/******************************************************************************* * Tracealyzer v2.4.1 Recorder Library * Percepio AB, www.percepio.com * * trcConfig.h * * Configuration parameters for the trace recorder library. Before using the * trace recorder library, please check that the default settings are * appropriate for your system, and if necessary adjust these. Most likely, you * will need to adjust the NTask, NISR, NQueue, NMutex and NSemaphore values to * reflect the number of such objects in your system. These may be * over-approximated, although larger values values implies more RAM usage. * * Terms of Use * This software is copyright Percepio AB. The recorder library is free for * use together with Percepio products. You may distribute the recorder library * in its original form, including modifications in trcHardwarePort.c/.h * given that these modification are clearly marked as your own modifications * and documented in the initial comment section of these source files. * This software is the intellectual property of Percepio AB and may not be * sold or in other ways commercially redistributed without explicit written * permission by Percepio AB. * * Disclaimer * The trace tool and recorder library is being delivered to you AS IS and * Percepio AB makes no warranty as to its use or performance. Percepio AB does * not and cannot warrant the performance or results you may obtain by using the * software or documentation. Percepio AB make no warranties, express or * implied, as to noninfringement of third party rights, merchantability, or * fitness for any particular purpose. In no event will Percepio AB, its * technology partners, or distributors be liable to you for any consequential, * incidental or special damages, including any lost profits or lost savings, * even if a representative of Percepio AB has been advised of the possibility * of such damages, or for any claim by any third party. Some jurisdictions do * not allow the exclusion or limitation of incidental, consequential or special * damages, or the exclusion of implied warranties or limitations on how long an * implied warranty may last, so the above limitations may not apply to you. * * Copyright Percepio AB, 2013. * www.percepio.com ******************************************************************************/ #ifndef TRCCONFIG_H #define TRCCONFIG_H /******************************************************************************* * CONFIGURATION RELATED TO CAPACITY AND ALLOCATION ******************************************************************************/ /******************************************************************************* * EVENT_BUFFER_SIZE * * Macro which should be defined as an integer value. * * This defines the capacity of the event buffer, i.e., the number of records * it may store. Each registered event typically use one record (4 byte), but * vTracePrintF may use multiple records depending on the number of data args. ******************************************************************************/ #define EVENT_BUFFER_SIZE 4000 /* Adjust wrt. to available RAM */ /******************************************************************************* * USE_LINKER_PRAGMA * * Macro which should be defined as an integer value, default is 0. * * If this is 1, the header file "recorderdata_linker_pragma.h" is included just * before the declaration of RecorderData (in trcBase.c), i.e., the trace data * structure. This allows the user to specify a pragma with linker options. * * Example (for IAR Embedded Workbench and NXP LPC17xx): * #pragma location="AHB_RAM_MEMORY" * * This example instructs the IAR linker to place RecorderData in another RAM * bank, the AHB RAM. This can also be used for other compilers with a similar * pragmas for linker options. * * Note that this only applies if using static allocation, see below. ******************************************************************************/ #define USE_LINKER_PRAGMA 0 /******************************************************************************* * SYMBOL_TABLE_SIZE * * Macro which should be defined as an integer value. * * This defines the capacity of the symbol table, in bytes. This symbol table * stores User Events labels and names of deleted tasks, queues, or other kernel * objects. Note that the names of active objects not stored here but in the * Object Table. Thus, if you don't use User Events or delete any kernel * objects you set this to zero (0) to minimize RAM usage. ******************************************************************************/ #define SYMBOL_TABLE_SIZE 1000 /******************************************************************************* * USE_SEPARATE_USER_EVENT_BUFFER * * Macro which should be defined as an integer value. * Default is zero (0). * * This enables and disables the use of the separate user event buffer. * * Note: When using the separate user event buffer, you may get an artificial * task instance named "Unknown actor". This is added as a placeholder when the * user event history is longer than the task scheduling history. ******************************************************************************/ #define USE_SEPARATE_USER_EVENT_BUFFER 0 /******************************************************************************* * USER_EVENT_BUFFER_SIZE * * Macro which should be defined as an integer value. * * This defines the capacity of the user event buffer, in number of slots. * A single user event can use between 1 and X slots, depending on the data. * * Only in use if