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/* vim: tabstop=4 shiftwidth=4 noexpandtab
*
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* klange ' s Slab Allocator
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*
* Implemented for CS241 , Fall 2010 , machine problem 7
* at the University of Illinois , Urbana - Champaign .
*
* Overall competition winner for speed .
* Well ranked in memory usage .
*
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* Copyright ( c ) 2010 - 2018 K . Lange . All rights reserved .
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*
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* Developed by : K . Lange < klange @ toaruos . org >
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* Dave Majnemer < dmajnem2 @ acm . uiuc . edu >
* Assocation for Computing Machinery
* University of Illinois , Urbana - Champaign
* http : //acm.uiuc.edu
*
* Permission is hereby granted , free of charge , to any person obtaining a copy
* of this software and associated documentation files ( the " Software " ) , to
* deal with the Software without restriction , including without limitation the
* rights to use , copy , modify , merge , publish , distribute , sublicense , and / or
* sell copies of the Software , and to permit persons to whom the Software is
* furnished to do so , subject to the following conditions :
* 1. Redistributions of source code must retain the above copyright notice ,
* this list of conditions and the following disclaimers .
* 2. Redistributions in binary form must reproduce the above copyright
* notice , this list of conditions and the following disclaimers in the
* documentation and / or other materials provided with the distribution .
* 3. Neither the names of the Association for Computing Machinery , the
* University of Illinois , nor the names of its contributors may be used
* to endorse or promote products derived from this Software without
* specific prior written permission .
*
* THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
* IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
* CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
* LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING
* FROM , OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* WITH THE SOFTWARE .
*
* # # # # # # # # # #
* # README #
* # # # # # # # # # #
*
* About the slab allocator
* " " " " " " " " " " " " " " " " " " " " " " " "
*
* This is a simple implementation of a " slab " allocator . It works by operating
* on " bins " of items of predefined sizes and a set of pseudo - bins of any size .
* When a new allocation request is made , the allocator determines if it will
* fit in an existing bin . If there are no bins of the correct size for a given
* allocation request , the allocator will make a bin and add it to a ( n empty )
* list of available bins of that size . In this implementation , we use sizes
* from 4 bytes ( 32 bit ) or 8 bytes ( 64 - bit ) to 2 KB for bins , fitting a 4 K page
* size . The implementation allows the number of pages in a single bin to be
* increased , as well as allowing for changing the size of page ( though this
* should , for the most part , remain 4 KB under any modern system ) .
*
* Special thanks
* " " " " " " " " " " " " " "
*
* I would like to thank Dave Majnemer , who I have credited above as a
* contributor , for his assistance . Without Dave , klmalloc would be a mash
* up of bits of forward movement in no discernible pattern . Dave helped
* me ensure that I could build a proper slab allocator and has consantly
* derided me for not fixing the bugs and to - do items listed in the last
* section of this readme .
*
* GCC Function Attributes
* " " " " " " " " " " " " " " " " " " " " " " "
*
* A couple of GCC function attributes , designated by the __attribute__
* directive , are used in this code to streamline optimization .
* I ' ve chosen to include a brief overview of the particular attributes
* I am making use of :
*
* - malloc :
* Tells gcc that a given function is a memory allocator
* and that non - NULL values it returns should never be
* associated with other chunks of memory . We use this for
* alloc , realloc and calloc , as is requested in the gcc
* documentation for the attribute .
*
* - always_inline :
* Tells gcc to always inline the given code , regardless of the
* optmization level . Small functions that would be noticeably
* slower with the overhead of paramter handling are given
* this attribute .
*
* - pure :
* Tells gcc that a function only uses inputs and its output .
*
* Things to work on
* " " " " " " " " " " " " " " " " "
*
* TODO : Try to be more consistent on comment widths . . .
* FIXME : Make thread safe ! Not necessary for competition , but would be nice .
* FIXME : Splitting / coalescing is broken . Fix this ASAP !
*
* */
/* Includes {{{ */
# include <syscall.h>
# include <assert.h>
# include <stdint.h>
# include <limits.h>
# include <string.h>
/* }}} */
/* Definitions {{{ */
# define sbrk syscall_sbrk
/*
* Defines for often - used integral values
* related to our binning and paging strategy .
