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/*******************************************************************************
* Copyright (c) 2006 International Business Machines Corporation. *
* All rights reserved. This program and the accompanying materials *
* are made available under the terms of the Common Public License v1.0 *
* which accompanies this distribution, and is available at *
* http://www.opensource.org/licenses/cpl1.0.php *
* *
* Contributors: *
* Douglas M. Pase - initial API and implementation *
* Tim Besard - prefetching, JIT compilation *
*******************************************************************************/
//
// Configuration
//
// Implementation header
#include "run.h"
// System includes
#include <cstdio>
#include <cstdlib>
#include <unistd.h>
#include <cstddef>
#include <algorithm>
#include <numa.h>
// Local includes
#include <AsmJit/AsmJit.h>
#include "timer.h"
//
// Implementation
//
typedef void (*benchmark)(const Chain**);
typedef benchmark (*generator)(int64 chains_per_thread,
int64 bytes_per_line, int64 bytes_per_chain,
int64 stride, int64 loop_length, int32 prefetch_hint);
static benchmark chase_pointers(int64 chains_per_thread,
int64 bytes_per_line, int64 bytes_per_chain,
int64 stride, int64 loop_length, int32 prefetch_hint);
Lock Run::global_mutex;
int64 Run::_ops_per_chain = 0;
std::vector<double> Run::_seconds;
Run::Run() :
exp(NULL), bp(NULL) {
}
Run::~Run() {
}
void Run::set(Experiment &e, SpinBarrier* sbp) {
this->exp = &e;
this->bp = sbp;
}
int Run::run() {
// first allocate all memory for the chains,
// making sure it is allocated within the
// intended numa domains
Chain** chain_memory = new Chain*[this->exp->chains_per_thread];
Chain** root = new Chain*[this->exp->chains_per_thread];
// establish the node id where this thread
// will run. threads are mapped to nodes
// by the set-up code for Experiment.
int run_node_id = this->exp->thread_domain[this->thread_id()];
numa_run_on_node(run_node_id);
// establish the node id where this thread's
// memory will be allocated.
for (int i=0; i < this->exp->chains_per_thread; i++) {
int alloc_node_id = this->exp->chain_domain[this->thread_id()][i];
struct bitmask *bitmask = numa_allocate_nodemask();
numa_bitmask_clearall(bitmask);
numa_bitmask_setbit(bitmask, alloc_node_id);
numa_set_membind(bitmask);
numa_free_nodemask(bitmask);
chain_memory[i] = new Chain[ this->exp->links_per_chain ];
}
// initialize the chains and
// select the function that
// will generate the tests
generator gen;
for (int i = 0; i < this->exp->chains_per_thread; i++) {
if (this->exp->access_pattern == Experiment::RANDOM) {
root[i] = random_mem_init(chain_memory[i]);
gen = chase_pointers;
} else if (this->exp->access_pattern == Experiment::STRIDED) {
if (0 < this->exp->stride) {
root[i] = forward_mem_init(chain_memory[i]);
} else {
root[i] = reverse_mem_init(chain_memory[i]);
}
gen = chase_pointers;
}
}
// compile benchmark
benchmark bench = gen(this->exp->chains_per_thread,
this->exp->bytes_per_line, this->exp->bytes_per_chain,
this->exp->stride, this->exp->loop_length,
this->exp->prefetch_hint);
// calculate the number of iterations
/*
* As soon as the thread count rises, this calculation HUGELY
* differs between runs. What does cause this? Threads are already
* limited to certain CPUs, so it's not caused by excessive switching.
* Strange cache behaviour?
