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android / platform / external / stressapptest / b0114cb9f332db144f65291211ae65f7f0e814e6 / . / src / sat.cc
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// Copyright 2006 Google Inc. All Rights Reserved.
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// sat.cc : a stress test for stressful testing
// stressapptest (or SAT, from Stressful Application Test) is a test
// designed to stress the system, as well as provide a comprehensive
// memory interface test.
// stressapptest can be run using memory only, or using many system components.
#include <errno.h>
#include <pthread.h>
#include <signal.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <sys/stat.h>
#include <sys/times.h>
// #define __USE_GNU
// #define __USE_LARGEFILE64
#include <fcntl.h>
#include <list>
#include <string>
// This file must work with autoconf on its public version,
// so these includes are correct.
#include "disk_blocks.h"
#include "logger.h"
#include "os.h"
#include "sat.h"
#include "sattypes.h"
#include "worker.h"
// stressapptest versioning here.
#ifndef PACKAGE_VERSION
static const char* kVersion = "1.0.0";
#else
static const char* kVersion = PACKAGE_VERSION;
#endif
// Global stressapptest reference, for use by signal handler.
// This makes Sat objects not safe for multiple instances.
namespace {
Sat *g_sat = NULL;
// Signal handler for catching break or kill.
//
// This must be installed after g_sat is assigned and while there is a single
// thread.
//
// This must be uninstalled while there is only a single thread, and of course
// before g_sat is cleared or deleted.
void SatHandleBreak(int signal) {
g_sat->Break();
}
}
// Opens the logfile for writing if necessary
bool Sat::InitializeLogfile() {
// Open logfile.
if (use_logfile_) {
logfile_ = open(logfilename_,
O_WRONLY | O_CREAT | O_DSYNC,
S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH);
if (logfile_ < 0) {
printf("Fatal Error: cannot open file %s for logging\n",
logfilename_);
bad_status();
return false;
}
// We seek to the end once instead of opening in append mode because no
// other processes should be writing to it while this one exists.
if (lseek(logfile_, 0, SEEK_END) == -1) {
printf("Fatal Error: cannot seek to end of logfile (%s)\n",
logfilename_);
bad_status();
return false;
}
Logger::GlobalLogger()->SetLogFd(logfile_);
}
return true;
}
// Check that the environment is known and safe to run on.
// Return 1 if good, 0 if unsuppported.
bool Sat::CheckEnvironment() {
// Check that this is not a debug build. Debug builds lack
// enough performance to stress the system.
#if !defined NDEBUG
if (run_on_anything_) {
logprintf(1, "Log: Running DEBUG version of SAT, "
"with significantly reduced coverage.\n");
} else {
logprintf(0, "Process Error: Running DEBUG version of SAT, "
"with significantly reduced coverage.\n");
logprintf(0, "Log: Command line option '-A' bypasses this error.\n");
bad_status();
return false;
}
#elif !defined CHECKOPTS
#error Build system regression - COPTS disregarded.
#endif
// Use all CPUs if nothing is specified.
if (memory_threads_ == -1) {
memory_threads_ = os_->num_cpus();
logprintf(7, "Log: Defaulting to %d copy threads\n", memory_threads_);
}
// Use all memory if no size is specified.
if (size_mb_ == 0)
size_mb_ = os_->FindFreeMemSize() / kMegabyte;
size_ = static_cast<int64>(size_mb_) * kMegabyte;
// Autodetect file locations.
if (findfiles_ && (file_threads_ == 0)) {
// Get a space separated sting of disk locations.
list<string> locations = os_->FindFileDevices();
// Extract each one.
while (!locations.empty()) {
// Copy and remove the disk name.
string disk = locations.back();
locations.pop_back();
logprintf(12, "Log: disk at %s\n", disk.c_str());
file_threads_++;
filename_.push_back(disk + "/sat_disk.a");
file_threads_++;
filename_.push_back(disk + "/sat_disk.b");
}
}
// We'd better have some memory by this point.
if (size_ < 1) {
logprintf(0, "Process Error: No memory found to test.\n");
bad_status();
return false;
}
if (tag_mode_ && ((file_threads_ > 0) ||
(disk_threads_ > 0) ||
(net_threads_ > 0))) {
logprintf(0, "Process Error: Memory tag mode incompatible "
"with disk/network DMA.\n");
bad_status();
return false;
}
// If platform is 32 bit Xeon, floor memory size to multiple of 4.
if (address_mode_ == 32) {
size_mb_ = (size_mb_ / 4) * 4;
size_ = size_mb_ * kMegabyte;
logprintf(1, "Log: Flooring memory allocation to multiple of 4: %lldMB\n",
size_mb_);
}
// Check if this system is on the whitelist for supported systems.
if (!os_->IsSupported()) {
if (run_on_anything_) {
logprintf(1, "Log: Unsupported system. Running with reduced coverage.\n");
// This is ok, continue on.
} else {
logprintf(0, "Process Error: Unsupported system, "
"no error reporting available\n");
logprintf(0, "Log: Command line option '-A' bypasses this error.\n");
bad_status();
return false;
}
}
return true;
}
// Allocates memory to run the test on
bool Sat::AllocateMemory() {
// Allocate our test memory.
bool result = os_->AllocateTestMem(size_, paddr_base_);
if (!result) {
logprintf(0, "Process Error: failed to allocate memory\n");
bad_status();
return false;
}
return true;
}
// Sets up access to data patterns
bool Sat::InitializePatterns() {
// Initialize pattern data.
patternlist_ = new PatternList();
if (!patternlist_) {
logprintf(0, "Process Error: failed to allocate patterns\n");
bad_status();
return false;
}
if (!patternlist_->Initialize()) {
logprintf(0, "Process Error: failed to initialize patternlist\n");
bad_status();
return false;
}
return true;
}
// Get any valid page, no tag specified.
bool Sat::GetValid(struct page_entry *pe) {
return GetValid(pe, kDontCareTag);
}
// Fetch and return empty and full pages into the empty and full pools.
bool Sat::GetValid(struct page_entry *pe, int32 tag) {
bool result = false;
// Get valid page depending on implementation.
if (pe_q_implementation_ == SAT_FINELOCK)
result = finelock_q_->GetValid(pe, tag);
else if (pe_q_implementation_ == SAT_ONELOCK)
result = valid_->PopRandom(pe);
if (result) {
pe->addr = os_->PrepareTestMem(pe->offset, page_length_); // Map it.
// Tag this access and current pattern.
pe->ts = os_->GetTimestamp();
pe->lastpattern = pe->pattern;
return (pe->addr != 0); // Return success or failure.
}
return false;
}
bool Sat::PutValid(struct page_entry *pe) {
if (pe->addr != 0)
os_->ReleaseTestMem(pe->addr, pe->offset, page_length_); // Unmap the page.
pe->addr = 0;
// Put valid page depending on implementation.
if (pe_q_implementation_ == SAT_FINELOCK)
return finelock_q_->PutValid(pe);
else if (pe_q_implementation_ == SAT_ONELOCK)
return valid_->Push(pe);
else
return false;
}
// Get an empty page with any tag.
bool Sat::GetEmpty(struct page_entry *pe) {
return GetEmpty(pe, kDontCareTag);
}
bool Sat::GetEmpty(struct page_entry *pe, int32 tag) {
bool result = false;
// Get empty page depending on implementation.
if (pe_q_implementation_ == SAT_FINELOCK)
result = finelock_q_->GetEmpty(pe, tag);
else if (pe_q_implementation_ == SAT_ONELOCK)
result = empty_->PopRandom(pe);
if (result) {
pe->addr = os_->PrepareTestMem(pe->offset, page_length_); // Map it.
return (pe->addr != 0); // Return success or failure.
