As thiton mentioned, this code could be I/O bounded. However, these days many computers may have SSDs and high-throughput RAID disks. In such case, you can get speedup from parallelization. Moreover, if the computation is not trivial, then parallelize wins. Even if the I/O is effectively serialized due to saturated bandwidth, you can still get speedup by distributing the computation to multicore.
Back to the question itself, you can parallelize this loop by OpenMP. With
stdin, I have no idea to parallelize because it needs to read sequentially and no prior information of the end. However, if you're working a typical file, you can do it.
Here is my code with
omp parallel. I used some Win32 API and MSVC CRT:
const static int BUFFER_SIZE = 1024;
const static int CONCURRENCY = 4;
DWORD start = GetTickCount();
#pragma omp parallel
int tid = omp_get_thread_num();
FILE* file = fopen("huge_file.dat", "rb");
_fseeki64(file, 0, SEEK_END);
uint64_t total_size = _ftelli64(file);
uint64_t my_start_pos = total_size/CONCURRENCY * tid;
uint64_t my_end_pos = min((total_size/CONCURRENCY * (tid + 1)), total_size);
uint64_t my_read_size = my_end_pos - my_start_pos;
_fseeki64(file, my_start_pos, SEEK_SET);
char* buffer = new char[BUFFER_SIZE];
uint64_t local_checksum = 0;
uint64_t local_read = 0;
while ((read_bytes = fread(buffer, 1, min(my_read_size, BUFFER_SIZE), file)) != 0 &&
my_read_size != 0)
local_read += read_bytes;
my_read_size -= read_bytes;
for (int i = 0; i < read_bytes; ++i)
local_checksum += (buffer[i]);
local_checksums[tid] = local_checksum;
local_reads[tid] = local_read;
uint64_t checksum = 0;
uint64_t total_read = 0;
for (int i = 0; i < CONCURRENCY; ++i)
checksum += local_checksums[i], total_read += local_reads[i];
std::cout << checksum << std::endl
<< total_read << std::endl
<< double(GetTickCount() - start)/1000. << std::endl;
This code looks a bit dirty because I needed to precisely distribute the amount of the file to be read. However, the code is fairly straightforward. One thing keep in mind is that you need to have a per-thread file pointer. You can't simply share a file pointer because the internal data structure may not be thread-safe. Also, this code can be parallelized by
parallel for. But, I think this approach is more natural.
Simple experimental results
I have tested this code to read a 10GB file on either a HDD (WD Green 2TB) and a SSD (Intel 120GB).
With a HDD, yes, no speedups were obtained. Even slowdown was observed. This clearly shows that this code is I/O bounded. This code virtually has no computation. Just I/O.
However, with a SSD, I had a speedup of 1.2 with 4 cores. Yes, the speedup is small. But, you still can get it with SSD. And, if the computation becomes a bit more (I just put a very short busy-waiting loop), speedups would be significant. I was able to get speedup of 2.5.
In sum, I'd like to recommend that you try to parallelize this code.
Also, if the computation is not trivial, I would recommend pipelining. The above code simply divides into several big chunks, resulting in poor cache efficiency. However, pipeline parallelization may yield better cache utilization. Try to use TBB for pipeline parallelization. They provide a simple pipeline construct.