*/
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# ifdef __x86_64__
# define NUM_BINS 10U /* Number of bins, total, under 64-bit. */
# define SMALLEST_BIN_LOG 3U /* Logarithm base two of the smallest bin: log_2(sizeof(int32)). */
# else
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# define NUM_BINS 11U /* Number of bins, total, under 32-bit. */
# define SMALLEST_BIN_LOG 2U /* Logarithm base two of the smallest bin: log_2(sizeof(int32)). */
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# endif
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# define BIG_BIN (NUM_BINS - 1) /* Index for the big bin, (NUM_BINS - 1) */
# define SMALLEST_BIN (1UL << SMALLEST_BIN_LOG) /* Size of the smallest bin. */
# define PAGE_SIZE 0x1000 /* Size of a page (in bytes), should be 4KB */
# define PAGE_MASK (PAGE_SIZE - 1) /* Block mask, size of a page * number of pages - 1. */
# define SKIP_P INT32_MAX /* INT32_MAX is half of UINT32_MAX; this gives us a 50% marker for skip lists. */
# define SKIP_MAX_LEVEL 6 /* We have a maximum of 6 levels in our skip lists. */
# define BIN_MAGIC 0xDEFAD00D
/* }}} */
/*
* Internal functions .
*/
static void * __attribute__ ( ( malloc ) ) klmalloc ( uintptr_t size ) ;
static void * __attribute__ ( ( malloc ) ) klrealloc ( void * ptr , uintptr_t size ) ;
static void * __attribute__ ( ( malloc ) ) klcalloc ( uintptr_t nmemb , uintptr_t size ) ;
static void * __attribute__ ( ( malloc ) ) klvalloc ( uintptr_t size ) ;
static void klfree ( void * ptr ) ;
static int volatile mem_lock = 0 ;
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static const char * _lock_holder ;
# ifdef assert
# undef assert
# define assert(statement) ((statement) ? (void)0 : _malloc_assert(__FILE__, __LINE__, __FUNCTION__, #statement))
# endif
# define WRITE(x) syscall_write(2, (char*)x, sizeof(x))
# define WRITEV(x) syscall_write(2, (char*)x, strlen(x))
static void _malloc_assert ( const char * file , int line , const char * func , const char * x ) {
WRITEV ( func ) ;
WRITE ( " in " ) ;
WRITEV ( file ) ;
WRITE ( " failed assertion: " ) ;
WRITEV ( x ) ;
WRITE ( " \n " ) ;
exit ( 1 ) ;
}
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extern int __libc_is_multicore ;
static inline void _yield ( void ) {
if ( ! __libc_is_multicore ) syscall_yield ( ) ;
}
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static void spin_lock ( int volatile * lock , const char * caller ) {
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while ( __sync_lock_test_and_set ( lock , 0x01 ) ) {
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_yield ( ) ;
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}
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_lock_holder = caller ;
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}
static void spin_unlock ( int volatile * lock ) {
__sync_lock_release ( lock ) ;
}
void * __attribute__ ( ( malloc ) ) malloc ( uintptr_t size ) {
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spin_lock ( & mem_lock , __FUNCTION__ ) ;
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void * ret = klmalloc ( size ) ;
spin_unlock ( & mem_lock ) ;
return ret ;
}
void * __attribute__ ( ( malloc ) ) realloc ( void * ptr , uintptr_t size ) {
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spin_lock ( & mem_lock , __FUNCTION__ ) ;
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void * ret = klrealloc ( ptr , size ) ;
spin_unlock ( & mem_lock ) ;
return ret ;
}
void * __attribute__ ( ( malloc ) ) calloc ( uintptr_t nmemb , uintptr_t size ) {
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spin_lock ( & mem_lock , __FUNCTION__ ) ;
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void * ret = klcalloc ( nmemb , size ) ;
spin_unlock ( & mem_lock ) ;
return ret ;
}
void * __attribute__ ( ( malloc ) ) valloc ( uintptr_t size ) {
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spin_lock ( & mem_lock , __FUNCTION__ ) ;
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void * ret = klvalloc ( size ) ;
spin_unlock ( & mem_lock ) ;
return ret ;
}
void free ( void * ptr ) {
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spin_lock ( & mem_lock , __FUNCTION__ ) ;
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klfree ( ptr ) ;
spin_unlock ( & mem_lock ) ;
}
/* Bin management {{{ */
/*
* Adjust bin size in bin_size call to proper bounds .
*/
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static inline uintptr_t __attribute__ ( ( always_inline , pure ) ) klmalloc_adjust_bin ( uintptr_t bin )
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{
if ( bin < = ( uintptr_t ) SMALLEST_BIN_LOG )
{
return 0 ;
}
bin - = SMALLEST_BIN_LOG + 1 ;
if ( bin > ( uintptr_t ) BIG_BIN ) {
return BIG_BIN ;
}
return bin ;
}
/*
* Given a size value , find the correct bin
* to place the requested allocation in .