USE_SEPARATE_USER_EVENT_BUFFER is set to 1. ******************************************************************************/ #define USER_EVENT_BUFFER_SIZE 500 /******************************************************************************* * USER_EVENT_CHANNELS * * Macro which should be defined as an integer value. * * This defines the number of allowed user event channels. * * Only in use if USE_SEPARATE_USER_EVENT_BUFFER is set to 1. ******************************************************************************/ #define CHANNEL_FORMAT_PAIRS 32 /******************************************************************************* * NTask, NISR, NQueue, NSemaphore, NMutex * * A group of Macros which should be defined as an integer value of zero (0) * or larger. * * This defines the capacity of the Object Property Table - the maximum number * of objects active at any given point within each object class. * * NOTE: In case objects are deleted and created during runtime, this setting * does not limit the total amount of objects, only the number of concurrently * active objects. * * Using too small values will give an error message through the vTraceError * routine, which makes the error message appear when opening the trace data * in Tracealyzer. If you are using the recorder status monitor task, * any error messages are displayed in console prints, assuming that the * print macro has been defined properly (vConsolePrintMessage). * * It can be wise to start with very large values for these constants, * unless you are very confident on these numbers. Then do a recording and * check the actual usage in Tracealyzer. This is shown by selecting * View -> Trace Details -> Resource Usage -> Object Table * * NOTE 2: Remember to account for all tasks created by the kernel, such as the * IDLE task, timer task, and any tasks created by other 3rd party * software components, such as communication stacks. The recorder also has an * optional monitor task to account for, if this is used. * Moreover, one task slot is used to indicate "(startup)", i.e., a fictive * task that represent the time before the scheduler starts. * NTask should thus be at least 2-3 slots larger than your application task count. * ******************************************************************************/ #define NTask 15 #define NISR 5 #define NQueue 5 #define NSemaphore 5 #define NMutex 5 /* Maximum object name length for each class (includes zero termination) */ #define NameLenTask 15 #define NameLenISR 15 #define NameLenQueue 15 #define NameLenSemaphore 15 #define NameLenMutex 15 /****************************************************************************** * TRACE_DESCRIPTION * * Macro which should be defined as a string. * * This string is stored in the trace and displayed in Tracealyzer. Can be * used to store, e.g., system version or build date. This is also used to store * internal error messages from the recorder, which if occurs overwrites the * value defined here. This may be maximum 256 chars. *****************************************************************************/ #define TRACE_DESCRIPTION "Tracealyzer Recorder Test Program" /****************************************************************************** * TRACE_DESCRIPTION_MAX_LENGTH * * The maximum length (including zero termination) for the TRACE_DESCRIPTION * string. Since this string also is used for internal error messages from the * recorder do not make it too short, as this may truncate the error messages. * Default is 80. * Maximum allowed length is 256 - the trace will fail to load if longer. *****************************************************************************/ #define TRACE_DESCRIPTION_MAX_LENGTH 80 /****************************************************************************** * TRACE_DATA_ALLOCATION * * This defines how to allocate the recorder data structure, i.e., using a * static declaration or using a dynamic allocation in runtime (malloc). * * Should be one of these two options: * - TRACE_DATA_ALLOCATION_STATIC (default) * - TRACE_DATA_ALLOCATION_DYNAMIC * * Using static allocation has the benefits of compile-time errors if the buffer * is too large (too large constants in trcConfig.h) and no need to call the * initialization routine (xTraceInitTraceData). * * Using dynamic allocation may give more flexibility in some cases. *****************************************************************************/ #define TRACE_DATA_ALLOCATION TRACE_DATA_ALLOCATION_STATIC /****************************************************************************** * CONFIGURATION REGARDING WHAT CODE/FEATURES TO INCLUDE *****************************************************************************/ /****************************************************************************** * USE_TRACE_ASSERT * * Macro which should be defined as either zero (0) or one (1). * Default is 0. * * If this is one (1), the TRACE_ASSERT macro will verify that a condition is * true. If the condition is false, vTraceError() will be called. *****************************************************************************/ #define USE_TRACE_ASSERT 0 /****************************************************************************** * INCLUDE_FLOAT_SUPPORT * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * If this is zero (0), all references to floating point values are removed, * in case floating point values are not supported by the platform used. * Floating point values are only used in vTracePrintF and its subroutines, to * store float (%f) or double (%lf) argments. * * Note: vTracePrintF can still be used with integer and string arguments in * either case. *****************************************************************************/ #define INCLUDE_FLOAT_SUPPORT 1 /****************************************************************************** * INCLUDE_USER_EVENTS * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * If this is zero (0) the code for creating User Events is excluded to * reduce code size. User Events are application-generated events, like * "printf" but for the trace log instead of console output. User Events are * much faster than a printf and can therefore be used in timing critical code. * See vTraceUserEvent() and vTracePrintF() in trcUser.h * * Note that Tracealyzer Standard Edition or Professional Edition is required * for User Events, they are not displayed in Tracealyzer Free Edition. *****************************************************************************/ #define INCLUDE_USER_EVENTS 1 /***************************************************************************** * INCLUDE_READY_EVENTS * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * If this is zero (0), the code for recording Ready events is * excluded. Note, this will make it impossible to calculate the correct * response times. *****************************************************************************/ #define INCLUDE_READY_EVENTS 1 /***************************************************************************** * INCLUDE_NEW_TIME_EVENTS * * Macro which should be defined as either zero (0) or one (1). * Default is 0. * * If this is zero (1), events will be generated whenever the os clock is * increased. *****************************************************************************/ #define INCLUDE_NEW_TIME_EVENTS 0 /***************************************************************************** * INCLUDE_ISR_TRACING * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * If this is zero (0), the code for recording Interrupt Service Routines is * excluded to reduce code size. * * Note, if the kernel has no central interrupt dispatcher, recording ISRs * require that you insert calls to vTraceStoreISRBegin and vTraceStoreISREnd * in your interrupt handlers. *****************************************************************************/ #define INCLUDE_ISR_TRACING 1 /****************************************************************************** * INCLUDE_OBJECT_DELETE * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * This must be enabled (1) if tasks, queues or other * traced kernel objects are deleted at runtime. If no deletes are made, this * can be set to 0 in order to exclude the delete-handling code. *****************************************************************************/ #define INCLUDE_OBJECT_DELETE 1 /****************************************************************************** * CONFIGURATION RELATED TO BEHAVIOR *****************************************************************************/ /****************************************************************************** * TRACE_RECORDER_STORE_MODE * * Macro which should be defined as one of: * - TRACE_STORE_MODE_RING_BUFFER * - TRACE_STORE_MODE_STOP_WHEN_FULL * Default is TRACE_STORE_MODE_RING_BUFFER. * * With TRACE_RECORDER_STORE_MODE set to TRACE_STORE_MODE_RING_BUFFER, the events are * stored in a ring buffer, i.e., where the oldest events are overwritten when * the buffer becomes full. This allows you to get the last events leading up * to an interesting state, e.g., an error, without having a large trace buffer * for string the whole run since startup. In this mode, the recorder can run * "forever" as the buffer never gets full, i.e., in the sense that it always * has room for more events. * * To fetch the trace in mode TRACE_STORE_MODE_RING_BUFFER, you need to first halt the * system using your debugger and then do a RAM dump, or to explicitly stop the * recorder using vTraceStop() and then store/upload the trace data using a * task that you need to provide yourself. The trace data is found in the struct * RecorderData, initialized in trcBase.c. * * Note that, if you upload the trace using a RAM dump, i.e., when the system is * halted on a breakpoint or by a debugger command, there is no need to stop the * recorder first. * * When TRACE_RECORDER_STORE_MODE is TRACE_STORE_MODE_STOP_WHEN_FULL, the recording is * stopped when the buffer becomes full. When the recorder stops itself this way * vTracePortEnd() is called which allows for custom actions, such as triggering * a task that stores the trace buffer, i.e., in case taking a RAM dump * using an on-chip debugger is not possible. In the Windows port, vTracePortEnd * saves the trace to file directly, but this is not recommended in a real-time * system since the scheduler is blocked during the processing of vTracePortEnd. *****************************************************************************/ #define TRACE_RECORDER_STORE_MODE TRACE_STORE_MODE_RING_BUFFER /****************************************************************************** * STOP_AFTER_N_EVENTS * * Macro which should be defined as an integer value, or not defined. * Default is -1 * * STOP_AFTER_N_EVENTS is intended for tests of the ring buffer mode (when * RECORDER_STORE_MODE is STORE_MODE_RING_BUFFER). It stops the recording when * the specified number of events has been observed. This value can be larger * than the buffer size, to allow for test of the "wrapping around" that occurs * in ring buffer mode . A negative value (or no