[kvm-unit-tests PATCH v7 2/2] riscv: sbi: Add tests for HSM extension
Andrew Jones
andrew.jones at linux.dev
Mon Nov 11 05:48:22 PST 2024
On Mon, Nov 11, 2024 at 01:16:33AM +0800, James Raphael Tiovalen wrote:
> Add some tests for all of the HSM extension functions. These tests
> ensure that the HSM extension functions follow the behavior as described
> in the SBI specification.
>
> Signed-off-by: James Raphael Tiovalen <jamestiotio at gmail.com>
> ---
> riscv/sbi.c | 612 ++++++++++++++++++++++++++++++++++++++++++++++++++++
> 1 file changed, 612 insertions(+)
>
> diff --git a/riscv/sbi.c b/riscv/sbi.c
> index 300e5cc9..021b606c 100644
> --- a/riscv/sbi.c
> +++ b/riscv/sbi.c
> @@ -21,6 +21,7 @@
> #include <asm/delay.h>
> #include <asm/io.h>
> #include <asm/mmu.h>
> +#include <asm/page.h>
> #include <asm/processor.h>
> #include <asm/sbi.h>
> #include <asm/setup.h>
> @@ -54,6 +55,11 @@ static struct sbiret sbi_dbcn_write_byte(uint8_t byte)
> return sbi_ecall(SBI_EXT_DBCN, SBI_EXT_DBCN_CONSOLE_WRITE_BYTE, byte, 0, 0, 0, 0, 0);
> }
>
> +static struct sbiret sbi_hart_suspend(uint32_t suspend_type, unsigned long resume_addr, unsigned long opaque)
> +{
> + return sbi_ecall(SBI_EXT_HSM, SBI_EXT_HSM_HART_SUSPEND, suspend_type, resume_addr, opaque, 0, 0, 0);
> +}
> +
> static struct sbiret sbi_system_suspend(uint32_t sleep_type, unsigned long resume_addr, unsigned long opaque)
> {
> return sbi_ecall(SBI_EXT_SUSP, 0, sleep_type, resume_addr, opaque, 0, 0, 0);
> @@ -834,6 +840,611 @@ static void check_susp(void)
> report_prefix_pop();
> }
>
> +static const char *hart_state_str[] = {
> + [SBI_EXT_HSM_STARTED] = "started",
> + [SBI_EXT_HSM_STOPPED] = "stopped",
> + [SBI_EXT_HSM_SUSPENDED] = "suspended",
> +};
> +struct hart_state_transition_info {
> + enum sbi_ext_hsm_sid initial_state;
> + enum sbi_ext_hsm_sid intermediate_state;
> + enum sbi_ext_hsm_sid final_state;
> +};
> +static cpumask_t sbi_hsm_started_hart_checks;
> +static bool sbi_hsm_invalid_hartid_check;
> +static bool sbi_hsm_timer_fired;
> +extern void sbi_hsm_check_hart_start(void);
> +extern void sbi_hsm_check_non_retentive_suspend(void);
> +
> +static void hsm_timer_irq_handler(struct pt_regs *regs)
> +{
> + timer_stop();
> + sbi_hsm_timer_fired = true;
> +}
> +
> +static void hsm_timer_setup(void)
> +{
> + install_irq_handler(IRQ_S_TIMER, hsm_timer_irq_handler);
> + timer_irq_enable();
> +}
> +
> +static void hsm_timer_teardown(void)
> +{
> + timer_irq_disable();
> + install_irq_handler(IRQ_S_TIMER, NULL);
> +}
> +
> +static void hart_check_already_started(void *data)
> +{
> + struct sbiret ret;
> + unsigned long hartid = current_thread_info()->hartid;
> + int me = smp_processor_id();
> +
> + ret = sbi_hart_start(hartid, virt_to_phys(&start_cpu), 0);
> +
> + if (ret.error == SBI_ERR_ALREADY_AVAILABLE)
> + cpumask_set_cpu(me, &sbi_hsm_started_hart_checks);
> +}
> +
> +static void hart_start_invalid_hartid(void *data)
> +{
> + struct sbiret ret;
> +
> + ret = sbi_hart_start(-1UL, virt_to_phys(&start_cpu), 0);
> +
> + if (ret.error == SBI_ERR_INVALID_PARAM)
> + sbi_hsm_invalid_hartid_check = true;
> +}
> +
> +static void hart_stop(void *data)
> +{
> + unsigned long hartid = current_thread_info()->hartid;
> + struct sbiret ret = sbi_hart_stop();
> +
> + report_fail("failed to stop hart %ld (error=%ld)", hartid, ret.error);
> +}
We already have stop_cpu() and can just extend it to also output hartid.
