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# Explain this implementation of malloc from the K&R book

This is an excerpt from the book on C by Kernighan and Ritchie. It shows how to implement a version of `malloc`. Although well commented, I am having great difficulty in understanding it. Can somebody please explain it?

``````typedef long Align; /* for alignment to long boundary */
struct {
union header *ptr; /* next block if on free list */
unsigned size; /* size of this block */
} s;
Align x; /* force alignment of blocks */
};

static Header base; /* empty list to get started */
static Header *freep = NULL; /* start of free list */
/* malloc: general-purpose storage allocator */
void *malloc(unsigned nbytes)
{
unsigned nunits;
if ((prevp = freep) == NULL) { /* no free list yet */
base.s.ptr = freeptr = prevptr = &base;
base.s.size = 0;
}
for (p = prevp->s.ptr; ; prevp = p, p = p->s.ptr) {
if (p->s.size >= nunits) { /* big enough */
if (p->s.size == nunits) /* exactly */
prevp->s.ptr = p->s.ptr;
else { /* allocate tail end */
p->s.size -= nunits;
p += p->s.size;
p->s.size = nunits
}
freep = prevp;
return (void *)(p+1);
}
if (p == freep) /* wrapped around free list */
if ((p = morecore(nunits)) == NULL)
return NULL; /* none left */
}
}

#define NALLOC 1024 /* minimum #units to request */
/* morecore: ask system for more memory */

{

char *cp, *sbrk(int);

if (nu < NALLOC)
nu = NALLOC;

if (cp == (char *) -1) /* no space at all */
return NULL;

up->s.size = nu;
free((void *)(up+1));

return freep;
}

/* free: put block ap in free list */
void free(void *ap) {
bp = (Header *)ap - 1; /* point to block header */
for (p = freep; !(bp > p && bp < p->s.ptr); p = p->s.ptr)
if (p >= p->s.ptr && (bp > p || bp < p->s.ptr))
break; /* freed block at start or end of arena */
if (bp + bp->size == p->s.ptr) {
bp->s.size += p->s.ptr->s.size;
bp->s.ptr = p->s.ptr->s.ptr;
} else
bp->s.ptr = p->s.ptr;

if (p + p->size == bp) {
p->s.size += bp->s.size;
p->s.ptr = bp->s.ptr;
} else
p->s.ptr = bp;
freep = p;
}
``````
-

## migrated from codereview.stackexchange.comOct 31 '12 at 13:52

This question came from our site for peer programmer code reviews.

I've got my K&R 2nd edition in front of me - a pretty early printing I would imagine - and it doesn't contain some of the problems the accepted answer refers to. Can I ask which edition you used and whether you typed the code in by hand? – JulianSymes Nov 27 '13 at 10:54
Maybe framing specific questions (eg. why and how exactly are the blocks aligned?) will result in more helpful answers? – Emaad Ahmed Manzoor Sep 10 '15 at 2:38

Ok, what we have here is a chunk of really poorly written code. What I will do in this post could best be described as software archaeology.

Step 1: fix the formatting.

The indention and compact format doesn't do anyone any good. Various spaces and empty rows need to be inserted. The comments could be written in more readable ways. I'll start by fixing that.

At the same time I'm changing the brace style from K&R style - please note that the K&R brace style is acceptable, this is merely a personal preference of mine. Another personal preference is to write the * for pointers next to the type pointed at. I'll not argue about (subjective) style matters here.

Also, the type definition of `Header` is completely unreadable, it needs a drastic fix.

