/*
* This allocator takes blocks from a coarser allocator (p->alloc) and
* uses them as arenas.
*
* An arena is split into a sequence of blocks of variable size. The
* blocks begin with a Bhdr that denotes the length (including the Bhdr)
* of the block. An arena begins with an Arena header block (Arena,
* ARENA_MAGIC) and ends with a Bhdr block with magic ARENATAIL_MAGIC and
* size 0. Intermediate blocks are either allocated or free. At the end
* of each intermediate block is a Btail, which contains information
* about where the block starts. This is useful for walking backwards.
*
* Free blocks (Free*) have a magic value of FREE_MAGIC in their Bhdr
* headers. They are kept in a binary tree (p->freeroot) traversible by
* walking ->left and ->right. Each node of the binary tree is a pointer
* to a circular doubly-linked list (next, prev) of blocks of identical
* size. Blocks are added to this ``tree of lists'' by pooladd(), and
* removed by pooldel().
*
* When freed, adjacent blocks are coalesced to create larger blocks when
* possible.
*
* Allocated blocks (Alloc*) have one of two magic values: KEMPT_MAGIC or
* UNKEMPT_MAGIC. When blocks are released from the pool, they have
* magic value UNKEMPT_MAGIC. Once the block has been trimmed by kemb()
* and the amount of user-requested data has been recorded in the
* datasize field of the tail, the magic value is changed to KEMPT_MAGIC.
* All blocks returned to callers should be of type KEMPT_MAGIC, as
* should all blocks passed to us by callers. The amount of data the user
* asked us for can be found by subtracting the short in tail->datasize
* from header->size. Further, the up to at most four bytes between the
* end of the user-requested data block and the actual Btail structure are
* marked with a magic value, which is checked to detect user overflow.
*
* The arenas returned by p->alloc are kept in a doubly-linked list
* (p->arenalist) running through the arena headers, sorted by descending
* base address (prev, next). When a new arena is allocated, we attempt
* to merge it with its two neighbors via p->merge.
*/
#include <u.h>
#include <libc.h>
#include <pool.h>
typedef struct Alloc Alloc;
typedef struct Arena Arena;
typedef struct Bhdr Bhdr;
typedef struct Btail Btail;
typedef struct Free Free;
struct Bhdr {
ulong magic;
ulong size;
};
enum {
NOT_MAGIC = 0xdeadfa11,
};
#define B2NB(b) ((Bhdr*)((uchar*)(b)+(b)->size))
#define SHORT(x) (((x)[0] << 8) | (x)[1])
#define PSHORT(p, x) \
(((uchar*)(p))[0] = ((x)>>8)&0xFF, \
((uchar*)(p))[1] = (x)&0xFF)
enum {
TAIL_MAGIC0 = 0xBE,
TAIL_MAGIC1 = 0xEF
};
struct Btail {
uchar magic0;
uchar datasize[2];
uchar magic1;
ulong size; /* same as Bhdr->size */
};
#define B2T(b) ((Btail*)((uchar*)(b)+(b)->size-sizeof(Btail)))
#define B2PT(b) ((Btail*)((uchar*)(b)-sizeof(Btail)))
#define T2HDR(t) ((Bhdr*)((uchar*)(t)+sizeof(Btail)-(t)->size))
struct Free {
Bhdr;
Free* left;
Free* right;
Free* next;
Free* prev;
};
enum {
FREE_MAGIC = 0xBA5EBA11,
};
/*
* the point of the notused fields is to make 8c differentiate
* between Bhdr and Allocblk, and between Kempt and Unkempt.
