--- title: Xenomai categories: embedded, arm, raspberrypi ... 建立環境 ============================== * 下載 Raspbian http://www.raspberrypi.org/downloads/ * Install Cross complier .. code-block:: c cd wget https://github.com/raspberrypi/tools/archive/master.tar.gz tar xzfv master.tar.gz * Download kernel .. code-block:: c git clone -b rpi-3.8.y --depth 1 git://github.com/raspberrypi/linux.git linux-rpi-3.8.y * Download Xenomai .. code-block:: c git clone git://git.xenomai.org/xenomai-head.git xenomai-head * Download minimal config .. code-block:: c wget https://www.dropbox.com/s/dcju74md5sz45at/rpi_xenomai_config * Apply ipipe core pre-patch .. code-block:: c cd linux-rpi-3.8.y patch -Np1 < ../xenomai-head/ksrc/arch/arm/patches/raspberry/ipipe-core-3.8.13-raspberry-pre-2.patch * Apply Xenomai ipipe core patch .. code-block:: c cd ./xenomai-head/scripts/prepare-kernel.sh --arch=arm --linux=linux-rpi-3.8.y --adeos=xenomai-head/ksrc/arch/arm/patches/ipipe-core-3.8.13-arm-3.patch * Apply ipipe core post-patch .. code-block:: c cd linux-rpi-3.8.y patch -Np1 < ../xenomai-head/ksrc/arch/arm/patches/raspberry/ipipe-core-3.8.13-raspberry-post-2.patch * Create build directory .. code-block:: c mkdir linux-rpi-3.8.y/build * Configure kernel .. code-block:: c cp rpi_xenomai_config linux-rpi-3.8.y/build/.config cd linux-rpi-3.8.y make mrproper make ARCH=arm O=build oldconfig * Compile Linux Kernel .. code-block:: c make ARCH=arm O=build CROSS_COMPILE=/home/$USER/workspace/tools-master/arm-bcm2708/arm-bcm2708hardfp-linux-gnueabi/bin/arm-bcm2708hardfp-linux-gnueabi- * Install modules .. code-block:: c make ARCH=arm O=build INSTALL_MOD_PATH=dist modules_install * Install headers .. code-block:: c make ARCH=arm O=build INSTALL_HDR_PATH=dist headers_install find build/dist/include \( -name .install -o -name ..install.cmd \) -delete * 編譯好的kernelImage,移到SD卡的 ``/boot/`` 路徑下並更改名稱為kernel.img * 將``linux-rpi-3.8.y/build/dist``中的Module,移到SD卡中的``/lib/modules`` * Compile Xenomai .. code-block:: c cd xenomai-head export PATH=../tools-master/arm-bcm2708/arm-bcm2708hardfp-linux-gnueabi/bin/:$PATH ./configure --host=arm-bcm2708hardfp-linux-gnueabi cd src mkdir dist make install DESTDIR=`pwd`/dist * dist中會出現``usr/xenomai``, 將這個資料夾移到sd卡中 ``/usr/`` * 用 minicom 連進 raspberry pi 中執行以下動作 .. code-block:: c export PATH=/usr/xenomai/bin:$PATH export LD_LIBRARY_PATH=/usr/xenomai/lib sudo modprobe xeno_posix Real Time 的定義 ============================== * Hard Real Time 系統一定可以在 Response Time 內完成指定的task * Soft Real Time 在特定的機率下,系統可以在 Response Time 內完成指定的task 作業系統架構 =========== .. image:: /embedded/xenomai/xenomai_arch.jpg Xenomai是一個linux kernel的patch 藉由在底層增加一個架構 負責硬體與接收interrupt 並將interrupt 傳給上層的OS(這邊稱為domain) 這個底層的架構是Adeos 是另一個open source的project 在api呼叫上可以看到不同層級的抽象化 ipipe_XXX -> rthal_XXX -> xnXXX 負責傳送interrupt的程式稱為ipipe 