And hartids should be output in hex since they can be sparse.
> +
> +static void hart_retentive_suspend(void *data)
> +{
> + unsigned long hartid = current_thread_info()->hartid;
> + struct sbiret ret = sbi_hart_suspend(SBI_EXT_HSM_HART_SUSPEND_RETENTIVE, 0, 0);
> +
> + if (ret.error)
> + report_fail("failed to retentive suspend hart %ld (error=%ld)", hartid, ret.error);
Instead of 'hart %ld', let's use 'cpu%d (hartid = %lx)'
Same comment for the other functions below.
> +}
> +
> +static void hart_non_retentive_suspend(void *data)
> +{
> + unsigned long hartid = current_thread_info()->hartid;
> + unsigned long params[] = {
> + [SBI_HSM_MAGIC_IDX] = SBI_HSM_MAGIC,
> + [SBI_HSM_HARTID_IDX] = hartid,
> + };
> + struct sbiret ret = sbi_hart_suspend(SBI_EXT_HSM_HART_SUSPEND_NON_RETENTIVE,
> + virt_to_phys(&sbi_hsm_check_non_retentive_suspend),
> + virt_to_phys(params));
> +
> + report_fail("failed to non-retentive suspend hart %ld (error=%ld)", hartid, ret.error);
> +}
> +
> +/* This test function is only being run on RV64 to verify that upper bits of suspend_type are ignored */
> +static void hart_retentive_suspend_with_msb_set(void *data)
> +{
> + unsigned long hartid = current_thread_info()->hartid;
> + unsigned long suspend_type = SBI_EXT_HSM_HART_SUSPEND_RETENTIVE | (_AC(1, UL) << (__riscv_xlen - 1));
> + struct sbiret ret = sbi_ecall(SBI_EXT_HSM, SBI_EXT_HSM_HART_SUSPEND, suspend_type, 0, 0, 0, 0, 0);
> +
> + if (ret.error)
> + report_fail("failed to retentive suspend hart %ld with MSB set (error=%ld)", hartid, ret.error);
> +}
> +
> +/* This test function is only being run on RV64 to verify that upper bits of suspend_type are ignored */
> +static void hart_non_retentive_suspend_with_msb_set(void *data)
> +{
> + unsigned long hartid = current_thread_info()->hartid;
> + unsigned long suspend_type = SBI_EXT_HSM_HART_SUSPEND_NON_RETENTIVE | (_AC(1, UL) << (__riscv_xlen - 1));
> + unsigned long params[] = {
> + [SBI_HSM_MAGIC_IDX] = SBI_HSM_MAGIC,
> + [SBI_HSM_HARTID_IDX] = hartid,
> + };
> +
> + struct sbiret ret = sbi_ecall(SBI_EXT_HSM, SBI_EXT_HSM_HART_SUSPEND, suspend_type,
> + virt_to_phys(&sbi_hsm_check_non_retentive_suspend), virt_to_phys(params),
> + 0, 0, 0);
> +
> + report_fail("failed to non-retentive suspend hart %ld with MSB set (error=%ld)", hartid, ret.error);
> +}
> +
> +static bool hart_wait_on_status(unsigned long hartid, enum sbi_ext_hsm_sid status, unsigned long duration)
> +{
> + struct sbiret ret;
> +
> + sbi_hsm_timer_fired = false;
> + timer_start(duration);
> +
> + ret = sbi_hart_get_status(hartid);
> +
> + while (!ret.error && ret.value == status && !sbi_hsm_timer_fired) {
> + cpu_relax();
> + ret = sbi_hart_get_status(hartid);
> + }
> +
> + timer_stop();
> +
> + if (sbi_hsm_timer_fired)
> + report_info("timer fired while waiting on status %u for hart %ld", status, hartid);
> + else if (ret.error)
> + report_fail("got %ld while waiting on status %u for hart %ld\n", ret.error, status, hartid);
> +
> + return !sbi_hsm_timer_fired && !ret.error;
> +}
> +
> +static int hart_wait_state_transition(cpumask_t mask, unsigned long duration, struct hart_state_transition_info states)
Why pass a copy of the cpumask instead of passing it by reference?