definition of this macro) * disables this feature. *****************************************************************************/ #define STOP_AFTER_N_EVENTS -1 /****************************************************************************** * USE_IMPLICIT_IFE_RULES * * Macro which should be defined as either zero (0) or one (1). * Default is 1. * * ### Instance Finish Events (IFE) ### * * For tasks with "infinite" main loops (non-terminating tasks), the concept * of a task instance has no clear definition, it is an application-specific * thing. Tracealyzer allows you to define Instance Finish Events (IFEs), * which marks the point in a cyclic task when the "task instance" ends. * The IFE is a blocking kernel call, typically in the main loop of a task * which typically reads a message queue, waits for a semaphore or performs * an explicit delay. * * If USE_IMPLICIT_IFE_RULES is one (1), the kernel macros (trcKernelPort.h) * will define what kernel calls are considered by default to be IFEs. * * However, Implicit IFEs only applies to blocking kernel calls. If a * service reads a message without blocking, it does not create a new * instance since no blocking occurred. * * Moreover, the actual IFE might sometimes be another blocking call. We * therefore allow for user-defined Explicit IFEs by calling * * vTraceTaskInstanceIsFinished() * * right before the kernel call considered as IFE. This does not create an * additional event but instead stores the service code and object handle * of the IFE call as properties of the task. * * If using Explicit IFEs and the task also calls an Implicit IFE, this may * result in additional incorrect task instances. * This is solved by disabling the Implicit IFEs for the task, by adding * a call to * * vTraceTaskSkipDefaultInstanceFinishedEvents() * * in the very beginning of that task. This allows you to combine Explicit IFEs * for some tasks with Implicit IFEs for the rest of the tasks, if * USE_IMPLICIT_IFE_RULES is 1. * * By setting USE_IMPLICIT_IFE_RULES to zero (0), the implicit IFEs are disabled * for all tasks. Tasks will then be considered to have a single instance only, * covering all execution fragments, unless you define an explicit IFE in each * task by calling vTraceTaskInstanceIsFinished before the blocking call. *****************************************************************************/ #define USE_IMPLICIT_IFE_RULES 1 /****************************************************************************** * INCLUDE_SAVE_TO_FILE * * Macro which should be defined as either zero (0) or one (1). * Default is 0. * * If enabled (1), the recorder will include code for saving the trace * to a local file system. ******************************************************************************/ #ifdef WIN32 #define INCLUDE_SAVE_TO_FILE 1 #else #define INCLUDE_SAVE_TO_FILE 0 #endif /****************************************************************************** * TRACE_PROGRESS_MONITOR_TASK_PRIORITY * * Macro which sets the priority of the "recorder status monitor" task. * * This task, vTraceMonitorTask in trcUser.c, periodically writes * the recorder status using the vTraceConsoleMessage macro, which is to * be mapped to your console "printf" routine. The task is named TraceMon but * is intentionally excluded from the demo trace. * * Default is tskIDLE_PRIORITY + 1 * Note that if your system constantly has a high CPU load from high-priority * tasks, this might not be get a chance to execute. * * See vTraceMonitorTask in trcUser.c *****************************************************************************/ #define TRACE_PROGRESS_MONITOR_TASK_PRIORITY (tskIDLE_PRIORITY + 1) /****************************************************************************** * TRACE_PROGRESS_MONITOR_TASK_STACKSIZE * * Macro which sets the stack size of the "recorder status monitor" task. * * This task, vTraceMonitorTask in trcUser.c, periodically writes * the recorder status using the vTraceConsoleMessage macro, which is to * be mapped to your console "printf" routine. The task is intentionally * excluded from the demo trace. * * See vTraceMonitorTask in trcUser.c *****************************************************************************/ #define TRACE_PROGRESS_MONITOR_TASK_STACKSIZE 500 /****************************************************************************** * TRACE_PROGRESS_MONITOR_TASK_PERIOD * * Macro which sets the period of the "recorder status monitor" task. * * This task, vTraceMonitorTask in trcUser.c, periodically writes * the recorder status using the vTraceConsoleMessage macro, which is to * be mapped to your console "printf" routine. The task is named TraceMon but * is intentionally excluded from the demo trace. * * Default is 1000 ticks (typically 1 second). On the Windows port, a lower * value is suggested since the Windows port runs very slowly, often 20-40 * times slower than the simulated time. * * See vTraceMonitorTask in trcUser.c *****************************************************************************/ #ifdef WIN32 #define TRACE_PROGRESS_MONITOR_TASK_PERIOD 100 #else #define TRACE_PROGRESS_MONITOR_TASK_PERIOD 1000 #endif /****************************************************************************** * TEAM_LICENSE_CODE * * Macro which defines a string - the team license code. * If no team license is available, this should be an empty string "". * This should be maximum 32 chars, including zero-termination. *****************************************************************************/ #define TEAM_LICENSE_CODE "" #endif