}
return false;
}
bool Sat::PutEmpty(struct page_entry *pe) {
if (pe->addr != 0)
os_->ReleaseTestMem(pe->addr, pe->offset, page_length_); // Unmap the page.
pe->addr = 0;
// Put empty page depending on implementation.
if (pe_q_implementation_ == SAT_FINELOCK)
return finelock_q_->PutEmpty(pe);
else if (pe_q_implementation_ == SAT_ONELOCK)
return empty_->Push(pe);
else
return false;
}
// Set up the bitmap of physical pages in case we want to see which pages were
// accessed under this run of SAT.
void Sat::AddrMapInit() {
if (!do_page_map_)
return;
// Find about how much physical mem is in the system.
// TODO(nsanders): Find some way to get the max
// and min phys addr in the system.
uint64 maxsize = os_->FindFreeMemSize() * 4;
sat_assert(maxsize != 0);
// Make a bitmask of this many pages. Assume that the memory is relatively
// zero based. This is true on x86, typically.
// This is one bit per page.
uint64 arraysize = maxsize / 4096 / 8;
unsigned char *bitmap = new unsigned char[arraysize];
sat_assert(bitmap);
// Mark every page as 0, not seen.
memset(bitmap, 0, arraysize);
page_bitmap_size_ = maxsize;
page_bitmap_ = bitmap;
}
// Add the 4k pages in this block to the array of pages SAT has seen.
void Sat::AddrMapUpdate(struct page_entry *pe) {
if (!do_page_map_)
return;
// Go through 4k page blocks.
uint64 arraysize = page_bitmap_size_ / 4096 / 8;
char *base = reinterpret_cast<char*>(pe->addr);
for (int i = 0; i < page_length_; i += 4096) {
uint64 paddr = os_->VirtualToPhysical(base + i);
uint32 offset = paddr / 4096 / 8;
unsigned char mask = 1 << ((paddr / 4096) % 8);
if (offset >= arraysize) {
logprintf(0, "Process Error: Physical address %#llx is "
"greater than expected %#llx.\n",
paddr, page_bitmap_size_);
sat_assert(0);
}
page_bitmap_[offset] |= mask;
}
}
// Print out the physical memory ranges that SAT has accessed.
void Sat::AddrMapPrint() {
if (!do_page_map_)
return;
uint64 pages = page_bitmap_size_ / 4096;
uint64 last_page = 0;
bool valid_range = false;
logprintf(4, "Log: Printing tested physical ranges.\n");
for (uint64 i = 0; i < pages; i ++) {
int offset = i / 8;
unsigned char mask = 1 << (i % 8);
bool touched = page_bitmap_[offset] & mask;
if (touched && !valid_range) {
valid_range = true;
last_page = i * 4096;
} else if (!touched && valid_range) {
valid_range = false;
logprintf(4, "Log: %#016llx - %#016llx\n", last_page, (i * 4096) - 1);
}
}
logprintf(4, "Log: Done printing physical ranges.\n");
}
// Initializes page lists and fills pages with data patterns.
bool Sat::InitializePages() {
int result = 1;
// Calculate needed page totals.
int64 neededpages = memory_threads_ +
invert_threads_ +
check_threads_ +
net_threads_ +
file_threads_;
// Empty-valid page ratio is adjusted depending on queue implementation.
// since fine-grain-locked queue keeps both valid and empty entries in the
// same queue and randomly traverse to find pages, the empty-valid ratio
// should be more even.
if (pe_q_implementation_ == SAT_FINELOCK)
freepages_ = pages_ / 5 * 2; // Mark roughly 2/5 of all pages as Empty.
else
freepages_ = (pages_ / 100) + (2 * neededpages);
if (freepages_ < neededpages) {
logprintf(0, "Process Error: freepages < neededpages.\n");
logprintf(1, "Stats: Total: %lld, Needed: %lld, Marked free: %lld\n",
static_cast<int64>(pages_),
static_cast<int64>(neededpages),
static_cast<int64>(freepages_));
bad_status();
return false;
}
if (freepages_ > pages_/2) {
logprintf(0, "Process Error: not enough pages for IO\n");
logprintf(1, "Stats: Total: %lld, Needed: %lld, Available: %lld\n",
static_cast<int64>(pages_),
static_cast<int64>(freepages_),
static_cast<int64>(pages_/2));
bad_status();
return false;
}
logprintf(12, "Log: Allocating pages, Total: %lld Free: %lld\n",
pages_,
freepages_);
// Initialize page locations.
for (int64 i = 0; i < pages_; i++) {
struct page_entry pe;
init_pe(&pe);
pe.offset = i * page_length_;
result &= PutEmpty(&pe);
}
if (!result) {
logprintf(0, "Process Error: while initializing empty_ list\n");
bad_status();
return false;
}
// Fill valid pages with test patterns.
// Use fill threads to do this.
WorkerStatus fill_status;
WorkerVector fill_vector;
logprintf(12, "Starting Fill threads: %d threads, %d pages\n",
fill_threads_, pages_);
// Initialize the fill threads.
for (int i = 0; i < fill_threads_; i++) {
FillThread *thread = new FillThread();
thread->InitThread(i, this, os_, patternlist_, &fill_status);
if (i != fill_threads_ - 1) {
logprintf(12, "Starting Fill Threads %d: %d pages\n",
i, pages_ / fill_threads_);
thread->SetFillPages(pages_ / fill_threads_);
// The last thread finishes up all the leftover pages.
} else {
logprintf(12, "Starting Fill Threads %d: %d pages\n",
i, pages_ - pages_ / fill_threads_ * i);
thread->SetFillPages(pages_ - pages_ / fill_threads_ * i);
}
fill_vector.push_back(thread);
}
// Spawn the fill threads.
fill_status.Initialize();
for (WorkerVector::const_iterator it = fill_vector.begin();
it != fill_vector.end(); ++it)
(*it)->SpawnThread();
// Reap the finished fill threads.
for (WorkerVector::const_iterator it = fill_vector.begin();
it != fill_vector.end(); ++it) {
(*it)->JoinThread();
if ((*it)->GetStatus() != 1) {
logprintf(0, "Thread %d failed with status %d at %.2f seconds\n",
(*it)->ThreadID(), (*it)->GetStatus(),
(*it)->GetRunDurationUSec() * 1.0/1000000);
bad_status();
return false;
}
delete (*it);
}
fill_vector.clear();
fill_status.Destroy();
logprintf(12, "Log: Done filling pages.\n");
logprintf(12, "Log: Allocating pages.\n");
AddrMapInit();
// Initialize page locations.
for (int64 i = 0; i < pages_; i++) {
struct page_entry pe;
// Only get valid pages with uninitialized tags here.
char buf[256];
if (GetValid(&pe, kInvalidTag)) {
int64 paddr = os_->VirtualToPhysical(pe.addr);
int32 region = os_->FindRegion(paddr);
os_->FindDimm(paddr, buf, sizeof(buf));
if (i < 256) {
logprintf(12, "Log: address: %#llx, %s\n", paddr, buf);
}
region_[region]++;
pe.paddr = paddr;
pe.tag = 1 << region;
region_mask_ |= pe.tag;
// Generate a physical region map
AddrMapUpdate(&pe);
// Note: this does not allocate free pages among all regions
// fairly. However, with large enough (thousands) random number
// of pages being marked free in each region, the free pages
// count in each region end up pretty balanced.
if (i < freepages_) {
result &= PutEmpty(&pe);
} else {
result &= PutValid(&pe);
}
} else {
logprintf(0, "Log: didn't tag all pages. %d - %d = %d\n",
pages_, i, pages_ - i);
return false;
}
}
logprintf(12, "Log: Done allocating pages.\n");
AddrMapPrint();
for (int i = 0; i < 32; i++) {
if (region_mask_ & (1 << i)) {
region_count_++;
logprintf(12, "Log: Region %d: %d.\n", i, region_[i]);
}
}
logprintf(5, "Log: Region mask: 0x%x\n", region_mask_);
return true;
}
// Print SAT version info.
bool Sat::PrintVersion() {
logprintf(1, "Stats: SAT revision %s, %d bit binary\n",
kVersion, address_mode_);
logprintf(5, "Log: %s from %s\n", Timestamp(), BuildChangelist());
return true;
}
// Initializes the resources that SAT needs to run.
