/**************************************************************************** * drivers/note/note_driver.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "sched/sched.h" #if defined(CONFIG_DRIVERS_NOTERAM) + defined(CONFIG_DRIVERS_NOTELOG) + \ defined(CONFIG_DRIVERS_NOTESNAP) + defined(CONFIG_DRIVERS_NOTERTT) + \ defined(CONFIG_SEGGER_SYSVIEW) > CONFIG_DRIVERS_NOTE_MAX # error "Maximum channel number exceeds. " #endif #define note_add(drv, note, notelen) \ ((drv)->ops->add(drv, note, notelen)) #define note_start(drv, tcb) \ ((drv)->ops->start && ((drv)->ops->start(drv, tcb), true)) #define note_stop(drv, tcb) \ ((drv)->ops->stop && ((drv)->ops->stop(drv, tcb), true)) #define note_suspend(drv, tcb) \ ((drv)->ops->suspend && ((drv)->ops->suspend(drv, tcb), true)) #define note_resume(drv, tcb) \ ((drv)->ops->resume && ((drv)->ops->resume(drv, tcb), true)) #define note_cpu_start(drv, tcb, cpu) \ ((drv)->ops->cpu_start && ((drv)->ops->cpu_start(drv, tcb, cpu), true)) #define note_cpu_started(drv, tcb) \ ((drv)->ops->cpu_started && ((drv)->ops->cpu_started(drv, tcb), true)) #define note_cpu_pause(drv, tcb, cpu) \ ((drv)->ops->cpu_pause && ((drv)->ops->cpu_pause(drv, tcb, cpu), true)) #define note_cpu_paused(drv, tcb) \ ((drv)->ops->cpu_paused && ((drv)->ops->cpu_paused(drv, tcb), true)) #define note_cpu_resume(drv, tcb, cpu) \ ((drv)->ops->cpu_resume && ((drv)->ops->cpu_resume(drv, tcb, cpu), true)) #define note_cpu_resumed(drv, tcb) \ ((drv)->ops->cpu_resumed && ((drv)->ops->cpu_resumed(drv, tcb), true)) #define note_premption(drv, tcb, locked) \ ((drv)->ops->premption && ((drv)->ops->premption(drv, tcb, locked), true)) #define note_csection(drv, tcb, enter) \ ((drv)->ops->csection && ((drv)->ops->csection(drv, tcb, enter), true)) #define note_spinlock(drv, tcb, spinlock, type) \ ((drv)->ops->spinlock && \ ((drv)->ops->spinlock(drv, tcb, spinlock, type), true)) #define note_syscall_enter(drv, nr, argc, ap) \ ((drv)->ops->syscall_enter && \ ((drv)->ops->syscall_enter(drv, nr, argc, ap), true)) #define note_syscall_leave(drv, nr, result) \ ((drv)->ops->syscall_leave && \ ((drv)->ops->syscall_leave(drv, nr, result), true)) #define note_irqhandler(drv, irq, handler, enter) \ ((drv)->ops->irqhandler && \ ((drv)->ops->irqhandler(drv, irq, handler, enter), true)) #define note_string(drv, ip, buf) \ ((drv)->ops->string && ((drv)->ops->string(drv, ip, buf), true)) #define note_dump(drv, ip, buf, len) \ ((drv)->ops->dump && ((drv)->ops->dump(drv, ip, event, buf, len), true)) #define note_vprintf(drv, ip, fmt, va) \ ((drv)->ops->vprintf && ((drv)->ops->vprintf(drv, ip, fmt, va), true)) #define note_vbprintf(drv, ip, event, fmt, va) \ ((drv)->ops->vbprintf && \ ((drv)->ops->vbprintf(drv, ip, event, fmt, va), true)) /**************************************************************************** * Private Types ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER struct note_filter_s { struct note_filter_mode_s mode; # ifdef CONFIG_SCHED_INSTRUMENTATION_DUMP struct note_filter_tag_s tag_mask; # endif # ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER struct note_filter_irq_s irq_mask; # endif # ifdef CONFIG_SCHED_INSTRUMENTATION_SYSCALL struct note_filter_syscall_s syscall_mask; # endif }; #endif struct note_startalloc_s { struct note_common_s nsa_cmn; /* Common note parameters */ #if CONFIG_TASK_NAME_SIZE > 0 char nsa_name[CONFIG_TASK_NAME_SIZE + 1]; #endif }; #if CONFIG_TASK_NAME_SIZE > 0 # define SIZEOF_NOTE_START(n) (sizeof(struct note_start_s) + (n) - 1) #else # define SIZEOF_NOTE_START(n) (sizeof(struct note_start_s)) #endif #if CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE > 0 struct note_taskname_info_s { uint8_t size; uint8_t pid[2]; char name[1]; }; struct note_taskname_s { size_t head; size_t tail; char buffer[CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE]; }; #endif /**************************************************************************** * Private Data ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER static struct note_filter_s g_note_filter = { { CONFIG_SCHED_INSTRUMENTATION_FILTER_DEFAULT_MODE #ifdef CONFIG_SMP , (cpu_set_t)CONFIG_SCHED_INSTRUMENTATION_CPUSET #endif } }; #ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER static unsigned int g_note_disabled_irq_nest[CONFIG_SMP_NCPUS]; #endif #endif FAR static struct note_driver_s * g_note_drivers[CONFIG_DRIVERS_NOTE_MAX + 