/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1996-2010. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
/* Implementation of the erlang external format
*
* And a nice cache mechanism which is used just to send a
* index indicating a specific atom to a remote node instead of the
* entire atom.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#define ERTS_WANT_EXTERNAL_TAGS
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "error.h"
#include "external.h"
#include "bif.h"
#include "big.h"
#include "dist.h"
#include "erl_binary.h"
#include "erl_bits.h"
#include "erl_zlib.h"
#ifdef HIPE
#include "hipe_mode_switch.h"
#endif
#define in_area(ptr,start,nbytes) ((Uint)((char*)(ptr) - (char*)(start)) < (nbytes))
#define MAX_STRING_LEN 0xffff
#define dec_set_creation(nodename,creat) \
(((nodename) == erts_this_node->sysname && (creat) == ORIG_CREATION) \
? erts_this_node->creation \
: (creat))
#undef ERTS_DEBUG_USE_DIST_SEP
#ifdef DEBUG
# if 0
/*
* Enabling ERTS_DEBUG_USE_DIST_SEP can be useful when debugging, but the
* result refuses to talk to nodes without it!
*/
# define ERTS_DEBUG_USE_DIST_SEP
# endif
#endif
/*
* For backward compatibility reasons, only encode integers that
* fit in 28 bits (signed) using INTEGER_EXT.
*/
#define IS_SSMALL28(x) (((Uint) (((x) >> (28-1)) + 1)) < 2)
/*
* Valid creations for nodes are 1, 2, or 3. 0 can also be sent
* as creation, though. When 0 is used as creation, the real creation
* is unknown. Creation 0 on data will be changed to current
* creation of the node which it belongs to when it enters
* that node.
* This typically happens when a remote pid is created with
* list_to_pid/1 and then sent to the remote node. This behavior
* has the undesirable effect that a pid can be passed between nodes,
* and as a result of that not being equal to itself (the pid that
* comes back isn't equal to the original pid).
*
*/
static byte* enc_term(ErtsAtomCacheMap *, Eterm, byte*, Uint32);
static Uint is_external_string(Eterm obj, int* p_is_string);
static byte* enc_atom(ErtsAtomCacheMap *, Eterm, byte*, Uint32);
static byte* enc_pid(ErtsAtomCacheMap *, Eterm, byte*, Uint32);
static byte* dec_term(ErtsDistExternal *, Eterm**, byte*, ErlOffHeap*, Eterm*);
static byte* dec_atom(ErtsDistExternal *, byte*, Eterm*);
static byte* dec_pid(ErtsDistExternal *, Eterm**, byte*, ErlOffHeap*, Eterm*);
static Sint decoded_size(byte *ep, byte* endp, int only_heap_bins);
static Uint encode_size_struct2(ErtsAtomCacheMap *, Eterm, unsigned);
#define ERTS_MAX_INTERNAL_ATOM_CACHE_ENTRIES 255
#define ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTE_IX(IIX) \
(((((Uint32) (IIX)) >> 1) & 0x7fffffff))
#define ERTS_DIST_HDR_ATOM_CACHE_FLAG_BIT_IX(IIX) \
(((IIX) << 2) & 7)
#define ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTES(NO_ATOMS) \
(((((Uint32) (NO_ATOMS)) >> 1) & 0x7fffffff)+1)
#define ERTS_DIST_HDR_LONG_ATOMS_FLG (1 << 0)
/* #define ERTS_ATOM_CACHE_HASH */
#define ERTS_USE_ATOM_CACHE_SIZE 2039
#if ERTS_ATOM_CACHE_SIZE < ERTS_USE_ATOM_CACHE_SIZE
#error "ERTS_USE_ATOM_CACHE_SIZE too large"
#endif
static ERTS_INLINE int
atom2cix(Eterm atom)
{
Uint val;
ASSERT(is_atom(atom));
val = atom_val(atom);
#ifdef ERTS_ATOM_CACHE_HASH
val = atom_tab(val)->slot.bucket.hvalue;
#endif
#if ERTS_USE_ATOM_CACHE_SIZE == 256
return (int) (val & ((Uint) 0xff));
#else
return (int) (val % ERTS_USE_ATOM_CACHE_SIZE);
#endif
}
int erts_debug_max_atom_out_cache_index(void)
{
return ERTS_USE_ATOM_CACHE_SIZE-1;
}
int
erts_debug_atom_to_out_cache_index(Eterm atom)
{
return atom2cix(atom);
}
void
erts_init_atom_cache_map(ErtsAtomCacheMap *acmp)
{
if (acmp) {
int ix;
for (ix = 0; ix < ERTS_ATOM_CACHE_SIZE; ix++)
acmp->cache[ix].iix = -1;
acmp->sz = 0;
acmp->hdr_sz = -1;
}
}
void
erts_reset_atom_cache_map(ErtsAtomCacheMap *acmp)
{
if (acmp) {
int i;
for (i = 0; i < acmp->sz; i++) {
ASSERT(0 <= acmp->cix[i] && acmp->cix[i] < ERTS_ATOM_CACHE_SIZE);
acmp->cache[acmp->cix[i]].iix = -1;
}
acmp->sz = 0;
acmp->hdr_sz = -1;
#ifdef DEBUG
for (i = 0; i < ERTS_ATOM_CACHE_SIZE; i++) {
ASSERT(acmp->cache[i].iix < 0);
}
#endif
}
}
void
erts_destroy_atom_cache_map(ErtsAtomCacheMap *acmp)
{
}
static ERTS_INLINE void
insert_acache_map(ErtsAtomCacheMap *acmp, Eterm atom)
{
if (acmp && acmp->sz < ERTS_MAX_INTERNAL_ATOM_CACHE_ENTRIES) {
int ix;
ASSERT(acmp->hdr_sz < 0);
ix = atom2cix(atom);
if (acmp->cache[ix].iix < 0) {
acmp->cache[ix].iix = acmp->sz;
acmp->cix[acmp->sz++] = ix;
acmp->cache[ix].atom = atom;
}
}
}
static ERTS_INLINE int
get_iix_acache_map(ErtsAtomCacheMap *acmp, Eterm atom)
{
if (!acmp)
return -1;
else {
int ix;
ASSERT(is_atom(atom));
ix = atom2cix(atom);
if (acmp->cache[ix].iix < 0) {
ASSERT(acmp->sz == ERTS_MAX_INTERNAL_ATOM_CACHE_ENTRIES);
return -1;
}
else {
ASSERT(acmp->cache[ix].iix < ERTS_ATOM_CACHE_SIZE);
return acmp->cache[ix].atom == atom ? acmp->cache[ix].iix : -1;
}
}
}
void
erts_finalize_atom_cache_map(ErtsAtomCacheMap *acmp)
{
if (acmp) {
#if MAX_ATOM_LENGTH > 255
#error "This code is not complete; long_atoms info need to be passed to the following stages."