Same question for the states struct.
> +{
> + struct sbiret ret;
> + unsigned long hartid;
> + int cpu, count = 0;
> +
> + for_each_cpu(cpu, &mask) {
> + hartid = cpus[cpu].hartid;
> + if (!hart_wait_on_status(hartid, states.initial_state, duration))
> + continue;
> + if (!hart_wait_on_status(hartid, states.intermediate_state, duration))
> + continue;
> +
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != states.final_state)
> + report_info("hart %ld status is not '%s' (ret.value=%ld)", hartid,
> + hart_state_str[states.final_state], ret.value);
> + else
> + count++;
> + }
> +
> + return count;
> +}
> +
> +static void hart_wait_until_idle(int max_cpus, unsigned long duration)
> +{
> + sbi_hsm_timer_fired = false;
> + timer_start(duration);
> +
> + while (cpumask_weight(&cpu_idle_mask) != max_cpus - 1 && !sbi_hsm_timer_fired)
The prefix 'max_' doesn't make much sense in this context, it's just a
parameter which isn't relative to anything else in this scope. That also
means that subtracting one from it seems like an odd thing to do. And,
looking ahead, I see we're not just waiting for the idle mask to have
that many arbitrary idle cpus, we're using this to check if all the cpus
in a particular mask are idle. That means we should be passing that mask
into this function and using cpumask_subset() for the check.
> + cpu_relax();
> +
> + timer_stop();
> +
> + if (sbi_hsm_timer_fired)
> + report_info("hsm timer fired before all secondary harts go to idle");
'all secondary' in this info line also means this function is specific to
a particular set of cpus. We should at least rename the function, then
we could either use cpumask_subset() as I point out above or still use
number of cpus, but rename 'max_cpus' to 'nr_secondaries' and not subtract
one. I think I prefer keeping it more generic by passing in a mask though,
as it would also be consistent with hart_wait_state_transition().
> +}
> +
> +static void check_hsm(void)
> +{
> + struct sbiret ret;
> + unsigned long hartid;
> + cpumask_t secondary_cpus_mask;
> + int hsm_start, hsm_stop, hsm_suspend, hsm_resume, hsm_check;
Isn't a single 'count' variable shared for all these tests sufficient?
> + struct hart_state_transition_info transition_states;
> + bool ipi_unavailable = false;
> + bool suspend_with_msb = false, resume_with_msb = false, check_with_msb = false, stop_with_msb = false;
Isn't a single 'pass' boolean sufficient for all these tests? Actually, I
don't think we even need any boolean. See below.
