Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Peter Shier | 1727 | 94.94% | 1 | 12.50% |
Sean Christopherson | 76 | 4.18% | 3 | 37.50% |
Jim Mattson | 9 | 0.49% | 1 | 12.50% |
Andrew Jones | 4 | 0.22% | 1 | 12.50% |
Vipin Sharma | 2 | 0.11% | 1 | 12.50% |
Ricardo Koller | 1 | 0.05% | 1 | 12.50% |
Total | 1819 | 8 |
// SPDX-License-Identifier: GPL-2.0 /* * xapic_ipi_test * * Copyright (C) 2020, Google LLC. * * This work is licensed under the terms of the GNU GPL, version 2. * * Test that when the APIC is in xAPIC mode, a vCPU can send an IPI to wake * another vCPU that is halted when KVM's backing page for the APIC access * address has been moved by mm. * * The test starts two vCPUs: one that sends IPIs and one that continually * executes HLT. The sender checks that the halter has woken from the HLT and * has reentered HLT before sending the next IPI. While the vCPUs are running, * the host continually calls migrate_pages to move all of the process' pages * amongst the available numa nodes on the machine. * * Migration is a command line option. When used on non-numa machines will * exit with error. Test is still usefull on non-numa for testing IPIs. */ #define _GNU_SOURCE /* for program_invocation_short_name */ #include <getopt.h> #include <pthread.h> #include <inttypes.h> #include <string.h> #include <time.h> #include "kvm_util.h" #include "numaif.h" #include "processor.h" #include "test_util.h" #include "vmx.h" /* Default running time for the test */ #define DEFAULT_RUN_SECS 3 /* Default delay between migrate_pages calls (microseconds) */ #define DEFAULT_DELAY_USECS 500000 /* * Vector for IPI from sender vCPU to halting vCPU. * Value is arbitrary and was chosen for the alternating bit pattern. Any * value should work. */ #define IPI_VECTOR 0xa5 /* * Incremented in the IPI handler. Provides evidence to the sender that the IPI * arrived at the destination */ static volatile uint64_t ipis_rcvd; /* Data struct shared between host main thread and vCPUs */ struct test_data_page { uint32_t halter_apic_id; volatile uint64_t hlt_count; volatile uint64_t wake_count; uint64_t ipis_sent; uint64_t migrations_attempted; uint64_t migrations_completed; uint32_t icr; uint32_t icr2; uint32_t halter_tpr; uint32_t halter_ppr; /* * Record local version register as a cross-check that APIC access * worked. Value should match what KVM reports (APIC_VERSION in * arch/x86/kvm/lapic.c). If test is failing, check that values match * to determine whether APIC access exits are working. */ uint32_t halter_lvr; }; struct thread_params { struct test_data_page *data; struct kvm_vcpu *vcpu; uint64_t *pipis_rcvd; /* host address of ipis_rcvd global */ }; void verify_apic_base_addr(void) { uint64_t msr = rdmsr(MSR_IA32_APICBASE); uint64_t base = GET_APIC_BASE(msr); GUEST_ASSERT(base == APIC_DEFAULT_GPA); } static void halter_guest_code(struct test_data_page *data) { verify_apic_base_addr(); xapic_enable(); data->halter_apic_id = GET_APIC_ID_FIELD(xapic_read_reg(APIC_ID)); data->halter_lvr = xapic_read_reg(APIC_LVR); /* * Loop forever HLTing and recording halts & wakes. Disable interrupts * each time around to minimize window between signaling the pending * halt to the sender vCPU and executing the halt. No need to disable on * first run as this vCPU executes first and the host waits for it to * signal going into first halt before starting the sender vCPU. Record * TPR and PPR for diagnostic purposes in case the test fails. */ for (;;) { data->halter_tpr = xapic_read_reg(APIC_TASKPRI); data->halter_ppr = xapic_read_reg(APIC_PROCPRI); data->hlt_count++; asm volatile("sti; hlt; cli"); data->wake_count++; } } /* * Runs on halter vCPU when IPI arrives. Write an arbitrary non-zero value to * enable diagnosing errant writes to the APIC access address backing page in * case of test failure. */ static void guest_ipi_handler(struct ex_regs *regs) { ipis_rcvd++; xapic_write_reg(APIC_EOI, 77); } static void sender_guest_code(struct test_data_page *data) { uint64_t last_wake_count; uint64_t last_hlt_count; uint64_t last_ipis_rcvd_count; uint32_t icr_val; uint32_t icr2_val; uint64_t tsc_start; verify_apic_base_addr(); xapic_enable(); /* * Init interrupt command register for sending IPIs * * Delivery mode=fixed, per SDM: * "Delivers the interrupt specified in the vector field to the target * processor." * * Destination mode=physical i.e. specify target by its local APIC * ID. This vCPU assumes that the halter vCPU has already started and * set data->halter_apic_id. */ icr_val = (APIC_DEST_PHYSICAL | APIC_DM_FIXED | IPI_VECTOR); icr2_val = SET_APIC_DEST_FIELD(data->halter_apic_id); data->icr = icr_val; data->icr2 = icr2_val; last_wake_count = data->wake_count; last_hlt_count = data->hlt_count; last_ipis_rcvd_count = ipis_rcvd; for (;;) { /* * Send IPI to halter vCPU. * First IPI can be sent unconditionally because halter vCPU * starts earlier. */ xapic_write_reg(APIC_ICR2, icr2_val); xapic_write_reg(APIC_ICR, icr_val); data->ipis_sent++; /* * Wait up to ~1 sec for halter to indicate that it has: * 1. Received the IPI * 2. Woken up from the halt * 3. Gone back into halt * Current CPUs typically run at 2.x Ghz which is ~2 * billion ticks per second. */ tsc_start = rdtsc(); while (rdtsc() - tsc_start < 2000000000) { if ((ipis_rcvd != last_ipis_rcvd_count) && (data->wake_count != last_wake_count) && (data->hlt_count != last_hlt_count)) break; } GUEST_ASSERT((ipis_rcvd != last_ipis_rcvd_count) && (data->wake_count != last_wake_count) && (data->hlt_count != last_hlt_count)); last_wake_count = data->wake_count; last_hlt_count = data->hlt_count; last_ipis_rcvd_count = ipis_rcvd; } } static void *vcpu_thread(void *arg) { struct thread_params *params = (struct thread_params *)arg; struct kvm_vcpu *vcpu = params->vcpu; struct ucall uc; int old; int r; r = pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, &old); TEST_ASSERT(r == 0, "pthread_setcanceltype failed on vcpu_id=%u with errno=%d", vcpu->id, r); fprintf(stderr, "vCPU thread running vCPU %u\n", vcpu->id); vcpu_run(vcpu); TEST_ASSERT_KVM_EXIT_REASON(vcpu, KVM_EXIT_IO); if (get_ucall(vcpu, &uc) == UCALL_ABORT) { TEST_ASSERT(false, "vCPU %u exited with error: %s.\n" "Sending vCPU sent %lu IPIs to halting vCPU\n" "Halting vCPU halted %lu times, woke %lu times, received %lu IPIs.