*/
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static inline uintptr_t __attribute__ ( ( always_inline , pure ) ) klmalloc_bin_size ( uintptr_t size ) {
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uintptr_t bin = sizeof ( size ) * CHAR_BIT - __builtin_clzl ( size ) ;
bin + = ! ! ( size & ( size - 1 ) ) ;
return klmalloc_adjust_bin ( bin ) ;
}
/*
* Bin header - One page of memory .
* Appears at the front of a bin to point to the
* previous bin ( or NULL if the first ) , the next bin
* ( or NULL if the last ) and the head of the bin , which
* is a stack of cells of data .
*/
typedef struct _klmalloc_bin_header {
struct _klmalloc_bin_header * next ; /* Pointer to the next node. */
void * head ; /* Head of this bin. */
uintptr_t size ; /* Size of this bin, if big; otherwise bin index. */
uint32_t bin_magic ;
} klmalloc_bin_header ;
/*
* A big bin header is basically the same as a regular bin header
* only with a pointer to the previous ( physically ) instead of
* a " next " and with a list of forward headers .
*/
typedef struct _klmalloc_big_bin_header {
struct _klmalloc_big_bin_header * next ;
void * head ;
uintptr_t size ;
uint32_t bin_magic ;
struct _klmalloc_big_bin_header * prev ;
struct _klmalloc_big_bin_header * forward [ SKIP_MAX_LEVEL + 1 ] ;
} klmalloc_big_bin_header ;
/*
* List of pages in a bin .
*/
typedef struct _klmalloc_bin_header_head {
klmalloc_bin_header * first ;
} klmalloc_bin_header_head ;
/*
* Array of available bins .
*/
static klmalloc_bin_header_head klmalloc_bin_head [ NUM_BINS - 1 ] ; /* Small bins */
static struct _klmalloc_big_bins {
klmalloc_big_bin_header head ;
int level ;
} klmalloc_big_bins ;
static klmalloc_big_bin_header * klmalloc_newest_big = NULL ; /* Newest big bin */
/* }}} Bin management */
/* Doubly-Linked List {{{ */
/*
* Remove an entry from a page list .
* Decouples the element from its
* position in the list by linking
* its neighbors to eachother .
*/
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static inline void __attribute__ ( ( always_inline ) ) klmalloc_list_decouple ( klmalloc_bin_header_head * head , klmalloc_bin_header * node ) {
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klmalloc_bin_header * next = node - > next ;
head - > first = next ;
node - > next = NULL ;
}
/*
* Insert an entry into a page list .
* The new entry is placed at the front
* of the list and the existing border
* elements are updated to point back
* to it ( our list is doubly linked ) .
*/
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static inline void __attribute__ ( ( always_inline ) ) klmalloc_list_insert ( klmalloc_bin_header_head * head , klmalloc_bin_header * node ) {
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node - > next = head - > first ;
head - > first = node ;
}
/*
* Get the head of a page list .
* Because redundant function calls
* are really great , and just in case
* we change the list implementation .
*/
static inline klmalloc_bin_header * __attribute__ ( ( always_inline ) ) klmalloc_list_head ( klmalloc_bin_header_head * head ) {
return head - > first ;
}
/* }}} Lists */
/* Skip List {{{ */
/*
* Skip lists are efficient
* data structures for storing
* and searching ordered data .
*
* Here , the skip lists are used
* to keep track of big bins .
*/
/*
* Generate a random value in an appropriate range .
* This is a xor - shift RNG .
*/
static uint32_t __attribute__ ( ( pure ) ) klmalloc_skip_rand ( void ) {
static uint32_t x = 123456789 ;
static uint32_t y = 362436069 ;
static uint32_t z = 521288629 ;
static uint32_t w = 88675123 ;
uint32_t t ;
t = x ^ ( x < < 11 ) ;
x = y ; y = z ; z = w ;
return w = w ^ ( w > > 19 ) ^ t ^ ( t > > 8 ) ;
}
/*
* Generate a random level for a skip node
*/
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static inline int __attribute__ ( ( pure , always_inline ) ) klmalloc_random_level ( void ) {
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int level = 0 ;
/*
* Keep trying to check rand ( ) against 50 % of its maximum .
* This provides 50 % , 25 % , 12.5 % , etc . chance for each level .
*/
while ( klmalloc_skip_rand ( ) < SKIP_P & & level < SKIP_MAX_LEVEL ) {
+ + level ;
}
return level ;
}
/*
* Find best fit for a given value .
*/
static klmalloc_big_bin_header * klmalloc_skip_list_findbest ( uintptr_t search_size ) {
klmalloc_big_bin_header * node = & klmalloc_big_bins . head ;
/*
* Loop through the skip list until we hit something > our search value .