> + int cpu, me = smp_processor_id();
> + int max_cpus = getenv("SBI_MAX_CPUS") ? strtol(getenv("SBI_MAX_CPUS"), NULL, 0) : nr_cpus;
> + unsigned long hsm_timer_duration = getenv("SBI_HSM_TIMER_DURATION")
> + ? strtol(getenv("SBI_HSM_TIMER_DURATION"), NULL, 0) : 200000;
> +
> + max_cpus = MIN(MIN(max_cpus, nr_cpus), cpumask_weight(&cpu_present_mask));
> +
> + report_prefix_push("hsm");
> +
> + if (!sbi_probe(SBI_EXT_HSM)) {
> + report_skip("hsm extension not available");
> + report_prefix_pop();
> + return;
> + }
> +
> + report_prefix_push("hart_get_status");
> +
> + hartid = current_thread_info()->hartid;
> + ret = sbi_hart_get_status(hartid);
> +
> + if (ret.error) {
> + report_fail("failed to get status of current hart (error=%ld)", ret.error);
> + report_prefix_popn(2);
> + return;
> + } else if (ret.value != SBI_EXT_HSM_STARTED) {
> + report_fail("current hart is not started (ret.value=%ld)", ret.value);
> + report_prefix_popn(2);
> + return;
> + }
> +
> + report_pass("status of current hart is started");
> +
> + report_prefix_pop();
> +
> + if (max_cpus < 2) {
> + report_skip("no other cpus to run the remaining hsm tests on");
> + report_prefix_pop();
> + return;
> + }
> +
> + report_prefix_push("hart_stop");
> +
> + cpumask_copy(&secondary_cpus_mask, &cpu_present_mask);
> + cpumask_clear_cpu(me, &secondary_cpus_mask);
> + hsm_timer_setup();
> + local_irq_enable();
> +
> + /* Assume that previous tests have not cleaned up and stopped the secondary harts */
> + on_cpumask_async(&secondary_cpus_mask, hart_stop, NULL);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STARTED,
> + .intermediate_state = SBI_EXT_HSM_STOP_PENDING,
> + .final_state = SBI_EXT_HSM_STOPPED,
> + };
> + hsm_stop = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_stop == max_cpus - 1, "all secondary harts stopped");
> +
> + report_prefix_pop();
> +
> + report_prefix_push("hart_start");
> +
> + for_each_cpu(cpu, &secondary_cpus_mask) {
> + hartid = cpus[cpu].hartid;
> + sbi_hsm_hart_start_params[cpu * SBI_HSM_NUM_OF_PARAMS + SBI_HSM_MAGIC_IDX] = SBI_HSM_MAGIC;
> + sbi_hsm_hart_start_params[cpu * SBI_HSM_NUM_OF_PARAMS + SBI_HSM_HARTID_IDX] = hartid;
> +
> + ret = sbi_hart_start(hartid, virt_to_phys(&sbi_hsm_check_hart_start),
> + virt_to_phys(&sbi_hsm_hart_start_params[cpu * SBI_HSM_NUM_OF_PARAMS]));
> + if (ret.error) {
> + report_fail("failed to start test hart %ld (error=%ld)", hartid, ret.error);
> + continue;
> + }
> + }
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STOPPED,
> + .intermediate_state = SBI_EXT_HSM_START_PENDING,
> + .final_state = SBI_EXT_HSM_STARTED,
> + };
> +
> + hsm_start = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> + hsm_check = 0;
> +
> + for_each_cpu(cpu, &secondary_cpus_mask) {
> + sbi_hsm_timer_fired = false;
> + timer_start(hsm_timer_duration);
> +
> + while (!(READ_ONCE(sbi_hsm_hart_start_checks[cpu]) & SBI_HSM_TEST_DONE) && !sbi_hsm_timer_fired)
> + cpu_relax();
> +
> + timer_stop();
> +
> + if (sbi_hsm_timer_fired) {
> + report_info("hsm timer fired before hart %ld is done with start checks", hartid);
> + continue;
> + }
> +
> + if (!(sbi_hsm_hart_start_checks[cpu] & SBI_HSM_TEST_SATP))
> + report_info("satp is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_hart_start_checks[cpu] & SBI_HSM_TEST_SIE))
> + report_info("sstatus.SIE is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_hart_start_checks[cpu] & SBI_HSM_TEST_MAGIC_A1))
> + report_info("a1 does not start with magic for test hart %ld", hartid);
> + else if (!(sbi_hsm_hart_start_checks[cpu] & SBI_HSM_TEST_HARTID_A1))
