ref: 74d91a0021de012908cfdb35fb61a1473a376130
dir: /lib/std/alloc.myr/
use "die"
use "extremum"
use "memops"
use "syswrap"
use "threadhooks"
use "types"
use "units"
use "bytealloc"
use "backtrace"
use "memops"
/*
The allocator implementation here is based on Bonwick's slab allocator.
For small allocations (up to Bktmax), it works by requesting large,
power of two aligned chunks from the operating system, and breaking
them into a linked list of equal sized chunks. Allocations are then
satisfied by taking the head of the list of chunks. Empty slabs
are removed from the freelist.
The data structure looks something like this:
Bkts:
[16 byte] -> [slab hdr | chunk -> chunk -> chunk] -> [slab hdr | chunk -> chunk -> chunk]
[32 byte] -> Zslab
[64 byte] -> [slab hdr | chunk -> chunk]
...
[32k byte] -> ...
Large allocations are simply satisfied by mmap().
*/
pkg std =
generic alloc : ( -> @a#)
generic zalloc : ( -> @a#)
generic free : (v:@a# -> void)
generic slalloc : (len : size -> @a[:])
generic slzalloc : (len : size -> @a[:])
generic slgrow : (sl : @a[:]#, len : size -> @a[:])
generic slzgrow : (sl : @a[:]#, len : size -> @a[:])
generic slfree : (sl : @a[:] -> void)
;;
type slheader = struct
cap : size /* capacity in bytes */
magic : size /* magic check value */
;;
/* Allocates an object of type @a, returning a pointer to it. */
generic alloc = {-> @a#
-> (bytealloc(sizeof(@a)) : @a#)
}
generic zalloc = {
-> (zbytealloc(sizeof(@a)) : @a#)
}
/* Frees a value of type @a */
generic free = {v:@a# -> void
bytefree((v : byte#), sizeof(@a))
}
/* allocates a slice of 'len' elements. */
generic slalloc = {len
var p, sz
if len == 0
-> [][:]
;;
sz = len*sizeof(@a) + align(sizeof(slheader), Align)
sz = allocsz(sz)
p = bytealloc(sz + sizeof(size))
p = inithdr(p, sz)
-> (p : @a#)[0:len]
}
generic slzalloc = {len
var p, sz
if len == 0
-> [][:]
;;
sz = len*sizeof(@a) + align(sizeof(slheader), Align)
sz = allocsz(sz)
p = zbytealloc(sz + sizeof(size))
p = inithdr(p, sz)
-> (p : @a#)[0:len]
}
const inithdr = {p, sz
var phdr, pdat, pend
phdr = (p : slheader#)
phdr.cap = sz - align(sizeof(slheader), Align)
/* add start/end magics */
phdr.magic = (0xdeadbeefbadf00d : size)
pdat = (p : size) + align(sizeof(slheader), Align)
pend = ((pdat : size) + sz - align(sizeof(slheader), Align) : size#)
pend# = 0xfee1deadfee1dead
-> (pdat : byte#)
}
const checkhdr = {p
var phdr, pend, addr
addr = (p : size)
addr -= align(sizeof(slheader), Align)
/* check start/end magics */
phdr = (addr : slheader#)
iassert(phdr.magic == (0xdeadbeefbadf00d : size), "corrupt memory\n")
pend = ((p : size) + phdr.cap : size#)
iassert(pend# == 0xfee1deadfee1dead, "corrupt memory")
}
/* Frees a slice */
generic slfree = {sl
var head, sz
if (sl : byte#) == Zslicep
-> void
;;
checkhdr((sl : byte#))
head = ((sl : byte#) : size)
head -= align(sizeof(slheader), Align)
sz = slcap((sl : byte#)) + align(sizeof(slheader), Align)
bytefree((head : byte#), sz + sizeof(size))
}
/* Grows a slice */
generic slgrow = {sl : @a[:]#, len
var cap, nel
var new
var n
/* if the slice doesn't need a bigger bucket, we don't need to realloc. */
cap = 0
if (sl# : byte#) != Zslicep
cap = slcap((sl# : byte#))
;;
if cap >= len*sizeof(@a)
/* cast to pointer to work around bounds check */
sl# = (sl# : @a#)[:len]
-> sl#
;;
/* grow in factors of 1.5 */
nel = sl#.len
while nel < len
nel += (nel >> 2) + 1
;;
new = slalloc(nel)
n = min(len, sl#.len)
memblit((new : byte#), (sl# : byte#), n * sizeof(@a))
if sl#.len > 0
slfree(sl#)
;;
sl# = new[:len]
-> sl#
}
/* Grows a slice, filling new entries with zero bytes */
generic slzgrow = {sl : @a[:]#, len
var oldlen
var base
oldlen = sl#.len
slgrow(sl, len)
base = ((sl# : byte#) : intptr)
if oldlen < len
memfill((sl#[oldlen:] : byte#), 0, (len - oldlen)*sizeof(@a))
;;
-> sl#
}
const slcap = {p
var phdr
phdr = ((p : size) - align(sizeof(slheader), Align) : slheader#)
std.iassert(phdr.magic == (0xdeadbeefbadf00d : size), "corrupt memory\n")
-> phdr.cap
}