And I spotted something completely obscure: they seem to have declared a function prototype inside the function. `Header* morecore(unsigned);`. This is very old and very poor style, and I'm not sure if C even allows it any longer. Lets just remove that line, whatever that function does, it will have to be defined elsewhere.

``````typedef long Align;                      /* for alignment to long boundary */

{
struct
{
union header *ptr;                   /* next block if on free list */
unsigned size;                       /* size of this block */
} s;

Align x;                               /* force alignment of blocks */

static Header base;                      /* empty list to get started */
static Header* freep = NULL;             /* start of free list */

/* malloc: general-purpose storage allocator */
void* malloc (unsigned nbytes)
{
unsigned  nunits;

if ((prevp = freep) == NULL)           /* no free list yet */
{
base.s.ptr = freeptr = prevptr = &base;
base.s.size = 0;
}

for (p = prevp->s.ptr; ; prevp = p, p = p->s.ptr)
{
if (p->s.size >= nunits)             /* big enough */
{
if (p->s.size == nunits)           /* exactly */
prevp->s.ptr = p->s.ptr;
else                               /* allocate tail end */
{
p->s.size -= nunits;
p += p->s.size;
p->s.size = nunits
}

freep = prevp;
return (void *)(p+1);
}

if (p == freep)                      /* wrapped around free list */
if ((p = morecore(nunits)) == NULL)
return NULL;                     /* none left */
}
}
``````

Ok now we might actually be able to read the code.

Step 2: weed out widely-recognized bad practice.

This code is filled with things that are nowadays regarded as bad practice. They need to be removed, since they jeopardize the safety, readability and maintenance of the code. If you want a reference to an authority preaching the same practices as me, check out the widely-recognized coding standard MISRA-C.

I have spotted and removed the following bad practices:

1) Just typing `unsigned` in the code could lead to be confusion: was this a typo by the programmer or was the intention to write `unsigned int`? We should replace all `unsigned` with `unsigned int`. But as we do that, we find that it is used in this context to give the size of various binary data. The correct type to use for such matters is the C standard type `size_t`. This is essentially just an unsigned int as well, but it is guaranteed to be "large enough" for the particular platform. The `sizeof` operator returns a result of type `size_t` and if we look at the C standard's definition of the real malloc, it is `void *malloc(size_t size);`. So `size_t` is the most correct type to use.

2) It is a bad idea to use the same name for our own malloc function as the one residing in stdlib.h. Should we need to include stdlib.h, things will get messy. As a rule of thumb, never use identifier names of C standard library functions in your own code. I'll change the name to kr_malloc.

3) The code is abusing the fact that all static variables are guaranteed to be initialized to zero. This is well-defined by the C standard, but a rather subtle rule. Lets initialize all statics explicitly, to show that we haven't forgotten to init them by accident.

4) Assignment inside conditions is dangerous and hard to read. This should be avoided if possible, since it can also lead to bugs, such as the classic = vs == bug.

5) Multiple assignments on the same row is hard to read, and also possibly dangerous, because of the order of evaluation.

6) Multiple declarations on the same row is hard to read, and dangerous, since it could lead to bugs when mixing data and pointer declarations. Always declare each variable on a row of its own.

7) Always uses braces after every statement. Not doing so will lead to bugs bugs bugs.

8) Never type cast from a specific pointer type to void*. It is unnecessary in C, and could hide away bugs that the compiler would otherwise have detected.

9) Avoid using multiple return statements inside a function. Sometimes they lead to clearer code, but in most cases they lead to spaghetti. As the code stands, we can't change that without rewriting the loop though, so I will fix this later.

10) Keep for loops simple. They should contain one init statement, one loop condition and one iteration, nothing else. This for loop, with the comma operator and everything, is very obscure. Again, we spot a need to rewrite this loop into something sane. I'll do this next, but for now we have:

``````typedef long Align;                      /* for alignment to long boundary */

{
struct
{
union header *ptr;                   /* next block if on free list */
size_t size;                         /* size of this block */
} s;

Align x;                               /* force alignment of blocks */

static Header base = {0};                /* empty list to get started */
static Header* freep = NULL;             /* start of free list */

/* malloc: general-purpose storage allocator */
void* kr_malloc (size_t nbytes)
{
size_t   nunits;

prevp = freep;
if (prevp == NULL)                     /* no free list yet */
{
base.s.ptr  = &base;
freeptr     = &base;
prevptr     = &base;
base.s.size = 0;
}

for (p = prevp->s.ptr; ; prevp = p, p = p->s.ptr)
{
if (p->s.size >= nunits)             /* big enough */
{
if (p->s.size == nunits)           /* exactly */
{
prevp->s.ptr = p->s.ptr;
}
else                               /* allocate tail end */
{
p->s.size -= nunits;
p += p->s.size;
p->s.size = nunits
}

freep = prevp;
return p+1;
}

if (p == freep)                      /* wrapped around free list */
{
p = morecore(nunits);
if (p == NULL)
{
return NULL;                     /* none left */
}
}
} /* for */
}
``````

Step 3: rewrite the obscure loop.