示意圖 http://www.xenomai.org/documentation/xenomai-2.6/html/pictures/life-with-adeos-img4.jpg .. image:: /embedded/xenomai/adeos.jpg 可以找到ipipe_raise_irq()將interrupt推到pipeline 在ipipe上每個domain都有自己的優先度 高優先度的domain會先接收到interrupt 高優先度的domain的thread 可以preempt低優先度domain的thread iPipe ++++++++++++++ 主要負責處理irq 與 timer(HRT), ipipe的工作很簡單 就是設定timer並將interrupt往上丟 * 相關檔案︰ - gic.c : Generic Interrupt Controller, Interrupt prioritization and distribution to each CPU interface. This is known as the Distributor. Priority masking and preemption handling for each CPU. This is known as the CPU Interface. - it8152.c:IRQ相關 - timer-sp.c:dual timer module(sp804) - vic.c: The VIC provides a software interface to the interrupt system. In a system with an interrupt controller, software must determine the source that is requesting service and where its service routine is loaded. A VIC does both of these in hardware. 功能為提供一個programable的介面讓使用者設定 - ipipe-tsc.c:設定精準度(刻度) - ipipe/compat.c:interrupt - sched/clock.c:取得cpu_clock 解析度為nanosecond,開機後從0開始上數 .. image:: /embedded/xenomai/cpu_distribute.jpg GIC大約是上圖的distributor的位置 VIC則是CPU interface的位置 但raspberry pi只有一顆CPU所以不會有SMP與 CPU affinity設定的問題 HAL ++++++++++++ Hardware Abstract Layer:process 透過HAL呼叫ipipe的服務。這一層主要是包裝ipipe 與底層資訊 讓nucleus可以不用看到硬體資訊。 Nucleus ++++++++++++ Xenomai的kernel, 包含一個scheduler,優先執行real-time tasks. Scheduler ++++++++++++ 優先處理realtime task ,linux也被視為其中一個thread,本身也有scheduler,但須等到沒有real-time task時(idle state),才會執行linux thread .. image:: /embedded/xenomai/xenomai_sched.jpg Skins ++++++++++++ 呼叫xenomai的界面, 有native rtdm posix等。 問題 ++++++++++++ 與 RT-PREEMPT 途徑的差異? * RT-PREEMPT 機制 - Preemptible critical sections - Preemptible interrupt handlers - Preemptible "interrupt disable" code sequences - Priority inheritance for in-kernel spinlocks and semaphores - Deferred operations - Latency-reduction measures 原本無法preempt的地方讓他可以preemt,讓spinlock 區塊在區分成可以preempt的地方跟不能preempt的地方,將IRQ handler移到thread中執行。 Priority inheritance 是讓握有spinlock 或 semaphore的process可以暫時的提高優先權 讓他可以盡快做完critical section釋放spinlock或semaphore 高Priority的 process才有辦法繼續執行 * RT_PREEMPT 與 xenomai的差異 RT_PREEMPT是基於linux架構去改進 讓更多地方能preempt 達到real-time的能力 Xenomai則是改變整個系統架構 新增一個scheduler與IRQ管理的機制 讓處理real-time task流程簡化到只剩ipipe->scheduler 就能執行 不會因linux龐大的架構影響到real-time task的處理時間 觀察與分析 ========= .. code-block:: prettyprint pi@raspberrypi:~$ cat /proc/xenomai/stat CPU PID MSW CSW PF STAT %CPU NAME 0 0 0 206 0 00500080 100.0 ROOT 0 0 0 2688553 0 00000000 0.0 IRQ3: [timer] * CPU : 目前這個tread是使用哪個CPU在運行,而rpi是單核心CPU,故顯示皆為0 * MSW : Mode SWitches, This value should only increase over time for threads that are expected to interact with Linux services. - 當process從primary mode轉成secondary mode或是secondary mode轉成primary mode時,將會紀錄一次的轉換。 - cyclictest的RT task因為會執行到memset,所以會從xenomai schedule跳到linux schedule,MSW+1,而執行完memset後將在跳回xenomai schedule,故再+1 * CSW : Number of Context SWitches (or IRQ hits for the particular CPU) * PF : Number of Page Faults (should stop increasing as soon as mlockall is in effect) * STAT : A bitfield describing the internal state of the thread. Bit values are defined in include/nucleus/thread.h (See status and mode bits). The STAT field from /proc/xenomai/sched gives a 1-letter-per-bit symbolic translation of a the most significant subset of those bits. * %CPU : CPU share of the thread (or IRQ handler) since the last retrieval of the statistics. * NAME : Name of the thread (or IRQ number and registered driver). Can be set, e.g., with the (non portable) POSIX-API-function pthread_set_name_np. See API documentation of the RTOS skin in question. .. code-block:: prettyprint pi@raspberrypi:~$ sudo /usr/xenomai/bin/cyclictest >/dev/null 2>/dev/null & [1] 2253 .. code-block:: prettyprint pi@raspberrypi:~$ ps aux | grep -i "cy" root 2253 0.5 0.3 4580 1464 ? S 03:34 0:00 sudo /usr/xenomai/bin/cyclictest root 2254 2.7 0.4 2340 2132 ? SLl 03:34 0:00 /usr/xenomai/bin/cyclictest pi 2259 0.0 0.1 3540 820 ttyAMA0 S+ 03:34 0:00 grep --color=auto -i cy .. code-block:: prettyprint pi@raspberrypi:~$ cat /proc/xenomai/stat CPU PID MSW CSW PF STAT %CPU NAME 0 0 0 255 0 00500080 100.0 ROOT 0 2254 1 1 0 00b00380 0.0 cyclictest 0 2256 2 48 0 00300184 0.0 cyclictest 0 0 0 2913946 0 00000000 0.0 IRQ3: [timer] .. code-block:: prettyprint pi@raspberrypi:~$ watch -n 1 cat /proc/xenomai/stat Every 1.0s: cat /proc/xenomai/stat Wed Jan 8 03:38:43 2014 CPU PID MSW CSW PF STAT %CPU NAME 0 0 0 442 0 00500080 99.9 ROOT 0 2254 1 1 0 00b00380 0.0 cyclictest 0 2256 2 235 0 00300184 0.0 cyclictest 0 0 0 2953543 0 00000000 0.1 IRQ3: [timer] 在這邊可以看到cyclictest有兩個pid,因為/usr/xenomai/bin/cyclictest它會先創一個thread,並讓這個thread跑nanosleep,所以會有兩個process。接著看向CSW,pid 2254的cyclictest, 他的CSW只有1。pid 2256的卻有235,這是因為2256是一個xenomai realtime task,而 2254是一個 linux的process,所以2256會優先執行,直到realtime task都做完才會換low priority的linux domain process取得CPU,因此2254的CSW值才會是1而沒有增加。 .. code-block:: prettyprint pi@raspberrypi:~$ sudo kill 2254 pi@raspberrypi:~$ ps aux | grep -i "cy" pi 2324 0.0 0.1 3540 820 ttyAMA0 R+ 03:46 0:00 grep --color=auto -i cy [1]+ Done sudo /usr/xenomai/bin/cyclictest > /dev/null 2> /dev/null pi@raspberrypi:~$ sudo /usr/xenomai/bin/cyclictest -p FIFO >/dev/null 2>/dev/null & * 在我們了解MSW時,嘗試了在-p後面加上了文字(如:FIFO、RR……) * 發現MSV的值開始往上增加,也發現一開始對於MSW的定義理解錯誤 .. code-block:: prettyprint CPU PID MSW CSW PF STAT %CPU NAME 0 0 0 75266 0 00500080 99.9 ROOT 0 2978 1 1 0 00b00380 0.0 cyclictest 0 2980 2 26846 0 00300184 0.0 cyclictest 0 7559 1 1 0 00b00380 0.0 cyclictest 0 7561 66 130 0 00b00184 0.0 cyclictest 0 0 0 11266931 0 00000000 0.1 IRQ3: [timer] * trace後才了解,這是xenomai在-p的指令上是使用atoi,將輸入的數字轉為int,但並沒有進行偵錯,才導致segment fault,而需跳轉到linux domain進行除錯。 