*/
if (0 == this->exp->iterations) {
volatile static double istart = 0;
volatile static double istop = 0;
volatile static double elapsed = 0;
volatile static int64 iters = 1;
volatile double bound = std::max(0.2, 10 * Timer::resolution());
for (iters = 1; elapsed <= bound; iters = iters << 1) {
// barrier
this->bp->barrier();
// start timer
if (this->thread_id() == 0) {
istart = Timer::seconds();
}
this->bp->barrier();
// chase pointers
for (int i = 0; i < iters; i++)
bench((const Chain**) root);
// barrier
this->bp->barrier();
// stop timer
if (this->thread_id() == 0) {
istop = Timer::seconds();
elapsed = istop - istart;
}
this->bp->barrier();
}
// calculate the number of iterations
if (this->thread_id() == 0) {
if (0 < this->exp->seconds) {
this->exp->iterations = std::max(1.0,
0.9999 + 0.5 * this->exp->seconds * iters / elapsed);
} else {
this->exp->iterations = std::max(1.0, 0.9999 + iters / elapsed);
}
//printf("Tested %d iterations: took %f seconds; scheduling %d iterations\n", iters, elapsed, this->exp->iterations);
}
this->bp->barrier();
}
// run the experiments
for (int e = 0; e < this->exp->experiments; e++) {
// barrier
this->bp->barrier();
// start timer
double start = 0;
if (this->thread_id() == 0)
start = Timer::seconds();
this->bp->barrier();
// chase pointers
for (int i = 0; i < this->exp->iterations; i++)
bench((const Chain**) root);
// barrier
this->bp->barrier();
// stop timer
double stop = 0;
if (this->thread_id() == 0)
stop = Timer::seconds();
this->bp->barrier();
if (0 <= e) {
if (this->thread_id() == 0) {
double delta = stop - start;
if (0 < delta) {
Run::_seconds.push_back(delta);
}
}
}
}
this->bp->barrier();
// clean the memory
for (int i = 0; i < this->exp->chains_per_thread; i++) {
if (chain_memory[i] != NULL
) delete[] chain_memory[i];
}
if (chain_memory != NULL
) delete[] chain_memory;
return 0;
}
int dummy = 0;
void Run::mem_check(Chain *m) {
if (m == NULL
) dummy += 1;
}
// exclude 2 and Mersenne primes, i.e.,
// primes of the form 2**n - 1, e.g.,
// 3, 7, 31, 127
static const int prime_table[] = { 5, 11, 13, 17, 19, 23, 37, 41, 43, 47, 53,
61, 71, 73, 79, 83, 89, 97, 101, 103, 109, 113, 131, 137, 139, 149, 151,
157, 163, };
static const int prime_table_size = sizeof prime_table / sizeof prime_table[0];
Chain*
Run::random_mem_init(Chain *mem) {
// initialize pointers --
// choose a page at random, then use
// one pointer from each cache line
// within the page. all pages and
// cache lines are chosen at random.
Chain* root = 0;
Chain* prev = 0;
int link_within_line = 0;
int64 local_ops_per_chain = 0;
// we must set a lock because random()
// is not thread safe
Run::global_mutex.lock();
setstate(this->exp->random_state[this->thread_id()]);
int page_factor = prime_table[random() % prime_table_size];
int page_offset = random() % this->exp->pages_per_chain;
Run::global_mutex.unlock();
// loop through the pages
for (int i = 0; i < this->exp->pages_per_chain; i++) {
int page = (page_factor * i + page_offset) % this->exp->pages_per_chain;
Run::global_mutex.lock();
setstate(this->exp->random_state[this->thread_id()]);
int line_factor = prime_table[random() % prime_table_size];
int line_offset = random() % this->exp->lines_per_page;
Run::global_mutex.unlock();
// loop through the lines within a page
for (int j = 0; j < this->exp->lines_per_page; j++) {
int line_within_page = (line_factor * j + line_offset)
% this->exp->lines_per_page;
int link = page * this->exp->links_per_page
+ line_within_page * this->exp->links_per_line
+ link_within_line;
if (root == 0) {
prev = root = mem + link;
local_ops_per_chain += 1;
} else {
