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Carnegie Mellon 1 Malloc Recitation Ben Spinelli Recitation 11: November 9, 2015.

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Presentation on theme: "Carnegie Mellon 1 Malloc Recitation Ben Spinelli Recitation 11: November 9, 2015."— Presentation transcript:

1 Carnegie Mellon 1 Malloc Recitation Ben Spinelli Recitation 11: November 9, 2015

2 Carnegie Mellon 2 Agenda Macros / Inline functions Quick pointer review Malloc

3 Carnegie Mellon 3 Macros / Inline Functions

4 Carnegie Mellon 4 Macros Pre-compile time Define constants:  #define NUM_ENTRIES 100  OK Define simple operations:  #define twice(x) 2*x  Not OK  twice(x+1) becomes 2*x+1  #define twice(x) (2*(x))  OK  Always wrap in parentheses; it’s a naive search-and-replace!

5 Carnegie Mellon 5 Macros Why macros?  “Faster” than function calls  Why?  For malloc  Quick access to header information (payload size, valid) Drawbacks  Less expressive than functions  Arguments are not typechecked, local variables  This can easily lead to errors that are more difficult to find

6 Carnegie Mellon 6 Inline Functions What’s the keyword inline do?  At compile-time replaces “function calls” with code More efficient than a normal function call  Less overhead – no need to set up stack/function call  Useful for functions that are  Called frequently  Small, e.g., int add(int x, int y);

7 Carnegie Mellon 7 Differences Macros done at pre-compile time Inline functions done at compile time  Stronger type checking / Argument consistency Macros cannot return anything (why not?) Macros can have unintended side effects  #define xsquared(x) (x*x)  What happens when xsquared(x++) is called? Hard to debug macros – errors generated on expanded code, not code that you typed

8 Carnegie Mellon 8 Macros / Inline Functions You will likely use both in malloc lab Macros are good for small tasks  Saves work in retyping tedious calculations  Can make code easier to understand  HEADER(ptr) versus doing the pointer arithmetic Some things are hard to code in macros, so this is where inline functions come into play  More efficient than normal function call  More expressive than macros

9 Carnegie Mellon 9 Pointers: casting, arithmetic, and dereferencing

10 Carnegie Mellon 10 Pointer casting Cast from  * to *  Gives back the same value  Changes the behavior that will happen when dereferenced  * to integer/ unsigned int  Pointers are really just 8-byte numbers  Taking advantage of this is an important part of malloc lab  Be careful, though, as this can easily lead to errors  integer/ unsigned int to *

11 Carnegie Mellon 11 Pointer arithmetic The expression ptr + a doesn’t mean the same thing as it would if ptr were an integer. Example: type_a* pointer = …; (void *) pointer2 = (void *) (pointer + a); This is really computing:  pointer2 = pointer + (a * sizeof(type_a))  lea (pointer, a, sizeof(type_a)), pointer2; Pointer arithmetic on void* is undefined

12 Carnegie Mellon 12 Pointer arithmetic int * ptr = (int *)0x12341230; int * ptr2 = ptr + 1; char * ptr = (char *)0x12341230; char * ptr2 = ptr + 1; int * ptr = (int *)0x12341230; int * ptr2 = ((int *) (((char *) ptr) + 1)); char * ptr = (char *)0x12341230; void * ptr2 = ptr + 1; char * ptr = (int *)0x12341230; void * ptr2 = ptr + 1;

13 Carnegie Mellon 13 Pointer arithmetic int * ptr = (int *)0x12341230; int * ptr2 = ptr + 1; //ptr2 is 0x12341234 char * ptr = (char *)0x12341230; char * ptr2 = ptr + 1; //ptr2 is 0x12341231 int * ptr = (int *)0x12341230; int * ptr2 = ((int *) (((char *) ptr) + 1)); //ptr2 is 0x12341231 char * ptr = (char *)0x12341230; void * ptr2 = ptr + 1; //ptr2 is 0x12341231 char * ptr = (int *)0x12341230; void * ptr2 = ptr + 1; //ptr2 is still 0x12341231

14 Carnegie Mellon 14 More pointer arithmetic int ** ptr = (int **)0x12341230; int * ptr2 = (int *) (ptr + 1); char ** ptr = (char **)0x12341230; short * ptr2 = (short *) (ptr + 1); int * ptr = (int *)0x12341230; void * ptr2 = &ptr + 1; int * ptr = (int *)0x12341230; void * ptr2 = ((void *) (*ptr + 1)); This is on a 64-bit machine!

15 Carnegie Mellon 15 More pointer arithmetic int ** ptr = (int **)0x12341230; int * ptr2 = (int *) (ptr + 1); //ptr2 = 0x12341238 char ** ptr = (char **)0x12341230; short * ptr2 = (short *) (ptr + 1); //ptr2 = 0x12341238 int * ptr = (int *)0x12341230; void * ptr2 = &ptr + 1;//ptr2 = ?? //ptr2 is actually 8 bytes higher than the address of the variable ptr, which is somewhere on the stack int * ptr = (int *)0x12341230; void * ptr2 = ((void *) (*ptr + 1)); //ptr2 = ?? //ptr2 is one plus the value at 0x12341230  (so undefined, but it probably segfaults)

16 Carnegie Mellon 16 Pointer dereferencing Basics  It must be a POINTER type (or cast to one) at the time of dereference  Cannot dereference expressions with type void*  Dereferencing a t* evaluates to a value with type t

17 Carnegie Mellon 17 Pointer dereferencing What gets “returned?” int * ptr1 = malloc(sizeof(int)); *ptr1 = 0xdeadbeef; int val1 = *ptr1; int val2 = (int) *((char *) ptr1); What are val1 and val2?