*/
struct Alloc {
Bhdr;
};
enum {
KEMPT_MAGIC = 0x0A110C09,
UNKEMPT_MAGIC = 0xCAB00D1E+1,
};
struct Arena {
Bhdr;
Arena* aup;
Arena* down;
ulong asize;
ulong pad; /* to a multiple of 8 bytes */
};
enum {
ARENA_MAGIC = 0xC0A1E5CE+1,
ARENATAIL_MAGIC = 0xEC5E1A0C+1,
};
#define A2TB(a) ((Bhdr*)((uchar*)(a)+(a)->asize-sizeof(Bhdr)))
#define A2B(a) B2NB(a)
enum {
MINBLOCKSIZE = sizeof(Free)+sizeof(Btail)
};
static uchar datamagic[] = { 0xFE, 0xF1, 0xF0, 0xFA };
#define Poison (void*)0xCafeBabe
#define _B2D(a) ((void*)((uchar*)a+sizeof(Bhdr)))
#define _D2B(v) ((Alloc*)((uchar*)v-sizeof(Bhdr)))
// static void* _B2D(void*);
// static void* _D2B(void*);
static void* B2D(Pool*, Alloc*);
static Alloc* D2B(Pool*, void*);
static Arena* arenamerge(Pool*, Arena*, Arena*);
static void blockcheck(Pool*, Bhdr*);
static Alloc* blockmerge(Pool*, Bhdr*, Bhdr*);
static Alloc* blocksetdsize(Pool*, Alloc*, ulong);
static Bhdr* blocksetsize(Bhdr*, ulong);
static ulong bsize2asize(Pool*, ulong);
static ulong dsize2bsize(Pool*, ulong);
static ulong getdsize(Alloc*);
static Alloc* kemb(Pool*, Alloc*, ulong);
static Free* listadd(Free*, Free*);
static Free* listdelete(Free*, Free*);
static void logstack(Pool*);
static Free** ltreewalk(Free**, ulong);
static void memmark(void*, int, ulong);
static Free* pooladd(Pool*, Alloc*);
static void* poolallocl(Pool*, ulong);
static void poolcheckl(Pool*);
static void poolcheckarena(Pool*, Arena*);
static int poolcompactl(Pool*);
static Alloc* pooldel(Pool*, Free*);
static void pooldumpl(Pool*);
static void pooldumparena(Pool*, Arena*);
static void poolfreel(Pool*, void*);
static void poolnewarena(Pool*, ulong);
static void* poolreallocl(Pool*, void*, ulong);
static Free* treedelete(Free*, Free*);
static Free* treeinsert(Free*, Free*);
static Free* treelookup(Free*, ulong);
static Free* treelookupgt(Free*, ulong);
/*
* Debugging
*
* Antagonism causes blocks to always be filled with garbage if their
* contents are undefined. This tickles both programs and the library.
* It's a linear time hit but not so noticeable during nondegenerate use.
* It would be worth leaving in except that it negates the benefits of the
* kernel's demand-paging. The tail magic and end-of-data magic
* provide most of the user-visible benefit that antagonism does anyway.
*
* Paranoia causes the library to recheck the entire pool on each lock
* or unlock. A failed check on unlock means we tripped over ourselves,
* while a failed check on lock tends to implicate the user. Paranoia has
* the potential to slow things down a fair amount for pools with large
* numbers of allocated blocks. It completely negates all benefits won
* by the binary tree. Turning on paranoia in the kernel makes it painfully
* slow.
*
* Verbosity induces the dumping of the pool via p->print at each lock operation.
* By default, only one line is logged for each alloc, free, and realloc.