*/
int i ;
for ( i = klmalloc_big_bins . level ; i > = 0 ; - - i ) {
while ( node - > forward [ i ] & & ( node - > forward [ i ] - > size < search_size ) ) {
node = node - > forward [ i ] ;
if ( node )
assert ( ( node - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
}
}
/*
* This value will either be NULL ( we found nothing )
* or a node ( we found a minimum fit ) .
*/
node = node - > forward [ 0 ] ;
if ( node ) {
assert ( ( uintptr_t ) node % PAGE_SIZE = = 0 ) ;
assert ( ( node - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
}
return node ;
}
/*
* Insert a header into the skip list .
*/
static void klmalloc_skip_list_insert ( klmalloc_big_bin_header * value ) {
/*
* You better be giving me something valid to insert ,
* or I will slit your * * * * ing throat .
*/
assert ( value ! = NULL ) ;
assert ( value - > head ! = NULL ) ;
assert ( ( uintptr_t ) value - > head > ( uintptr_t ) value ) ;
if ( value - > size > NUM_BINS ) {
assert ( ( uintptr_t ) value - > head < ( uintptr_t ) value + value - > size ) ;
} else {
assert ( ( uintptr_t ) value - > head < ( uintptr_t ) value + PAGE_SIZE ) ;
}
assert ( ( uintptr_t ) value % PAGE_SIZE = = 0 ) ;
assert ( ( value - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
assert ( value - > size ! = 0 ) ;
/*
* Starting from the head node of the bin locator . . .
*/
klmalloc_big_bin_header * node = & klmalloc_big_bins . head ;
klmalloc_big_bin_header * update [ SKIP_MAX_LEVEL + 1 ] ;
/*
* Loop through the skiplist to find the right place
* to insert the node ( where - > forward [ ] > value )
*/
int i ;
for ( i = klmalloc_big_bins . level ; i > = 0 ; - - i ) {
while ( node - > forward [ i ] & & node - > forward [ i ] - > size < value - > size ) {
node = node - > forward [ i ] ;
if ( node )
assert ( ( node - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
}
update [ i ] = node ;
}
node = node - > forward [ 0 ] ;
/*
* Make the new skip node and update
* the forward values .
*/
if ( node ! = value ) {
int level = klmalloc_random_level ( ) ;
/*
* Get all of the nodes before this .
*/
if ( level > klmalloc_big_bins . level ) {
for ( i = klmalloc_big_bins . level + 1 ; i < = level ; + + i ) {
update [ i ] = & klmalloc_big_bins . head ;
}
klmalloc_big_bins . level = level ;
}
/*
* Make the new node .
*/
node = value ;
/*
* Run through and point the preceeding nodes
* for each level to the new node .
*/
for ( i = 0 ; i < = level ; + + i ) {
node - > forward [ i ] = update [ i ] - > forward [ i ] ;
if ( node - > forward [ i ] )
assert ( ( node - > forward [ i ] - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
update [ i ] - > forward [ i ] = node ;
}
}
}
/*
* Delete a header from the skip list .
* Be sure you didn ' t change the size , or we won ' t be able to find it .
*/
static void klmalloc_skip_list_delete ( klmalloc_big_bin_header * value ) {
/*
* Debug assertions
*/
assert ( value ! = NULL ) ;
assert ( value - > head ) ;
assert ( ( uintptr_t ) value - > head > ( uintptr_t ) value ) ;
if ( value - > size > NUM_BINS ) {
assert ( ( uintptr_t ) value - > head < ( uintptr_t ) value + value - > size ) ;
} else {
assert ( ( uintptr_t ) value - > head < ( uintptr_t ) value + PAGE_SIZE ) ;
}
/*
* Starting from the bin header , again . . .
*/
klmalloc_big_bin_header * node = & klmalloc_big_bins . head ;
klmalloc_big_bin_header * update [ SKIP_MAX_LEVEL + 1 ] ;
/*
* Find the node .
*/
int i ;
for ( i = klmalloc_big_bins . level ; i > = 0 ; - - i ) {
while ( node - > forward [ i ] & & node - > forward [ i ] - > size < value - > size ) {
node = node - > forward [ i ] ;
if ( node )
assert ( ( node - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
}
update [ i ] = node ;
}
node = node - > forward [ 0 ] ;
while ( node ! = value ) {
node = node - > forward [ 0 ] ;
}
if ( node ! = value ) {
node = klmalloc_big_bins . head . forward [ 0 ] ;
while ( node - > forward [ 0 ] & & node - > forward [ 0 ] ! = value ) {
node = node - > forward [ 0 ] ;
}
node = node - > forward [ 0 ] ;
}
/*
* If we found the node , delete it ;
* otherwise , we do nothing .