int long_atoms = 0; /* !0 if one or more atoms are long than 255. */
#endif
int i;
int sz;
int fix_sz
= 1 /* VERSION_MAGIC */
+ 1 /* DIST_HEADER */
+ 1 /* number of internal cache entries */
;
int min_sz;
ASSERT(acmp->hdr_sz < 0);
/* Make sure cache update instructions fit */
min_sz = fix_sz+(2+4)*acmp->sz;
sz = fix_sz;
for (i = 0; i < acmp->sz; i++) {
Eterm atom;
int len;
atom = acmp->cache[acmp->cix[i]].atom;
ASSERT(is_atom(atom));
len = atom_tab(atom_val(atom))->len;
#if MAX_ATOM_LENGTH > 255
if (!long_atoms && len > 255)
long_atoms = 1;
#endif
/* Enough for a new atom cache value */
sz += 1 /* cix */ + 1 /* length */ + len /* text */;
}
#if MAX_ATOM_LENGTH > 255
if (long_atoms)
sz += acmp->sz; /* we need 2 bytes per atom for length */
#endif
/* Dynamically sized flag field */
sz += ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTES(acmp->sz);
if (sz < min_sz)
sz = min_sz;
acmp->hdr_sz = sz;
}
}
Uint
erts_encode_ext_dist_header_size(ErtsAtomCacheMap *acmp)
{
if (!acmp)
return 0;
else {
ASSERT(acmp->hdr_sz >= 0);
return acmp->hdr_sz;
}
}
byte *erts_encode_ext_dist_header_setup(byte *ctl_ext, ErtsAtomCacheMap *acmp)
{
/* Maximum number of atom must be less than the maximum of a 32 bits
unsigned integer. Check is done in erl_init.c, erl_start function. */
if (!acmp)
return ctl_ext;
else {
int i;
byte *ep = ctl_ext;
ASSERT(acmp->hdr_sz >= 0);
/*
* Write cache update instructions. Note that this is a purely
* internal format, never seen on the wire. This section is later
* rewritten by erts_encode_ext_dist_header_finalize() while updating
* the cache. We write the header backwards just before the
* actual term(s).
*/
for (i = acmp->sz-1; i >= 0; i--) {
Uint32 aval;
ASSERT(0 <= acmp->cix[i] && acmp->cix[i] < ERTS_ATOM_CACHE_SIZE);
ASSERT(i == acmp->cache[acmp->cix[i]].iix);
ASSERT(is_atom(acmp->cache[acmp->cix[i]].atom));
aval = (Uint32) atom_val(acmp->cache[acmp->cix[i]].atom);
ep -= 4;
put_int32(aval, ep);
ep -= 2;
put_int16(acmp->cix[i], ep);
}
--ep;
put_int8(acmp->sz, ep);
*--ep = DIST_HEADER;
*--ep = VERSION_MAGIC;
return ep;
}
}
byte *erts_encode_ext_dist_header_finalize(byte *ext, ErtsAtomCache *cache)
{
byte *ip;
byte instr_buf[(2+4)*ERTS_ATOM_CACHE_SIZE];
int ci, sz;
register byte *ep = ext;
ASSERT(ep[0] == VERSION_MAGIC);
if (ep[1] != DIST_HEADER)
return ext;
/*
* Update output atom cache and write the external version of
* the dist header. We write the header backwards just
* before the actual term(s).
*/
ep += 2;
ci = (int) get_int8(ep);
ASSERT(0 <= ci && ci < ERTS_ATOM_CACHE_SIZE);
ep += 1;
sz = (2+4)*ci;
ip = &instr_buf[0];
sys_memcpy((void *) ip, (void *) ep, sz);
ep += sz;
/* ep now points to the beginning of the control message term */
#ifdef ERTS_DEBUG_USE_DIST_SEP
ASSERT(*ep == VERSION_MAGIC);
#endif
if (ci > 0) {
Uint32 flgs_buf[((ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTES(
ERTS_MAX_INTERNAL_ATOM_CACHE_ENTRIES)-1)
/ sizeof(Uint32))+1];
register Uint32 flgs;
int iix, flgs_bytes, flgs_buf_ix, used_half_bytes;
#ifdef DEBUG
int tot_used_half_bytes;
#endif
flgs_bytes = ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTES(ci);
ASSERT(flgs_bytes <= sizeof(flgs_buf));
#if MAX_ATOM_LENGTH > 255
/* long_atoms info needs to be passed from previous stages */
if (long_atoms)
flgs |= ERTS_DIST_HDR_LONG_ATOMS_FLG;
#endif
flgs = 0;
flgs_buf_ix = 0;
if ((ci & 1) == 0)
used_half_bytes = 2;
else
used_half_bytes = 1;
#ifdef DEBUG
tot_used_half_bytes = used_half_bytes;
#endif
iix = ci-1;
while (iix >= 0) {
int cix;
Eterm atom;
if (used_half_bytes != 8)
flgs <<= 4;
else {
flgs_buf[flgs_buf_ix++] = flgs;
flgs = 0;
used_half_bytes = 0;
}
ip = &instr_buf[0] + (2+4)*iix;
cix = (int) get_int16(&ip[0]);
ASSERT(0 <= cix && cix < ERTS_ATOM_CACHE_SIZE);
atom = make_atom((Uint) get_int32(&ip[2]));
if (cache->out_arr[cix] == atom) {
--ep;
put_int8(cix, ep);
flgs |= ((cix >> 8) & 7);
}
else {
Atom *a;
cache->out_arr[cix] = atom;
a = atom_tab(atom_val(atom));
sz = a->len;
ep -= sz;
sys_memcpy((void *) ep, (void *) a->name, sz);
#if MAX_ATOM_LENGTH > 255
if (long_atoms) {
ep -= 2;
put_int16(sz, ep);
}
else
#endif
{
ASSERT(0 <= sz && sz <= 255);
--ep;
put_int8(sz, ep);
}
--ep;
put_int8(cix, ep);
flgs |= (8 | ((cix >> 8) & 7));
}
iix--;
used_half_bytes++;
#ifdef DEBUG
tot_used_half_bytes++;
#endif
}
ASSERT(tot_used_half_bytes == 2*flgs_bytes);
flgs_buf[flgs_buf_ix] = flgs;
flgs_buf_ix = 0;
while (1) {
flgs = flgs_buf[flgs_buf_ix];
if (flgs_bytes > 4) {
*--ep = (byte) ((flgs >> 24) & 0xff);