For the reasons mentioned earlier. We can see that this loop goes on forever, it terminates by returning from the function, either when the allocation is done, or when there is no memory left. So lets create that as a loop condition, and lift out the return to the end of the function where it should be. And lets get rid of that ugly comma operator.

I'll introduce two new variables: one result variable to hold the resulting pointer, and another to keep track of whether the loop should continue or not. I'll blow K&R's minds by using the `bool` type, which is part of the C language since 1999.

(I hope I haven't altered the algorithm with this change, I believe I haven't)

``````#include <stdbool.h>

typedef long Align;                      /* for alignment to long boundary */

{
struct
{
union header *ptr;                   /* next block if on free list */
size_t size;                         /* size of this block */
} s;

Align x;                               /* force alignment of blocks */

static Header base = {0};                /* empty list to get started */
static Header* freep = NULL;             /* start of free list */

/* malloc: general-purpose storage allocator */
void* kr_malloc (size_t nbytes)
{
size_t   nunits;
void*    result;
bool     is_allocating;

prevp = freep;
if (prevp == NULL)                     /* no free list yet */
{
base.s.ptr  = &base;
freeptr     = &base;
prevptr     = &base;
base.s.size = 0;
}

is_allocating = true;
for (p = prevp->s.ptr; is_allocating; p = p->s.ptr)
{
if (p->s.size >= nunits)             /* big enough */
{
if (p->s.size == nunits)           /* exactly */
{
prevp->s.ptr = p->s.ptr;
}
else                               /* allocate tail end */
{
p->s.size -= nunits;
p += p->s.size;
p->s.size = nunits
}

freep = prevp;
result = p+1;
is_allocating = false;             /* we are done */
}

if (p == freep)                      /* wrapped around free list */
{
p = morecore(nunits);
if (p == NULL)
{
result = NULL;                   /* none left */
is_allocating = false;
}
}
prevp = p;
} /* for */

return result;
}
``````

Step 4: make this crap compile.

Since this is from K&R, it is filled with typos. `sizeof(header)` should be `sizeof(Header)`. There are missing semi-colons. They use different names freep, prevp versus freeptr, prevptr, but clearly mean the same variable. I believe the latter were actually better names, so lets use those.

``````#include <stdbool.h>

typedef long Align;                      /* for alignment to long boundary */

{
struct
{
union header *ptr;                   /* next block if on free list */
size_t size;                         /* size of this block */
} s;

Align x;                               /* force alignment of blocks */

static Header base = {0};                /* empty list to get started */
static Header* freeptr = NULL;           /* start of free list */

/* malloc: general-purpose storage allocator */
void* kr_malloc (size_t nbytes)
{
size_t   nunits;
void*    result;
bool     is_allocating;

prevptr = freeptr;
if (prevptr == NULL)                   /* no free list yet */
{
base.s.ptr  = &base;
freeptr     = &base;
prevptr     = &base;
base.s.size = 0;
}

is_allocating = true;
for (p = prevptr->s.ptr; is_allocating; p = p->s.ptr)
{
if (p->s.size >= nunits)             /* big enough */
{
if (p->s.size == nunits)           /* exactly */
{
prevptr->s.ptr = p->s.ptr;
}
else                               /* allocate tail end */
{
p->s.size -= nunits;
p += p->s.size;
p->s.size = nunits;
}

freeptr = prevptr;
result = p+1;
is_allocating = false;             /* we are done */
}

if (p == freeptr)                    /* wrapped around free list */
{
p = morecore(nunits);
if (p == NULL)
{
result = NULL;                   /* none left */
is_allocating = false;
}
}
prevptr = p;
} /* for */

return result;
}
``````

And now we have somewhat readable, maintainable code, without numerous dangerous practices, that will even compile! So now we could actually start to ponder about what the code is actually doing.

