2: Memory management

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C provides 4 functions for dynamic memory allocation:

malloc, which takes an integer size, in bytes, and returns a pointer to a newly-allocated chunk of memory with (at least) the given size. If it can’t satisfy the request, it returns the special pointer value NULL.
calloc, which is the same as malloc except that it also clears the newly allocated chunk; that is, it sets all bytes in the chunk to 0.
free, which takes a pointer to a previously allocated chunk and deallocates it; that is, it makes the space available for future allocation.
realloc, which takes a pointer to a previously allocated chunk and a new size. It allocates a chunk of memory with the new size, copies data from the old chunk to the new, frees the old chunk, and returns a pointer to the new chunk.

This API is notoriously error-prone and unforgiving. Memory management is one of the most challenging parts of designing large software systems, which is why most modern languages provide higher-level memory management features like garbage collection.

2.1: Memory errors
This page addresses the complexities of C memory management, likening it to a strict teacher enforcing rules. It outlines frequent errors, such as improper memory access and freeing, which can lead to unpredictable issues in large programs. The text emphasizes the necessity of careful design and following API guidelines for safe memory management, while also noting the balance between safety and performance, particularly in relation to array bounds checking.
2.2: Memory leaks
This page discusses memory leaks in programs, highlighting their potential to exhaust system resources when allocated memory isn't freed. It emphasizes the importance of checking malloc's return value to avoid segmentation faults and suggests wrapping malloc in a custom function for easier error checking. The page notes that large applications, such as web browsers, often face memory management issues and recommends tools like ps and top to monitor memory usage by processes.
2.3: Implementation
This page discusses memory allocation, particularly heap management using functions such as malloc, free, calloc, and realloc. It covers how malloc checks for free chunks and requests memory via sbrk, highlighting concepts like boundary tags and free lists. The performance of malloc is influenced by free chunk availability and size, while fragmentation can impact memory efficiency. A solid grasp of these principles is essential for effective memory management in programming.

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