ft_malloc

malloc project @ 42

Mandatory part

Rewrite malloc free and realloc functions.

also write a show_alloc_mem function to printing memory allocations.

Like the real malloc, the allocated memory must be stored in pre-allocated "zones" (bins), unless the requested size is too big, then the allocation must be fitted.

Two zones are required:

• Tiny zones of N size, storing allocations from 0 to n size
• Small zones of M size, storing allocations from n+1 to m size
• Larges allocations, fitted allocations beginning from m+1

Zones size must be a multiple of page size, acquired through getpagesize(). Allocations (and internally required allocations) must be executed with mmap, de-allocations with munmap

Bonus part

• Making mandatory functions thread safe
• Debug flags
• Additional info print (mem dump, allocations history...) through said flags or extra functions
• De-fragmented bins on free and realloc

Mandatory part code explanation

Slightly inspired from debian glibc malloc.

When words related to allocation will be put between double quotes it means that it is not necessarily an allocation, attributing a portion of a bin is not an allocation, a fitted allocation is indeed an allocation.

Since most of the explanations are not linked to real memory allocations made with mmap and applies to bin or fitted "allocations", whether it is an attribution or an allocation do not change how it is organised.

Brief explanation of memory alignement

The computer read memory by sections of 4/8 bytes, or 32/64 bits, this determines the name of the architecture.

Aligning memory corresponds to set variables on start of 4/8 bytes sections. If this is not respected, it raises :

• Constraint violation: an alignment error interrupts the execution of instructions.

• Non-optimal alignment: twice 4 well-aligned bytes are read, then the 4 misaligned bytes are extracted from these 8 bytes, which takes much longer than reading 4 well-aligned bytes.

Considering this, compilers will automatically align memory when possible by padding memory with char, meaning that, when the fields of a structure are not positioned properly or the total size of a structure is not a multiple of 4/8, it will take more memory than it should, due to padding.

However, when freely attributing values in memory, it is required to be careful with alignement, to prevent unnecessary slowdowns.

Chunks

Every memory "allocation" (bin or fitted) is preceded by a header. The combination of a memory "allocation" (data) and it's header is called a chunk.

The header bears the following information :

• Allocation size (unsigned long)
• Allocation real size (unsigned long)
• Pointer to next chunk (void *)
• Pointer to previous chunk (void *)

For a total of 16/32 bytes on 32/64 bits architectures. The structure itself is memory aligned and the start of the data is also aligned. The data size is always set to a multiple of 8, this forces memory alignement on every architecture.

The data size is often larger than what was asked, to keep memory aligned. The portion of data that matches the size asked by the user (real size) is called provided data, the remainder is called tail.

To sum things up, this is how a chunk is organised in memory (assuming a line is 4/8 bytes) :

Header	size of data (size)
	size of provided data (real size)
	pointer to next chunk (next)
	pointer to previous chunk (prev)
data	provided data (could be any size)
	tail (could be any size)

The size of the provided data is only here for debug information and show_alloc_mem.

Pros and cons

The pros of overhead instead of exported bookkeeping is that it is way faster to retrieve data related to a chunk with a pointer (in free or realloc for example) since it only required to subtract the header size to the pointer to retrieve its header.

It also takes less space since it does not contain pointers to data.

It also requires fewer calls to mmap (which are fairly slow) since it is not allocated elsewhere, data and header are allocated in a single call.

The cons are that a non-cautious user writing out of provided data bounds might ruin the bookkeeping data and ruin malloc... But well, nobody is supposed to write out of bounds right ?

Bins

In the similar way as a chunk, bins have a preceding header, the only differences are that the size corresponds to the full zone size, header included, and that the real size field is unused and that pointers point to bins instead of chunks.

malloc

When calling malloc, if the size is not too high for a bin (then it just will perform a fitted allocation) it will iterate in the proper bin corresponding to the size and find a free chunk with the proper size, this helps to prevent bin fragmentation. if it reaches the end of a bin and there is enough space left in the bin, it will attribute a chunk in the bin. If there is not enough space left in the bin, it will create a new bin.

If several contiguous freed chunks total size matches the new chunks size they will be joined as a single chunk, again, to prevent fragmentation.

free

When calling free, if the size is not too high for a bin (then it will just unmap the chunk and sort out next/prev pointers) it will check if the provided chunk is at the end of a bin, if so, the chunk will be de-attributed then it will iterate backward to find contiguous chunks to de-attribute them, this helps to prevent bin fragmentation.

If the bin ends up being empty, it is de-allocated to reduce the program's memory footprint.

realloc

When calling realloc, if the size is not too high for a bin (which will be covered in a few lines) it will run a few checks :

• If the new size is equal the current real size, if so, it will just return the provided pointer.

• If the new size is lesser than the current real size, it will adjust the chunk's real size and return the provided pointer.

• If it is greater than the current real size, but lesser than the chunk's data size, it will adjust the chunk's real size and return the provided pointer.

In the two previous cases, if the chunk is at the end of a bin, the chunk will be expanded (if there is enough space left) or trimmed to fit the new size.

• If the new size is greater than the chunk's data size (or bin's left size if it is at the end of a bin) it will store the chunk's data in a buffer, free the chunk, call malloc to get a new chunk and copy the buffer into the new chunk's data.

In a similar fashion. if the size is too big for a bin, it will try to expand or trim the chunk with mmap, if it worked, chunk's size and real size is changed accordingly and the provided pointer is returned. If it did not work, it will copy the chunk's data to the new chunk and return a pointer to the new chunk's data.

Bonus part code explanation

None of the bonuses really requires an explanation, besides eventually de-fragmentation...

Preventing fragmentation is already covered in the mandatory part (to be fair, if one wants to do this bonus, it is recommended to code the mandatory part with de-fragmentation in mind...).

Making the lib thread-safe is not that hard, the easiest implementation is to lock / unlock a mutex before each call of the exposed functions. could eventually be optimized, but for little to no gain. To make it fancier, it is possible to add build time parameters to not include thread-safe logic when not required.