*--ep = (byte) ((flgs >> 16) & 0xff);
*--ep = (byte) ((flgs >> 8) & 0xff);
*--ep = (byte) (flgs & 0xff);
flgs_buf_ix++;
flgs_bytes -= 4;
}
else {
switch (flgs_bytes) {
case 4:
*--ep = (byte) ((flgs >> 24) & 0xff);
case 3:
*--ep = (byte) ((flgs >> 16) & 0xff);
case 2:
*--ep = (byte) ((flgs >> 8) & 0xff);
case 1:
*--ep = (byte) (flgs & 0xff);
}
break;
}
}
}
--ep;
put_int8(ci, ep);
*--ep = DIST_HEADER;
*--ep = VERSION_MAGIC;
return ep;
}
Uint erts_encode_dist_ext_size(Eterm term, Uint32 flags, ErtsAtomCacheMap *acmp)
{
Uint sz = 0;
#ifndef ERTS_DEBUG_USE_DIST_SEP
if (!(flags & DFLAG_DIST_HDR_ATOM_CACHE))
#endif
sz++ /* VERSION_MAGIC */;
sz += encode_size_struct2(acmp, term, flags);
return sz;
}
Uint erts_encode_ext_size(Eterm term)
{
return encode_size_struct2(NULL, term, TERM_TO_BINARY_DFLAGS)
+ 1 /* VERSION_MAGIC */;
}
void erts_encode_dist_ext(Eterm term, byte **ext, Uint32 flags, ErtsAtomCacheMap *acmp)
{
byte *ep = *ext;
#ifndef ERTS_DEBUG_USE_DIST_SEP
if (!(flags & DFLAG_DIST_HDR_ATOM_CACHE))
#endif
*ep++ = VERSION_MAGIC;
ep = enc_term(acmp, term, ep, flags);
if (!ep)
erl_exit(ERTS_ABORT_EXIT,
"%s:%d:erts_encode_dist_ext(): Internal data structure error\n",
__FILE__, __LINE__);
*ext = ep;
}
void erts_encode_ext(Eterm term, byte **ext)
{
byte *ep = *ext;
*ep++ = VERSION_MAGIC;
ep = enc_term(NULL, term, ep, TERM_TO_BINARY_DFLAGS);
if (!ep)
erl_exit(ERTS_ABORT_EXIT,
"%s:%d:erts_encode_ext(): Internal data structure error\n",
__FILE__, __LINE__);
*ext = ep;
}
ErtsDistExternal *
erts_make_dist_ext_copy(ErtsDistExternal *edep, Uint xsize)
{
size_t align_sz;
size_t dist_ext_sz;
size_t ext_sz;
byte *ep;
ErtsDistExternal *new_edep;
dist_ext_sz = ERTS_DIST_EXT_SIZE(edep);
ASSERT(edep->ext_endp && edep->extp);
ASSERT(edep->ext_endp >= edep->extp);
ext_sz = edep->ext_endp - edep->extp;
align_sz = ERTS_WORD_ALIGN_PAD_SZ(dist_ext_sz + ext_sz);
new_edep = erts_alloc(ERTS_ALC_T_EXT_TERM_DATA,
dist_ext_sz + ext_sz + align_sz + xsize);
ep = (byte *) new_edep;
sys_memcpy((void *) ep, (void *) edep, dist_ext_sz);
ep += dist_ext_sz;
if (new_edep->dep)
erts_refc_inc(&new_edep->dep->refc, 1);
new_edep->extp = ep;
new_edep->ext_endp = ep + ext_sz;
new_edep->heap_size = -1;
sys_memcpy((void *) ep, (void *) edep->extp, ext_sz);
return new_edep;
}
int
erts_prepare_dist_ext(ErtsDistExternal *edep,
byte *ext,
Uint size,
DistEntry *dep,
ErtsAtomCache *cache)
{
#undef ERTS_EXT_FAIL
#undef ERTS_EXT_HDR_FAIL
#if 1
#define ERTS_EXT_FAIL goto fail
#define ERTS_EXT_HDR_FAIL goto bad_hdr
#else
#define ERTS_EXT_FAIL abort()
#define ERTS_EXT_HDR_FAIL abort()
#endif
register byte *ep = ext;
edep->heap_size = -1;
edep->ext_endp = ext+size;
if (size < 2)
ERTS_EXT_FAIL;
if (ep[0] != VERSION_MAGIC) {
erts_dsprintf_buf_t *dsbufp = erts_create_logger_dsbuf();
if (dep)
erts_dsprintf(dsbufp,
"** Got message from incompatible erlang on "
"channel %d\n",
dist_entry_channel_no(dep));
else
erts_dsprintf(dsbufp,
"** Attempt to convert old incompatible "
"binary %d\n",
*ep);
erts_send_error_to_logger_nogl(dsbufp);
ERTS_EXT_FAIL;
}
edep->flags = 0;
edep->dep = dep;
if (dep) {
erts_smp_de_rlock(dep);
if (dep->flags & DFLAG_DIST_HDR_ATOM_CACHE)
edep->flags |= ERTS_DIST_EXT_DFLAG_HDR;
edep->flags |= (dep->connection_id & ERTS_DIST_EXT_CON_ID_MASK);
erts_smp_de_runlock(dep);
}
if (ep[1] != DIST_HEADER) {
if (edep->flags & ERTS_DIST_EXT_DFLAG_HDR)
ERTS_EXT_HDR_FAIL;
edep->attab.size = 0;
edep->extp = ext;
}
else {
int tix;
int no_atoms;
if (!(edep->flags & ERTS_DIST_EXT_DFLAG_HDR))
ERTS_EXT_HDR_FAIL;
#undef CHKSIZE
#define CHKSIZE(SZ) \
do { if ((SZ) > edep->ext_endp - ep) ERTS_EXT_HDR_FAIL; } while(0)
CHKSIZE(1+1+1);
ep += 2;
no_atoms = (int) get_int8(ep);
if (no_atoms < 0 || ERTS_ATOM_CACHE_SIZE < no_atoms)
ERTS_EXT_HDR_FAIL;
ep++;
if (no_atoms) {
#if MAX_ATOM_LENGTH > 255
int long_atoms = 0;
#endif
#ifdef DEBUG
byte *flgs_buf = ep;
#endif
byte *flgsp = ep;
int flgs_size = ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTES(no_atoms);
int byte_ix;
int bit_ix;
int got_flgs;
register Uint32 flgs = 0;
CHKSIZE(flgs_size);
ep += flgs_size;
/*
* Check long atoms flag
*/
byte_ix = ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTE_IX(no_atoms);
bit_ix = ERTS_DIST_HDR_ATOM_CACHE_FLAG_BIT_IX(no_atoms);
if (flgsp[byte_ix] & (((byte) ERTS_DIST_HDR_LONG_ATOMS_FLG)
<< bit_ix)) {
#if MAX_ATOM_LENGTH > 255
long_atoms = 1;
#else
ERTS_EXT_HDR_FAIL; /* Long atoms not supported yet */
#endif
}
#ifdef DEBUG
byte_ix = 0;
bit_ix = 0;
#endif
got_flgs = 0;
/*
* Setup the atom translation table.
