#include "kvmxx.hh" #include "exception.hh" #include "memmap.hh" #include "identity.hh" #include #include #include namespace { const int page_size = 4096; int64_t nr_total_pages = 256 * 1024; int64_t nr_slot_pages = 256 * 1024; // Return the current time in nanoseconds. uint64_t time_ns() { struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return ts.tv_sec * (uint64_t)1000000000 + ts.tv_nsec; } // Update nr_to_write pages selected from nr_pages pages. void write_mem(void* slot_head, int64_t nr_to_write, int64_t nr_pages) { char* var = static_cast(slot_head); int64_t interval = nr_pages / nr_to_write; for (int64_t i = 0; i < nr_to_write; ++i) { ++(*var); var += interval * page_size; } } // Let the guest update nr_to_write pages selected from nr_pages pages. void do_guest_write(kvm::vcpu& vcpu, void* slot_head, int64_t nr_to_write, int64_t nr_pages) { identity::vcpu guest_write_thread(vcpu, std::bind(write_mem, slot_head, nr_to_write, nr_pages)); vcpu.run(); } // Check how long it takes to update dirty log. void check_dirty_log(kvm::vcpu& vcpu, mem_slot& slot, void* slot_head) { slot.set_dirty_logging(true); slot.update_dirty_log(); for (int64_t i = 1; i <= nr_slot_pages; i *= 2) { do_guest_write(vcpu, slot_head, i, nr_slot_pages); uint64_t start_ns = time_ns(); int n = slot.update_dirty_log(); uint64_t end_ns = time_ns(); printf("get dirty log: %10lld ns for %10d dirty pages (expected %lld)\n", end_ns - start_ns, n, i); } slot.set_dirty_logging(false); } } void parse_options(int ac, char **av) { int opt; char *endptr; while ((opt = getopt(ac, av, "n:m:")) != -1) { switch (opt) { case 'n': errno = 0; nr_slot_pages = strtol(optarg, &endptr, 10); if (errno || endptr == optarg) { printf("dirty-log-perf: Invalid number: -n %s\n", optarg); exit(1); } if (*endptr == 'k' || *endptr == 'K') { nr_slot_pages *= 1024; } break; case 'm': errno = 0; nr_total_pages = strtol(optarg, &endptr, 10); if (errno || endptr == optarg) { printf("dirty-log-perf: Invalid number: -m %s\n", optarg); exit(1); } if (*endptr == 'k' || *endptr == 'K') { nr_total_pages *= 1024; } break; default: printf("dirty-log-perf: Invalid option\n"); exit(1); } } if (nr_slot_pages > nr_total_pages) { printf("dirty-log-perf: Invalid setting: slot %lld > mem %lld\n", nr_slot_pages, nr_total_pages); exit(1); } printf("dirty-log-perf: %lld slot pages / %lld mem pages\n", nr_slot_pages, nr_total_pages); } int test_main(int ac, char **av) { kvm::system sys; kvm::vm vm(sys); mem_map memmap(vm); parse_options(ac, av); void* mem_head; int64_t mem_size = nr_total_pages * page_size; if (posix_memalign(&mem_head, page_size, mem_size)) { printf("dirty-log-perf: Could not allocate guest memory.\n"); exit(1); } uint64_t mem_addr = reinterpret_cast(mem_head); identity::hole hole(mem_head, mem_size); identity::vm ident_vm(vm, memmap, hole); kvm::vcpu vcpu(vm, 0); uint64_t slot_size = nr_slot_pages * page_size; uint64_t next_size = mem_size - slot_size; uint64_t next_addr = mem_addr + slot_size; mem_slot slot(memmap, mem_addr, slot_size, mem_head); mem_slot other_slot(memmap, next_addr, next_size, (void *)next_addr); // pre-allocate shadow pages do_guest_write(vcpu, mem_head, nr_total_pages, nr_total_pages); check_dirty_log(vcpu, slot, mem_head); return 0; } int main(int ac, char** av) { return try_main(test_main, ac, av); }