The struct "Header" is, as you might have guessed, the declaration of a node in a linked list. Each such node contains a pointer to the next one. I don't quite understand the morecore function, nor the "wrap-around", I have never used this function, nor `sbrk`. But I assume that it allocates a header as specified in this struct, and also some chunk of raw data following that header. If so, that explains why there is no actual data pointer: the data is assumed to follow the header, adjacently in memory. So for each node, we get the header, and we get a chunk of raw data following the header.

The iteration itself is pretty straight-forward, they are going through a single-linked list, one node at a time.

At the end of the loop, they set the pointer to point one past the end of the "chunk", then store that in a static variable, so that the program will remember where it previously allocated memory, next time the function is called.

They are using a trick to make their header end up on an aligned memory address: they store all the overhead info in a union together with a variable large enough to correspond to the platform's alignment requirement. So if the size of "ptr" plus the size of "size" are too small to give the exact alignment, the union guarantees that at least sizeof(Align) bytes are allocated. I believe that this whole trick is obsolete today, since the C standard mandates automatic struct/union padding.

-
Most of the bad practices you mentioned aren't, they're language features. I kind of agree with #1; #2 is irrelevant, and the rest is a matter of style. – netcoder Oct 31 '12 at 13:57
In my 25+ years of coding, this is the first time I've ever heard K&R called "incredibly hyped up" and flawed. – Rob Oct 31 '12 at 13:59
@Rob Are you also using 25+ years old compilers? 25+ year old OS? On a 25+ year old computer? There is plenty of perfectly valid criticism against the book if you only look around. If you are going to down vote me just because I told you that the sun is the center of the solar system, and not the earth, at least provide some rationale over why you think I'm wrong. I'd just love to hear your logical reasoning over why the original code is oh-so-good. It will even enforce you to make your own opinion about the book, instead of following the convenient bandwagon. – Lundin Oct 31 '12 at 14:21
@Cupidvogel: Spreading information as factual when it is totally subjective is a good enough reason for me. – netcoder Oct 31 '12 at 20:07
and we never did get to explaining how the code actually works – pm100 Oct 8 '14 at 23:32

I'm studying K&R as I'd imagine OP was when he asked this question, and I came here because I also found these implementations to be confusing. While the accepted answer is very detailed and helpful, I tried to take a different tack which was to understand the code as it was originally written - I've gone through the code and added comments to the sections of the code that were difficult to me. This includes code for the other routines in the section (which are the functions `free` and `memcore` - I've renamed them `kandr_malloc` and `kandr_free` to avoid conflicts with the stdlib). I thought I would leave this here as a supplement to the accepted answer, for other students who may find it helpful.

I acknowledge that the comments in this code are excessive. Please know that I am only doing this as a learning exercise and I am not proposing that this is a good way to actually write code.

I took the liberty of changing some variable names to ones that seemed more intuitive to me; other than that the code is essentially left intact. It seems to compile and run fine for the test programs that I used, although valgrind had complaints for some applications.