*/
edep->flags |= ERTS_DIST_EXT_ATOM_TRANS_TAB;
edep->attab.size = no_atoms;
for (tix = 0; tix < no_atoms; tix++) {
Eterm atom;
int cix;
int len;
if (!got_flgs) {
int left = no_atoms - tix;
if (left > 6) {
flgs = ((((Uint32) flgsp[3]) << 24)
| (((Uint32) flgsp[2]) << 16)
| (((Uint32) flgsp[1]) << 8)
| ((Uint32) flgsp[0]));
flgsp += 4;
}
else {
flgs = 0;
switch (left) {
case 6:
case 5:
flgs |= (((Uint32) flgsp[2]) << 16);
case 4:
case 3:
flgs |= (((Uint32) flgsp[1]) << 8);
case 2:
case 1:
flgs |= ((Uint32) flgsp[0]);
}
}
got_flgs = 8;
}
ASSERT(byte_ix == ERTS_DIST_HDR_ATOM_CACHE_FLAG_BYTE_IX(tix));
ASSERT(bit_ix == ERTS_DIST_HDR_ATOM_CACHE_FLAG_BIT_IX(tix));
ASSERT((flgs & 3)
== (((flgs_buf[byte_ix]
& (((byte) 3) << bit_ix)) >> bit_ix) & 3));
CHKSIZE(1);
cix = (int) ((flgs & 7) << 8);
if ((flgs & 8) == 0) {
/* atom already cached */
cix += (int) get_int8(ep);
if (cix >= ERTS_ATOM_CACHE_SIZE)
ERTS_EXT_HDR_FAIL;
ep++;
atom = cache->in_arr[cix];
if (!is_atom(atom))
ERTS_EXT_HDR_FAIL;
edep->attab.atom[tix] = atom;
}
else {
/* new cached atom */
cix += (int) get_int8(ep);
if (cix >= ERTS_ATOM_CACHE_SIZE)
ERTS_EXT_HDR_FAIL;
ep++;
#if MAX_ATOM_LENGTH > 255
if (long_atoms) {
CHKSIZE(2);
len = get_int16(ep);
ep += 2;
}
else
#endif
{
CHKSIZE(1);
len = get_int8(ep);
ep++;
}
if (len > MAX_ATOM_LENGTH)
ERTS_EXT_HDR_FAIL; /* Too long atom */
CHKSIZE(len);
atom = am_atom_put((char *) ep, len);
ep += len;
cache->in_arr[cix] = atom;
edep->attab.atom[tix] = atom;
}
flgs >>= 4;
got_flgs--;
#ifdef DEBUG
bit_ix += 4;
if (bit_ix >= 8) {
bit_ix = 0;
flgs = (int) flgs_buf[++byte_ix];
ASSERT(byte_ix < flgs_size);
}
#endif
}
}
edep->extp = ep;
#ifdef ERTS_DEBUG_USE_DIST_SEP
if (*ep != VERSION_MAGIC)
ERTS_EXT_HDR_FAIL;
#endif
}
#ifdef ERTS_DEBUG_USE_DIST_SEP
if (*ep != VERSION_MAGIC)
ERTS_EXT_FAIL;
#endif
return 0;
#undef CHKSIZE
#undef ERTS_EXT_FAIL
#undef ERTS_EXT_HDR_FAIL
bad_hdr:
if (dep) {
erts_dsprintf_buf_t *dsbufp = erts_create_logger_dsbuf();
erts_dsprintf(dsbufp,
"%T got a corrupted distribution header from %T "
"on distribution channel %d\n",
erts_this_node->sysname,
edep->dep->sysname,
dist_entry_channel_no(edep->dep));
for (ep = ext; ep < edep->ext_endp; ep++)
erts_dsprintf(dsbufp, ep != ext ? ",%b8u" : "<<%b8u", *ep);
erts_dsprintf(dsbufp, ">>");
erts_send_warning_to_logger_nogl(dsbufp);
}
fail:
if (dep)
erts_kill_dist_connection(dep, dep->connection_id);
return -1;
}
static void
bad_dist_ext(ErtsDistExternal *edep)
{
if (edep->dep) {
DistEntry *dep = edep->dep;
erts_dsprintf_buf_t *dsbufp = erts_create_logger_dsbuf();
byte *ep;
erts_dsprintf(dsbufp,
"%T got a corrupted external term from %T "
"on distribution channel %d\n",
erts_this_node->sysname,
dep->sysname,
dist_entry_channel_no(dep));
for (ep = edep->extp; ep < edep->ext_endp; ep++)
erts_dsprintf(dsbufp,
ep != edep->extp ? ",%b8u" : "<<...,%b8u",
*ep);
erts_dsprintf(dsbufp, ">>\n");
erts_dsprintf(dsbufp, "ATOM_CACHE_REF translations: ");
if (!(edep->flags & ERTS_DIST_EXT_ATOM_TRANS_TAB) || !edep->attab.size)
erts_dsprintf(dsbufp, "none");
else {
int i;
erts_dsprintf(dsbufp, "0=%T", edep->attab.atom[0]);
for (i = 1; i < edep->attab.size; i++)
erts_dsprintf(dsbufp, ", %d=%T", i, edep->attab.atom[i]);
}
erts_send_warning_to_logger_nogl(dsbufp);
erts_kill_dist_connection(dep, ERTS_DIST_EXT_CON_ID(edep));
}
}
Sint
erts_decode_dist_ext_size(ErtsDistExternal *edep, int no_refc_bins)
{
Sint res;
byte *ep;
if (edep->extp >= edep->ext_endp)
goto fail;
#ifndef ERTS_DEBUG_USE_DIST_SEP
if (edep->flags & ERTS_DIST_EXT_DFLAG_HDR) {
if (*edep->extp == VERSION_MAGIC)
goto fail;
ep = edep->extp;
}
else
#endif
{
if (*edep->extp != VERSION_MAGIC)
goto fail;
ep = edep->extp+1;
}
res = decoded_size(ep, edep->ext_endp, no_refc_bins);
if (res >= 0)
return res;
fail:
bad_dist_ext(edep);
return -1;
}
Sint erts_decode_ext_size(byte *ext, Uint size, int no_refc_bins)
{
if (size == 0 || *ext != VERSION_MAGIC)
return -1;
return decoded_size(ext+1, ext+size, no_refc_bins);
}
/*
** hpp is set to either a &p->htop or
** a pointer to a memory pointer (form message buffers)
** on return hpp is updated to point after allocated data
*/
Eterm
erts_decode_dist_ext(Eterm** hpp,
ErlOffHeap* off_heap,
ErtsDistExternal *edep)
{
Eterm obj;
byte* ep = edep->extp;
if (ep >= edep->ext_endp)
goto error;
#ifndef ERTS_DEBUG_USE_DIST_SEP
if (edep->flags & ERTS_DIST_EXT_DFLAG_HDR) {
if (*ep == VERSION_MAGIC)
goto error;
}
else
#endif
{
if (*ep != VERSION_MAGIC)
goto error;
ep++;
}
ep = dec_term(edep, hpp, ep, off_heap, &obj);
if (!ep)
goto error;
edep->extp = ep;
return obj;
