTask.Abort() EdkLogger.SetLevel(OldLogLevel) def DumpBuildData(self): CacheDirectory = os.path.join(self.WorkspaceDir, gBuildCacheDir) Utils.CreateDirectory(CacheDirectory) Utils.DataDump(Utils.gFileTimeStampCache, os.path.join(CacheDirectory, "gFileTimeStampCache")) Utils.DataDump(Utils.gDependencyDatabase, os.path.join(CacheDirectory, "gDependencyDatabase")) def RestoreBuildData(self): FilePath = os.path.join(self.WorkspaceDir, gBuildCacheDir, "gFileTimeStampCache") if Utils.gFileTimeStampCache == {} and os.path.isfile(FilePath): Utils.gFileTimeStampCache = Utils.DataRestore(FilePath) if Utils.gFileTimeStampCache == None: Utils.gFileTimeStampCache = {} FilePath = os.path.join(self.WorkspaceDir, gBuildCacheDir, "gDependencyDatabase") if Utils.gDependencyDatabase == {} and os.path.isfile(FilePath): Utils.gDependencyDatabase = Utils.DataRestore(FilePath) if Utils.gDependencyDatabase == None: Utils.gDependencyDatabase = {} def ParseDefines(DefineList=[]): DefineDict = {} if DefineList != None: for Define in DefineList: DefineTokenList = Define.split("=", 1) if not GlobalData.gMacroNamePattern.match(DefineTokenList[0]): EdkLogger.error('build', FORMAT_INVALID, "The macro name must be in the pattern [A-Z][A-Z0-9_]*", ExtraData=DefineTokenList[0]) if len(DefineTokenList) == 1: DefineDict[DefineTokenList[0]] = "TRUE" else: DefineDict[DefineTokenList[0]] = DefineTokenList[1].strip() return DefineDict gParamCheck = [] def SingleCheckCallback(option, opt_str, value, parser): if option not in gParamCheck: setattr(parser.values, option.dest, value) gParamCheck.append(option) else: parser.error("Option %s only allows one instance in command line!" % option) ## Parse command line options # # Using standard Python module optparse to parse command line option of this tool. # # @retval Opt A optparse.Values object containing the parsed options # @retval Args Target of build command # def MyOptionParser(): Parser = OptionParser(description=__copyright__,version=__version__,prog="build.exe",usage="%prog [options] [all|fds|genc|genmake|clean|cleanall|cleanlib|modules|libraries|run]") Parser.add_option("-a", "--arch", action="append", type="choice", choices=['IA32','X64','IPF','EBC','ARM', 'AARCH64'], dest="TargetArch", help="ARCHS is one of list: IA32, X64, IPF, ARM, AARCH64 or EBC, which overrides target.txt's TARGET_ARCH definition. To specify more archs, please repeat this option.") Parser.add_option("-p", "--platform", action="callback", type="string", dest="PlatformFile", callback=SingleCheckCallback, help="Build the platform specified by the DSC file name argument, overriding target.txt's ACTIVE_PLATFORM definition.") Parser.add_option("-m", "--module", action="callback", type="string", dest="ModuleFile", callback=SingleCheckCallback, help="Build the module specified by the INF file name argument.") Parser.add_option("-b", "--buildtarget", type="string", dest="BuildTarget", help="Using the TARGET to build the platform, overriding target.txt's TARGET definition.", action="append") Parser.add_option("-t", "--tagname", action="append", type="string", dest="ToolChain", help="Using the Tool Chain Tagname to build the platform, overriding target.txt's TOOL_CHAIN_TAG definition.") Parser.add_option("-x", "--sku-id", action="callback", type="string", dest="SkuId", callback=SingleCheckCallback, help="Using this name of SKU ID to build the platform, overriding SKUID_IDENTIFIER in DSC file.") Parser.add_option("-n", action="callback", type="int", dest="ThreadNumber", callback=SingleCheckCallback, help="Build the platform using multi-threaded compiler. The value overrides target.txt's MAX_CONCURRENT_THREAD_NUMBER. Less than 2 will disable multi-thread builds.") Parser.add_option("-f", "--fdf", action="callback", type="string", dest="FdfFile", callback=SingleCheckCallback, help="The name of the FDF file to use, which overrides the setting in the DSC file.") Parser.add_option("-r", "--rom-image", action="append", type="string", dest="RomImage", default=[], help="The name of FD to be generated. The name must be from [FD] section in FDF file.") Parser.add_option("-i", "--fv-image", action="append", type="string", dest="FvImage", default=[], help="The name of FV to be generated. The name must be from [FV] section in FDF file.") Parser.add_option("-C", "--capsule-image", action="append", type="string", dest="CapName", default=[], help="The name of Capsule to be generated. The name must be from [Capsule] section in FDF file.") Parser.add_option("-u", "--skip-autogen", action="store_true", dest="SkipAutoGen", help="Skip