Also: some of the text in the comments is lifted directly from K&R or the man pages - I do not intend to take any credit for these sections.

``````#include <unistd.h>  // sbrk

#define NALLOC 1024  // Number of block sizes to allocate on call to sbrk
#ifdef NULL
#undef NULL
#endif
#define NULL 0

// long is chosen as an instance of the most restrictive alignment type
typedef long Align;

/* Construct Header data structure.  To ensure that the storage returned by
* kandr_malloc is aligned properly for the objects that are stored in it, all
* blocks are multiples of the header size, and the header itself is aligned
* properly.  This is achieved through the use of a union; this data type is big
* enough to hold the "widest" member, and the alignment is appropriate for all
* of the types in the union.  Thus by including a member of type Align, which
* is an instance of the most restrictive type, we guarantee that the size of
* Header is aligned to the worst-case boundary.  The Align field is never used;
* it just forces each header to the desired alignment.
*/
struct {
unsigned size;
} s;

Align x;
};

static Header *freep = NULL;  // Free list starting point

void kandr_free(void *ptr);

void *kandr_malloc(unsigned nbytes) {

unsigned nunits;

/* Calculate the number of memory units needed to provide at least nbytes of
* memory.
*
* Suppose that we need n >= 0 bytes and that the memory unit sizes are b > 0
* bytes.  Then n / b (using integer division) yields one less than the number
* of units needed to provide n bytes of memory, except in the case that n is
* a multiple of b; then it provides exactly the number of units needed.  It
* can be verified that (n - 1) / b provides one less than the number of units
* needed to provide n bytes of memory for all values of n > 0.  Thus ((n - 1)
* / b) + 1 provides exactly the number of units needed for n > 0.
*
* The extra sizeof(Header) in the numerator is to include the unit of memory
* needed for the header itself.
*/

// case: no free list yet exists; we have to initialize.
if (freep == NULL) {

// Create degenerate free list; base points to itself and has size 0
base.s.next = &base;
base.s.size = 0;

// Set free list starting point to base address
freep = &base;
}

/* Initialize pointers to two consecutive blocks in the free list, which we
* call prevp (the previous block) and currp (the current block)
*/
prevp = freep;
currp = prevp->s.next;

/* Step through the free list looking for a block of memory large enough to
* fit nunits units of memory into.  If the whole list is traversed without
* finding such a block, then morecore is called to request more memory from
* the OS.
*/
for (; ; prevp = currp, currp = currp->s.next) {

/* case: found a block of memory in free list large enough to fit nunits
* units of memory into.  Partition block if necessary, remove it from the
* free list, and return the address of the block (after moving past the
*/
if (currp->s.size >= nunits) {

/* case: block is exactly the right size; remove the block from the free
* list by pointing the previous block to the next block.
*/
if (currp->s.size == nunits) {
/* Note that this line wouldn't work as intended if we were down to only
* 1 block.  However, we would never make it here in that scenario
* because the block at &base has size 0 and thus the conditional will
* fail (note that nunits is always >= 1).  It is true that if the block
* at &base had combined with another block, then previous statement
* wouldn't apply - but presumably since base is a global variable and
* future blocks are allocated on the heap, we can be sure that they
* won't border each other.
*/
prevp->s.next = currp->s.next;
}
/* case: block is larger than the amount of memory asked for; allocate
* tail end of the block to the user.
*/
else {
// Changes the memory stored at currp to reflect the reduced block size
currp->s.size -= nunits;
// Find location at which to create the block header for the new block
currp += currp->s.size;
// Store the block size in the new header
currp->s.size = nunits;
}

/* Set global starting position to the previous pointer.  Next call to
* malloc will start either at the remaining part of the partitioned block
* if a partition occurred, or at the block after the selected block if
* not.
*/
freep = prevp;

/* Return the location of the start of the memory, i.e. after adding one
* so as to move past the header
*/
return (void *) (currp + 1);

} // end found a block of memory in free list case

/* case: we've wrapped around the free list without finding a block large
* enough to fit nunits units of memory into.  Call morecore to request that
* at least nunits units of memory are allocated.
*/
if (currp == freep) {
/* morecore returns freep; the reason that we have to assign currp to it
* again (since we just tested that they are equal), is that there is a
* call to free inside of morecore that can potentially change the value
* of freep.  Thus we reassign it so that we can be assured that the newly
* added block is found before (currp == freep) again.
*/
if ((currp = morecore(nunits)) == NULL) {
return NULL;
}
} // end wrapped around free list case
} // end step through free list looking for memory loop
}

void *freemem;    // The address of the newly created memory

/* Obtaining memory from OS is a comparatively expensive operation, so obtain
* at least NALLOC blocks of memory and partition as needed
*/
if (nunits < NALLOC) {
nunits = NALLOC;
}

/* Request that the OS increment the program's data space.  sbrk changes the
* location of the program break, which defines the end of the process's data
* segment (i.e., the program break is the first location after the end of the