error:
bad_dist_ext(edep);
return THE_NON_VALUE;
}
Eterm erts_decode_ext(Eterm **hpp, ErlOffHeap *off_heap, byte **ext)
{
Eterm obj;
byte *ep = *ext;
if (*ep++ != VERSION_MAGIC)
return THE_NON_VALUE;
ep = dec_term(NULL, hpp, ep, off_heap, &obj);
if (!ep) {
#ifdef DEBUG
bin_write(ERTS_PRINT_STDERR,NULL,*ext,500);
#endif
return THE_NON_VALUE;
}
*ext = ep;
return obj;
}
/**********************************************************************/
BIF_RETTYPE erts_debug_dist_ext_to_term_2(BIF_ALIST_2)
{
Eterm res;
Eterm *hp;
Eterm *hendp;
Uint hsz;
ErtsDistExternal ede;
Eterm *tp;
Eterm real_bin;
Uint offset;
Uint size;
Uint bitsize;
Uint bitoffs;
Uint arity;
int i;
ede.flags = ERTS_DIST_EXT_ATOM_TRANS_TAB;
ede.dep = NULL;
ede.heap_size = -1;
if (is_not_tuple(BIF_ARG_1))
goto badarg;
tp = tuple_val(BIF_ARG_1);
arity = arityval(tp[0]);
if (arity > ERTS_MAX_INTERNAL_ATOM_CACHE_ENTRIES)
goto badarg;
ede.attab.size = arity;
for (i = 1; i <= arity; i++) {
if (is_not_atom(tp[i]))
goto badarg;
ede.attab.atom[i-1] = tp[i];
}
if (is_not_binary(BIF_ARG_2))
goto badarg;
size = binary_size(BIF_ARG_2);
if (size == 0)
goto badarg;
ERTS_GET_REAL_BIN(BIF_ARG_2, real_bin, offset, bitoffs, bitsize);
if (bitsize != 0)
goto badarg;
ede.extp = binary_bytes(real_bin)+offset;
ede.ext_endp = ede.extp + size;
hsz = erts_decode_dist_ext_size(&ede, 0);
if (hsz < 0)
goto badarg;
hp = HAlloc(BIF_P, hsz);
hendp = hp + hsz;
res = erts_decode_dist_ext(&hp, &MSO(BIF_P), &ede);
HRelease(BIF_P, hendp, hp);
if (is_value(res))
BIF_RET(res);
badarg:
BIF_ERROR(BIF_P, BADARG);
}
Eterm
term_to_binary_1(Process* p, Eterm Term)
{
return erts_term_to_binary(p, Term, 0, TERM_TO_BINARY_DFLAGS);
}
Eterm
term_to_binary_2(Process* p, Eterm Term, Eterm Flags)
{
int level = 0;
Uint flags = TERM_TO_BINARY_DFLAGS;
while (is_list(Flags)) {
Eterm arg = CAR(list_val(Flags));
Eterm* tp;
if (arg == am_compressed) {
level = Z_DEFAULT_COMPRESSION;
} else if (is_tuple(arg) && *(tp = tuple_val(arg)) == make_arityval(2)) {
if (tp[1] == am_minor_version && is_small(tp[2])) {
switch (signed_val(tp[2])) {
case 0:
flags = TERM_TO_BINARY_DFLAGS;
break;
case 1:
flags = TERM_TO_BINARY_DFLAGS|DFLAG_NEW_FLOATS;
break;
default:
goto error;
}
} else if (tp[1] == am_compressed && is_small(tp[2])) {
level = signed_val(tp[2]);
if (!(0 <= level && level < 10)) {
goto error;
}
} else {
goto error;
}
} else {
error:
BIF_ERROR(p, BADARG);
}
Flags = CDR(list_val(Flags));
}
if (is_not_nil(Flags)) {
goto error;
}
return erts_term_to_binary(p, Term, level, flags);
}
static uLongf binary2term_uncomp_size(byte* data, Sint size)
{
z_stream stream;
int err;
const uInt chunk_size = 64*1024; /* Ask tmp-alloc about a suitable size? */
void* tmp_buf = erts_alloc(ERTS_ALC_T_TMP, chunk_size);
uLongf uncomp_size = 0;
stream.next_in = (Bytef*)data;
stream.avail_in = (uInt)size;
stream.next_out = tmp_buf;
stream.avail_out = (uInt)chunk_size;
erl_zlib_alloc_init(&stream);
err = inflateInit(&stream);
if (err == Z_OK) {
do {
stream.next_out = tmp_buf;
stream.avail_out = chunk_size;
err = inflate(&stream, Z_NO_FLUSH);
uncomp_size += chunk_size - stream.avail_out;
}while (err == Z_OK);
inflateEnd(&stream);
}
erts_free(ERTS_ALC_T_TMP, tmp_buf);
return err == Z_STREAM_END ? uncomp_size : 0;
}
static ERTS_INLINE Sint
binary2term_prepare(ErtsBinary2TermState *state, byte *data, Sint data_size)
{
Sint res;
byte *bytes = data;
Sint size = data_size;
state->exttmp = 0;
if (size < 1 || *bytes != VERSION_MAGIC) {
error:
if (state->exttmp)
erts_free(ERTS_ALC_T_TMP, state->extp);
state->extp = NULL;
state->exttmp = 0;
return -1;
}
bytes++;
size--;
if (size < 5 || *bytes != COMPRESSED) {
state->extp = bytes;
}
else {
uLongf dest_len = (Uint32) get_int32(bytes+1);
bytes += 5;
size -= 5;
if (dest_len > 32*1024*1024
|| (state->extp = erts_alloc_fnf(ERTS_ALC_T_TMP, dest_len)) == NULL) {
if (dest_len != binary2term_uncomp_size(bytes, size)) {
goto error;
}
state->extp = erts_alloc(ERTS_ALC_T_TMP, dest_len);
}
state->exttmp = 1;
if (erl_zlib_uncompress(state->extp, &dest_len, bytes, size) != Z_OK)
goto error;
size = (Sint) dest_len;
}
res = decoded_size(state->extp, state->extp + size, 0);
if (res < 0)
goto error;
return res;
}
static ERTS_INLINE void
binary2term_abort(ErtsBinary2TermState *state)
{
if (state->exttmp) {
state->exttmp = 0;
erts_free(ERTS_ALC_T_TMP, state->extp);
}
}
static ERTS_INLINE Eterm
binary2term_create(ErtsDistExternal *edep, ErtsBinary2TermState *state, Eterm **hpp, ErlOffHeap *ohp)
{
Eterm res;
if (!dec_term(edep, hpp, state->extp, ohp, &res))
res = THE_NON_VALUE;