1] = { #ifdef CONFIG_DRIVERS_NOTERAM (FAR struct note_driver_s *)&g_noteram_driver, #endif #ifdef CONFIG_DRIVERS_NOTELOG &g_notelog_driver, #endif NULL }; #if CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE > 0 static struct note_taskname_s g_note_taskname; #endif #if defined(CONFIG_SCHED_INSTRUMENTATION_FILTER) static spinlock_t g_note_lock; #endif /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: sched_note_flatten * * Description: * Copy the data in the little endian layout * ****************************************************************************/ static inline void sched_note_flatten(FAR uint8_t *dst, FAR void *src, size_t len) { #ifdef CONFIG_ENDIAN_BIG FAR uint8_t *end = (FAR uint8_t *)src + len - 1; while (len-- > 0) { *dst++ = *end--; } #else memcpy(dst, src, len); #endif } /**************************************************************************** * Name: note_common * * Description: * Fill in some of the common fields in the note structure. * * Input Parameters: * tcb - The TCB containing the information * note - The common note structure to use * length - The total lengthof the note structure * type - The type of the note * * Returned Value: * None * ****************************************************************************/ static void note_common(FAR struct tcb_s *tcb, FAR struct note_common_s *note, uint8_t length, uint8_t type) { #ifdef CONFIG_SCHED_INSTRUMENTATION_PERFCOUNT struct timespec perftime; #endif struct timespec ts; clock_systime_timespec(&ts); #ifdef CONFIG_SCHED_INSTRUMENTATION_PERFCOUNT up_perf_convert(up_perf_gettime(), &perftime); ts.tv_nsec = perftime.tv_nsec; #endif /* Save all of the common fields */ note->nc_length = length; note->nc_type = type; if (tcb == NULL) { note->nc_priority = CONFIG_INIT_PRIORITY; #ifdef CONFIG_SMP note->nc_cpu = 0; #endif memset(note->nc_pid, 0, sizeof(tcb->pid)); } else { note->nc_priority = tcb->sched_priority; #ifdef CONFIG_SMP note->nc_cpu = tcb->cpu; #endif sched_note_flatten(note->nc_pid, &tcb->pid, sizeof(tcb->pid)); } sched_note_flatten(note->nc_systime_nsec, &ts.tv_nsec, sizeof(ts.tv_nsec)); sched_note_flatten(note->nc_systime_sec, &ts.tv_sec, sizeof(ts.tv_sec)); } /**************************************************************************** * Name: note_isenabled * * Description: * Check whether the instrumentation is enabled. * * Input Parameters: * None * * Returned Value: * True is returned if the instrumentation is enabled. * ****************************************************************************/ static inline int note_isenabled(void) { #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!(g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_ENABLE)) { return false; } #ifdef CONFIG_SMP /* Ignore notes that are not in the set of monitored CPUs */ if (CPU_ISSET(this_cpu(), &g_note_filter.mode.cpuset) == 0) { /* Not in the set of monitored CPUs. Do not log the note. */ return false; } #endif #endif return true; } /**************************************************************************** * Name: note_isenabled_switch * * Description: * Check whether the switch instrumentation is enabled. * * Input Parameters: * None * * Returned Value: * True is returned if the instrumentation is enabled. * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_SWITCH static inline int note_isenabled_switch(void) { #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!note_isenabled()) { return false; } /* If the switch trace is disabled, do nothing. */ if ((g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_SWITCH) == 0) { return false; } #endif return true; } #endif /**************************************************************************** * Name: note_isenabled_syscall * * Description: * Check whether the syscall instrumentation is enabled. * * Input Parameters: * nr - syscall number * * Returned Value: * True is returned if the instrumentation is enabled. * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_SYSCALL static inline int note_isenabled_syscall(int nr) { #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!note_isenabled()) { return false; } /* Exclude the case of syscall called by the interrupt handler which is * not traced. */ if (up_interrupt_context()) { #ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER int cpu = this_cpu(); if (g_note_disabled_irq_nest[cpu] > 0) { return false; } #else return false; #endif } /* If the syscall trace is disabled or the syscall number is masked, * do nothing. */ if (!