* uninitialized data segment).  Increasing the program break has the effect
* of allocating memory to the process.  On success, brk returns the previous
* break - so if the break was increased, then this value is a pointer to the
* start of the newly allocated memory.
*/
// case: unable to allocate more memory; sbrk returns (void *) -1 on error
if (freemem == (void *) -1) {
return NULL;
}

// Construct new block
insertp->s.size = nunits;

/* Insert block into the free list so that it is available for malloc.  Note
* that we add 1 to the address, effectively moving to the first position
* after the header data, since of course we want the block header to be
* transparent for the user's interactions with malloc and free.
*/
kandr_free((void *) (insertp + 1));

/* Returns the start of the free list; recall that freep has been set to the
* block immediately preceeding the newly allocated memory (by free).  Thus by
* returning this value the calling function can immediately find the new
* memory by following the pointer to the next block.
*/
return freep;
}

void kandr_free(void *ptr) {

// Find address of block header for the data to be inserted
insertp = ((Header *) ptr) - 1;

/* Step through the free list looking for the position in the list to place
* the insertion block.  In the typical circumstances this would be the block
* immediately to the left of the insertion block; this is checked for by
* finding a block that is to the left of the insertion block and such that
* the following block in the list is to the right of the insertion block.
* However this check doesn't check for one such case, and misses another.  We
* still have to check for the cases where either the insertion block is
* either to the left of every other block owned by malloc (the case that is
* missed), or to the right of every block owned by malloc (the case not
* checked for).  These last two cases are what is checked for by the
* condition inside of the body of the loop.
*/
for (currp = freep; !((currp < insertp) && (insertp < currp->s.next)); currp = currp->s.next) {

/* currp >= currp->s.ptr implies that the current block is the rightmost
* block in the free list.  Then if the insertion block is to the right of
* that block, then it is the new rightmost block; conversely if it is to
* the left of the block that currp points to (which is the current leftmost
* block), then the insertion block is the new leftmost block.  Note that
* this conditional handles the case where we only have 1 block in the free
* list (this case is the reason that we need >= in the first test rather
* than just >).
*/
if ((currp >= currp->s.next) && ((currp < insertp) || (insertp < currp->s.next))) {
break;
}
}

/* Having found the correct location in the free list to place the insertion
* block, now we have to (i) link it to the next block, and (ii) link the
* previous block to it.  These are the tasks of the next two if/else pairs.
*/

/* case: the end of the insertion block is adjacent to the beginning of
* another block of data owned by malloc.  Absorb the block on the right into
* the block on the left (i.e. the previously existing block is absorbed into
* the insertion block).
*/
if ((insertp + insertp->s.size) == currp->s.next) {
insertp->s.size += currp->s.next->s.size;
insertp->s.next = currp->s.next->s.next;
}
/* case: the insertion block is not left-adjacent to the beginning of another
* block of data owned by malloc.  Set the insertion block member to point to
* the next block in the list.
*/
else {
insertp->s.next = currp->s.next;
}

/* case: the end of another block of data owned by malloc is adjacent to the
* beginning of the insertion block.  Absorb the block on the right into the
* block on the left (i.e. the insertion block is absorbed into the preceeding
* block).
*/
if ((currp + currp->s.size) == insertp) {
currp->s.size += insertp->s.size;
currp->s.next = insertp->s.next;
}
/* case: the insertion block is not right-adjacent to the end of another block
* of data owned by malloc.  Set the previous block in the list to point to
* the insertion block.
*/
else {
currp->s.next = insertp;
}

/* Set the free pointer list to start the block previous to the insertion
* block.  This makes sense because calls to malloc start their search for
* memory at the next block after freep, and the insertion block has as good a
* chance as any of containing a reasonable amount of memory since we've just
* added some to it.  It also coincides with calls to morecore from
* kandr_malloc because the next search in the iteration looks at exactly the
* right memory block.
*/
freep = currp;
}
``````
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Good lord, that is such a thorough and detailed answer! Thanks! I am broke now, but one day I will be rich (with SO credits), and then I will award you a thoroughly deserved bounty.. :) Having said that, although it is well commented, I am still having problems with the utility of the `Align` word and what it does, and what you mean by alignment. Can you explain a bit more? – AttitudeMonger Apr 9 at 11:22
I'm only learning these concepts myself right now, so I can only say what I think is happening. Computer architectures operate on words, i.e. 32- or 64- bit segments of data. The `malloc` routine here operates on multiples of a particular unit size of memory, defined as `sizeof(Header)`. When we allocate data we need it to start and end at word boundaries. So I think they choose a data type that has a full word length, which guarantees that `sizeof(Header)` is a multiple of the word size, and consequently that `malloc` allocates data that starts and ends on the word boundaries. – dpritch Apr 9 at 19:20