*/
/* the if(!x);else avoids ``dangling else'' problems */
#define antagonism if(!(p->flags & POOL_ANTAGONISM));else
#define paranoia if(!(p->flags & POOL_PARANOIA));else
#define verbosity if(!(p->flags & POOL_VERBOSITY));else
#define DPRINT if(!(p->flags & POOL_DEBUGGING));else p->print
#define LOG if(!(p->flags & POOL_LOGGING));else p->print
/*
* Tree walking
*/
/* ltreewalk: return address of pointer to node of size == size */
static Free**
ltreewalk(Free **t, ulong size)
{
Free **ot;
// Free **hist[40];
// int nhist;
// nhist = 0;
ot = t;
assert(t != nil /* ltreewalk */);
for(;;) {
// hist[nhist++] = t;
if(*t == nil)
return t;
assert((*t)->magic == FREE_MAGIC);
if(size == (*t)->size)
return t;
if(size < (*t)->size)
t = &(*t)->left;
else
t = &(*t)->right;
}
return nil; /* not reached */
}
/* treelookup: find node in tree with size == size */
static Free*
treelookup(Free *t, ulong size)
{
return *ltreewalk(&t, size);
}
/* treeinsert: insert node into tree */
static Free*
treeinsert(Free *tree, Free *node)
{
Free **loc, *repl;
assert(node != nil /* treeinsert */);
loc = ltreewalk(&tree, node->size);
if(*loc == nil) {
node->left = nil;
node->right = nil;
} else { /* replace existing node */
repl = *loc;
node->left = repl->left;
node->right = repl->right;
}
*loc = node;
return tree;
}
/* treedelete: remove node from tree */
static Free*
treedelete(Free *tree, Free *node)
{
Free **loc, **lsucc, *succ;
assert(node != nil /* treedelete */);
loc = ltreewalk(&tree, node->size);
assert(*loc == node);
if(node->left == nil)
*loc = node->right;
else if(node->right == nil)
*loc = node->left;
else {
/* have two children, use inorder successor as replacement */
for(lsucc = &node->right; (*lsucc)->left; lsucc = &(*lsucc)->left)
;
succ = *lsucc;
*lsucc = succ->right;
succ->left = node->left;
succ->right = node->right;
*loc = succ;
}
node->left = node->right = Poison;
return tree;
}
/* treelookupgt: find smallest node in tree with size >= size */
static Free*
treelookupgt(Free *t, ulong size)
{
Free *lastgood; /* last node we saw that was big enough */
lastgood = nil;
for(;;) {
if(t == nil)
return lastgood;
if(size == t->size)
return t;
if(size < t->size) {
lastgood = t;
t = t->left;
} else {
t = t->right;
}
}
return nil; /* not reached */
}
/*
* List maintenance
*/
/* listadd: add a node to a doubled linked list */
static Free*
listadd(Free *list, Free *node)
{
if(list == nil) {
node->next = node;
node->prev = node;
return node;
}
node->prev = list->prev;
node->next = list;
node->prev->next = node;
node->next->prev = node;
return list;
}
/* listdelete: remove node from a doubly linked list */
static Free*
listdelete(Free *list, Free *node)
{
if(node->next == node) { /* singular list */
node->prev = node->next = Poison;
return nil;
}
node->next->prev = node->prev;
node->prev->next = node->next;
if(list == node)
list = node->next;
node->prev = node->next = Poison;
return list;
}
/*
* Pool maintenance
*/
/* pooladd: add anode to the free pool */
static Free*
pooladd(Pool *p, Alloc *anode)
{
Free *lst, *olst;
Free *node;
Free **parent;
antagonism {