if (state->exttmp) {
state->exttmp = 0;
erts_free(ERTS_ALC_T_TMP, state->extp);
}
return res;
}
Sint
erts_binary2term_prepare(ErtsBinary2TermState *state, byte *data, Sint data_size)
{
return binary2term_prepare(state, data, data_size);
}
void
erts_binary2term_abort(ErtsBinary2TermState *state)
{
binary2term_abort(state);
}
Eterm
erts_binary2term_create(ErtsBinary2TermState *state, Eterm **hpp, ErlOffHeap *ohp)
{
return binary2term_create(NULL,state, hpp, ohp);
}
BIF_RETTYPE binary_to_term_1(BIF_ALIST_1)
{
Sint heap_size;
Eterm res;
Eterm* hp;
Eterm* endp;
Sint size;
byte* bytes;
byte* temp_alloc = NULL;
ErtsBinary2TermState b2ts;
if ((bytes = erts_get_aligned_binary_bytes(BIF_ARG_1, &temp_alloc)) == NULL) {
error:
erts_free_aligned_binary_bytes(temp_alloc);
BIF_ERROR(BIF_P, BADARG);
}
size = binary_size(BIF_ARG_1);
heap_size = binary2term_prepare(&b2ts, bytes, size);
if (heap_size < 0)
goto error;
hp = HAlloc(BIF_P, heap_size);
endp = hp + heap_size;
res = binary2term_create(NULL, &b2ts, &hp, &MSO(BIF_P));
erts_free_aligned_binary_bytes(temp_alloc);
if (hp > endp) {
erl_exit(1, ":%s, line %d: heap overrun by %d words(s)\n",
__FILE__, __LINE__, hp-endp);
}
HRelease(BIF_P, endp, hp);
if (res == THE_NON_VALUE)
goto error;
return res;
}
BIF_RETTYPE binary_to_term_2(BIF_ALIST_2)
{
Sint heap_size;
Eterm res;
Eterm opts;
Eterm opt;
Eterm* hp;
Eterm* endp;
Sint size;
byte* bytes;
byte* temp_alloc = NULL;
ErtsBinary2TermState b2ts;
ErtsDistExternal fakedep;
fakedep.flags = 0;
opts = BIF_ARG_2;
while (is_list(opts)) {
opt = CAR(list_val(opts));
if (opt == am_safe) {
fakedep.flags |= ERTS_DIST_EXT_BTT_SAFE;
} else {
goto error;
}
opts = CDR(list_val(opts));
}
if (is_not_nil(opts))
goto error;
if ((bytes = erts_get_aligned_binary_bytes(BIF_ARG_1, &temp_alloc)) == NULL) {
error:
erts_free_aligned_binary_bytes(temp_alloc);
BIF_ERROR(BIF_P, BADARG);
}
size = binary_size(BIF_ARG_1);
heap_size = binary2term_prepare(&b2ts, bytes, size);
if (heap_size < 0)
goto error;
hp = HAlloc(BIF_P, heap_size);
endp = hp + heap_size;
res = binary2term_create(&fakedep, &b2ts, &hp, &MSO(BIF_P));
erts_free_aligned_binary_bytes(temp_alloc);
if (hp > endp) {
erl_exit(1, ":%s, line %d: heap overrun by %d words(s)\n",
__FILE__, __LINE__, hp-endp);
}
HRelease(BIF_P, endp, hp);
if (res == THE_NON_VALUE)
goto error;
return res;
}
Eterm
external_size_1(Process* p, Eterm Term)
{
Uint size = erts_encode_ext_size(Term);
if (IS_USMALL(0, size)) {
BIF_RET(make_small(size));
} else {
Eterm* hp = HAlloc(p, BIG_UINT_HEAP_SIZE);
BIF_RET(uint_to_big(size, hp));
}
}
Eterm
erts_term_to_binary(Process* p, Eterm Term, int level, Uint flags)
{
int size;
Eterm bin;
size_t real_size;
byte* endp;
size = encode_size_struct2(NULL, Term, flags) + 1 /* VERSION_MAGIC */;
if (level != 0) {
byte buf[256];
byte* bytes = buf;
byte* out_bytes;
uLongf dest_len;
if (sizeof(buf) < size) {
bytes = erts_alloc(ERTS_ALC_T_TMP, size);
}
if ((endp = enc_term(NULL, Term, bytes, flags))
== NULL) {
erl_exit(1, "%s, line %d: bad term: %x\n",
__FILE__, __LINE__, Term);
}
real_size = endp - bytes;
if (real_size > size) {
erl_exit(1, "%s, line %d: buffer overflow: %d word(s)\n",
__FILE__, __LINE__, real_size - size);
}
/*
* We don't want to compress if compression actually increases the size.
* Therefore, don't give zlib more out buffer than the size of the
* uncompressed external format (minus the 5 bytes needed for the
* COMPRESSED tag). If zlib returns any error, we'll revert to using
* the original uncompressed external term format.
*/
if (real_size < 5) {
dest_len = 0;
} else {
dest_len = real_size - 5;
}
bin = new_binary(p, NULL, real_size+1);
out_bytes = binary_bytes(bin);
out_bytes[0] = VERSION_MAGIC;
if (erl_zlib_compress2(out_bytes+6, &dest_len, bytes, real_size, level) != Z_OK) {
sys_memcpy(out_bytes+1, bytes, real_size);
bin = erts_realloc_binary(bin, real_size+1);
} else {
out_bytes[1] = COMPRESSED;
put_int32(real_size, out_bytes+2);
bin = erts_realloc_binary(bin, dest_len+6);
}
if (bytes != buf) {
erts_free(ERTS_ALC_T_TMP, bytes);
}
return bin;
} else {
byte* bytes;
bin = new_binary(p, (byte *)NULL, size);
bytes = binary_bytes(bin);
bytes[0] = VERSION_MAGIC;
if ((endp = enc_term(NULL, Term, bytes+1, flags))
== NULL) {
erl_exit(1, "%s, line %d: bad term: %x\n",
__FILE__, __LINE__, Term);
}
real_size = endp - bytes;
if (real_size > size) {
erl_exit(1, "%s, line %d: buffer overflow: %d word(s)\n",
__FILE__, __LINE__, endp - (bytes + size));
}
return erts_realloc_binary(bin, real_size);
}
}
/*
* This function fills ext with the external format of atom.