// This needs to be called before Run(), and after ParseArgs().
// Returns true on success, false on error, and will exit() on help message.
bool Sat::Initialize() {
g_sat = this;
// Initializes sync'd log file to ensure output is saved.
if (!InitializeLogfile())
return false;
Logger::GlobalLogger()->StartThread();
logprintf(5, "Log: Commandline - %s\n", cmdline_.c_str());
PrintVersion();
std::map<std::string, std::string> options;
GoogleOsOptions(&options);
// Initialize OS/Hardware interface.
os_ = OsLayerFactory(options);
if (!os_) {
bad_status();
return false;
}
if (min_hugepages_mbytes_ > 0)
os_->SetMinimumHugepagesSize(min_hugepages_mbytes_ * kMegabyte);
if (!os_->Initialize()) {
logprintf(0, "Process Error: Failed to initialize OS layer\n");
bad_status();
delete os_;
return false;
}
// Checks that OS/Build/Platform is supported.
if (!CheckEnvironment())
return false;
if (error_injection_)
os_->set_error_injection(true);
// Run SAT in monitor only mode, do not continue to allocate resources.
if (monitor_mode_) {
logprintf(5, "Log: Running in monitor-only mode. "
"Will not allocate any memory nor run any stress test. "
"Only polling ECC errors.\n");
return true;
}
// Allocate the memory to test.
if (!AllocateMemory())
return false;
logprintf(5, "Stats: Starting SAT, %dM, %d seconds\n",
static_cast<int>(size_/kMegabyte),
runtime_seconds_);
if (!InitializePatterns())
return false;
// Initialize memory allocation.
pages_ = size_ / page_length_;
// Allocate page queue depending on queue implementation switch.
if (pe_q_implementation_ == SAT_FINELOCK) {
finelock_q_ = new FineLockPEQueue(pages_, page_length_);
if (finelock_q_ == NULL)
return false;
finelock_q_->set_os(os_);
os_->set_err_log_callback(finelock_q_->get_err_log_callback());
} else if (pe_q_implementation_ == SAT_ONELOCK) {
empty_ = new PageEntryQueue(pages_);
valid_ = new PageEntryQueue(pages_);
if ((empty_ == NULL) || (valid_ == NULL))
return false;
}
if (!InitializePages()) {
logprintf(0, "Process Error: Initialize Pages failed\n");
return false;
}
return true;
}
// Constructor and destructor.
Sat::Sat() {
// Set defaults, command line might override these.
runtime_seconds_ = 20;
page_length_ = kSatPageSize;
disk_pages_ = kSatDiskPage;
pages_ = 0;
size_mb_ = 0;
size_ = size_mb_ * kMegabyte;
min_hugepages_mbytes_ = 0;
freepages_ = 0;
paddr_base_ = 0;
user_break_ = false;
verbosity_ = 8;
Logger::GlobalLogger()->SetVerbosity(verbosity_);
strict_ = 1;
warm_ = 0;
run_on_anything_ = 0;
use_logfile_ = 0;
logfile_ = 0;
// Detect 32/64 bit binary.
void *pvoid = 0;
address_mode_ = sizeof(pvoid) * 8;
error_injection_ = false;
crazy_error_injection_ = false;
max_errorcount_ = 0; // Zero means no early exit.
stop_on_error_ = false;
error_poll_ = true;
findfiles_ = false;
do_page_map_ = false;
page_bitmap_ = 0;
page_bitmap_size_ = 0;
// Cache coherency data initialization.
cc_test_ = false; // Flag to trigger cc threads.
cc_cacheline_count_ = 2; // Two datastructures of cache line size.
cc_inc_count_ = 1000; // Number of times to increment the shared variable.
cc_cacheline_data_ = 0; // Cache Line size datastructure.
sat_assert(0 == pthread_mutex_init(&worker_lock_, NULL));
file_threads_ = 0;
net_threads_ = 0;
listen_threads_ = 0;
// Default to autodetect number of cpus, and run that many threads.
memory_threads_ = -1;
invert_threads_ = 0;
fill_threads_ = 8;
check_threads_ = 0;
cpu_stress_threads_ = 0;
disk_threads_ = 0;
total_threads_ = 0;
region_mask_ = 0;
region_count_ = 0;
for (int i = 0; i < 32; i++) {
region_[i] = 0;
}
region_mode_ = 0;
errorcount_ = 0;
statuscount_ = 0;
valid_ = 0;
empty_ = 0;
finelock_q_ = 0;
// Default to use fine-grain lock for better performance.
pe_q_implementation_ = SAT_FINELOCK;
os_ = 0;
patternlist_ = 0;
logfilename_[0] = 0;
read_block_size_ = 512;
write_block_size_ = -1;
segment_size_ = -1;
cache_size_ = -1;
blocks_per_segment_ = -1;
read_threshold_ = -1;
write_threshold_ = -1;
non_destructive_ = 1;
monitor_mode_ = 0;
tag_mode_ = 0;
random_threads_ = 0;
pause_delay_ = 600;
pause_duration_ = 15;
}
// Destructor.
Sat::~Sat() {
// We need to have called Cleanup() at this point.
// We should probably enforce this.
}
#define ARG_KVALUE(argument, variable, value) \
if (!strcmp(argv[i], argument)) { \
variable = value; \
continue; \
}
#define ARG_IVALUE(argument, variable) \
if (!strcmp(argv[i], argument)) { \
i++; \
if (i < argc) \
variable = strtoull(argv[i], NULL, 0); \
continue; \
}
#define ARG_SVALUE(argument, variable) \
if (!strcmp(argv[i], argument)) { \
i++; \
if (i < argc) \
snprintf(variable, sizeof(variable), "%s", argv[i]); \
continue; \
}
// Configures SAT from command line arguments.
// This will call exit() given a request for
// self-documentation or unexpected args.
bool Sat::ParseArgs(int argc, char **argv) {
int i;
uint64 filesize = page_length_ * disk_pages_;
// Parse each argument.
for (i = 1; i < argc; i++) {
// Switch to fall back to corase-grain-lock queue. (for benchmarking)
ARG_KVALUE("--coarse_grain_lock", pe_q_implementation_, SAT_ONELOCK);
// Set number of megabyte to use.
ARG_IVALUE("-M", size_mb_);
// Set minimum megabytes of hugepages to require.
ARG_IVALUE("-H", min_hugepages_mbytes_);
// Set number of seconds to run.