memmark(_B2D(anode), 0xF7, anode->size-sizeof(Bhdr)-sizeof(Btail));
}
node = (Free*)anode;
node->magic = FREE_MAGIC;
parent = ltreewalk(&p->freeroot, node->size);
olst = *parent;
lst = listadd(olst, node);
if(olst != lst) /* need to update tree */
*parent = treeinsert(*parent, lst);
p->curfree += node->size;
return node;
}
/* pooldel: remove node from the free pool */
static Alloc*
pooldel(Pool *p, Free *node)
{
Free *lst, *olst;
Free **parent;
parent = ltreewalk(&p->freeroot, node->size);
olst = *parent;
assert(olst != nil /* pooldel */);
lst = listdelete(olst, node);
if(lst == nil)
*parent = treedelete(*parent, olst);
else if(lst != olst)
*parent = treeinsert(*parent, lst);
node->left = node->right = Poison;
p->curfree -= node->size;
antagonism {
memmark(_B2D(node), 0xF9, node->size-sizeof(Bhdr)-sizeof(Btail));
}
node->magic = UNKEMPT_MAGIC;
return (Alloc*)node;
}
/*
* Block maintenance
*/
/* block allocation */
static ulong
dsize2bsize(Pool *p, ulong sz)
{
sz += sizeof(Bhdr)+sizeof(Btail);
if(sz < p->minblock)
sz = p->minblock;
sz = (sz+p->quantum-1)&~(p->quantum-1);
return sz;
}
static ulong
bsize2asize(Pool *p, ulong sz)
{
sz += sizeof(Arena)+sizeof(Btail);
if(sz < p->minarena)
sz = p->minarena;
sz = (sz+p->quantum)&~(p->quantum-1);
return sz;
}
/* blockmerge: merge a and b, known to be adjacent */
/* both are removed from pool if necessary. */
static Alloc*
blockmerge(Pool *pool, Bhdr *a, Bhdr *b)
{
Btail *t;
assert(B2NB(a) == b);
if(a->magic == FREE_MAGIC)
pooldel(pool, (Free*)a);
if(b->magic == FREE_MAGIC)
pooldel(pool, (Free*)b);
t = B2T(a);
t->size = (ulong)Poison;
t->magic0 = NOT_MAGIC;
t->magic1 = NOT_MAGIC;
PSHORT(t->datasize, NOT_MAGIC);
a->size += b->size;
t = B2T(a);
t->size = a->size;
PSHORT(t->datasize, 0xFFFF);
b->size = NOT_MAGIC;
b->magic = NOT_MAGIC;
a->magic = UNKEMPT_MAGIC;
return (Alloc*)a;
}
/* blocksetsize: set the total size of a block, fixing tail pointers */
static Bhdr*
blocksetsize(Bhdr *b, ulong bsize)
{
Btail *t;
assert(b->magic != FREE_MAGIC /* blocksetsize */);
b->size = bsize;
t = B2T(b);
t->size = b->size;
t->magic0 = TAIL_MAGIC0;
t->magic1 = TAIL_MAGIC1;
return b;
}
/* getdsize: return the requested data size for an allocated block */
static ulong
getdsize(Alloc *b)
{
Btail *t;
t = B2T(b);
return b->size - SHORT(t->datasize);
}
/* blocksetdsize: set the user data size of a block */
static Alloc*
blocksetdsize(Pool *p, Alloc *b, ulong dsize)
{
Btail *t;
uchar *q, *eq;
assert(b->size >= dsize2bsize(p, dsize));
assert(b->size - dsize < 0x10000);
t = B2T(b);
PSHORT(t->datasize, b->size - dsize);
q=(uchar*)_B2D(b)+dsize;
eq = (uchar*)t;
if(eq > q+4)
eq = q+4;
for(; q<eq; q++)
*q = datamagic[((ulong)q)%nelem(datamagic)];
return b;
}
/* kemb: trim a block down to what is needed to hold dsize bytes of user data */
static Alloc*
kemb(Pool *p, Alloc *b, ulong dsize)
{
ulong extra, bsize;
Alloc *frag;
bsize = dsize2bsize(p, dsize);
extra = b->size - bsize;
if(b->size - dsize >= 0x10000 ||
(extra >= bsize>>2 && extra >= MINBLOCKSIZE && extra >= p->minblock)) {
blocksetsize(b, bsize);
frag = (Alloc*) B2NB(b);
antagonism {