*/
if ( node = = value ) {
for ( i = 0 ; i < = klmalloc_big_bins . level ; + + i ) {
if ( update [ i ] - > forward [ i ] ! = node ) {
break ;
}
update [ i ] - > forward [ i ] = node - > forward [ i ] ;
if ( update [ i ] - > forward [ i ] ) {
assert ( ( uintptr_t ) ( update [ i ] - > forward [ i ] ) % PAGE_SIZE = = 0 ) ;
assert ( ( update [ i ] - > forward [ i ] - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
}
}
while ( klmalloc_big_bins . level > 0 & & klmalloc_big_bins . head . forward [ klmalloc_big_bins . level ] = = NULL ) {
- - klmalloc_big_bins . level ;
}
}
}
/* }}} */
/* Stack {{{ */
/*
* Pop an item from a block .
* Free space is stored as a stack ,
* so we get a free space for a bin
* by popping a free node from the
* top of the stack .
*/
static void * klmalloc_stack_pop ( klmalloc_bin_header * header ) {
assert ( header ) ;
assert ( header - > head ! = NULL ) ;
assert ( ( uintptr_t ) header - > head > ( uintptr_t ) header ) ;
if ( header - > size > NUM_BINS ) {
assert ( ( uintptr_t ) header - > head < ( uintptr_t ) header + header - > size ) ;
} else {
assert ( ( uintptr_t ) header - > head < ( uintptr_t ) header + PAGE_SIZE ) ;
assert ( ( uintptr_t ) header - > head > ( uintptr_t ) header + sizeof ( klmalloc_bin_header ) - 1 ) ;
}
/*
* Remove the current head and point
* the head to where the old head pointed .
*/
void * item = header - > head ;
uintptr_t * * head = header - > head ;
uintptr_t * next = * head ;
header - > head = next ;
return item ;
}
/*
* Push an item into a block .
* When we free memory , we need
* to add the freed cell back
* into the stack of free spaces
* for the block .
*/
static void klmalloc_stack_push ( klmalloc_bin_header * header , void * ptr ) {
assert ( ptr ! = NULL ) ;
assert ( ( uintptr_t ) ptr > ( uintptr_t ) header ) ;
if ( header - > size > NUM_BINS ) {
assert ( ( uintptr_t ) ptr < ( uintptr_t ) header + header - > size ) ;
} else {
assert ( ( uintptr_t ) ptr < ( uintptr_t ) header + PAGE_SIZE ) ;
}
uintptr_t * * item = ( uintptr_t * * ) ptr ;
* item = ( uintptr_t * ) header - > head ;
header - > head = item ;
}
/*
* Is this cell stack empty ?
* If the head of the stack points
* to NULL , we have exhausted the
* stack , so there is no more free
* space available in the block .
*/
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static inline int __attribute__ ( ( always_inline ) ) klmalloc_stack_empty ( klmalloc_bin_header * header ) {
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return header - > head = = NULL ;
}
/* }}} Stack */
/* malloc() {{{ */
static void * __attribute__ ( ( malloc ) ) klmalloc ( uintptr_t size ) {
/*
* C standard implementation :
* If size is zero , we can choose do a number of things .
* This implementation will return a NULL pointer .
*/
if ( __builtin_expect ( size = = 0 , 0 ) )
return NULL ;
/*
* Find the appropriate bin for the requested
* allocation and start looking through that list .
*/
unsigned int bucket_id = klmalloc_bin_size ( size ) ;
if ( bucket_id < BIG_BIN ) {
/*
* Small bins .
*/
klmalloc_bin_header * bin_header = klmalloc_list_head ( & klmalloc_bin_head [ bucket_id ] ) ;
if ( ! bin_header ) {
/*
* Grow the heap for the new bin .
*/
bin_header = ( klmalloc_bin_header * ) sbrk ( PAGE_SIZE ) ;
bin_header - > bin_magic = BIN_MAGIC ;
assert ( ( uintptr_t ) bin_header % PAGE_SIZE = = 0 ) ;
/*
* Set the head of the stack .
*/
bin_header - > head = ( void * ) ( ( uintptr_t ) bin_header + sizeof ( klmalloc_bin_header ) ) ;
/*
* Insert the new bin at the front of
* the list of bins for this size .
*/
klmalloc_list_insert ( & klmalloc_bin_head [ bucket_id ] , bin_header ) ;
/*
* Initialize the stack inside the bin .