* If it's an old atom we just supply an index, otherwise
* we insert the index _and_ the entire atom. This way the receiving side
* does not have to perform an hash on the etom to locate it, and
* we save a lot of space on the wire.
*/
static byte*
enc_atom(ErtsAtomCacheMap *acmp, Eterm atom, byte *ep, Uint32 dflags)
{
int iix;
int i, j;
ASSERT(is_atom(atom));
/*
* term_to_binary/1,2 and the initial distribution message
* don't use the cache.
*/
iix = get_iix_acache_map(acmp, atom);
if (iix < 0) {
i = atom_val(atom);
j = atom_tab(i)->len;
if ((MAX_ATOM_LENGTH <= 255 || j <= 255)
&& (dflags & DFLAG_SMALL_ATOM_TAGS)) {
*ep++ = SMALL_ATOM_EXT;
put_int8(j, ep);
ep++;
}
else {
*ep++ = ATOM_EXT;
put_int16(j, ep);
ep += 2;
}
sys_memcpy((char *) ep, (char*)atom_tab(i)->name, (int) j);
ep += j;
return ep;
}
/* The atom is referenced in the cache. */
*ep++ = ATOM_CACHE_REF;
put_int8(iix, ep);
ep++;
return ep;
}
static byte*
enc_pid(ErtsAtomCacheMap *acmp, Eterm pid, byte* ep, Uint32 dflags)
{
Uint on, os;
*ep++ = PID_EXT;
/* insert atom here containing host and sysname */
ep = enc_atom(acmp, pid_node_name(pid), ep, dflags);
/* two bytes for each number and serial */
on = pid_number(pid);
os = pid_serial(pid);
put_int32(on, ep);
ep += 4;
put_int32(os, ep);
ep += 4;
*ep++ = pid_creation(pid);
return ep;
}
/* Expect an atom in plain text or cached */
static byte*
dec_atom(ErtsDistExternal *edep, byte* ep, Eterm* objp)
{
Uint len;
int n;
switch (*ep++) {
case ATOM_CACHE_REF:
if (!(edep && (edep->flags & ERTS_DIST_EXT_ATOM_TRANS_TAB)))
goto error;
n = get_int8(ep);
ep++;
if (n >= edep->attab.size)
goto error;
ASSERT(is_atom(edep->attab.atom[n]));
*objp = edep->attab.atom[n];
break;
case ATOM_EXT:
len = get_int16(ep),
ep += 2;
goto dec_atom_common;
case SMALL_ATOM_EXT:
len = get_int8(ep);
ep++;
dec_atom_common:
if (edep && (edep->flags & ERTS_DIST_EXT_BTT_SAFE)) {
if (!erts_atom_get((char*)ep, len, objp)) {
goto error;
}
} else {
*objp = am_atom_put((char*)ep, len);
}
ep += len;
break;
default:
error:
*objp = NIL; /* Don't leave a hole in the heap */
return NULL;
}
return ep;
}
static byte*
dec_pid(ErtsDistExternal *edep, Eterm** hpp, byte* ep, ErlOffHeap* off_heap, Eterm* objp)
{
Eterm sysname;
Uint data;
Uint num;
Uint ser;
Uint cre;
ErlNode *node;
*objp = NIL; /* In case we fail, don't leave a hole in the heap */
/* eat first atom */
if ((ep = dec_atom(edep, ep, &sysname)) == NULL)
return NULL;
num = get_int32(ep);
ep += 4;
if (num > ERTS_MAX_PID_NUMBER)
return NULL;
ser = get_int32(ep);
ep += 4;
if (ser > ERTS_MAX_PID_SERIAL)
return NULL;
if ((cre = get_int8(ep)) >= MAX_CREATION)
return NULL;
ep += 1;
/*
* We are careful to create the node entry only after all
* validity tests are done.
*/
cre = dec_set_creation(sysname,cre);
node = erts_find_or_insert_node(sysname,cre);
data = make_pid_data(ser, num);
if(node == erts_this_node) {
*objp = make_internal_pid(data);
} else {
ExternalThing *etp = (ExternalThing *) *hpp;
*hpp += EXTERNAL_THING_HEAD_SIZE + 1;
etp->header = make_external_pid_header(1);
etp->next = off_heap->externals;
etp->node = node;
etp->data.ui[0] = data;
off_heap->externals = etp;
*objp = make_external_pid(etp);
}
return ep;
}
#define ENC_TERM ((Eterm) 0)
#define ENC_ONE_CONS ((Eterm) 1)
#define ENC_PATCH_FUN_SIZE ((Eterm) 2)
#define ENC_LAST_ARRAY_ELEMENT ((Eterm) 3)
static byte*
enc_term(ErtsAtomCacheMap *acmp, Eterm obj, byte* ep, Uint32 dflags)
{
DECLARE_WSTACK(s);
Uint n;
Uint i;
Uint j;
Uint* ptr;
Eterm val;
FloatDef f;
#if HALFWORD_HEAP
UWord wobj;
#endif
goto L_jump_start;
outer_loop:
while (!WSTACK_ISEMPTY(s)) {
#if HALFWORD_HEAP
obj = (Eterm) (wobj = WSTACK_POP(s));
#else
obj = WSTACK_POP(s);
#endif
switch (val = WSTACK_POP(s)) {
case ENC_TERM:
break;
case ENC_ONE_CONS:
encode_one_cons:
{
Eterm* cons = list_val(obj);
Eterm tl;
obj = CAR(cons);
tl = CDR(cons);
WSTACK_PUSH(s, is_list(tl) ? ENC_ONE_CONS : ENC_TERM);
WSTACK_PUSH(s, tl);
}
break;
case ENC_PATCH_FUN_SIZE:
{
#if HALFWORD_HEAP
byte* size_p = (byte *) wobj;
#else
byte* size_p = (byte *) obj;
#endif
put_int32(ep - size_p, size_p);
}
goto outer_loop;
case ENC_LAST_ARRAY_ELEMENT:
{
#if HALFWORD_HEAP
Eterm* ptr = (Eterm *) wobj;
#else
Eterm* ptr = (Eterm *) obj;
#endif
obj = *ptr;
}
break;
default: /* ENC_LAST_ARRAY_ELEMENT+1 and upwards */
{
#if HALFWORD_HEAP
Eterm* ptr = (Eterm *) wobj;
#else
Eterm* ptr = (Eterm *) obj;
#endif
obj = *ptr++;