> + report_info("a0 is not hartid for test hart %ld", hartid);
> + else
> + hsm_check++;
> + }
> +
> + report(hsm_start == max_cpus - 1, "all secondary harts started");
> + report(hsm_check == max_cpus - 1,
> + "all secondary harts have expected register values after hart start");
> +
> + report_prefix_pop();
> +
> + report_prefix_push("hart_stop");
> +
> + memset(sbi_hsm_stop_hart, 1, sizeof(sbi_hsm_stop_hart));
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STARTED,
> + .intermediate_state = SBI_EXT_HSM_STOP_PENDING,
> + .final_state = SBI_EXT_HSM_STOPPED,
> + };
> + hsm_stop = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_stop == max_cpus - 1, "all secondary harts stopped");
> +
> + /* Reset the stop flags so that we can reuse them after suspension tests */
> + memset(sbi_hsm_stop_hart, 0, sizeof(sbi_hsm_stop_hart));
> +
> + report_prefix_pop();
> +
> + report_prefix_push("hart_start");
> +
> + /* Select just one secondary cpu to run the invalid hartid test */
> + on_cpu(cpumask_next(-1, &secondary_cpus_mask), hart_start_invalid_hartid, NULL);
> +
> + report(sbi_hsm_invalid_hartid_check, "secondary hart refuse to start with invalid hartid");
> +
> + on_cpumask_async(&secondary_cpus_mask, hart_check_already_started, NULL);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STOPPED,
> + .intermediate_state = SBI_EXT_HSM_START_PENDING,
> + .final_state = SBI_EXT_HSM_STARTED,
> + };
> +
> + hsm_start = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_start == max_cpus - 1, "all secondary harts started");
> +
> + hart_wait_until_idle(max_cpus, hsm_timer_duration);
> +
> + report(cpumask_weight(&cpu_idle_mask) == max_cpus - 1,
> + "all secondary harts successfully executed code after start");
> + report(cpumask_weight(&cpu_online_mask) == max_cpus, "all secondary harts online");
The above two tests aren't really testing the SBI implementation as much as
they are the kvm-unit-tests framework. Let's just drop them.
> + report(cpumask_weight(&sbi_hsm_started_hart_checks) == max_cpus - 1,
> + "all secondary harts are already started");
> +
> + report_prefix_pop();
> +
> + report_prefix_push("hart_suspend");
> +
> + if (!sbi_probe(SBI_EXT_IPI)) {
> + report_skip("skipping suspension tests since ipi extension is unavailable");
> + report_prefix_pop();
> + ipi_unavailable = true;
> + goto sbi_hsm_hart_stop_tests;
> + }
> +
> + on_cpumask_async(&secondary_cpus_mask, hart_retentive_suspend, NULL);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STARTED,
> + .intermediate_state = SBI_EXT_HSM_SUSPEND_PENDING,
> + .final_state = SBI_EXT_HSM_SUSPENDED,
> + };
> +
> + hsm_suspend = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_suspend == max_cpus - 1, "all secondary harts retentive suspended");
> +
> + /* Ignore the return value since we check the status of each hart anyway */
> + sbi_send_ipi_cpumask(&secondary_cpus_mask);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_SUSPENDED,
> + .intermediate_state = SBI_EXT_HSM_RESUME_PENDING,
> + .final_state = SBI_EXT_HSM_STARTED,
> + };
> +
> + hsm_resume = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_resume == max_cpus - 1, "all secondary harts retentive resumed");
> +
> + hart_wait_until_idle(max_cpus, hsm_timer_duration);
> +
> + report(cpumask_weight(&cpu_idle_mask) == max_cpus - 1,
> + "all secondary harts successfully executed code after retentive suspend");
> + report(cpumask_weight(&cpu_online_mask) == max_cpus,
> + "all secondary harts online");
Same comment as above. We can drop these.