AutoGen step.") Parser.add_option("-e", "--re-parse", action="store_true", dest="Reparse", help="Re-parse all meta-data files.") Parser.add_option("-c", "--case-insensitive", action="store_true", dest="CaseInsensitive", default=False, help="Don't check case of file name.") Parser.add_option("-w", "--warning-as-error", action="store_true", dest="WarningAsError", help="Treat warning in tools as error.") Parser.add_option("-j", "--log", action="store", dest="LogFile", help="Put log in specified file as well as on console.") Parser.add_option("-s", "--silent", action="store_true", type=None, dest="SilentMode", help="Make use of silent mode of (n)make.") Parser.add_option("-q", "--quiet", action="store_true", type=None, help="Disable all messages except FATAL ERRORS.") Parser.add_option("-v", "--verbose", action="store_true", type=None, help="Turn on verbose output with informational messages printed, "\ "including library instances selected, final dependency expression, "\ "and warning messages, etc.") Parser.add_option("-d", "--debug", action="store", type="int", help="Enable debug messages at specified level.") Parser.add_option("-D", "--define", action="append", type="string", dest="Macros", help="Macro: \"Name [= Value]\".") Parser.add_option("-y", "--report-file", action="store", dest="ReportFile", help="Create/overwrite the report to the specified filename.") Parser.add_option("-Y", "--report-type", action="append", type="choice", choices=['PCD','LIBRARY','FLASH','DEPEX','BUILD_FLAGS','FIXED_ADDRESS', 'EXECUTION_ORDER'], dest="ReportType", default=[], help="Flags that control the type of build report to generate. Must be one of: [PCD, LIBRARY, FLASH, DEPEX, BUILD_FLAGS, FIXED_ADDRESS, EXECUTION_ORDER]. "\ "To specify more than one flag, repeat this option on the command line and the default flag set is [PCD, LIBRARY, FLASH, DEPEX, BUILD_FLAGS, FIXED_ADDRESS]") Parser.add_option("-F", "--flag", action="store", type="string", dest="Flag", help="Specify the specific option to parse EDK UNI file. Must be one of: [-c, -s]. -c is for EDK framework UNI file, and -s is for EDK UEFI UNI file. "\ "This option can also be specified by setting *_*_*_BUILD_FLAGS in [BuildOptions] section of platform DSC. If they are both specified, this value "\ "will override the setting in [BuildOptions] section of platform DSC.") Parser.add_option("-N", "--no-cache", action="store_true", dest="DisableCache", default=False, help="Disable build cache mechanism") (Opt, Args)=Parser.parse_args() return (Opt, Args) ## Tool entrance method # # This method mainly dispatch specific methods per the command line options. # If no error found, return zero value so the caller of this tool can know # if it's executed successfully or not. # # @retval 0 Tool was successful # @retval 1 Tool failed # def Main(): StartTime = time.time() # Initialize log system EdkLogger.Initialize() # # Parse the options and args # (Option, Target) = MyOptionParser() GlobalData.gOptions = Option GlobalData.gCaseInsensitive = Option.CaseInsensitive # Set log level if Option.verbose != None: EdkLogger.SetLevel(EdkLogger.VERBOSE) elif Option.quiet != None: EdkLogger.SetLevel(EdkLogger.QUIET) elif Option.debug != None: EdkLogger.SetLevel(Option.debug + 1) else: EdkLogger.SetLevel(EdkLogger.INFO) if Option.LogFile != None: EdkLogger.SetLogFile(Option.LogFile) if Option.WarningAsError == True: EdkLogger.SetWarningAsError() if platform.platform().find("Windows") >= 0: GlobalData.gIsWindows = True else: GlobalData.gIsWindows = False EdkLogger.quiet("Build environment: %s" % platform.platform()) EdkLogger.quiet(time.strftime("Build start time: %H:%M:%S, %b.%d %Y\n", time.localtime())); ReturnCode = 0 MyBuild = None try: if len(Target) == 0: Target = "all" elif len(Target) >= 2: EdkLogger.error("build", OPTION_NOT_SUPPORTED, "More than one targets are not supported.", ExtraData="Please select one of: %s" %(' '.join(gSupportedTarget))) else: Target = Target[0].lower() if Target not in gSupportedTarget: EdkLogger.error("build", OPTION_NOT_SUPPORTED, "Not supported target [%s]." % Target, ExtraData="Please select one of: %s" %(' '.join(gSupportedTarget))) # # Check environment variable: EDK_TOOLS_PATH, WORKSPACE, PATH # CheckEnvVariable() GlobalData.gCommandLineDefines.update(ParseDefines(Option.Macros)) Workspace = os.getenv("WORKSPACE") # # Get files real name in workspace dir # GlobalData.gAllFiles = Utils.DirCache(Workspace) WorkingDirectory = os.getcwd() if not Option.ModuleFile: FileList = glob.glob(os.path.normpath(os.path.join(WorkingDirectory, '*.inf'))) FileNum = len(FileList) if FileNum >= 2: EdkLogger.error("build", OPTION_NOT_SUPPORTED, "There are %d INF files in %s." % (FileNum, WorkingDirectory), ExtraData="Please use '-m ' switch to choose one.") elif FileNum == 1: Option.ModuleFile = NormFile(FileList[0], Workspace) if Option.ModuleFile: if os.path.isabs (Option.ModuleFile): if os.path.normcase (os.path.normpath(Option.ModuleFile)).find (Workspace) == 0: Option.ModuleFile = NormFile(os.path.normpath(Option.ModuleFile), Workspace) Option.ModuleFile = PathClass(Option.ModuleFile, Workspace) ErrorCode, ErrorInfo = Option.ModuleFile.Validate(".inf", False) if ErrorCode != 0: EdkLogger.error("build", ErrorCode, ExtraData=ErrorInfo) if Option.PlatformFile != None: if os.path.isabs (Option.PlatformFile): if os.path.normcase (os.path.normpath(Option.PlatformFile)).find (Workspace) == 0: Option.PlatformFile = NormFile(os.path.normpath(Option.PlatformFile), Workspace) Option.PlatformFile = PathClass(Option.PlatformFile, Workspace) if Option.FdfFile != None: if os.path.isabs (Option.FdfFile): if os.path.normcase (os.path.normpath(Option.FdfFile)).find (Workspace) == 0: Option.FdfFile = NormFile(os.path.normpath(Option.FdfFile), Workspace) Option.FdfFile = PathClass(Option.FdfFile, Workspace) ErrorCode, ErrorInfo = Option.FdfFile.Validate(".fdf", False) if ErrorCode != 0: EdkLogger.error("build", ErrorCode, ExtraData=ErrorInfo) if Option.Flag != None and Option.Flag not in ['-c', '-s']: EdkLogger.error("build", OPTION_VALUE_INVALID, "UNI flag must be one of -c or -s") MyBuild = Build(Target, Workspace, Option) GlobalData.gCommandLineDefines['ARCH'] = ' '.join(MyBuild.ArchList) MyBuild.Launch() # Drop temp tables to avoid database locked. for TmpTableName in TmpTableDict: SqlCommand = """drop table IF EXISTS %s""" % TmpTableName TmpTableDict[TmpTableName].execute(SqlCommand) #MyBuild.DumpBuildData() except FatalError, X: if MyBuild != None: # for multi-thread build exits safely MyBuild.Relinquish() if Option != None and Option.debug != None: EdkLogger.quiet("(Python %s on %s) " % (platform.python_version(), sys.platform) + traceback.format_exc()) ReturnCode = X.args[0] except Warning, X: # error from Fdf parser if MyBuild != None: # for multi-thread build exits safely MyBuild.Relinquish() if Option != None and Option.debug != None: EdkLogger.quiet("(Python %s on %s) " % (platform.python_version(), sys.platform) + traceback.format_exc()) else: EdkLogger.error(X.ToolName, FORMAT_INVALID, File=X.FileName, Line=X.LineNumber, ExtraData=X.Message, RaiseError = False) ReturnCode = FORMAT_INVALID except KeyboardInterrupt: ReturnCode = ABORT_ERROR if Option != None and Option.debug != None: EdkLogger.quiet("(Python %s on %s) " % (platform.python_version(), sys.platform) + traceback.format_exc()) except: if MyBuild != None: # for multi-thread build exits safely MyBuild.Relinquish() # try to get the meta-file from the object causing exception Tb = sys.exc_info()[-1] MetaFile = GlobalData.gProcessingFile while Tb != None: if 'self' in Tb.tb_frame.f_locals and hasattr(Tb.tb_frame.f_locals['self'], 'MetaFile'): MetaFile = Tb.tb_frame.f_locals['self'].MetaFile Tb = Tb.tb_next EdkLogger.error( "\nbuild", CODE_ERROR, "Unknown fatal error when processing [%s]" % MetaFile, ExtraData="\n(Please send email to edk2-buildtools-devel@lists.sourceforge.net for help, attaching following call stack trace!)\n", RaiseError=False ) EdkLogger.quiet("(Python %s on %s) " % (platform.python_version(), sys.platform) + traceback.format_exc()) ReturnCode = CODE_ERROR finally: Utils.Progressor.Abort() if ReturnCode == 0: Conclusion = "Done" elif ReturnCode == ABORT_ERROR: Conclusion = "Aborted" else: Conclusion = "Failed" FinishTime = time.time() BuildDuration = time.gmtime(int(round(FinishTime - StartTime))) BuildDurationStr = "" if BuildDuration.tm_yday > 1: BuildDurationStr = time.strftime("%H:%M:%S", BuildDuration) + ", %d day(s)"%(BuildDuration.tm_yday - 1) else: BuildDurationStr = time.strftime("%H:%M:%S", BuildDuration) if MyBuild != None: MyBuild.BuildReport.GenerateReport(BuildDurationStr) MyBuild.Db.Close() EdkLogger.SetLevel(EdkLogger.QUIET) EdkLogger.quiet("\n- %s -" % Conclusion) EdkLogger.quiet(time.strftime("Build end time: %H:%M:%S, %b.%d %Y", time.localtime())) EdkLogger.quiet("Build total time: %s\n" % BuildDurationStr) return ReturnCode if __name__ == '__main__': r = Main() ## 0-127 is a safe return range, and 1 is a standard default error if r < 0 or r > 127: r = 1 sys.exit(r)