效能表現 ======= * Stock Linux .. code-block:: prettyprint cyclictest -p 90 - m -c 0 -i 200 -n -h 100 -q -l 1000 >log .. image:: /embedded/xenomai/001.png * PREEMPT_RT-patched Linux .. code-block:: prettyprint cyclictest -p 90 - m -c 0 -i 200 -n -h 100 -q -l 1000 >log .. image:: /embedded/xenomai/preemptRt.png * Xenomai-patched Linux .. code-block:: prettyprint /usr/xenomai/bin/cyclictest -p 90 - m -c 0 -i 200 -n -v 100 -q -l 100" >log .. image:: /embedded/xenomai/002.png Cyclictest 原理 ============== * 概念:設定一個時間間隔->取得現在時間->讓process 睡一個間隔->process醒來後再取一次時間->比對兩次取得的時間差與設定的間隔差距 * pseudocode: .. code-block:: prettyprint clock_gettime((&now)) next = now + par->interval while (!shutdown) { clock_nanosleep((&next)) clock_gettime((&now)) diff = calcdiff(now, next) # update stat-> min, max, total latency, cycles # update the histogram data next += interval } * 造成時間差的原因 - timer精準度 - IRQ latency - IRQ handler duration - scheduler latency - scheduler duration * 實作流程 1.cyclictest建立一個timerthread 這是一個realtime 的 thread 2.timerthread會重複的執行取第一次時間 nanosleep(interval) 取第二次時間 比對兩次時間差與interval的差異 3.將結果輸出在terminal - 在cylictic test 的main函式使用posix skin的api 建立timerthread .. code-block:: prettyprint pthread_create(&stat[i].thread, &thattr, timerthread, &par[i]); //pthread_create()定義在ksrc/skins/posix/thread.c .. code-block:: prettyprint int pthread_create(pthread_t *tid, const pthread_attr_t * attr, void *(*start) (void *), void *arg){ union xnsched_policy_param param; /**使用schedule的參數 可能是sched_rt_param 或 sched_idle_param(這兩個的參數都只有一個int prio)/ struct xnthread_start_attr sattr; struct xnthread_init_attr iattr; pthread_t thread, cur; /* *pthread_t = pse51thread , pse51thread由xnthread_t與其他成員組成*/ xnflags_t flags = 0; size_t stacksize; const char *name; int prio, ret; spl_t s; if (attr && attr->magic != PSE51_THREAD_ATTR_MAGIC) return EINVAL; /*下面開始分配thread空間 初始化thread */ thread = (pthread_t)xnmalloc(sizeof(*thread)); if (!thread) return EAGAIN; thread->attr = attr ? *attr : default_attr; cur = pse51_current_thread(); if (thread->attr.inheritsched == PTHREAD_INHERIT_SCHED) { /* cur may be NULL if pthread_create is not called by a pse51 thread, in which case trying to inherit scheduling parameters is treated as an error. */ /*這邊應該是說 如果不是用xnthread做出來的pse51 thread而是linux本身的posix pthread 則當作error*/ if (!cur) { xnfree(thread); return EINVAL; } pthread_getschedparam_ex(cur, &thread->attr.policy, &thread->attr.schedparam_ex); } prio = thread->attr.schedparam_ex.sched_priority; stacksize = thread->attr.stacksize; name = thread->attr.name; if (thread->attr.fp) flags |= XNFPU; if (!start) flags |= XNSHADOW; /* Note: no interrupt shield. */ iattr.tbase = pse51_tbase; iattr.name = name; iattr.flags = flags; iattr.ops = &pse51_thread_ops; iattr.stacksize = stacksize; param.rt.prio = prio; hread->arg = arg; xnsynch_init(&thread->join_synch, XNSYNCH_PRIO, NULL); thread->nrt_joiners = 0; pse51_cancel_init_thread(thread); pse51_signal_init_thread(thread, cur); pse51_tsd_init_thread(thread); pse51_timer_init_thread(thread); if (thread->attr.policy == SCHED_RR) xnpod_set_thread_tslice(&thread->threadbase, pse51_time_slice); xnlock_get_irqsave(&nklock, s); thread->container = &pse51_kqueues(0)->threadq; appendq(thread->container, &thread->link); xnlock_put_irqrestore(&nklock, s); #ifdef CONFIG_XENO_OPT_PERVASIVE thread->hkey.u_tid = 0; thread->hkey.mm = NULL; #endif /* CONFIG_XENO_OPT_PERVASIVE */ /* We need an anonymous registry entry to obtain a handle for fast mutex locking. */ ret = xnthread_register(&thread->threadbase, ""); if (ret) { thread_destroy(thread); return ret; } *tid = thread; /* Must be done before the thread is started. */ /* Do not start shadow threads (i.e. start == NULL). */ if (start) { sattr.mode = 0; sattr.imask = 0; sattr.affinity = thread->attr.affinity; sattr.entry = thread_trampoline; sattr.cookie = thread; xnpod_start_thread(&thread->threadbase, &sattr); } return 0; } - 建立一個thread叫timerthread,timerthread主要做的事情是呼叫clock_nanosleep這個function .. code-block:: prettyprint int clock_nanosleep(clockid_t clock_id, int flags, const struct timespec *rqtp, struct timespec *rmtp){ xnthread_t *cur; spl_t s; int err = 0; if (xnpod_unblockable_p()) return EPERM; if (clock_id != CLOCK_MONOTONIC && clock_id != CLOCK_REALTIME) return ENOTSUP; if ((unsigned long)rqtp->tv_nsec >= ONE_BILLION) return EINVAL; if (flags & ~TIMER_ABSTIME) return EINVAL; cur = xnpod_current_thread(); xnlock_get_irqsave(&nklock, s); thread_cancellation_point(cur); xnpod_suspend_thread(cur, XNDELAY, ts2ticks_ceil(rqtp) + 1, clock_flag(flags, clock_id), NULL); thread_cancellation_point(cur); if (xnthread_test_info(cur, XNBREAK)) { if (flags == 0 && rmtp) { xnsticks_t rem; rem = xntimer_get_timeout_stopped(&cur->rtimer); xnlock_put_irqrestore(&nklock, s); ticks2ts(rmtp, rem > 1 ? rem : 0); } else xnlock_put_irqrestore(&nklock, s); return EINTR; } xnlock_put_irqrestore(&nklock, s); return err; } clock_nanosleep主要用的api有下面幾個 - xnpod_current_thread .. code-block:: prettyprint #define xnpod_current_thread() \ (xnpod_current_sched()->curr) #define xnpod_current_sched() \ xnpod_sched_slot(xnarch_current_cpu()) #define xnpod_sched_slot(cpu) \ (&nkpod->sched[cpu]) //可以發現最後取得的東西是&nkpod->sched[current_cpu]->curr - xnarch_current_cpu .. code-block:: prettyprint static inline unsigned xnarch_current_cpu(void) { return rthal_processor_id(); //xnarch東西跟平台有關 因此會接到rthal這個abstraction layout } - rthal_processor_id() .. code-block:: prettyprint #difine rthal_processor_id() ipipe_processor_id() #define ipipe_processor_id() (0) //因為rapsberry pi只有一顆cpu 沒有SMP 所以會是使用這個macro 在這邊就能看到關於硬體的會從xnarch -> rthal -> ipipe - xnlock_get_irqsave .. code-block:: prettyprint #define xnlock_get_irqsave(lock,x) \ ((x) = __xnlock_get_irqsave(lock XNLOCK_DBG_CONTEXT)) static inline spl_t __xnlock_get_irqsave(xnlock_t *lock /*, */ XNLOCK_DBG_CONTEXT_ARGS) { unsigned long flags; rthal_local_irq_save(flags); if (__xnlock_get(lock /*, */ XNLOCK_DBG_PASS_CONTEXT)) flags |= 2; /* Recursive acquisition */ return flags; } - rthal_local_irq_save .. code-block:: prettyprint #define rthal_local_irq_save(x) ((x) = ipipe_test_and_stall_pipeline_head() & 1) static inline unsigned long ipipe_test_and_stall_pipeline_head(void) { return ipipe_test_and_stall_head(); } static inline unsigned long ipipe_test_and_stall_head(void) { hard_local_irq_disable(); return __test_and_set_bit(IPIPE_STALL_FLAG, &__ipipe_head_status); } - hard_local_irq_disable .. code-block:: prettyprint static inline void hard_local_irq_disable_notrace(void) { #if __LINUX_ARM_ARCH__ >= 6 __asm__("cpsid i @ __cli" : : : "memory", "cc"); #else /* linux arch <= 5 */ unsigned long temp; __asm__ __volatile__( "mrs %0, cpsr @ hard_local_irq_disable\n" "orr %0, %0, #128\n" "msr cpsr_c, %0" : "=r" (temp) : : "memory", "cc"); #endif /* linux arch <= 5 */ } - __xnlock_get .. code-block:: prettyprint #define xnlock_get(lock) __xnlock_get(lock XNLOCK_DBG_CONTEXT) static inline int __xnlock_get(xnlock_t *lock /*, */ XNLOCK_DBG_CONTEXT_ARGS) { unsigned long long start; int cpu = xnarch_current_cpu(); if (atomic_read(&lock->owner) == cpu) return 1; xnlock_dbg_prepare_acquire(&start); if (unlikely(atomic_cmpxchg(&lock->owner, ~0, cpu) != ~0)) __xnlock_spin(lock /*, */ XNLOCK_DBG_PASS_CONTEXT); xnlock_dbg_acquired(lock, cpu, &start /*, */ XNLOCK_DBG_PASS_CONTEXT); return 0; } - thread_cancellation_point .. code-block:: prettyprint static inline void thread_cancellation_point (xnthread_t *thread) { pthread_t cur = thread2pthread(thread); if(cur && cur->cancel_request && thread_getcancelstate(cur) == PTHREAD_CANCEL_ENABLE ) pse51_thread_abort(cur, PTHREAD_CANCELED); } void pse51_thread_abort(pthread_t thread, void *status) { thread_exit_status(thread) = status; thread_setcancelstate(thread, PTHREAD_CANCEL_DISABLE); thread_setcanceltype(thread, PTHREAD_CANCEL_DEFERRED); xnpod_delete_thread(&thread->threadbase); } - xnpod_delete_thread - xnpod_suspend_thread - xnthread_test_info - xnlock_put_irqstore .. code-block:: prettyprint static inline void xnlock_put_irqrestore (xnlock_t *lock, spl_t flags) { /* Only release the lock if we didn't take it recursively. */ if (!