memmark(frag, 0xF1, extra);
}
frag->magic = UNKEMPT_MAGIC;
blocksetsize(frag, extra);
pooladd(p, frag);
}
b->magic = KEMPT_MAGIC;
blocksetdsize(p, b, dsize);
return b;
}
/*
* Arena maintenance
*/
/* arenasetsize: set arena size, updating tail */
static void
arenasetsize(Arena *a, ulong asize)
{
Bhdr *atail;
a->asize = asize;
atail = A2TB(a);
atail->magic = ARENATAIL_MAGIC;
atail->size = 0;
}
/* poolnewarena: allocate new arena */
static void
poolnewarena(Pool *p, ulong asize)
{
Arena *a;
Arena *ap, *lastap;
Alloc *b;
LOG(p, "newarena %lud\n", asize);
if(p->cursize+asize > p->maxsize) {
if(poolcompactl(p) == 0)
LOG(p, "pool too big: %lud+%lud > %lud\n",
p->cursize, asize, p->maxsize);
return;
}
if((a = p->alloc(asize)) == nil) {
/* assume errstr set by p->alloc */
return;
}
p->cursize += asize;
/* arena hdr */
a->magic = ARENA_MAGIC;
blocksetsize(a, sizeof(Arena));
arenasetsize(a, asize);
blockcheck(p, a);
/* create one large block in arena */
b = (Alloc*)A2B(a);
b->magic = UNKEMPT_MAGIC;
blocksetsize(b, (uchar*)A2TB(a)-(uchar*)b);
blockcheck(p, b);
pooladd(p, b);
blockcheck(p, b);
/* sort arena into descending sorted arena list */
for(lastap=nil, ap=p->arenalist; ap > a; lastap=ap, ap=ap->down)
;
if(a->down = ap) /* assign = */
a->down->aup = a;
if(a->aup = lastap) /* assign = */
a->aup->down = a;
else
p->arenalist = a;
/* merge with surrounding arenas if possible */
/* must do a with up before down with a (think about it) */
if(a->aup)
arenamerge(p, a, a->aup);
if(a->down)
arenamerge(p, a->down, a);
}
/* blockresize: grow a block to encompass space past its end, possibly by */
/* trimming it into two different blocks. */
static void
blockgrow(Pool *p, Bhdr *b, ulong nsize)
{
if(b->magic == FREE_MAGIC) {
Alloc *a;
Bhdr *bnxt;
a = pooldel(p, (Free*)b);
blockcheck(p, a);
blocksetsize(a, nsize);
blockcheck(p, a);
bnxt = B2NB(a);
if(bnxt->magic == FREE_MAGIC)
a = blockmerge(p, a, bnxt);
blockcheck(p, a);
pooladd(p, a);
} else {
Alloc *a;
ulong dsize;
a = (Alloc*)b;
dsize = getdsize(a);
blocksetsize(a, nsize);
kemb(p, a, dsize);
}
}
/* arenamerge: attempt to coalesce to arenas that might be adjacent */
static Arena*
arenamerge(Pool *p, Arena *bot, Arena *top)
{
Bhdr *bbot, *btop;
Btail *t;
blockcheck(p, bot);
blockcheck(p, top);
assert(bot->aup == top && top > bot);
if(p->merge == nil || p->merge(bot, top) == 0)
return nil;
/* remove top from list */
if(bot->aup = top->aup) /* assign = */
bot->aup->down = bot;
else
p->arenalist = bot;
/* save ptrs to last block in bot, first block in top */
t = B2PT(A2TB(bot));
bbot = T2HDR(t);
btop = A2B(top);
blockcheck(p, bbot);
blockcheck(p, btop);
/* grow bottom arena to encompass top */
arenasetsize(bot, top->asize + ((uchar*)top - (uchar*)bot));
/* grow bottom block to encompass space between arenas */
blockgrow(p, bbot, (uchar*)btop-(uchar*)bbot);
blockcheck(p, bbot);
return bot;
}
/* dumpblock: print block's vital stats */
static void
dumpblock(Pool *p, Bhdr *b)
{
ulong *dp;
ulong dsize;
uchar *cp;
dp = (ulong*)b;
p->print(p, "pool %s block %p\nhdr %.8lux %.8
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