ARG_IVALUE("-s", runtime_seconds_);
// Set number of memory copy threads.
ARG_IVALUE("-m", memory_threads_);
// Set number of memory invert threads.
ARG_IVALUE("-i", invert_threads_);
// Set number of check-only threads.
ARG_IVALUE("-c", check_threads_);
// Set number of cache line size datastructures.
ARG_IVALUE("--cc_inc_count", cc_inc_count_);
// Set number of cache line size datastructures
ARG_IVALUE("--cc_line_count", cc_cacheline_count_);
// Flag set when cache coherency tests need to be run
ARG_KVALUE("--cc_test", cc_test_, 1);
// Set number of CPU stress threads.
ARG_IVALUE("-C", cpu_stress_threads_);
// Set logfile name.
ARG_SVALUE("-l", logfilename_);
// Verbosity level.
ARG_IVALUE("-v", verbosity_);
// Set maximum number of errors to collect. Stop running after this many.
ARG_IVALUE("--max_errors", max_errorcount_);
// Set pattern block size.
ARG_IVALUE("-p", page_length_);
// Set pattern block size.
ARG_IVALUE("--filesize", filesize);
// NUMA options.
ARG_KVALUE("--local_numa", region_mode_, kLocalNuma);
ARG_KVALUE("--remote_numa", region_mode_, kRemoteNuma);
// Autodetect tempfile locations.
ARG_KVALUE("--findfiles", findfiles_, 1);
// Inject errors to force miscompare code paths
ARG_KVALUE("--force_errors", error_injection_, true);
ARG_KVALUE("--force_errors_like_crazy", crazy_error_injection_, true);
if (crazy_error_injection_)
error_injection_ = true;
// Stop immediately on any arror, for debugging HW problems.
ARG_KVALUE("--stop_on_errors", stop_on_error_, 1);
// Don't use internal error polling, allow external detection.
ARG_KVALUE("--no_errors", error_poll_, 0);
// Never check data as you go.
ARG_KVALUE("-F", strict_, 0);
// Warm the cpu as you go.
ARG_KVALUE("-W", warm_, 1);
// Allow runnign on unknown systems with base unimplemented OsLayer
ARG_KVALUE("-A", run_on_anything_, 1);
// Size of read blocks for disk test.
ARG_IVALUE("--read-block-size", read_block_size_);
// Size of write blocks for disk test.
ARG_IVALUE("--write-block-size", write_block_size_);
// Size of segment for disk test.
ARG_IVALUE("--segment-size", segment_size_);
// Size of disk cache size for disk test.
ARG_IVALUE("--cache-size", cache_size_);
// Number of blocks to test per segment.
ARG_IVALUE("--blocks-per-segment", blocks_per_segment_);
// Maximum time a block read should take before warning.
ARG_IVALUE("--read-threshold", read_threshold_);
// Maximum time a block write should take before warning.
ARG_IVALUE("--write-threshold", write_threshold_);
// Do not write anything to disk in the disk test.
ARG_KVALUE("--destructive", non_destructive_, 0);
// Run SAT in monitor mode. No test load at all.
ARG_KVALUE("--monitor_mode", monitor_mode_, true);
// Run SAT in address mode. Tag all cachelines by virt addr.
ARG_KVALUE("--tag_mode", tag_mode_, true);
// Dump range map of tested pages..
ARG_KVALUE("--do_page_map", do_page_map_, true);
// Specify the physical address base to test.
ARG_IVALUE("--paddr_base", paddr_base_);
// Specify the frequency for power spikes.
ARG_IVALUE("--pause_delay", pause_delay_);
// Specify the duration of each pause (for power spikes).
ARG_IVALUE("--pause_duration", pause_duration_);
// Disk device names
if (!strcmp(argv[i], "-d")) {
i++;
if (i < argc) {
disk_threads_++;
diskfilename_.push_back(string(argv[i]));
blocktables_.push_back(new DiskBlockTable());
}
continue;
}
// Set number of disk random threads for each disk write thread.
ARG_IVALUE("--random-threads", random_threads_);
// Set a tempfile to use in a file thread.
if (!strcmp(argv[i], "-f")) {
i++;
if (i < argc) {
file_threads_++;
filename_.push_back(string(argv[i]));
}
continue;
}
// Set a hostname to use in a network thread.
if (!strcmp(argv[i], "-n")) {
i++;
if (i < argc) {
net_threads_++;
ipaddrs_.push_back(string(argv[i]));
}
continue;
}
// Run threads that listen for incoming SAT net connections.
ARG_KVALUE("--listen", listen_threads_, 1);
if (CheckGoogleSpecificArgs(argc, argv, &i)) {
continue;
}
// Default:
PrintVersion();
PrintHelp();
if (strcmp(argv[i], "-h") && strcmp(argv[i], "--help")) {
printf("\n Unknown argument %s\n", argv[i]);
bad_status();
exit(1);
}
// Forget it, we printed the help, just bail.
// We don't want to print test status, or any log parser stuff.
exit(0);
}
Logger::GlobalLogger()->SetVerbosity(verbosity_);
// Update relevant data members with parsed input.
// Translate MB into bytes.
size_ = static_cast<int64>(size_mb_) * kMegabyte;
// Set logfile flag.
if (strcmp(logfilename_, ""))
use_logfile_ = 1;
// Checks valid page length.
if (page_length_ &&
!(page_length_ & (page_length_ - 1)) &&
(page_length_ > 1023)) {
// Prints if we have changed from default.
if (page_length_ != kSatPageSize)
logprintf(12, "Log: Updating page size to %d\n", page_length_);
} else {
// Revert to default page length.
logprintf(6, "Process Error: "
"Invalid page size %d\n", page_length_);
page_length_ = kSatPageSize;
return false;
}
// Set disk_pages_ if filesize or page size changed.
if (filesize != static_cast<uint64>(page_length_) *
static_cast<uint64>(disk_pages_)) {
disk_pages_ = filesize / page_length_;
if (disk_pages_ == 0)
disk_pages_ = 1;
}
// Print each argument.