(g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_SYSCALL) || NOTE_FILTER_SYSCALLMASK_ISSET(nr - CONFIG_SYS_RESERVED, &g_note_filter.syscall_mask)) { return false; } #endif return true; } #endif /**************************************************************************** * Name: note_isenabled_irqhandler * * Description: * Check whether the interrupt handler instrumentation is enabled. * * Input Parameters: * irq - IRQ number * enter - interrupt enter/leave flag * * Returned Value: * True is returned if the instrumentation is enabled. * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER static inline int note_isenabled_irq(int irq, bool enter) { #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!note_isenabled()) { return false; } /* If the IRQ trace is disabled or the IRQ number is masked, disable * subsequent syscall traces until leaving the interrupt handler */ if (!(g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_IRQ) || NOTE_FILTER_IRQMASK_ISSET(irq, &g_note_filter.irq_mask)) { int cpu = this_cpu(); if (enter) { g_note_disabled_irq_nest[cpu]++; } else { g_note_disabled_irq_nest[cpu]--; } return false; } #endif return true; } #endif /**************************************************************************** * Name: note_isenabled_dump * * Description: * Check whether the dump instrumentation is enabled. * * Input Parameters: * tag: The dump instrumentation tag * * Returned Value: * True is returned if the instrumentation is enabled. * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_DUMP static inline int note_isenabled_dump(uint32_t tag) { # ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!note_isenabled()) { return false; } /* If the dump trace is disabled, do nothing. */ if (!(g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_DUMP) || NOTE_FILTER_TAGMASK_ISSET(tag, &g_note_filter.tag_mask)) { return false; } # endif return true; } #endif #if CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE > 0 /**************************************************************************** * Name: note_find_taskname * * Description: * Find task name info corresponding to the specified PID * * Input Parameters: * PID - Task ID * * Returned Value: * Pointer to the task name info * If the corresponding info doesn't exist in the buffer, NULL is returned. * ****************************************************************************/ static FAR struct note_taskname_info_s *note_find_taskname(pid_t pid) { FAR struct note_taskname_info_s *ti; int n = g_note_taskname.tail; while (n != g_note_taskname.head) { ti = (FAR struct note_taskname_info_s *) &g_note_taskname.buffer[n]; if (ti->pid[0] + (ti->pid[1] << 8) == pid) { return ti; } n += ti->size; if (n >= CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE) { n -= CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE; } } return NULL; } /**************************************************************************** * Name: note_record_taskname * * Description: * Record the task name info of the specified task * * Input Parameters: * PID - Task ID * name - task name * * Returned Value: * None * ****************************************************************************/ static void note_record_taskname(pid_t pid, FAR const char *name) { FAR struct note_taskname_info_s *ti; size_t tilen; size_t namelen; size_t skiplen; size_t remain; namelen = strlen(name); DEBUGASSERT(namelen <= CONFIG_TASK_NAME_SIZE); tilen = sizeof(struct note_taskname_info_s) + namelen; DEBUGASSERT(tilen <= UCHAR_MAX); skiplen = CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE - g_note_taskname.head; if (skiplen >= tilen + sizeof(struct note_taskname_info_s)) { skiplen = 0; /* Have enough space at the tail - needn't skip */ } if (g_note_taskname.head >= g_note_taskname.tail) { remain = CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE - (g_note_taskname.head - g_note_taskname.tail); } else { remain = g_note_taskname.tail - g_note_taskname.head; } while (skiplen + tilen >= remain) { /* No enough space, drop the old info */ ti = (FAR struct note_taskname_info_s *) &g_note_taskname.buffer[g_note_taskname.tail]; g_note_taskname.tail = (g_note_taskname.tail + ti->size) % CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE; remain += ti->size; } if (skiplen) { /* Fill