18 Carnegie Mellon 18 Pointer dereferencing What gets “returned?” int * ptr1 = malloc(sizeof(int)); *ptr1 = 0xdeadbeef; int val1 = *ptr1; int val2 = (int) *((char *) ptr1); //val1 = 0xdeadbeef; //val2 = 0xffffffef; What happened??

19 Carnegie Mellon 19 Malloc

20 Carnegie Mellon 20 Malloc basics What is dynamic memory allocation? Terms you will need to know  malloc/ calloc / realloc  free  sbrk  payload  fragmentation (internal vs. external)  coalescing  Bi-directional  Immediate vs. Deferred

21 Carnegie Mellon 21

22 Carnegie Mellon 22 Fragmentation Internal fragmentation  Result of payload being smaller than block size.  void * m1 = malloc(3); void * m1 = malloc(3);  m1,m2 both have to be aligned to 8 bytes… External fragmentation

23 Carnegie Mellon 23

24 Carnegie Mellon 24 Implementation Hurdles How do we know where the blocks are? How do we know how big the blocks are? How do we know which blocks are free? Remember: can’t buffer calls to malloc and free… must deal with them real-time. Remember: calls to free only takes a pointer, not a pointer and a size. Solution: Need a data structure to store information on the “blocks”  Where do I keep this data structure?  We can’t allocate a space for it, that’s what we are writing!

25 Carnegie Mellon 25 The data structure Requirements:  The data structure needs to tell us where the blocks are, how big they are, and whether they’re free  We need to be able to CHANGE the data structure during calls to malloc and free  We need to be able to find the next free block that is “a good fit for” a given payload  We need to be able to quickly mark a block as free/allocated  We need to be able to detect when we’re out of blocks.  What do we do when we’re out of blocks?

26 Carnegie Mellon 26 The data structure It would be convenient if it worked like: malloc_struct malloc_data_structure; … ptr = malloc(100, &malloc_data_structure); … free(ptr, &malloc_data_structure); … Instead all we have is the memory we’re giving out.  All of it doesn’t have to be payload! We can use some of that for our data structure.

27 Carnegie Mellon 27 The data structure The data structure IS your memory! A start:   What goes in the header?  That’s your job!  Lets say somebody calls free(p2), how can I coalesce?  Maybe you need a footer? Maybe not?

28 Carnegie Mellon 28 The data structure Common types  Implicit List  Root -> block1 -> block2 -> block3 -> …  Explicit List  Root -> free block 1 -> free block 2 -> free block 3 -> …  Segregated List  Small-malloc root -> free small block 1 -> free small block 2 -> …  Medium-malloc root -> free medium block 1 -> …  Large-malloc root -> free block chunk1 -> …

29 Carnegie Mellon 29 Implicit List From the root, can traverse across blocks using headers Can find a free block this way Can take a while to find a free block  How would you know when you have to call sbrk?

30 Carnegie Mellon 30 Explicit List Improvement over implicit list From a root, keep track of all free blocks in a (doubly) linked list  Remember a doubly linked list has pointers to next and previous When malloc is called, can now find a free block quickly  What happens if the list is a bunch of small free blocks but we want a really big one?  How can we speed this up?

31 Carnegie Mellon 31 Segregated List An optimization for explicit lists Can be thought of as multiple explicit lists  What should we group by? Grouped by size – let’s us quickly find a block of the size we want What size/number of buckets should we use?  This is up to you to decide

32 Carnegie Mellon 32 Design Considerations I found a chunk that fits the necessary payload… should I look for a better fit or not? (First fit vs. Best fit) Splitting a free block: void* ptr = malloc(200); free(ptr); ptr = malloc(50); //use same space, then “mark” remaining bytes as free void* ptr = malloc(200); free(ptr); ptr = malloc(192);//use same space, then “mark” remaining bytes as free??

33 Carnegie Mellon 33 Design Considerations Free blocks: address-ordered or LIFO  What’s the difference?  Pros and cons? Coalescing  When do you coalesce? You will need to be using an explicit list at minimum score points  But don’t try to go straight to your final design, build it up iteratively.

34 Carnegie Mellon 34 Heap Checker Part of the assignment is writing a heap checker  This is here to help you.  Write the heap checker as you go, don’t think of it as something to do at the end  A good heap checker will make debugging much, much easier Heap checker tips  Heap checker should run silently until it finds an error  Otherwise you will get more output than is useful  You might find it useful to add a “verbose” flag, however  Consider using a macro to turn the heap checker on and off  This way you don’t have to edit all of the places you call it  There is a built-in macro called __LINE__ that gets replaced with the line number it’s on  You can use this to make the heap checker tell you where it failed

35 Carnegie Mellon 35 Demo Running Traces Heap checker Using gprof to profile

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