for (int i = 0; i < argc; i++) {
if (i)
cmdline_ += " ";
cmdline_ += argv[i];
}
return true;
}
void Sat::PrintHelp() {
printf("Usage: ./sat(32|64) [options]\n"
" -M mbytes megabytes of ram to test\n"
" -H mbytes minimum megabytes of hugepages to require\n"
" -s seconds number of seconds to run\n"
" -m threads number of memory copy threads to run\n"
" -i threads number of memory invert threads to run\n"
" -C threads number of memory CPU stress threads to run\n"
" --findfiles find locations to do disk IO automatically\n"
" -d device add a direct write disk thread with block "
"device (or file) 'device'\n"
" -f filename add a disk thread with "
"tempfile 'filename'\n"
" -l logfile log output to file 'logfile'\n"
" --max_errors n exit early after finding 'n' errors\n"
" -v level verbosity (0-20), default is 8\n"
" -W Use more CPU-stressful memory copy\n"
" -A run in degraded mode on incompatible systems\n"
" -p pagesize size in bytes of memory chunks\n"
" --filesize size size of disk IO tempfiles\n"
" -n ipaddr add a network thread connecting to "
"system at 'ipaddr'\n"
" --listen run a thread to listen for and respond "
"to network threads.\n"
" --no_errors run without checking for ECC or other errors\n"
" --force_errors inject false errors to test error handling\n"
" --force_errors_like_crazy inject a lot of false errors "
"to test error handling\n"
" -F don't result check each transaction\n"
" --stop_on_errors Stop after finding the first error.\n"
" --read-block-size size of block for reading (-d)\n"
" --write-block-size size of block for writing (-d). If not "
"defined, the size of block for writing will be defined as the "
"size of block for reading\n"
" --segment-size size of segments to split disk into (-d)\n"
" --cache-size size of disk cache (-d)\n"
" --blocks-per-segment number of blocks to read/write per "
"segment per iteration (-d)\n"
" --read-threshold maximum time (in us) a block read should "
"take (-d)\n"
" --write-threshold maximum time (in us) a block write "
"should take (-d)\n"
" --random-threads number of random threads for each disk "
"write thread (-d)\n"
" --destructive write/wipe disk partition (-d)\n"
" --monitor_mode only do ECC error polling, no stress load.\n"
" --cc_test do the cache coherency testing\n"
" --cc_inc_count number of times to increment the "
"cacheline's member\n"
" --cc_line_count number of cache line sized datastructures "
"to allocate for the cache coherency threads to operate\n"
" --paddr_base allocate memory starting from this address\n"
" --pause_delay delay (in seconds) between power spikes\n"
" --pause_duration duration (in seconds) of each pause\n"
" --local_numa : choose memory regions associated with "
"each CPU to be tested by that CPU\n"
" --remote_numa : choose memory regions not associated with "
"each CPU to be tested by that CPU\n");
}
bool Sat::CheckGoogleSpecificArgs(int argc, char **argv, int *i) {
// Do nothing, no google-specific argument on public stressapptest
return false;
}
void Sat::GoogleOsOptions(std::map<std::string, std::string> *options) {
// Do nothing, no OS-specific argument on public stressapptest
}
// Launch the SAT task threads. Returns 0 on error.
void Sat::InitializeThreads() {
// Memory copy threads.
AcquireWorkerLock();
logprintf(12, "Log: Starting worker threads\n");
WorkerVector *memory_vector = new WorkerVector();
// Error polling thread.
// This may detect ECC corrected errors, disk problems, or
// any other errors normally hidden from userspace.
WorkerVector *error_vector = new WorkerVector();
if (error_poll_) {
ErrorPollThread *thread = new ErrorPollThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
error_vector->insert(error_vector->end(), thread);
} else {
logprintf(5, "Log: Skipping error poll thread due to --no_errors flag\n");
}
workers_map_.insert(make_pair(kErrorType, error_vector));
// Only start error poll threads for monitor-mode SAT,
// skip all other types of worker threads.
if (monitor_mode_) {
ReleaseWorkerLock();
return;
}
for (int i = 0; i < memory_threads_; i++) {
CopyThread *thread = new CopyThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&power_spike_status_);
if ((region_count_ > 1) && (region_mode_)) {
int32 region = region_find(i % region_count_);
cpu_set_t *cpuset = os_->FindCoreMask(region);
sat_assert(cpuset);
if (region_mode_ == kLocalNuma) {
// Choose regions associated with this CPU.
thread->set_cpu_mask(cpuset);
thread->set_tag(1 << region);
} else if (region_mode_ == kRemoteNuma) {
// Choose regions not associated with this CPU..
thread->set_cpu_mask(cpuset);
thread->set_tag(region_mask_ & ~(1 << region));
}
} else {
cpu_set_t available_cpus;
thread->AvailableCpus(&available_cpus);
int cores = cpuset_count(&available_cpus);
// Don't restrict thread location if we have more than one
// thread per core. Not so good for performance.
if (cpu_stress_threads_ + memory_threads_ <= cores) {
// Place a thread on alternating cores first.
// This assures interleaved core use with no overlap.
int nthcore = i;
int nthbit = (((2 * nthcore) % cores) +
(((2 * nthcore) / cores) % 2)) % cores;
cpu_set_t all_cores;
cpuset_set_ab(&all_cores, 0, cores);
if (!cpuset_isequal(&available_cpus, &all_cores)) {
// We are assuming the bits are contiguous.
// Complain if this is not so.
logprintf(0, "Log: cores = %s, expected %s\n",
cpuset_format(&available_cpus).c_str(),
cpuset_format(&all_cores).c_str());
}
// Set thread affinity.
thread->set_cpu_mask_to_cpu(nthbit);
}
}
memory_vector->insert(memory_vector->end(), thread);
}
workers_map_.insert(make_pair(kMemoryType, memory_vector));
// File IO threads.
WorkerVector *fileio_vector = new WorkerVector();
for (int i = 0; i < file_threads_; i++) {
FileThread *thread = new FileThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&power_spike_status_);
thread->SetFile(filename_[i].c_str());
// Set disk threads high priority. They don't take much processor time,
// but blocking them will delay disk IO.
thread->SetPriority(WorkerThread::High);
fileio_vector->insert(fileio_vector->end(), thread);
}
workers_map_.insert(make_pair(kFileIOType, fileio_vector));
// Net IO threads.
WorkerVector *netio_vector = new WorkerVector();
WorkerVector *netslave_vector = new WorkerVector();
if (listen_threads_ > 0) {
// Create a network slave thread. This listens for connections.
NetworkListenThread *thread = new NetworkListenThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
netslave_vector->insert(netslave_vector->end(), thread);
}
for (int i = 0; i < net_threads_; i++) {
NetworkThread *thread = new NetworkThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
thread->SetIP(ipaddrs_[i].c_str());
netio_vector->insert(netio_vector->end(), thread);
}
workers_map_.insert(make_pair(kNetIOType, netio_vector));
workers_map_.insert(make_pair(kNetSlaveType, netslave_vector));
// Result check threads.
WorkerVector *check_vector = new WorkerVector();
for (int i = 0; i < check_threads_; i++) {
CheckThread *thread = new CheckThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
check_vector->insert(check_vector->end(), thread);
}
workers_map_.insert(make_pair(kCheckType, check_vector));
// Memory invert threads.
logprintf(12, "Log: Starting invert threads\n");
WorkerVector *invert_vector = new WorkerVector();
for (int i = 0; i < invert_threads_; i++) {
InvertThread *thread = new InvertThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
invert_vector->insert(invert_vector->end(), thread);
}
workers_map_.insert(make_pair(kInvertType, invert_vector));
// Disk stress threads.
WorkerVector *disk_vector = new WorkerVector();
WorkerVector *random_vector = new WorkerVector();
logprintf(12, "Log: Starting disk stress threads\n");
for (int i = 0; i < disk_threads_; i++) {
// Creating write threads
DiskThread *thread = new DiskThread(blocktables_[i]);
thread->InitThread(total_threads_++, this, os_, patternlist_,
&power_spike_status_);
thread->SetDevice(diskfilename_[i].c_str());
if (thread->SetParameters(read_block_size_, write_block_size_,
segment_size_, cache_size_,
blocks_per_segment_,
read_threshold_, write_threshold_,
non_destructive_)) {
disk_vector->insert(disk_vector->end(), thread);
} else {
logprintf(12, "Log: DiskThread::SetParameters() failed\n");
delete thread;
}
for (int j = 0; j < random_threads_; j++) {
// Creating random threads
RandomDiskThread *rthread = new RandomDiskThread(blocktables_[i]);
rthread->InitThread(total_threads_++, this, os_, patternlist_,
&power_spike_status_);
rthread->SetDevice(diskfilename_[i].c_str());
if (rthread->SetParameters(read_block_size_, write_block_size_,
segment_size_, cache_size_,
blocks_per_segment_,
read_threshold_, write_threshold_,
non_destructive_)) {
random_vector->insert(random_vector->end(), rthread);
} else {
logprintf(12, "Log: RandomDiskThread::SetParameters() failed\n");
delete rthread;
}
}
}
workers_map_.insert(make_pair(kDiskType, disk_vector));
workers_map_.insert(make_pair(kRandomDiskType, random_vector));
// CPU stress threads.