the skipped region with an invalid info */ ti = (FAR struct note_taskname_info_s *) &g_note_taskname.buffer[g_note_taskname.head]; ti->size = skiplen; ti->pid[0] = 0xff; ti->pid[1] = 0xff; ti->name[0] = '\0'; /* Move to the begin of circle buffer */ g_note_taskname.head = 0; } ti = (FAR struct note_taskname_info_s *) &g_note_taskname.buffer[g_note_taskname.head]; ti->size = tilen; ti->pid[0] = pid & 0xff; ti->pid[1] = (pid >> 8) & 0xff; strlcpy(ti->name, name, namelen + 1); g_note_taskname.head += tilen; } #endif /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: sched_note_* * * Description: * These are the hooks into the scheduling instrumentation logic. Each * simply formats the note associated with the schedule event and adds * that note to the circular buffer. * * Input Parameters: * tcb - The TCB of the thread. * * Returned Value: * None * * Assumptions: * We are within a critical section. * ****************************************************************************/ void sched_note_start(FAR struct tcb_s *tcb) { struct note_startalloc_s note; unsigned int length; FAR struct note_driver_s **driver; bool formatted = false; #if CONFIG_TASK_NAME_SIZE > 0 int namelen; #endif if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_start(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } if (!formatted) { formatted = true; /* Copy the task name (if possible) and * get the length of the note */ #if CONFIG_TASK_NAME_SIZE > 0 namelen = strlen(tcb->name); DEBUGASSERT(namelen <= CONFIG_TASK_NAME_SIZE); strlcpy(note.nsa_name, tcb->name, sizeof(note.nsa_name)); length = SIZEOF_NOTE_START(namelen + 1); #else length = SIZEOF_NOTE_START(0); #endif /* Finish formatting the note */ note_common(tcb, ¬e.nsa_cmn, length, NOTE_START); } /* Add the note to circular buffer */ note_add(*driver, ¬e, length); } } void sched_note_stop(FAR struct tcb_s *tcb) { struct note_stop_s note; FAR struct note_driver_s **driver; bool formatted = false; #if CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE > 0 note_record_taskname(tcb->pid, tcb->name); #endif if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_stop(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.nsp_cmn, sizeof(struct note_stop_s), NOTE_STOP); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_stop_s)); } } #ifdef CONFIG_SCHED_INSTRUMENTATION_SWITCH void sched_note_suspend(FAR struct tcb_s *tcb) { struct note_suspend_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_suspend(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.nsu_cmn, sizeof(struct note_suspend_s), NOTE_SUSPEND); note.nsu_state = tcb->task_state; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_suspend_s)); } } void sched_note_resume(FAR struct tcb_s *tcb) { struct note_resume_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_resume(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.nre_cmn, sizeof(struct note_resume_s), NOTE_RESUME); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_resume_s)); } } #endif #ifdef CONFIG_SMP void sched_note_cpu_start(FAR struct tcb_s *tcb, int cpu) { struct note_cpu_start_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_start(*driver, tcb, cpu)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncs_cmn, sizeof(struct note_cpu_start_s), NOTE_CPU_START); note.ncs_target = (uint8_t)cpu; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_start_s)); } } void sched_note_cpu_started(FAR struct tcb_s *tcb) { struct note_cpu_started_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_started(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncs_cmn, sizeof(struct note_cpu_started_s), NOTE_CPU_STARTED); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_started_s)); } } #ifdef CONFIG_SCHED_INSTRUMENTATION_SWITCH void sched_note_cpu_pause(FAR struct tcb_s *tcb, int cpu) { struct note_cpu_pause_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_pause(*driver, tcb, cpu)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncp_cmn, sizeof(struct note_cpu_pause_s), NOTE_CPU_PAUSE); note.ncp_target = (uint8_t)cpu; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_pause_s)); } } void sched_note_cpu_paused(FAR struct tcb_s *tcb) { struct note_cpu_paused_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_paused(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncp_cmn, sizeof(struct