/* int_latency_bench.c - interrupt latency benchmark support */ /* * Copyright (c) 2012-2015 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ #include "toolchain.h" #include "sections.h" #include /* uint32_t */ #include /* ULONG_MAX */ #include /* printk */ #include #include #define NB_CACHE_WARMING_DRY_RUN 7 /* * Timestamp corresponding to when interrupt were turned off. * A value of zero indicated interrupt are not currently locked. */ static uint32_t int_locked_timestamp; /* stats tracking the minimum and maximum time when interrupts were locked */ static uint32_t int_locked_latency_min = ULONG_MAX; static uint32_t int_locked_latency_max; /* overhead added to intLock/intUnlock by this latency benchmark */ static uint32_t initial_start_delay; static uint32_t nesting_delay; static uint32_t stop_delay; /* counter tracking intLock/intUnlock calls once interrupt are locked */ static uint32_t int_lock_unlock_nest; /* indicate if the interrupt latency benchamrk is ready to be used */ static uint32_t int_latency_bench_ready; /* min amount of time it takes from HW interrupt generation to 'C' handler */ uint32_t _hw_irq_to_c_handler_latency = ULONG_MAX; /** * * @brief Start tracking time spent with interrupts locked * * calls to lock interrupt can nest, so this routine can be called numerous * times before interrupt are unlocked * * @return N/A * */ void _int_latency_start(void) { /* when interrupts are not already locked, take time stamp */ if (!int_locked_timestamp && int_latency_bench_ready) { int_locked_timestamp = k_cycle_get_32(); int_lock_unlock_nest = 0; } int_lock_unlock_nest++; } /** * * @brief Stop accumulating time spent for when interrupts are locked * * This is only call once when the interrupt are being reenabled * * @return N/A * */ void _int_latency_stop(void) { uint32_t delta; uint32_t delayOverhead; uint32_t currentTime = k_cycle_get_32(); /* ensured intLatencyStart() was invoked first */ if (int_locked_timestamp) { /* * time spent with interrupt lock is: * (current time - time when interrupt got disabled first) - * (delay when invoking start + number nested calls to intLock * * time it takes to call intLatencyStart + intLatencyStop) */ delta = (currentTime - int_locked_timestamp); /* * Substract overhead introduce by the int latency benchmark * only if * it is bigger than delta. It can be possible sometimes for * delta to * be smaller than the estimated overhead. */ delayOverhead = (initial_start_delay + ((int_lock_unlock_nest - 1) * nesting_delay) + stop_delay); if (delta >= delayOverhead) delta -= delayOverhead; /* update max */ if (delta > int_locked_latency_max) int_locked_latency_max = delta; /* update min */ if (delta < int_locked_latency_min) int_locked_latency_min = delta; /* interrupts are now enabled, get ready for next interrupt lock */ int_locked_timestamp = 0; } } /** * * @brief Initialize interrupt latency benchmark * * @return N/A * */ void int_latency_init(void) { uint32_t timeToReadTime; uint32_t cacheWarming = NB_CACHE_WARMING_DRY_RUN; int_latency_bench_ready = 1; /* * measuring delay introduced by the interrupt latency benchmark few * times to ensure we get the best possible values. The overhead of * invoking the latency can changes runtime (i.e. cache hit or miss) * but an estimated overhead is used to adjust Max interrupt latency. * The overhead introduced by benchmark is composed of three values: * initial_start_delay, nesting_delay, stop_delay. */ while (cacheWarming) { /* measure how much time it takes to read time */ timeToReadTime = k_cycle_get_32(); timeToReadTime = k_cycle_get_32() - timeToReadTime; /* measure time to call intLatencyStart() and intLatencyStop * takes */ initial_start_delay = k_cycle_get_32(); _int_latency_start(); initial_start_delay = k_cycle_get_32() - initial_start_delay - timeToReadTime; nesting_delay = k_cycle_get_32(); _int_latency_start(); nesting_delay = k_cycle_get_32() - nesting_delay - timeToReadTime; stop_delay = k_cycle_get_32(); _int_latency_stop(); stop_delay = k_cycle_get_32() - stop_delay - timeToReadTime; /* re-initialize globals to default values */ int_locked_latency_min = ULONG_MAX; int_locked_latency_max = 0; cacheWarming--; } } /** * * @brief Dumps interrupt latency values * * The interrupt latency value measures * * @return N/A * */ void int_latency_show(void) { uint32_t intHandlerLatency = 0; if (!int_latency_bench_ready) { printk("error: int_latency_init() has not been invoked\n"); return; } if (int_locked_latency_min != ULONG_MAX) { if (_hw_irq_to_c_handler_latency == ULONG_MAX) { intHandlerLatency = 0; printk(" Min latency from hw interrupt up to 'C' int. " "handler: " "not measured\n"); } else { intHandlerLatency = _hw_irq_to_c_handler_latency; printk(" Min latency from hw interrupt up to 'C' int. " "handler:" " %d tcs = %d nsec\n", intHandlerLatency, SYS_CLOCK_HW_CYCLES_TO_NS(intHandlerLatency)); } printk(" Max interrupt latency (includes hw int. to 'C' " "handler):" " %d tcs = %d nsec\n", int_locked_latency_max + intHandlerLatency, SYS_CLOCK_HW_CYCLES_TO_NS(int_locked_latency_max + intHandlerLatency)); printk(" Overhead substracted from Max int. latency:\n" " for int. lock : %d tcs = %d nsec\n" " each time int. lock nest: %d tcs = %d nsec\n" " for int. unlocked : %d tcs = %d nsec\n", initial_start_delay, SYS_CLOCK_HW_CYCLES_TO_NS(initial_start_delay), nesting_delay, SYS_CLOCK_HW_CYCLES_TO_NS(nesting_delay), stop_delay, SYS_CLOCK_HW_CYCLES_TO_NS(stop_delay)); } else { printk("interrupts were not locked and unlocked yet\n"); } /* * Lets start with new values so that one extra long path executed * with interrupt disabled hide smaller paths with interrupt * disabled. */ int_locked_latency_min = ULONG_MAX; int_locked_latency_max = 0; }