\n" "Halter TPR=%#x PPR=%#x LVR=%#x\n" "Migrations attempted: %lu\n" "Migrations completed: %lu", vcpu->id, (const char *)uc.args[0], params->data->ipis_sent, params->data->hlt_count, params->data->wake_count, *params->pipis_rcvd, params->data->halter_tpr, params->data->halter_ppr, params->data->halter_lvr, params->data->migrations_attempted, params->data->migrations_completed); } return NULL; } static void cancel_join_vcpu_thread(pthread_t thread, struct kvm_vcpu *vcpu) { void *retval; int r; r = pthread_cancel(thread); TEST_ASSERT(r == 0, "pthread_cancel on vcpu_id=%d failed with errno=%d", vcpu->id, r); r = pthread_join(thread, &retval); TEST_ASSERT(r == 0, "pthread_join on vcpu_id=%d failed with errno=%d", vcpu->id, r); TEST_ASSERT(retval == PTHREAD_CANCELED, "expected retval=%p, got %p", PTHREAD_CANCELED, retval); } void do_migrations(struct test_data_page *data, int run_secs, int delay_usecs, uint64_t *pipis_rcvd) { long pages_not_moved; unsigned long nodemask = 0; unsigned long nodemasks[sizeof(nodemask) * 8]; int nodes = 0; time_t start_time, last_update, now; time_t interval_secs = 1; int i, r; int from, to; unsigned long bit; uint64_t hlt_count; uint64_t wake_count; uint64_t ipis_sent; fprintf(stderr, "Calling migrate_pages every %d microseconds\n", delay_usecs); /* Get set of first 64 numa nodes available */ r = get_mempolicy(NULL, &nodemask, sizeof(nodemask) * 8, 0, MPOL_F_MEMS_ALLOWED); TEST_ASSERT(r == 0, "get_mempolicy failed errno=%d", errno); fprintf(stderr, "Numa nodes found amongst first %lu possible nodes " "(each 1-bit indicates node is present): %#lx\n", sizeof(nodemask) * 8, nodemask); /* Init array of masks containing a single-bit in each, one for each * available node. migrate_pages called below requires specifying nodes * as bit masks. */ for (i = 0, bit = 1; i < sizeof(nodemask) * 8; i++, bit <<= 1) { if (nodemask & bit) { nodemasks[nodes] = nodemask & bit; nodes++; } } TEST_ASSERT(nodes > 1, "Did not find at least 2 numa nodes. Can't do migration"); fprintf(stderr, "Migrating amongst %d nodes found\n", nodes); from = 0; to = 1; start_time = time(NULL); last_update = start_time; ipis_sent = data->ipis_sent; hlt_count = data->hlt_count; wake_count = data->wake_count; while ((int)(time(NULL) - start_time) < run_secs) { data->migrations_attempted++; /* * migrate_pages with PID=0 will migrate all pages of this * process between the nodes specified as bitmasks. The page * backing the APIC access address belongs to this process * because it is allocated by KVM in the context of the * KVM_CREATE_VCPU ioctl. If that assumption ever changes this * test may break or give a false positive signal. */ pages_not_moved = migrate_pages(0, sizeof(nodemasks[from]), &nodemasks[from], &nodemasks[to]); if (pages_not_moved < 0) fprintf(stderr, "migrate_pages failed, errno=%d\n", errno); else if (pages_not_moved > 0) fprintf(stderr, "migrate_pages could not move %ld pages\n", pages_not_moved); else data->migrations_completed++; from = to; to++; if (to == nodes) to = 0; now = time(NULL); if (((now - start_time) % interval_secs == 0) && (now != last_update)) { last_update = now; fprintf(stderr, "%lu seconds: Migrations attempted=%lu completed=%lu, " "IPIs sent=%lu received=%lu, HLTs=%lu wakes=%lu\n", now - start_time, data->migrations_attempted, data->migrations_completed, data->ipis_sent, *pipis_rcvd, data->hlt_count, data->wake_count); TEST_ASSERT(ipis_sent != data->ipis_sent && hlt_count != data->hlt_count && wake_count != data->wake_count, "IPI, HLT and wake count have not increased " "in the last %lu seconds. " "HLTer is likely hung.", interval_secs); ipis_sent = data->ipis_sent; hlt_count = data->hlt_count; wake_count = data->wake_count; } usleep(delay_usecs); } } void get_cmdline_args(int argc, char *argv[], int *run_secs, bool *migrate, int *delay_usecs) { for (;;) { int opt = getopt(argc, argv, "s:d:m"); if (opt == -1) break; switch (opt) { case 's': *run_secs = parse_size(optarg); break; case 'm': *migrate = true; break; case 'd': *delay_usecs = parse_size(optarg); break; default: TEST_ASSERT(false, "Usage: -s <runtime seconds>. Default is %d seconds.