WorkerVector *cpu_vector = new WorkerVector();
logprintf(12, "Log: Starting cpu stress threads\n");
for (int i = 0; i < cpu_stress_threads_; i++) {
CpuStressThread *thread = new CpuStressThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
// Don't restrict thread location if we have more than one
// thread per core. Not so good for performance.
cpu_set_t available_cpus;
thread->AvailableCpus(&available_cpus);
int cores = cpuset_count(&available_cpus);
if (cpu_stress_threads_ + memory_threads_ <= cores) {
// Place a thread on alternating cores first.
// Go in reverse order for CPU stress threads. This assures interleaved
// core use with no overlap.
int nthcore = (cores - 1) - i;
int nthbit = (((2 * nthcore) % cores) +
(((2 * nthcore) / cores) % 2)) % cores;
cpu_set_t all_cores;
cpuset_set_ab(&all_cores, 0, cores);
if (!cpuset_isequal(&available_cpus, &all_cores)) {
logprintf(0, "Log: cores = %s, expected %s\n",
cpuset_format(&available_cpus).c_str(),
cpuset_format(&all_cores).c_str());
}
// Set thread affinity.
thread->set_cpu_mask_to_cpu(nthbit);
}
cpu_vector->insert(cpu_vector->end(), thread);
}
workers_map_.insert(make_pair(kCPUType, cpu_vector));
// CPU Cache Coherency Threads - one for each core available.
if (cc_test_) {
WorkerVector *cc_vector = new WorkerVector();
logprintf(12, "Log: Starting cpu cache coherency threads\n");
// Allocate the shared datastructure to be worked on by the threads.
cc_cacheline_data_ = reinterpret_cast<cc_cacheline_data*>(
malloc(sizeof(cc_cacheline_data) * cc_cacheline_count_));
sat_assert(cc_cacheline_data_ != NULL);
// Initialize the strucutre.
memset(cc_cacheline_data_, 0,
sizeof(cc_cacheline_data) * cc_cacheline_count_);
int num_cpus = CpuCount();
// Allocate all the nums once so that we get a single chunk
// of contiguous memory.
int *num;
int err_result = posix_memalign(
reinterpret_cast<void**>(&num),
kCacheLineSize, sizeof(*num) * num_cpus * cc_cacheline_count_);
sat_assert(err_result == 0);
int cline;
for (cline = 0; cline < cc_cacheline_count_; cline++) {
memset(num, 0, sizeof(num_cpus) * num_cpus);
cc_cacheline_data_[cline].num = num;
num += num_cpus;
}
int tnum;
for (tnum = 0; tnum < num_cpus; tnum++) {
CpuCacheCoherencyThread *thread =
new CpuCacheCoherencyThread(cc_cacheline_data_, cc_cacheline_count_,
tnum, cc_inc_count_);
thread->InitThread(total_threads_++, this, os_, patternlist_,
&continuous_status_);
// Pin the thread to a particular core.
thread->set_cpu_mask_to_cpu(tnum);
// Insert the thread into the vector.
cc_vector->insert(cc_vector->end(), thread);
}
workers_map_.insert(make_pair(kCCType, cc_vector));
}
ReleaseWorkerLock();
}
// Return the number of cpus actually present in the machine.
int Sat::CpuCount() {
return sysconf(_SC_NPROCESSORS_CONF);
}
// Notify and reap worker threads.
void Sat::JoinThreads() {
logprintf(12, "Log: Joining worker threads\n");
power_spike_status_.StopWorkers();
continuous_status_.StopWorkers();
AcquireWorkerLock();
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
logprintf(12, "Log: Joining thread %d\n", (*it)->ThreadID());
(*it)->JoinThread();
}
}
ReleaseWorkerLock();
QueueStats();
// Finish up result checking.
// Spawn 4 check threads to minimize check time.
logprintf(12, "Log: Finished countdown, begin to result check\n");
WorkerStatus reap_check_status;
WorkerVector reap_check_vector;
// No need for check threads for monitor mode.
if (!monitor_mode_) {
// Initialize the check threads.
for (int i = 0; i < fill_threads_; i++) {
CheckThread *thread = new CheckThread();
thread->InitThread(total_threads_++, this, os_, patternlist_,
&reap_check_status);
logprintf(12, "Log: Finished countdown, begin to result check\n");
reap_check_vector.push_back(thread);
}
}
reap_check_status.Initialize();
// Check threads should be marked to stop ASAP.
reap_check_status.StopWorkers();
// Spawn the check threads.
for (WorkerVector::const_iterator it = reap_check_vector.begin();
it != reap_check_vector.end(); ++it) {
logprintf(12, "Log: Spawning thread %d\n", (*it)->ThreadID());
(*it)->SpawnThread();
}
// Join the check threads.
for (WorkerVector::const_iterator it = reap_check_vector.begin();
it != reap_check_vector.end(); ++it) {
logprintf(12, "Log: Joining thread %d\n", (*it)->ThreadID());
(*it)->JoinThread();
}
// Reap all children. Stopped threads should have already ended.
// Result checking threads will end when they have finished
// result checking.
logprintf(12, "Log: Join all outstanding threads\n");
// Find all errors.
errorcount_ = GetTotalErrorCount();
AcquireWorkerLock();
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
logprintf(12, "Log: Reaping thread status %d\n", (*it)->ThreadID());
if ((*it)->GetStatus() != 1) {
logprintf(0, "Process Error: Thread %d failed with status %d at "
"%.2f seconds\n",
(*it)->ThreadID(), (*it)->GetStatus(),
(*it)->GetRunDurationUSec()*1.0/1000000);
bad_status();
}
int priority = 12;
if ((*it)->GetErrorCount())
priority = 5;
logprintf(priority, "Log: Thread %d found %lld hardware incidents\n",
(*it)->ThreadID(), (*it)->GetErrorCount());
}
}
ReleaseWorkerLock();
// Add in any errors from check threads.
for (WorkerVector::const_iterator it = reap_check_vector.begin();
it != reap_check_vector.end(); ++it) {
logprintf(12, "Log: Reaping thread status %d\n", (*it)->ThreadID());
if ((*it)->GetStatus() != 1) {
logprintf(0, "Process Error: Thread %d failed with status %d at "
"%.2f seconds\n",
(*it)->ThreadID(), (*it)->GetStatus(),
(*it)->GetRunDurationUSec()*1.0/1000000);
bad_status();
}
errorcount_ += (*it)->GetErrorCount();
int priority = 12;
if ((*it)->GetErrorCount())
priority = 5;
logprintf(priority, "Log: Thread %d found %lld hardware incidents\n",
(*it)->ThreadID(), (*it)->GetErrorCount());
delete (*it);
}
reap_check_vector.clear();
reap_check_status.Destroy();
}
// Print queuing information.