> +
> + on_cpumask_async(&secondary_cpus_mask, hart_non_retentive_suspend, NULL);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STARTED,
> + .intermediate_state = SBI_EXT_HSM_SUSPEND_PENDING,
> + .final_state = SBI_EXT_HSM_SUSPENDED,
> + };
> +
> + hsm_suspend = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_suspend == max_cpus - 1, "all secondary harts non-retentive suspended");
> +
> + /* Ignore the return value since we check the status of each hart anyway */
> + sbi_send_ipi_cpumask(&secondary_cpus_mask);
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_SUSPENDED,
> + .intermediate_state = SBI_EXT_HSM_RESUME_PENDING,
> + .final_state = SBI_EXT_HSM_STARTED,
> + };
> +
> + hsm_resume = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> + hsm_check = 0;
> +
> + for_each_cpu(cpu, &secondary_cpus_mask) {
> + sbi_hsm_timer_fired = false;
> + timer_start(hsm_timer_duration);
> +
> + while (!((READ_ONCE(sbi_hsm_non_retentive_hart_suspend_checks[cpu])) & SBI_HSM_TEST_DONE)
> + && !sbi_hsm_timer_fired)
> + cpu_relax();
> +
> + timer_stop();
> +
> + if (sbi_hsm_timer_fired) {
> + report_info("hsm timer fired before hart %ld is done with non-retentive resume checks",
> + hartid);
> + continue;
> + }
> +
> + if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_SATP))
> + report_info("satp is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_SIE))
> + report_info("sstatus.SIE is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_MAGIC_A1))
> + report_info("a1 does not start with magic for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_HARTID_A1))
> + report_info("a0 is not hartid for test hart %ld", hartid);
> + else
> + hsm_check++;
> + }
> +
> + report(hsm_resume == max_cpus - 1, "all secondary harts non-retentive resumed");
> + report(hsm_check == max_cpus - 1,
> + "all secondary harts have expected register values after non-retentive resume");
> +
> + report_prefix_pop();
> +
> +sbi_hsm_hart_stop_tests:
> + report_prefix_push("hart_stop");
> +
> + if (ipi_unavailable)
> + on_cpumask_async(&secondary_cpus_mask, hart_stop, NULL);
> + else
> + memset(sbi_hsm_stop_hart, 1, sizeof(sbi_hsm_stop_hart));
> +
> + transition_states = (struct hart_state_transition_info) {
> + .initial_state = SBI_EXT_HSM_STARTED,
> + .intermediate_state = SBI_EXT_HSM_STOP_PENDING,
> + .final_state = SBI_EXT_HSM_STOPPED,
> + };
> + hsm_stop = hart_wait_state_transition(secondary_cpus_mask, hsm_timer_duration, transition_states);
> +
> + report(hsm_stop == max_cpus - 1, "all secondary harts stopped");
> +
> + report_prefix_pop();
> +
> + if (__riscv_xlen == 32 || ipi_unavailable) {
> + local_irq_disable();
> + hsm_timer_teardown();
> + report_prefix_pop();
> + return;
> + }
> +
> + report_prefix_push("hart_suspend");
> +
> + /* Select just one secondary cpu to run suspension tests with MSB of suspend type being set */
> + cpu = cpumask_next(-1, &secondary_cpus_mask);
> + hartid = cpus[cpu].hartid;
> +
> + /* Boot up the secondary cpu and let it proceed to the idle loop */
> + on_cpu(cpu, start_cpu, NULL);
> +
> + on_cpu_async(cpu, hart_retentive_suspend_with_msb_set, NULL);
> +
> + if (hart_wait_on_status(hartid, SBI_EXT_HSM_STARTED, hsm_timer_duration) &&
> + hart_wait_on_status(hartid, SBI_EXT_HSM_SUSPEND_PENDING, hsm_timer_duration)) {
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != SBI_EXT_HSM_SUSPENDED)
> + report_info("hart %ld status is not 'suspended' (ret.value=%ld)", hartid, ret.value);
> + else
> + suspend_with_msb = true;
> + }
This looks like hart_wait_state_transition() so we could just use that
with a mask that only has 'cpu' set in it. Then, the count returned
from that call could be checked below...
> +
> + report(suspend_with_msb, "secondary hart retentive suspended with MSB set");
report(count, ...)
Same comment for the similar ones below.
