| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Eric Biggers | 491 | 87.52% | 3 | 75.00% |
| David Gow | 70 | 12.48% | 1 | 25.00% |
| Total | 561 | 4 |
/* SPDX-License-Identifier: GPL-2.0-or-later */ /* * Helper function for testing code in interrupt contexts * * Copyright 2025 Google LLC */ #ifndef _KUNIT_RUN_IN_IRQ_CONTEXT_H #define _KUNIT_RUN_IN_IRQ_CONTEXT_H #include <kunit/test.h> #include <linux/timekeeping.h> #include <linux/hrtimer.h> #include <linux/workqueue.h> struct kunit_irq_test_state { bool (*func)(void *test_specific_state); void *test_specific_state; bool task_func_reported_failure; bool hardirq_func_reported_failure; bool softirq_func_reported_failure; atomic_t task_func_calls; atomic_t hardirq_func_calls; atomic_t softirq_func_calls; ktime_t interval; struct hrtimer timer; struct work_struct bh_work; }; static enum hrtimer_restart kunit_irq_test_timer_func(struct hrtimer *timer) { struct kunit_irq_test_state *state = container_of(timer, typeof(*state), timer); int task_calls, hardirq_calls, softirq_calls; WARN_ON_ONCE(!in_hardirq()); task_calls = atomic_read(&state->task_func_calls); hardirq_calls = atomic_inc_return(&state->hardirq_func_calls); softirq_calls = atomic_read(&state->softirq_func_calls); /* * If the timer is firing too often for the softirq or task to ever have * a chance to run, increase the timer interval. This is needed on very * slow systems. */ if (hardirq_calls >= 20 && (softirq_calls == 0 || task_calls == 0)) state->interval = ktime_add_ns(state->interval, 250); if (!state->func(state->test_specific_state)) state->hardirq_func_reported_failure = true; hrtimer_forward_now(&state->timer, state->interval); queue_work(system_bh_wq, &state->bh_work); return HRTIMER_RESTART; } static void kunit_irq_test_bh_work_func(struct work_struct *work) { struct kunit_irq_test_state *state = container_of(work, typeof(*state), bh_work); WARN_ON_ONCE(!in_serving_softirq()); atomic_inc(&state->softirq_func_calls); if (!state->func(state->test_specific_state)) state->softirq_func_reported_failure = true; } /* * Helper function which repeatedly runs the given @func in task, softirq, and * hardirq context concurrently, and reports a failure to KUnit if any * invocation of @func in any context returns false. @func is passed * @test_specific_state as its argument. At most 3 invocations of @func will * run concurrently: one in each of task, softirq, and hardirq context. @func * will continue running until either @max_iterations calls have been made (so * long as at least one each runs in task, softirq, and hardirq contexts), or * one second has passed. * * The main purpose of this interrupt context testing is to validate fallback * code paths that run in contexts where the normal code path cannot be used, * typically due to the FPU or vector registers already being in-use in kernel * mode. These code paths aren't covered when the test code is executed only by * the KUnit test runner thread in task context. The reason for the concurrency * is because merely using hardirq context is not sufficient to reach a fallback * code path on some architectures; the hardirq actually has to occur while the * FPU or vector unit was already in-use in kernel mode. * * Another purpose of this testing is to detect issues with the architecture's * irq_fpu_usable() and kernel_fpu_begin/end() or equivalent functions, * especially in softirq context when the softirq may have interrupted a task * already using kernel-mode FPU or vector (if the arch didn't prevent that). * Crypto functions are often executed in softirqs, so this is important. */ static inline void kunit_run_irq_test(struct kunit *test, bool (*func)(void *), int max_iterations, void *test_specific_state) { struct kunit_irq_test_state state = { .func = func, .test_specific_state = test_specific_state, /* * Start with a 5us timer interval. If the system can't keep * up, kunit_irq_test_timer_func() will increase it. */ .interval = us_to_ktime(5), }; unsigned long end_jiffies; int task_calls, hardirq_calls, softirq_calls; /* * Set up a hrtimer (the way we access hardirq context) and a work * struct for the BH workqueue (the way we access softirq context). */ hrtimer_setup_on_stack(&state.timer, kunit_irq_test_timer_func, CLOCK_MONOTONIC, HRTIMER_MODE_REL_HARD); INIT_WORK_ONSTACK(&state.bh_work, kunit_irq_test_bh_work_func); /* * Run for up to max_iterations (including at least one task, softirq, * and hardirq), or 1 second, whichever comes first. */ end_jiffies = jiffies + HZ; hrtimer_start(&state.timer, state.interval, HRTIMER_MODE_REL_HARD); do { if (!func(test_specific_state)) state.task_func_reported_failure = true; task_calls = atomic_inc_return(&state.task_func_calls); hardirq_calls = atomic_read(&state.hardirq_func_calls); softirq_calls = atomic_read(&state.softirq_func_calls); } while ((task_calls + hardirq_calls + softirq_calls < max_iterations || (task_calls == 0 || hardirq_calls == 0 || softirq_calls == 0)) && !time_after(jiffies, end_jiffies)); /* Cancel the timer and work. */ hrtimer_cancel(&state.timer); flush_work(&state.bh_work); /* Sanity check: the timer and BH functions should have been run. */ KUNIT_EXPECT_GT_MSG(test, atomic_read(&state.hardirq_func_calls), 0, "Timer function was not called"); KUNIT_EXPECT_GT_MSG(test, atomic_read(&state.softirq_func_calls), 0, "BH work function was not called"); /* Check for failure reported from any context. */ KUNIT_EXPECT_FALSE_MSG(test, state.task_func_reported_failure, "Failure reported from task context"); KUNIT_EXPECT_FALSE_MSG(test, state.hardirq_func_reported_failure, "Failure reported from hardirq context"); KUNIT_EXPECT_FALSE_MSG(test, state.softirq_func_reported_failure, "Failure reported from softirq context"); } #endif /* _KUNIT_RUN_IN_IRQ_CONTEXT_H */
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