\n" "-m adds calls to migrate_pages while vCPUs are running." " Default is no migrations.\n" "-d <delay microseconds> - delay between migrate_pages() calls." " Default is %d microseconds.", DEFAULT_RUN_SECS, DEFAULT_DELAY_USECS); } } } int main(int argc, char *argv[]) { int r; int wait_secs; const int max_halter_wait = 10; int run_secs = 0; int delay_usecs = 0; struct test_data_page *data; vm_vaddr_t test_data_page_vaddr; bool migrate = false; pthread_t threads[2]; struct thread_params params[2]; struct kvm_vm *vm; uint64_t *pipis_rcvd; get_cmdline_args(argc, argv, &run_secs, &migrate, &delay_usecs); if (run_secs <= 0) run_secs = DEFAULT_RUN_SECS; if (delay_usecs <= 0) delay_usecs = DEFAULT_DELAY_USECS; vm = vm_create_with_one_vcpu(¶ms[0].vcpu, halter_guest_code); vm_init_descriptor_tables(vm); vcpu_init_descriptor_tables(params[0].vcpu); vm_install_exception_handler(vm, IPI_VECTOR, guest_ipi_handler); virt_pg_map(vm, APIC_DEFAULT_GPA, APIC_DEFAULT_GPA); params[1].vcpu = vm_vcpu_add(vm, 1, sender_guest_code); test_data_page_vaddr = vm_vaddr_alloc_page(vm); data = addr_gva2hva(vm, test_data_page_vaddr); memset(data, 0, sizeof(*data)); params[0].data = data; params[1].data = data; vcpu_args_set(params[0].vcpu, 1, test_data_page_vaddr); vcpu_args_set(params[1].vcpu, 1, test_data_page_vaddr); pipis_rcvd = (uint64_t *)addr_gva2hva(vm, (uint64_t)&ipis_rcvd); params[0].pipis_rcvd = pipis_rcvd; params[1].pipis_rcvd = pipis_rcvd; /* Start halter vCPU thread and wait for it to execute first HLT. */ r = pthread_create(&threads[0], NULL, vcpu_thread, ¶ms[0]); TEST_ASSERT(r == 0, "pthread_create halter failed errno=%d", errno); fprintf(stderr, "Halter vCPU thread started\n"); wait_secs = 0; while ((wait_secs < max_halter_wait) && !data->hlt_count) { sleep(1); wait_secs++; } TEST_ASSERT(data->hlt_count, "Halter vCPU did not execute first HLT within %d seconds", max_halter_wait); fprintf(stderr, "Halter vCPU thread reported its APIC ID: %u after %d seconds.\n", data->halter_apic_id, wait_secs); r = pthread_create(&threads[1], NULL, vcpu_thread, ¶ms[1]); TEST_ASSERT(r == 0, "pthread_create sender failed errno=%d", errno); fprintf(stderr, "IPI sender vCPU thread started. Letting vCPUs run for %d seconds.\n", run_secs); if (!migrate) sleep(run_secs); else do_migrations(data, run_secs, delay_usecs, pipis_rcvd); /* * Cancel threads and wait for them to stop. */ cancel_join_vcpu_thread(threads[0], params[0].vcpu); cancel_join_vcpu_thread(threads[1], params[1].vcpu); fprintf(stderr, "Test successful after running for %d seconds.\n" "Sending vCPU sent %lu IPIs to halting vCPU\n" "Halting vCPU halted %lu times, woke %lu times, received %lu IPIs.\n" "Halter APIC ID=%#x\n" "Sender ICR value=%#x ICR2 value=%#x\n" "Halter TPR=%#x PPR=%#x LVR=%#x\n" "Migrations attempted: %lu\n" "Migrations completed: %lu\n", run_secs, data->ipis_sent, data->hlt_count, data->wake_count, *pipis_rcvd, data->halter_apic_id, data->icr, data->icr2, data->halter_tpr, data->halter_ppr, data->halter_lvr, data->migrations_attempted, data->migrations_completed); kvm_vm_free(vm); return 0; }
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