void Sat::QueueStats() {
finelock_q_->QueueAnalysis();
}
void Sat::AnalysisAllStats() {
float max_runtime_sec = 0.;
float total_data = 0.;
float total_bandwidth = 0.;
float thread_runtime_sec = 0.;
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
thread_runtime_sec = (*it)->GetRunDurationUSec()*1.0/1000000;
total_data += (*it)->GetMemoryCopiedData();
total_data += (*it)->GetDeviceCopiedData();
if (thread_runtime_sec > max_runtime_sec) {
max_runtime_sec = thread_runtime_sec;
}
}
}
total_bandwidth = total_data / max_runtime_sec;
logprintf(0, "Stats: Completed: %.2fM in %.2fs %.2fMB/s, "
"with %d hardware incidents, %d errors\n",
total_data,
max_runtime_sec,
total_bandwidth,
errorcount_,
statuscount_);
}
void Sat::MemoryStats() {
float memcopy_data = 0.;
float memcopy_bandwidth = 0.;
WorkerMap::const_iterator mem_it = workers_map_.find(
static_cast<int>(kMemoryType));
WorkerMap::const_iterator file_it = workers_map_.find(
static_cast<int>(kFileIOType));
sat_assert(mem_it != workers_map_.end());
sat_assert(file_it != workers_map_.end());
for (WorkerVector::const_iterator it = mem_it->second->begin();
it != mem_it->second->end(); ++it) {
memcopy_data += (*it)->GetMemoryCopiedData();
memcopy_bandwidth += (*it)->GetMemoryBandwidth();
}
for (WorkerVector::const_iterator it = file_it->second->begin();
it != file_it->second->end(); ++it) {
memcopy_data += (*it)->GetMemoryCopiedData();
memcopy_bandwidth += (*it)->GetMemoryBandwidth();
}
GoogleMemoryStats(&memcopy_data, &memcopy_bandwidth);
logprintf(4, "Stats: Memory Copy: %.2fM at %.2fMB/s\n",
memcopy_data,
memcopy_bandwidth);
}
void Sat::GoogleMemoryStats(float *memcopy_data,
float *memcopy_bandwidth) {
// Do nothing, should be implemented by subclasses.
}
void Sat::FileStats() {
float file_data = 0.;
float file_bandwidth = 0.;
WorkerMap::const_iterator file_it = workers_map_.find(
static_cast<int>(kFileIOType));
sat_assert(file_it != workers_map_.end());
for (WorkerVector::const_iterator it = file_it->second->begin();
it != file_it->second->end(); ++it) {
file_data += (*it)->GetDeviceCopiedData();
file_bandwidth += (*it)->GetDeviceBandwidth();
}
logprintf(4, "Stats: File Copy: %.2fM at %.2fMB/s\n",
file_data,
file_bandwidth);
}
void Sat::CheckStats() {
float check_data = 0.;
float check_bandwidth = 0.;
WorkerMap::const_iterator check_it = workers_map_.find(
static_cast<int>(kCheckType));
sat_assert(check_it != workers_map_.end());
for (WorkerVector::const_iterator it = check_it->second->begin();
it != check_it->second->end(); ++it) {
check_data += (*it)->GetMemoryCopiedData();
check_bandwidth += (*it)->GetMemoryBandwidth();
}
logprintf(4, "Stats: Data Check: %.2fM at %.2fMB/s\n",
check_data,
check_bandwidth);
}
void Sat::NetStats() {
float net_data = 0.;
float net_bandwidth = 0.;
WorkerMap::const_iterator netio_it = workers_map_.find(
static_cast<int>(kNetIOType));
WorkerMap::const_iterator netslave_it = workers_map_.find(
static_cast<int>(kNetSlaveType));
sat_assert(netio_it != workers_map_.end());
sat_assert(netslave_it != workers_map_.end());
for (WorkerVector::const_iterator it = netio_it->second->begin();
it != netio_it->second->end(); ++it) {
net_data += (*it)->GetDeviceCopiedData();
net_bandwidth += (*it)->GetDeviceBandwidth();
}
for (WorkerVector::const_iterator it = netslave_it->second->begin();
it != netslave_it->second->end(); ++it) {
net_data += (*it)->GetDeviceCopiedData();
net_bandwidth += (*it)->GetDeviceBandwidth();
}
logprintf(4, "Stats: Net Copy: %.2fM at %.2fMB/s\n",
net_data,
net_bandwidth);
}
void Sat::InvertStats() {
float invert_data = 0.;
float invert_bandwidth = 0.;
WorkerMap::const_iterator invert_it = workers_map_.find(
static_cast<int>(kInvertType));
sat_assert(invert_it != workers_map_.end());
for (WorkerVector::const_iterator it = invert_it->second->begin();
it != invert_it->second->end(); ++it) {
invert_data += (*it)->GetMemoryCopiedData();
invert_bandwidth += (*it)->GetMemoryBandwidth();
}
logprintf(4, "Stats: Invert Data: %.2fM at %.2fMB/s\n",
invert_data,
invert_bandwidth);
}
void Sat::DiskStats() {
float disk_data = 0.;
float disk_bandwidth = 0.;
WorkerMap::const_iterator disk_it = workers_map_.find(
static_cast<int>(kDiskType));
WorkerMap::const_iterator random_it = workers_map_.find(
static_cast<int>(kRandomDiskType));
sat_assert(disk_it != workers_map_.end());
sat_assert(random_it != workers_map_.end());
for (WorkerVector::const_iterator it = disk_it->second->begin();
it != disk_it->second->end(); ++it) {
disk_data += (*it)->GetDeviceCopiedData();
disk_bandwidth += (*it)->GetDeviceBandwidth();
}
for (WorkerVector::const_iterator it = random_it->second->begin();
it != random_it->second->end(); ++it) {
disk_data += (*it)->GetDeviceCopiedData();
disk_bandwidth += (*it)->GetDeviceBandwidth();
}
logprintf(4, "Stats: Disk: %.2fM at %.2fMB/s\n",
disk_data,
disk_bandwidth);
}
// Process worker thread data for bandwidth information, and error results.
// You can add more methods here just subclassing SAT.
void Sat::RunAnalysis() {
AnalysisAllStats();
MemoryStats();
FileStats();
NetStats();
CheckStats();
InvertStats();
DiskStats();
}
// Get total error count, summing across all threads..
int64 Sat::GetTotalErrorCount() {
int64 errors = 0;
AcquireWorkerLock();
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
errors += (*it)->GetErrorCount();
}
}
ReleaseWorkerLock();
return errors;
}
void Sat::SpawnThreads() {
logprintf(12, "Log: Initializing WorkerStatus objects\n");
power_spike_status_.Initialize();
continuous_status_.Initialize();
logprintf(12, "Log: Spawning worker threads\n");
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
logprintf(12, "Log: Spawning thread %d\n", (*it)->ThreadID());
(*it)->SpawnThread();
}
}
}
// Delete used worker thread objects.
void Sat::DeleteThreads() {
logprintf(12, "Log: Deleting worker threads\n");
for (WorkerMap::const_iterator map_it = workers_map_.begin();
map_it != workers_map_.end(); ++map_it) {
for (WorkerVector::const_iterator it = map_it->second->begin();
it != map_it->second->end(); ++it) {
logprintf(12, "Log: Deleting thread %d\n", (*it)->ThreadID());
delete (*it);
}
delete map_it->second;
}
workers_map_.clear();
logprintf(12, "Log: Destroying WorkerStatus objects\n");
power_spike_status_.Destroy();
continuous_status_.Destroy();
}
namespace {
// Calculates the next time an action in Sat::Run() should occur, based on a
// schedule derived from a start point and a regular frequency.
//
// Using frequencies instead of intervals with their accompanying drift allows
// users to better predict when the actions will occur throughout a run.