* The stack is initially full , with each
* entry pointing to the next until the end
* which points to NULL .
*/
uintptr_t adj = SMALLEST_BIN_LOG + bucket_id ;
uintptr_t i , available = ( ( PAGE_SIZE - sizeof ( klmalloc_bin_header ) ) > > adj ) - 1 ;
uintptr_t * * base = bin_header - > head ;
for ( i = 0 ; i < available ; + + i ) {
/*
* Our available memory is made into a stack , with each
* piece of memory turned into a pointer to the next
* available piece . When we want to get a new piece
* of memory from this block , we just pop off a free
* spot and give its address .
*/
base [ i < < bucket_id ] = ( uintptr_t * ) & base [ ( i + 1 ) < < bucket_id ] ;
}
base [ available < < bucket_id ] = NULL ;
bin_header - > size = bucket_id ;
}
uintptr_t * * item = klmalloc_stack_pop ( bin_header ) ;
if ( klmalloc_stack_empty ( bin_header ) ) {
klmalloc_list_decouple ( & ( klmalloc_bin_head [ bucket_id ] ) , bin_header ) ;
}
return item ;
} else {
/*
* Big bins .
*/
klmalloc_big_bin_header * bin_header = klmalloc_skip_list_findbest ( size ) ;
if ( bin_header ) {
assert ( bin_header - > size > = size ) ;
/*
* If we found one , delete it from the skip list
*/
klmalloc_skip_list_delete ( bin_header ) ;
/*
* Retreive the head of the block .
*/
uintptr_t * * item = klmalloc_stack_pop ( ( klmalloc_bin_header * ) bin_header ) ;
#if 0
/*
* Resize block , if necessary
*/
assert ( bin_header - > head = = NULL ) ;
uintptr_t old_size = bin_header - > size ;
//uintptr_t rsize = size;
/*
* Round the requeste size to our full required size .
*/
size = ( ( size + sizeof ( klmalloc_big_bin_header ) ) / PAGE_SIZE + 1 ) * PAGE_SIZE - sizeof ( klmalloc_big_bin_header ) ;
assert ( ( size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
if ( bin_header - > size > size * 2 ) {
assert ( old_size ! = size ) ;
/*
* If we have extra space , start splitting .
*/
bin_header - > size = size ;
assert ( sbrk ( 0 ) > = bin_header - > size + ( uintptr_t ) bin_header ) ;
/*
* Make a new block at the end of the needed space .
*/
klmalloc_big_bin_header * header_new = ( klmalloc_big_bin_header * ) ( ( uintptr_t ) bin_header + sizeof ( klmalloc_big_bin_header ) + size ) ;
assert ( ( uintptr_t ) header_new % PAGE_SIZE = = 0 ) ;
memset ( header_new , 0 , sizeof ( klmalloc_big_bin_header ) + sizeof ( void * ) ) ;
header_new - > prev = bin_header ;
if ( bin_header - > next ) {
bin_header - > next - > prev = header_new ;
}
header_new - > next = bin_header - > next ;
bin_header - > next = header_new ;
if ( klmalloc_newest_big = = bin_header ) {
klmalloc_newest_big = header_new ;
}
header_new - > size = old_size - ( size + sizeof ( klmalloc_big_bin_header ) ) ;
assert ( ( ( uintptr_t ) header_new - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
fprintf ( stderr , " Splitting %p [now %zx] at %p [%zx] from [%zx,%zx]. \n " , ( void * ) bin_header , bin_header - > size , ( void * ) header_new , header_new - > size , old_size , size ) ;
/*
* Free the new block .
*/
klfree ( ( void * ) ( ( uintptr_t ) header_new + sizeof ( klmalloc_big_bin_header ) ) ) ;
}
# endif
return item ;
} else {
/*
* Round requested size to a set of pages , plus the header size .
*/
uintptr_t pages = ( size + sizeof ( klmalloc_big_bin_header ) ) / PAGE_SIZE + 1 ;
bin_header = ( klmalloc_big_bin_header * ) sbrk ( PAGE_SIZE * pages ) ;
bin_header - > bin_magic = BIN_MAGIC ;
assert ( ( uintptr_t ) bin_header % PAGE_SIZE = = 0 ) ;
/*
* Give the header the remaining space .
*/
bin_header - > size = pages * PAGE_SIZE - sizeof ( klmalloc_big_bin_header ) ;
assert ( ( bin_header - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
/*
* Link the block in physical memory .