note_cpu_paused_s), NOTE_CPU_PAUSED); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_paused_s)); } } void sched_note_cpu_resume(FAR struct tcb_s *tcb, int cpu) { struct note_cpu_resume_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_resume(*driver, tcb, cpu)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncr_cmn, sizeof(struct note_cpu_resume_s), NOTE_CPU_RESUME); note.ncr_target = (uint8_t)cpu; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_resume_s)); } } void sched_note_cpu_resumed(FAR struct tcb_s *tcb) { struct note_cpu_resumed_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled_switch()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_cpu_resumed(*driver, tcb)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncr_cmn, sizeof(struct note_cpu_resumed_s), NOTE_CPU_RESUMED); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_cpu_resumed_s)); } } #endif #endif #ifdef CONFIG_SCHED_INSTRUMENTATION_PREEMPTION void sched_note_premption(FAR struct tcb_s *tcb, bool locked) { struct note_preempt_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_premption(*driver, tcb, locked)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.npr_cmn, sizeof(struct note_preempt_s), locked ? NOTE_PREEMPT_LOCK : NOTE_PREEMPT_UNLOCK); sched_note_flatten(note.npr_count, &tcb->lockcount, sizeof(tcb->lockcount)); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_preempt_s)); } } #endif #ifdef CONFIG_SCHED_INSTRUMENTATION_CSECTION void sched_note_csection(FAR struct tcb_s *tcb, bool enter) { struct note_csection_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_csection(*driver, tcb, enter)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.ncs_cmn, sizeof(struct note_csection_s), enter ? NOTE_CSECTION_ENTER : NOTE_CSECTION_LEAVE); #ifdef CONFIG_SMP sched_note_flatten(note.ncs_count, &tcb->irqcount, sizeof(tcb->irqcount)); #endif } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_csection_s)); } } #endif /**************************************************************************** * Name: sched_note_spinlock * * Description: * Common logic for NOTE_SPINLOCK, NOTE_SPINLOCKED, and NOTE_SPINUNLOCK * * Input Parameters: * tcb - The TCB containing the information * note - The common note structure to use * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_SPINLOCKS void sched_note_spinlock(FAR struct tcb_s *tcb, FAR volatile spinlock_t *spinlock, int type) { struct note_spinlock_s note; FAR struct note_driver_s **driver; bool formatted = false; if (!note_isenabled()) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_spinlock(*driver, tcb, spinlock, type)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.nsp_cmn, sizeof(struct note_spinlock_s), type); sched_note_flatten(note.nsp_spinlock, &spinlock, sizeof(spinlock)); note.nsp_value = *(FAR uint8_t *)spinlock; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_spinlock_s)); } } #endif #ifdef CONFIG_SCHED_INSTRUMENTATION_SYSCALL void sched_note_syscall_enter(int nr, int argc, ...) { struct note_syscall_enter_s note; FAR struct note_driver_s **driver; bool formatted = false; FAR struct tcb_s *tcb = this_task(); unsigned int length; FAR uint8_t *args; uintptr_t arg; va_list ap; int i; if (!note_isenabled_syscall(nr)) { return; } #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER if (!(g_note_filter.mode.flag & NOTE_FILTER_MODE_FLAG_SYSCALL_ARGS)) { argc = 0; } #endif va_start(ap, argc); for (driver = g_note_drivers; *driver; driver++) { va_list copy; va_copy(copy, ap); if (note_syscall_enter(*driver, nr, argc, ©)) { va_end(copy); continue; } if ((*driver)->ops->add == NULL) { va_end(copy); continue; } /* Format the note */ if (!formatted) { formatted = true; length = SIZEOF_NOTE_SYSCALL_ENTER(argc); note_common(tcb, ¬e.nsc_cmn, length, NOTE_SYSCALL_ENTER); DEBUGASSERT(nr <= UCHAR_MAX); note.nsc_nr = nr; DEBUGASSERT(argc <= MAX_SYSCALL_ARGS); note.nsc_argc = argc; /* If needed, retrieve the given syscall arguments */ args = note.nsc_args; for (i = 0; i < argc; i++) { arg = (uintptr_t)va_arg(copy, uintptr_t); sched_note_flatten(args, &arg, sizeof(arg)); args += sizeof(uintptr_t); } } va_end(copy); /* Add the note to circular buffer */ note_add(*driver, ¬e, length); } va_end(ap); } void sched_note_syscall_leave(int nr, uintptr_t result) { struct note_syscall_leave_s note; FAR struct note_driver_s **driver; bool formatted = false; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_syscall(nr)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_syscall_leave(*driver, nr, result)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note_common(tcb, ¬e.nsc_cmn, sizeof(struct note_syscall_leave_s), NOTE_SYSCALL_LEAVE); DEBUGASSERT(nr <= UCHAR_MAX); note.nsc_nr = nr; sched_note_flatten(note.nsc_result, &result, sizeof(result)); } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_syscall_leave_s)); } } #endif #ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER void sched_note_irqhandler(int irq, FAR void *handler, bool enter) { struct note_irqhandler_s note; FAR struct note_driver_s **driver; bool formatted = false; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_irq(irq, enter)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_irqhandler(*driver, irq, handler, enter)) { continue; } if ((*driver)->ops->add == NULL) { continue; } if (!formatted) { formatted = true; note_common(tcb, ¬e.nih_cmn, sizeof(struct note_irqhandler_s), enter ? NOTE_IRQ_ENTER : NOTE_IRQ_LEAVE); DEBUGASSERT(irq <= UCHAR_MAX); note.nih_irq = irq; note.nih_handler = (uintptr_t)handler; } /* Add the note to circular buffer */ note_add(*driver, ¬e, sizeof(struct note_irqhandler_s)); } } #endif #ifdef CONFIG_SCHED_INSTRUMENTATION_DUMP void sched_note_string_ip(uint32_t tag, uintptr_t ip, FAR const char *buf) { FAR struct note_string_s *note; uint8_t data[255]; unsigned int length; FAR struct note_driver_s **driver; bool formatted = false; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_dump(tag)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_string(*driver, ip, buf)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note = (FAR struct note_string_s *)data; length = SIZEOF_NOTE_STRING(strlen(buf)); if (length > sizeof(data)) { length = sizeof(data); } note_common(tcb, ¬e->nst_cmn, length, NOTE_DUMP_STRING); sched_note_flatten(note->nst_ip, &ip, sizeof(uintptr_t)); memcpy(note->nst_data, buf, length - sizeof(struct note_string_s)); data[length - 1] = '\0'; } /* Add the note to circular buffer */ note_add(*driver, note, length); } } void sched_note_dump_ip(uint32_t tag, uintptr_t ip, uint8_t event, FAR const void *buf, size_t len) { FAR struct note_binary_s *note; FAR struct note_driver_s **driver; bool formatted = false; char data[255]; unsigned int length; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_dump(tag)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_dump(*driver, ip, buf, len)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note = (FAR struct note_binary_s *)data; length = SIZEOF_NOTE_BINARY(len); if (length > sizeof(data)) { length = sizeof(data); } note_common(tcb, ¬e->nbi_cmn, length, NOTE_DUMP_BINARY); sched_note_flatten(note->nbi_ip, &ip, sizeof(uintptr_t)); note->nbi_event = event; memcpy(note->nbi_data, buf, length - sizeof(struct note_binary_s) + 1); } /* Add the note to circular buffer */ note_add(*driver, note, length); } } void sched_note_vprintf_ip(uint32_t tag, uintptr_t ip, FAR const char *fmt, va_list va) { FAR struct note_string_s *note; uint8_t data[255]; unsigned int length; FAR struct note_driver_s **driver; bool formatted = false; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_dump(tag)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_vprintf(*driver, ip, fmt, va)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note = (FAR struct note_string_s *)data; length = vsnprintf(note->nst_data, sizeof(data) - sizeof(struct note_string_s), fmt, va); length = SIZEOF_NOTE_STRING(length); if (length > sizeof(data)) { length = sizeof(data); } note_common(tcb, ¬e->nst_cmn, length, NOTE_DUMP_STRING); sched_note_flatten(note->nst_ip, &ip, sizeof(uintptr_t)); } /* Add the note to circular buffer */ note_add(*driver, note, length); } } void sched_note_vbprintf_ip(uint32_t tag, uintptr_t ip, uint8_t event, FAR const char *fmt, va_list va) { FAR struct note_binary_s *note; FAR struct note_driver_s **driver; bool formatted = false; uint8_t data[255]; begin_packed_struct union { char c; short s; int i; long l; #ifdef CONFIG_HAVE_LONG_LONG long long ll; #endif intmax_t im; size_t sz; ptrdiff_t ptr; #ifdef CONFIG_HAVE_FLOAT float f; #endif #ifdef CONFIG_HAVE_DOUBLE double d; #endif #ifdef CONFIG_HAVE_LONG_DOUBLE long double ld; #endif } end_packed_struct *var; char c; int length; bool search_fmt = 0; int next = 0; FAR struct tcb_s *tcb = this_task(); if (!note_isenabled_dump(tag)) { return; } for (driver = g_note_drivers; *driver; driver++) { if (note_vbprintf(*driver, ip, event, fmt, va)) { continue; } if ((*driver)->ops->add == NULL) { continue; } /* Format the note */ if (!formatted) { formatted = true; note = (FAR struct note_binary_s *)data; length = sizeof(data) - sizeof(struct note_binary_s) + 1; while ((c = *fmt++) != '\0') { if (c != '%' && search_fmt == 0) { continue; } search_fmt = 1; var = (FAR void *)¬e->nbi_data[next]; if (c == 'd' || c == 'i' || c == 'u' || c == 'o' || c == 'x' || c == 'X') { if (*(fmt - 2) == 'h' && *(fmt - 3) == 'h') { if (next + sizeof(var->c) > length) { break; } var->c = va_arg(va, int); next += sizeof(var->c); } else if (*(fmt - 2) == 'h') { if (next + sizeof(var->s) > length) { break; } var->s = va_arg(va, int); next += sizeof(var->s); } else if (*(fmt - 2) == 'j') { if (next + sizeof(var->im) > length) { break; } var->im = va_arg(va, intmax_t); next += sizeof(var->im); } #ifdef CONFIG_HAVE_LONG_LONG else if (*(fmt - 2) == 'l' && *(fmt - 3) == 'l') { if (next + sizeof(var->ll) > length) { break; } var->ll = va_arg(va, long long); next += sizeof(var->ll); } #endif else if (*(fmt - 2) == 'l') { if (next + sizeof(var->l) > length) { break; } var->l = va_arg(va, long); next += sizeof(var->l); } else if (*(fmt - 2) == 'z') { if (next + sizeof(var->sz) > length) { break; } var->sz = va_arg(va, size_t); next += sizeof(var->sz); } else if (*(fmt - 2) == 't') { if (next + sizeof(var->ptr) > length) { break; } var->ptr = va_arg(va, ptrdiff_t); next += sizeof(var->ptr); } else { if (next + sizeof(var->i) > length) { break; } var->i = va_arg(va, int); next += sizeof(var->i); } search_fmt = 0; } if (c == 'e' || c == 'f' || c == 'g' || c == 'E' || c == 'F' || c == 'G') { if (*(fmt - 2) == 'L') { #ifdef CONFIG_HAVE_LONG_DOUBLE if (next + sizeof(var->ld) > length) { break; } var->ld = va_arg(va, long double); next += sizeof(var->ld); #endif } else if (*(fmt - 2) == 'l') { #ifdef CONFIG_HAVE_DOUBLE if (next + sizeof(var->d) > length) { break; } var->d = va_arg(va, double); next += sizeof(var->d); #endif } else #ifdef CONFIG_HAVE_FLOAT { if (next + sizeof(var->l) > length) { break; } var->l = va_arg(va, double); next += sizeof(var->l); #endif } search_fmt = 0; } } length = SIZEOF_NOTE_BINARY(next); note_common(tcb, ¬e->nbi_cmn, length, NOTE_DUMP_BINARY); sched_note_flatten(note->nbi_ip, &ip, sizeof(uintptr_t)); note->nbi_event = event; } /* Add the note to circular buffer */ note_add(*driver, note, length); } } void sched_note_printf_ip(uint32_t tag, uintptr_t ip, FAR const char *fmt, ...) { va_list va; va_start(va, fmt); sched_note_vprintf_ip(tag, ip, fmt, va); va_end(va); } void sched_note_bprintf_ip(uint32_t tag, uintptr_t ip, uint8_t event, FAR const char *fmt, ...) { va_list va; va_start(va, fmt); sched_note_vbprintf_ip(tag, ip, event, fmt, va); va_end(va); } #endif /* CONFIG_SCHED_INSTRUMENTATION_DUMP */ #ifdef CONFIG_SCHED_INSTRUMENTATION_FILTER /**************************************************************************** * Name: sched_note_filter_mode * * Description: * Set and get note filter mode. * (Same as NOTECTL_GETMODE / NOTECTL_SETMODE ioctls) * * Input Parameters: * oldm - A writable pointer to struct note_filter_mode_s to get current * filter mode * If 0, no data is written. * newm - A read-only pointer to struct note_filter_mode_s which holds the * new filter mode * If 0, the filter mode is not updated. * * Returned Value: * None * ****************************************************************************/ void sched_note_filter_mode(FAR struct note_filter_mode_s *oldm, FAR struct note_filter_mode_s *newm) { irqstate_t irq_mask; irq_mask = spin_lock_irqsave_wo_note(&g_note_lock); if (oldm != NULL) { *oldm = g_note_filter.mode; } if (newm != NULL) { g_note_filter.mode = *newm; } spin_unlock_irqrestore_wo_note(&g_note_lock, irq_mask); } /**************************************************************************** * Name: sched_note_filter_syscall * * Description: * Set and get syscall filter setting * (Same as NOTECTL_GETSYSCALLFILTER / NOTECTL_SETSYSCALLFILTER ioctls) * * Input Parameters: * oldf - A writable pointer to struct note_filter_syscall_s to get * current syscall filter setting * If 0, no data is written. * newf - A read-only pointer to struct note_filter_syscall_s of the * new syscall filter setting * If 0, the setting is not