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I have written a small program and compiled it under Solaris/Linux platform to measure the performance of applying this code to my application.

The program is written in such a way, initially using a sbrk(0) system call, I have taken base address of the heap region. After that I have allocated 1.5 GB of memory using a malloc system call, Then I used a memcpy system call to copy 1.5 GB of content to the allocated memory area. Then, I freed the allocated memory.

After freeing, I used the sbrk(0) system call again to view the heap size.

This is where I get a little confused. In Solaris, even though I freed the memory allocated (nearly 1.5 GB), the heap size of the process is huge. But I run the same application in Linux, after freeing, I found that the heap size of the process is equal to the size of the heap memory before allocation of 1.5 GB.

I know Solaris does not free memory immediately, but I don't know how to tune the Solaris kernel to immediately free the memory after the free() system call.

Why don't I have the same problem under Linux?

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1 Answer 1

up vote 3 down vote accepted

I got the answer for the question that i have asked.

Application Memory Allocators:

C and C++ developers must manually manage memory allocation and free memory. The default memory allocator is in the libc library.

Libc Note that after free()is executed, the freed space is made available for further allocation by the application and not returned to the system. Memory is returned to the system only when the application terminates. That's why the application's process size usually never decreases. But for a long-running application, the application process size usually remains in a stable state because the freed memory can be reused. If this is not the case, then most likely the application is leaking memory, that is, allocated memory is used but never freed when no longer in use and the pointer to the allocated memory is not tracked by the application—basically lost.

The default memory allocator in libc is not good for multi-threaded applications when a concurrent malloc or free operation occurs frequently, especially for multi-threaded C++ applications. This is because creating and destroying C++ objects is part of C++ application development style. When the default libc allocator is used, the heap is protected by a single heap-lock, causing the default allocator not to be scalable for multi-threaded applications due to heavy lock contentions during malloc or free operations. It's easy to detect this problem with Solaris tools, as follows.

First, use prstat -mL -p to see if the application spends much time on locks; look at the LCK column. For example:

-bash-3.2# prstat -mL -p 14052
 14052 root     0.6 0.7 0.0 0.0 0.0  35 0.0  64 245  13 841   0 test_vector_/721
 14052 root     1.0 0.0 0.0 0.0 0.0  35 0.0  64 287   5 731   0 test_vector_/941
 14052 root     1.0 0.0 0.0 0.0 0.0  35 0.0  64 298   3 680   0 test_vector_/181
 14052 root     1.0 0.1 0.0 0.0 0.0  35 0.0  64 298   3  1K   0 test_vector_/549

It shows that the application spend about 35 percent of its time waiting for locks.

Then, using the plockstat(1M) tool, find what locks the application is waiting for. For example, trace the application for 5 seconds with process ID 14052, and then filter the output with the c++filt utility for demangling C++ symbol names. (The c++filt utility is provided with the Sun Studio software.) Filtering through c++filt is not needed if the application is not a C++ application.

-bash-3.2#  plockstat -e 5 -p 14052 | c++filt
Mutex block
Count     nsec   Lock                         Caller
 9678 166540561‘libc_malloc_lock‘void operator 

 5530 197179848‘libc_malloc_lock‘void*operator 


From the preceding, you can see that the heap-lock libc_malloc_lock is heavily contended for and is a likely cause for the scaling issue. The solution for this scaling problem of the libc allocator is to use an improved memory allocator like the libumem library.

Also visit:

Thanks for all who tried to answer my question, Santhosh.

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