*/
bin_header - > prev = klmalloc_newest_big ;
if ( bin_header - > prev ) {
bin_header - > prev - > next = bin_header ;
}
klmalloc_newest_big = bin_header ;
bin_header - > next = NULL ;
/*
* Return the head of the block .
*/
bin_header - > head = NULL ;
return ( void * ) ( ( uintptr_t ) bin_header + sizeof ( klmalloc_big_bin_header ) ) ;
}
}
}
/* }}} */
/* free() {{{ */
static void klfree ( void * ptr ) {
/*
* C standard implementation : Do nothing when NULL is passed to free .
*/
if ( __builtin_expect ( ptr = = NULL , 0 ) ) {
return ;
}
/*
* Woah , woah , hold on , was this a page - aligned block ?
*/
if ( ( uintptr_t ) ptr % PAGE_SIZE = = 0 ) {
/*
* Well howdy - do , it was .
*/
ptr = ( void * ) ( ( uintptr_t ) ptr - 1 ) ;
}
/*
* Get our pointer to the head of this block by
* page aligning it .
*/
klmalloc_bin_header * header = ( klmalloc_bin_header * ) ( ( uintptr_t ) ptr & ( uintptr_t ) ~ PAGE_MASK ) ;
assert ( ( uintptr_t ) header % PAGE_SIZE = = 0 ) ;
if ( header - > bin_magic ! = BIN_MAGIC )
return ;
/*
* For small bins , the bin number is stored in the size
* field of the header . For large bins , the actual size
* available in the bin is stored in this field . It ' s
* easy to tell which is which , though .
*/
uintptr_t bucket_id = header - > size ;
if ( bucket_id > ( uintptr_t ) NUM_BINS ) {
bucket_id = BIG_BIN ;
klmalloc_big_bin_header * bheader = ( klmalloc_big_bin_header * ) header ;
assert ( bheader ) ;
assert ( bheader - > head = = NULL ) ;
assert ( ( bheader - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
/*
* Coalesce forward blocks into us .
*/
#if 0
if ( bheader ! = klmalloc_newest_big ) {
/*
* If we are not the newest big bin , there is most definitely
* something in front of us that we can read .
*/
assert ( ( bheader - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
klmalloc_big_bin_header * next = ( void * ) ( ( uintptr_t ) bheader + sizeof ( klmalloc_big_bin_header ) + bheader - > size ) ;
assert ( ( uintptr_t ) next % PAGE_SIZE = = 0 ) ;
if ( next = = bheader - > next & & next - > head ) { //next->size > NUM_BINS && next->head) {
/*
* If that something is an available big bin , we can
* coalesce it into us to form one larger bin .
*/
uintptr_t old_size = bheader - > size ;
klmalloc_skip_list_delete ( next ) ;
bheader - > size = ( uintptr_t ) bheader - > size + ( uintptr_t ) sizeof ( klmalloc_big_bin_header ) + next - > size ;
assert ( ( bheader - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
if ( next = = klmalloc_newest_big ) {
/*
* If the guy in front of us was the newest ,
* we are now the newest ( as we are him ) .
*/
klmalloc_newest_big = bheader ;
} else {
if ( next - > next ) {
next - > next - > prev = bheader ;
}
}
fprintf ( stderr , " Coelesced (forwards) %p [%zx] <- %p [%zx] = %zx \n " , ( void * ) bheader , old_size , ( void * ) next , next - > size , bheader - > size ) ;
}
}
# endif
/*
* Coalesce backwards
*/
#if 0
if ( bheader - > prev & & bheader - > prev - > head ) {
/*
* If there is something behind us , it is available , and there is nothing between
* it and us , we can coalesce ourselves into it to form a big block .
*/
if ( ( uintptr_t ) bheader - > prev + ( bheader - > prev - > size + sizeof ( klmalloc_big_bin_header ) ) = = ( uintptr_t ) bheader ) {
uintptr_t old_size = bheader - > prev - > size ;
klmalloc_skip_list_delete ( bheader - > prev ) ;
bheader - > prev - > size = ( uintptr_t ) bheader - > prev - > size + ( uintptr_t ) bheader - > size + sizeof ( klmalloc_big_bin_header ) ;
assert ( ( bheader - > prev - > size + sizeof ( klmalloc_big_bin_header ) ) % PAGE_SIZE = = 0 ) ;
klmalloc_skip_list_insert ( bheader - > prev ) ;
if ( klmalloc_newest_big = = bheader ) {
klmalloc_newest_big = bheader - > prev ;
} else {
if ( bheader - > next ) {
bheader - > next - > prev = bheader - > prev ;
}
}
fprintf ( stderr , " Coelesced (backwards) %p [%zx] <- %p [%zx] = %zx \n " , ( void * ) bheader - > prev , old_size , ( void * ) bheader , bheader - > size , bheader - > size ) ;
/*
* If we coalesced backwards , we are done .