(flags & 2)) xnlock_put (lock); rthal_local_irq_restore (flags & 1); } static inline void xnlock_put (xnlock_t *lock) { if (xnlock_dbg_release(lock)) return; /* * Make sure all data written inside the lock is visible to * other CPUs before we release the lock. */ xnarch_memory_barrier(); atomic_set(&lock->owner, ~0); } static inline int xnlock_dbg_release(xnlock_t *lock) { extern xnlockinfo_t xnlock_stats[]; unsigned long long lock_time = rthal_rdtsc() - lock->lock_date; int cpu = xnarch_current_cpu(); xnlockinfo_t *stats = &xnlock_stats[cpu]; if (unlikely(atomic_read(&lock->owner) != cpu)) { rthal_emergency_console(); printk(KERN_ERR "Xenomai: unlocking unlocked nucleus lock %p" " on CPU #%d\n" " owner = %s:%u (%s(), CPU #%d)\n", lock, cpu, lock->file, lock->line, lock->function, lock->cpu); show_stack(NULL,NULL); return 1; } lock->cpu = -lock->cpu; /* File that we released it. */ if (lock_time > stats->lock_time) { stats->lock_time = lock_time; stats->spin_time = lock->spin_time; stats->file = lock->file; stats->function = lock->function; stats->line = lock->line; } return 0; } #define xnarch_memory_barrier() __sync_synchronize() #define rthal_local_irq_restore(x) ipipe_restore_pipeline_head(x) static inline xnticks_t xntimer_get_timeout_stopped (xntimer_t *timer) { return timer->base->ops->get_timer_timeout (timer); } * `Cyclictest`_ * Test case: POSIX interval timer, Interval 500 micro seconds,. 100000 loops, 100% load. - Commandline: cyclictest -t1 -p 80 -i 500 -l 100000 * 使用 PREEMPT LINUX .. code-block:: prettyprint root@raspberrypi:/home/pi# sudo ./cyclictest -t1 -p 80 -i 500 -l 100000 # /dev/cpu_dma_latency set to 0us policy: fifo: loadavg: 0.00 0.01 0.05 1/61 2064 T: 0 ( 2063) P:80 I:500 C: 100000 Min: 27 Act: 49 Avg: 42 Max: 1060 * 使用 RT-PREEMPT .. code-block:: prettyprint Linux raspberrypi 3.6.11+ #474 PREEMPT Thu Jun 13 17:14:42 BST 2013 armv6l GNU/Linux Min: 22 Act: 31 Avg: 32 Max: 169 * 使用 Xenomai .. code-block:: prettyprint Linux raspberrypi 3.8.13-core+ #1 Thu Feb 27 03:02:16 CST 2014 armv6l GNU/Linux Min: 1 Act: 5 Avg: 6 Max: 41 .. code-block:: prettyprint root@raspberrypi:/home/pi# /usr/xenomai/bin/cyclictest -t1 -p 80 -i 500 -l 10000 0.08 0.06 0.05 1/61 2060 T: 0 ( 2060) P:80 I: 500 C: 100000 Min: -4 Act: -2 Avg: 0 Max: 30 T:thread P:priority I:interval C:執行cycle數 Min:最小延遲 Act:此次延遲時間 Avg:平均延遲 Max:最大延遲 最重要的是Max值 為了確保realtime 要能知道worst case 讓開發者可以評估最差的情況可以在多少時間內可以做出回應 Hackpad ======= * 討論&紀錄 https://embedded2014.hackpad.com/Xenomai-raspberry-note-XwJtuQn9nkD * 整理 https://embedded2014.hackpad.com/Xenomai-z2CJPjPLTer 組員 ==== * 向澐 * 林家宏 * 呂科進 * 趙愷文 * 阮志偉 * 陳建霖 參考資料 ======= * https://code.google.com/p/picnc/wiki/RPiXenomaiKernel * https://code.google.com/p/picnc/wiki/CreateRaspbianLinuxCNC * http://www.camelsoftware.com/firetail/blog/raspberry-pi/real-time-operating-systems/ * `Quadruped Linux robot feels its way over obstacles`_ * ` Choosing between Xenomai and Linux for real-time applications`_ * `Real Time Systems`_ * http://www.cs.ru.nl/lab/xenomai/exercises/ * `背景知識 `_ * `應用案例 `_ * `real-time Linux 介紹 `_ * `Xenomai 專案維護人的介紹 `_ * `RTOS 定義 `_