> +
> + /* Ignore the return value since we manually validate the status of the hart anyway */
> + sbi_send_ipi_cpu(cpu);
> +
> + if (hart_wait_on_status(hartid, SBI_EXT_HSM_SUSPENDED, hsm_timer_duration) &&
> + hart_wait_on_status(hartid, SBI_EXT_HSM_RESUME_PENDING, hsm_timer_duration)) {
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != SBI_EXT_HSM_STARTED)
> + report_info("hart %ld status is not 'started' (ret.value=%ld)", hartid, ret.value);
> + else
> + resume_with_msb = true;
> + }
> +
> + report(resume_with_msb, "secondary hart retentive resumed with MSB set");
> +
> + /* Reset these flags so that we can reuse them for the non-retentive suspension test */
> + suspend_with_msb = false;
> + resume_with_msb = false;
> + sbi_hsm_stop_hart[cpu] = 0;
> + sbi_hsm_non_retentive_hart_suspend_checks[cpu] = 0;
> +
> + on_cpu_async(cpu, hart_non_retentive_suspend_with_msb_set, NULL);
> +
> + if (hart_wait_on_status(hartid, SBI_EXT_HSM_STARTED, hsm_timer_duration) &&
> + hart_wait_on_status(hartid, SBI_EXT_HSM_SUSPEND_PENDING, hsm_timer_duration)) {
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != SBI_EXT_HSM_SUSPENDED)
> + report_info("hart %ld status is not 'suspended' (ret.value=%ld)", hartid, ret.value);
> + else
> + suspend_with_msb = true;
> + }
> +
> + report(suspend_with_msb, "secondary hart non-retentive suspended with MSB set");
> +
> + /* Ignore the return value since we manually validate the status of the hart anyway */
> + sbi_send_ipi_cpu(cpu);
> +
> + if (hart_wait_on_status(hartid, SBI_EXT_HSM_SUSPENDED, hsm_timer_duration) &&
> + hart_wait_on_status(hartid, SBI_EXT_HSM_RESUME_PENDING, hsm_timer_duration)) {
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != SBI_EXT_HSM_STARTED)
> + report_info("hart %ld status is not 'started' (ret.value=%ld)", hartid, ret.value);
> + else
> + resume_with_msb = true;
> +
> + sbi_hsm_timer_fired = false;
> + timer_start(hsm_timer_duration);
> +
> + while (!((READ_ONCE(sbi_hsm_non_retentive_hart_suspend_checks[cpu])) & SBI_HSM_TEST_DONE)
> + && !sbi_hsm_timer_fired)
> + cpu_relax();
> +
> + timer_stop();
> +
> + if (sbi_hsm_timer_fired) {
> + report_info("hsm timer fired before hart %ld is done with non-retentive resume checks",
> + hartid);
> + } else {
> + if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_SATP))
> + report_info("satp is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_SIE))
> + report_info("sstatus.SIE is not zero for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_MAGIC_A1))
> + report_info("a1 does not start with magic for test hart %ld", hartid);
> + else if (!(sbi_hsm_non_retentive_hart_suspend_checks[cpu] & SBI_HSM_TEST_HARTID_A1))
> + report_info("a0 is not hartid for test hart %ld", hartid);
> + else
> + check_with_msb = true;
> + }
> + }
> +
> + report(resume_with_msb, "secondary hart non-retentive resumed with MSB set");
> + report(check_with_msb,
> + "secondary hart has expected register values after non-retentive resume with MSB set");
> +
> + report_prefix_pop();
> +
> + report_prefix_push("hart_stop");
> +
> + sbi_hsm_stop_hart[cpu] = 1;
> +
> + if (hart_wait_on_status(hartid, SBI_EXT_HSM_STARTED, hsm_timer_duration) &&
> + hart_wait_on_status(hartid, SBI_EXT_HSM_STOP_PENDING, hsm_timer_duration)) {
> + ret = sbi_hart_get_status(hartid);
> + if (ret.error)
> + report_info("hart %ld get status failed (error=%ld)", hartid, ret.error);
> + else if (ret.value != SBI_EXT_HSM_STOPPED)
> + report_info("hart %ld status is not 'stopped' (ret.value=%ld)", hartid, ret.value);
> + else
> + stop_with_msb = true;
> + }
> +
> + report(stop_with_msb, "secondary hart stopped after suspension tests with MSB set");
> +
> + local_irq_disable();
> + hsm_timer_teardown();
> + report_prefix_popn(2);
> +}
> +
> int main(int argc, char **argv)
> {
> if (argc > 1 && !strcmp(argv[1], "-h")) {
> @@ -845,6 +1456,7 @@ int main(int argc, char **argv)
> check_base();
> check_time();
> check_ipi();
> + check_hsm();
> check_dbcn();
> check_susp();
>
> --
> 2.43.0
>
Thanks,
drew
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