prev->next = mem + link;
prev = prev->next;
local_ops_per_chain += 1;
}
}
}
prev->next = root;
Run::global_mutex.lock();
Run::_ops_per_chain = local_ops_per_chain;
Run::global_mutex.unlock();
return root;
}
Chain*
Run::forward_mem_init(Chain *mem) {
Chain* root = 0;
Chain* prev = 0;
int link_within_line = 0;
int64 local_ops_per_chain = 0;
for (int i = 0; i < this->exp->lines_per_chain; i += this->exp->stride) {
int link = i * this->exp->links_per_line + link_within_line;
if (root == NULL) {
prev = root = mem + link;
local_ops_per_chain += 1;
} else {
prev->next = mem + link;
prev = prev->next;
local_ops_per_chain += 1;
}
}
prev->next = root;
Run::global_mutex.lock();
Run::_ops_per_chain = local_ops_per_chain;
Run::global_mutex.unlock();
return root;
}
Chain*
Run::reverse_mem_init(Chain *mem) {
Chain* root = 0;
Chain* prev = 0;
int link_within_line = 0;
int64 local_ops_per_chain = 0;
int stride = -this->exp->stride;
int last;
for (int i = 0; i < this->exp->lines_per_chain; i += stride) {
last = i;
}
for (int i = last; 0 <= i; i -= stride) {
int link = i * this->exp->links_per_line + link_within_line;
if (root == 0) {
prev = root = mem + link;
local_ops_per_chain += 1;
} else {
prev->next = mem + link;
prev = prev->next;
local_ops_per_chain += 1;
}
}
prev->next = root;
Run::global_mutex.lock();
Run::_ops_per_chain = local_ops_per_chain;
Run::global_mutex.unlock();
return root;
}
static benchmark chase_pointers(int64 chains_per_thread, // memory loading per thread
int64 bytes_per_line, // ignored
int64 bytes_per_chain, // ignored
int64 stride, // ignored
int64 loop_length, // length of the inner loop
int32 prefetch_hint // use of prefetching
) {
// Create Compiler.
AsmJit::Compiler c;
// Tell compiler the function prototype we want. It allocates variables representing
// function arguments that can be accessed through Compiler or Function instance.
c.newFunction(AsmJit::CALL_CONV_DEFAULT, AsmJit::FunctionBuilder1<AsmJit::Void, const Chain**>());
// Try to generate function without prolog/epilog code:
c.getFunction()->setHint(AsmJit::FUNCTION_HINT_NAKED, true);
// Create labels.
AsmJit::Label L_Loop = c.newLabel();
// Function arguments.
AsmJit::GPVar chain(c.argGP(0));
// Save the head
std::vector<AsmJit::GPVar> heads(chains_per_thread);
for (int i = 0; i < chains_per_thread; i++) {
AsmJit::GPVar head = c.newGP();
c.mov(head, ptr( chain, i * sizeof( Chain * ) ) );
heads[i] = head;
}
// Current position
std::vector<AsmJit::GPVar> positions(chains_per_thread);
for (int i = 0; i < chains_per_thread; i++) {
AsmJit::GPVar position = c.newGP();
c.mov(position, heads[i]);
positions[i] = position;
}
// Loop.
c.bind(L_Loop);
// Process all links
for (int i = 0; i < chains_per_thread; i++) {
// Chase pointer
c.mov(positions[i], ptr(positions[i], offsetof(Chain, next)));
// Prefetch next
switch (prefetch_hint)
{
case Experiment::T0:
c.prefetch(ptr(positions[i]), AsmJit::PREFETCH_T0);
break;
case Experiment::T1:
c.prefetch(ptr(positions[i]), AsmJit::PREFETCH_T1);
break;
case Experiment::T2:
c.prefetch(ptr(positions[i]), AsmJit::PREFETCH_T2);
break;
case Experiment::NTA:
c.prefetch(ptr(positions[i]), AsmJit::PREFETCH_NTA);
break;
case Experiment::NONE:
default:
break;
}
}
// Wait
for (int i = 0; i < loop_length; i++)
c.nop();
// Test if end reached
c.cmp(heads[0], positions[0]);
c.jne(L_Loop);
// Finish.
c.endFunction();
// Make JIT function.
benchmark fn = AsmJit::function_cast<benchmark>(c.make());
// Ensure that everything is ok.
if (!fn) {
printf("Error making jit function (%u).\n", c.getError());
return 0;
}
return fn;
}
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