updated. * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_SYSCALL void sched_note_filter_syscall(FAR struct note_filter_syscall_s *oldf, FAR struct note_filter_syscall_s *newf) { irqstate_t irq_mask; irq_mask = spin_lock_irqsave_wo_note(&g_note_lock); if (oldf != NULL) { /* Return the current filter setting */ *oldf = g_note_filter.syscall_mask; } if (newf != NULL) { /* Replace the syscall filter mask by the provided setting */ g_note_filter.syscall_mask = *newf; } spin_unlock_irqrestore_wo_note(&g_note_lock, irq_mask); } #endif /**************************************************************************** * Name: sched_note_filter_irq * * Description: * Set and get IRQ filter setting * (Same as NOTECTL_GETIRQFILTER / NOTECTL_SETIRQFILTER ioctls) * * Input Parameters: * oldf - A writable pointer to struct note_filter_irq_s to get * current IRQ filter setting * If 0, no data is written. * newf - A read-only pointer to struct note_filter_irq_s of the new * IRQ filter setting * If 0, the setting is not updated. * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_IRQHANDLER void sched_note_filter_irq(FAR struct note_filter_irq_s *oldf, FAR struct note_filter_irq_s *newf) { irqstate_t irq_mask; irq_mask = spin_lock_irqsave_wo_note(&g_note_lock); if (oldf != NULL) { /* Return the current filter setting */ *oldf = g_note_filter.irq_mask; } if (newf != NULL) { /* Replace the syscall filter mask by the provided setting */ g_note_filter.irq_mask = *newf; } spin_unlock_irqrestore_wo_note(&g_note_lock, irq_mask); } #endif /**************************************************************************** * Name: sched_note_filter_tag * * Description: * Set and get tag filter setting * (Same as NOTECTL_GETDUMPFILTER / NOTECTL_SETDUMPFILTER ioctls) * * Input Parameters: * oldf - A writable pointer to struct note_filter_tag_s to get * current dump filter setting * If 0, no data is written. * newf - A read-only pointer to struct note_filter_tag_s of the * new dump filter setting * If 0, the setting is not updated. * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_SCHED_INSTRUMENTATION_DUMP void sched_note_filter_tag(FAR struct note_filter_tag_s *oldf, FAR struct note_filter_tag_s *newf) { irqstate_t falgs; falgs = spin_lock_irqsave_wo_note(&g_note_lock); if (oldf != NULL) { /* Return the current filter setting */ *oldf = g_note_filter.tag_mask; } if (newf != NULL) { /* Replace the dump filter mask by the provided setting */ g_note_filter.tag_mask = *newf; } spin_unlock_irqrestore_wo_note(&g_note_lock, falgs); } #endif #endif /* CONFIG_SCHED_INSTRUMENTATION_FILTER */ #if CONFIG_DRIVERS_NOTE_TASKNAME_BUFSIZE > 0 /**************************************************************************** * Name: note_get_taskname * * Description: * Get the task name string of the specified PID * * Input Parameters: * PID - Task ID * * Returned Value: * Retrun name if task name can be retrieved, otherwise NULL ****************************************************************************/ FAR const char *note_get_taskname(pid_t pid) { FAR struct note_taskname_info_s *ti; FAR struct tcb_s *tcb; tcb = nxsched_get_tcb(pid); if (tcb != NULL) { return tcb->name; } ti = note_find_taskname(pid); if (ti != NULL) { return ti->name; } return NULL; } #endif /**************************************************************************** * Name: note_driver_register ****************************************************************************/ int note_driver_register(FAR struct note_driver_s *driver) { int i; DEBUGASSERT(driver); for (i = 0; i < CONFIG_DRIVERS_NOTE_MAX; i++) { if (g_note_drivers[i] == NULL) { g_note_drivers[i] = driver; return OK; } } return -ENOMEM; } #ifdef CONFIG_SCHED_INSTRUMENTATION_FUNCTION /**************************************************************************** * Name: __cyg_profile_func_enter ****************************************************************************/ void noinstrument_function __cyg_profile_func_enter(void *this_fn, void *call_site) { sched_note_string_ip(NOTE_TAG_ALWAYS, (uintptr_t)this_fn, "B"); } /**************************************************************************** * Name: __cyg_profile_func_exit ****************************************************************************/ void noinstrument_function __cyg_profile_func_exit(void *this_fn, void *call_site) { sched_note_string_ip(NOTE_TAG_ALWAYS, (uintptr_t)this_fn, "E"); } #endif