*/
return ;
}
}
# endif
/*
* Push new space back into the stack .
*/
klmalloc_stack_push ( ( klmalloc_bin_header * ) bheader , ( void * ) ( ( uintptr_t ) bheader + sizeof ( klmalloc_big_bin_header ) ) ) ;
assert ( bheader - > head ! = NULL ) ;
/*
* Insert the block into list of available slabs .
*/
klmalloc_skip_list_insert ( bheader ) ;
} else {
/*
* If the stack is empty , we are freeing
* a block from a previously full bin .
* Return it to the busy bins list .
*/
if ( klmalloc_stack_empty ( header ) ) {
klmalloc_list_insert ( & klmalloc_bin_head [ bucket_id ] , header ) ;
}
/*
* Push new space back into the stack .
*/
klmalloc_stack_push ( header , ptr ) ;
}
}
/* }}} */
/* valloc() {{{ */
static void * __attribute__ ( ( malloc ) ) klvalloc ( uintptr_t size ) {
/*
* Allocate a page - aligned block .
* XXX : THIS IS HORRIBLY , HORRIBLY WASTEFUL ! ! ONLY USE THIS
* IF YOU KNOW WHAT YOU ARE DOING !
*/
uintptr_t true_size = size + PAGE_SIZE - sizeof ( klmalloc_big_bin_header ) ; /* Here we go... */
void * result = klmalloc ( true_size ) ;
void * out = ( void * ) ( ( uintptr_t ) result + ( PAGE_SIZE - sizeof ( klmalloc_big_bin_header ) ) ) ;
assert ( ( uintptr_t ) out % PAGE_SIZE = = 0 ) ;
return out ;
}
/* }}} */
/* realloc() {{{ */
static void * __attribute__ ( ( malloc ) ) klrealloc ( void * ptr , uintptr_t size ) {
/*
* C standard implementation : When NULL is passed to realloc ,
* simply malloc the requested size and return a pointer to that .
*/
if ( __builtin_expect ( ptr = = NULL , 0 ) )
return klmalloc ( size ) ;
/*
* C standard implementation : For a size of zero , free the
* pointer and return NULL , allocating no new memory .
*/
if ( __builtin_expect ( size = = 0 , 0 ) )
{
free ( ptr ) ;
return NULL ;
}
/*
* Find the bin for the given pointer
* by aligning it to a page .
*/
klmalloc_bin_header * header_old = ( void * ) ( ( uintptr_t ) ptr & ( uintptr_t ) ~ PAGE_MASK ) ;
if ( header_old - > bin_magic ! = BIN_MAGIC ) {
assert ( 0 & & " Bad magic on realloc. " ) ;
return NULL ;
}
uintptr_t old_size = header_old - > size ;
if ( old_size < ( uintptr_t ) BIG_BIN ) {
/*
* If we are copying from a small bin ,
* we need to get the size of the bin
* from its id .
*/
old_size = ( 1UL < < ( SMALLEST_BIN_LOG + old_size ) ) ;
}
/*
* ( This will only happen for a big bin , mathematically speaking )
* If we still have room in our bin for the additonal space ,
* we don ' t need to do anything .
*/
if ( old_size > = size ) {
/*
* TODO : Break apart blocks here , which is far more important
* than breaking them up on allocations .
*/
return ptr ;
}
/*
* Reallocate more memory .
*/
void * newptr = klmalloc ( size ) ;
if ( __builtin_expect ( newptr ! = NULL , 1 ) ) {
/*
* Copy the old value into the new value .
* Be sure to only copy as much as was in
* the old block .
*/
memcpy ( newptr , ptr , old_size ) ;
klfree ( ptr ) ;
return newptr ;
}
/*
* We failed to allocate more memory ,
* which means we ' re probably out .
*
* Bail and return NULL .
*/
return NULL ;
}
/* }}} */
/* calloc() {{{ */
static void * __attribute__ ( ( malloc ) ) klcalloc ( uintptr_t nmemb , uintptr_t size ) {
/*
* Allocate memory and zero it before returning
* a pointer to the newly allocated memory .
*
* Implemented by way of a simple malloc followed
* by a memset to 0x00 across the length of the
* requested memory chunk .
*/
void * ptr = klmalloc ( nmemb * size ) ;
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if ( ptr ) memset ( ptr , 0x00 , nmemb * size ) ;
2018-02-25 08:13:54 +03:00
return ptr ;
}
/* }}} */