//
// Arguments:
// frequency: seconds
// start: unixtime
// now: unixtime
//
// Returns: unixtime
inline time_t NextOccurance(time_t frequency, time_t start, time_t now) {
return start + frequency + (((now - start) / frequency) * frequency);
}
}
// Run the actual test.
bool Sat::Run() {
// Install signal handlers to gracefully exit in the middle of a run.
//
// Why go through this whole rigmarole? It's the only standards-compliant
// (C++ and POSIX) way to handle signals in a multithreaded program.
// Specifically:
//
// 1) (C++) The value of a variable not of type "volatile sig_atomic_t" is
// unspecified upon entering a signal handler and, if modified by the
// handler, is unspecified after leaving the handler.
//
// 2) (POSIX) After the value of a variable is changed in one thread, another
// thread is only guaranteed to see the new value after both threads have
// acquired or released the same mutex or rwlock, synchronized to the
// same barrier, or similar.
//
// #1 prevents the use of #2 in a signal handler, so the signal handler must
// be called in the same thread that reads the "volatile sig_atomic_t"
// variable it sets. We enforce that by blocking the signals in question in
// the worker threads, forcing them to be handled by this thread.
logprintf(12, "Log: Installing signal handlers\n");
sigset_t new_blocked_signals;
sigemptyset(&new_blocked_signals);
sigaddset(&new_blocked_signals, SIGINT);
sigaddset(&new_blocked_signals, SIGTERM);
sigset_t prev_blocked_signals;
pthread_sigmask(SIG_BLOCK, &new_blocked_signals, &prev_blocked_signals);
sighandler_t prev_sigint_handler = signal(SIGINT, SatHandleBreak);
sighandler_t prev_sigterm_handler = signal(SIGTERM, SatHandleBreak);
// Kick off all the worker threads.
logprintf(12, "Log: Launching worker threads\n");
InitializeThreads();
SpawnThreads();
pthread_sigmask(SIG_SETMASK, &prev_blocked_signals, NULL);
logprintf(12, "Log: Starting countdown with %d seconds\n", runtime_seconds_);
// In seconds.
static const time_t kSleepFrequency = 5;
// All of these are in seconds. You probably want them to be >=
// kSleepFrequency and multiples of kSleepFrequency, but neither is necessary.
static const time_t kInjectionFrequency = 10;
static const time_t kPrintFrequency = 10;
const time_t start = time(NULL);
const time_t end = start + runtime_seconds_;
time_t now = start;
time_t next_print = start + kPrintFrequency;
time_t next_pause = start + pause_delay_;
time_t next_resume = 0;
time_t next_injection;
if (crazy_error_injection_) {
next_injection = start + kInjectionFrequency;
} else {
next_injection = 0;
}
while (now < end) {
// This is an int because it's for logprintf().
const int seconds_remaining = end - now;
if (user_break_) {
// Handle early exit.
logprintf(0, "Log: User exiting early (%d seconds remaining)\n",
seconds_remaining);
break;
}
// If we have an error limit, check it here and see if we should exit.
if (max_errorcount_ != 0) {
uint64 errors = GetTotalErrorCount();
if (errors > max_errorcount_) {
logprintf(0, "Log: Exiting early (%d seconds remaining) "
"due to excessive failures (%lld)\n",
seconds_remaining,
errors);
break;
}
}
if (now >= next_print) {
// Print a count down message.
logprintf(5, "Log: Seconds remaining: %d\n", seconds_remaining);
next_print = NextOccurance(kPrintFrequency, start, now);
}
if (next_injection && now >= next_injection) {
// Inject an error.
logprintf(4, "Log: Injecting error (%d seconds remaining)\n",
seconds_remaining);
struct page_entry src;
GetValid(&src);
src.pattern = patternlist_->GetPattern(0);
PutValid(&src);
next_injection = NextOccurance(kInjectionFrequency, start, now);
}
if (next_pause && now >= next_pause) {
// Tell worker threads to pause in preparation for a power spike.
logprintf(4, "Log: Pausing worker threads in preparation for power spike "
"(%d seconds remaining)\n", seconds_remaining);
power_spike_status_.PauseWorkers();
logprintf(12, "Log: Worker threads paused\n");
next_pause = 0;
next_resume = now + pause_duration_;
}
if (next_resume && now >= next_resume) {
// Tell worker threads to resume in order to cause a power spike.
logprintf(4, "Log: Resuming worker threads to cause a power spike (%d "
"seconds remaining)\n", seconds_remaining);
power_spike_status_.ResumeWorkers();
logprintf(12, "Log: Worker threads resumed\n");
next_pause = NextOccurance(pause_delay_, start, now);
next_resume = 0;
}
sat_sleep(NextOccurance(kSleepFrequency, start, now) - now);
now = time(NULL);
}
JoinThreads();
logprintf(0, "Stats: Found %lld hardware incidents\n", errorcount_);
if (!monitor_mode_)
RunAnalysis();
DeleteThreads();
logprintf(12, "Log: Uninstalling signal handlers\n");
signal(SIGINT, prev_sigint_handler);
signal(SIGTERM, prev_sigterm_handler);
return true;
}
// Clean up all resources.
bool Sat::Cleanup() {
g_sat = NULL;
Logger::GlobalLogger()->StopThread();
Logger::GlobalLogger()->SetStdoutOnly();
if (logfile_) {
close(logfile_);
logfile_ = 0;
}
if (patternlist_) {
patternlist_->Destroy();
delete patternlist_;
patternlist_ = 0;
}
if (os_) {
os_->FreeTestMem();
delete os_;
os_ = 0;
}
if (empty_) {
delete empty_;
empty_ = 0;
}
if (valid_) {
delete valid_;
valid_ = 0;
}
if (finelock_q_) {
delete finelock_q_;
finelock_q_ = 0;
}
if (page_bitmap_) {
delete[] page_bitmap_;
}
for (size_t i = 0; i < blocktables_.size(); i++) {
delete blocktables_[i];
}
if (cc_cacheline_data_) {
// The num integer arrays for all the cacheline structures are
// allocated as a single chunk. The pointers in the cacheline struct
// are populated accordingly. Hence calling free on the first
// cacheline's num's address is going to free the entire array.
// TODO(aganti): Refactor this to have a class for the cacheline
// structure (currently defined in worker.h) and clean this up
// in the destructor of that class.
if (cc_cacheline_data_[0].num) {
free(cc_cacheline_data_[0].num);
}
free(cc_cacheline_data_);
}
sat_assert(0 == pthread_mutex_destroy(&worker_lock_));
return true;
}
// Pretty print really obvious results.
bool Sat::PrintResults() {
bool result = true;
logprintf(4, "\n");
if (statuscount_) {
logprintf(4, "Status: FAIL - test encountered procedural errors\n");
result = false;
} else if (errorcount_) {
logprintf(4, "Status: FAIL - test discovered HW problems\n");
result = false;
} else {
logprintf(4, "Status: PASS - please verify no corrected errors\n");
}
logprintf(4, "\n");
return result;
}
// Helper functions.
void Sat::AcquireWorkerLock() {
sat_assert(0 == pthread_mutex_lock(&worker_lock_));
}
void Sat::ReleaseWorkerLock() {
sat_assert(0 == pthread_mutex_unlock(&worker_lock_));
}
void logprintf(int priority, const char *format, ...) {
va_list args;
va_start(args, format);
Logger::GlobalLogger()->VLogF(priority, format, args);
va_end(args);
}