WSTACK_PUSH(s, val-1);
WSTACK_PUSH(s, (UWord) ptr);
}
break;
}
L_jump_start:
switch(tag_val_def(obj)) {
case NIL_DEF:
*ep++ = NIL_EXT;
break;
case ATOM_DEF:
ep = enc_atom(acmp,obj,ep,dflags);
break;
case SMALL_DEF:
{
Sint val = signed_val(obj);
if ((Uint)val < 256) {
*ep++ = SMALL_INTEGER_EXT;
put_int8(val, ep);
ep++;
} else if (sizeof(Sint) == 4 || IS_SSMALL28(val)) {
*ep++ = INTEGER_EXT;
put_int32(val, ep);
ep += 4;
} else {
DeclareTmpHeapNoproc(tmp_big,2);
Eterm big;
UseTmpHeapNoproc(2);
big = small_to_big(val, tmp_big);
*ep++ = SMALL_BIG_EXT;
n = big_bytes(big);
ASSERT(n < 256);
put_int8(n, ep);
ep += 1;
*ep++ = big_sign(big);
ep = big_to_bytes(big, ep);
UnUseTmpHeapNoproc(2);
}
}
break;
case BIG_DEF:
if ((n = big_bytes(obj)) < 256) {
*ep++ = SMALL_BIG_EXT;
put_int8(n, ep);
ep += 1;
}
else {
*ep++ = LARGE_BIG_EXT;
put_int32(n, ep);
ep += 4;
}
*ep++ = big_sign(obj);
ep = big_to_bytes(obj, ep);
break;
case PID_DEF:
case EXTERNAL_PID_DEF:
ep = enc_pid(acmp, obj, ep, dflags);
break;
case REF_DEF:
case EXTERNAL_REF_DEF: {
Uint32 *ref_num;
ASSERT(dflags & DFLAG_EXTENDED_REFERENCES);
*ep++ = NEW_REFERENCE_EXT;
i = ref_no_of_numbers(obj);
put_int16(i, ep);
ep += 2;
ep = enc_atom(acmp,ref_node_name(obj),ep,dflags);
*ep++ = ref_creation(obj);
ref_num = ref_numbers(obj);
for (j = 0; j < i; j++) {
put_int32(ref_num[j], ep);
ep += 4;
}
break;
}
case PORT_DEF:
case EXTERNAL_PORT_DEF:
*ep++ = PORT_EXT;
ep = enc_atom(acmp,port_node_name(obj),ep,dflags);
j = port_number(obj);
put_int32(j, ep);
ep += 4;
*ep++ = port_creation(obj);
break;
case LIST_DEF:
{
int is_str;
i = is_external_string(obj, &is_str);
if (is_str) {
*ep++ = STRING_EXT;
put_int16(i, ep);
ep += 2;
while (is_list(obj)) {
Eterm* cons = list_val(obj);
*ep++ = unsigned_val(CAR(cons));
obj = CDR(cons);
}
} else {
*ep++ = LIST_EXT;
put_int32(i, ep);
ep += 4;
goto encode_one_cons;
}
}
break;
case TUPLE_DEF:
ptr = tuple_val(obj);
i = arityval(*ptr);
ptr++;
if (i <= 0xff) {
*ep++ = SMALL_TUPLE_EXT;
put_int8(i, ep);
ep += 1;
} else {
*ep++ = LARGE_TUPLE_EXT;
put_int32(i, ep);
ep += 4;
}
if (i > 0) {
WSTACK_PUSH(s, ENC_LAST_ARRAY_ELEMENT+i-1);
WSTACK_PUSH(s, (UWord) ptr);
}
break;
case FLOAT_DEF:
GET_DOUBLE(obj, f);
if (dflags & DFLAG_NEW_FLOATS) {
*ep++ = NEW_FLOAT_EXT;
#ifdef WORDS_BIGENDIAN
put_int32(f.fw[0], ep);
ep += 4;
put_int32(f.fw[1], ep);
#else
put_int32(f.fw[1], ep);
ep += 4;
put_int32(f.fw[0], ep);
#endif
ep += 4;
} else {
*ep++ = FLOAT_EXT;
/* now the sprintf which does the work */
i = sys_double_to_chars(f.fd, (char*) ep);
/* Don't leave garbage after the float! (Bad practice in general,
* and Purify complains.)
*/
sys_memset(ep+i, 0, 31-i);
ep += 31;
}
break;
case BINARY_DEF:
{
Uint bitoffs;
Uint bitsize;
byte* bytes;
ERTS_GET_BINARY_BYTES(obj, bytes, bitoffs, bitsize);
if (bitsize == 0) {
/* Plain old byte-sized binary. */
*ep++ = BINARY_EXT;
j = binary_size(obj);
put_int32(j, ep);
ep += 4;
copy_binary_to_buffer(ep, 0, bytes, bitoffs, 8*j);
ep += j;
} else if (dflags & DFLAG_BIT_BINARIES) {
/* Bit-level binary. */
*ep++ = BIT_BINARY_EXT;
j = binary_size(obj);
put_int32((j+1), ep);
ep += 4;
*ep++ = bitsize;
ep[j] = 0; /* Zero unused bits at end of binary */
copy_binary_to_buffer(ep, 0, bytes, bitoffs, 8*j+bitsize);
ep += j + 1;
} else {
/*
* Bit-level binary, but the receiver doesn't support it.
* Build a tuple instead.
*/
*ep++ = SMALL_TUPLE_EXT;
*ep++ = 2;
*ep++ = BINARY_EXT;
j = binary_size(obj);
put_int32((j+1), ep);
ep += 4;
ep[j] = 0; /* Zero unused bits at end of binary */
copy_binary_to_buffer(ep, 0, bytes, bitoffs, 8*j+bitsize);
ep += j+1;
*ep++ = SMALL_INTEGER_EXT;
*ep++ = bitsize;
}
break;
}
case EXPORT_DEF:
{
Export* exp = *((Export **) (export_val(obj) + 1));
if ((dflags & DFLAG_EXPORT_PTR_TAG) != 0) {
*ep++ = EXPORT_EXT;
ep = enc_atom(acmp, exp->code[0], ep, dflags);
ep = enc_atom(acmp, exp->code[1], ep, dflags);
ep = enc_term(acmp, make_small(exp->code[2]), ep, dflags);
} else {
/* Tag, arity */
*ep++ = SMALL_TUPLE_EXT;
put_int8(2, ep);
ep += 1;
/* Module name */
ep = enc_atom(acmp, exp->code[0], ep, dflags);
/* Function name */
ep = enc_atom(acmp, exp->code[1], ep, dflags);
}
break;
}
break;
case FUN_DEF:
{
ErlFunThing* funp = (ErlFunThing *) fun_val(obj);
if ((dflags & DFLAG_NEW_FUN_TAGS) != 0) {
int ei;
*ep++ = NEW_FUN_EXT;
WSTACK_PUSH(s, ENC_PATCH_FUN_SIZE);
WSTACK_PUSH(s, (UWord) ep); /* Position for patching in size */
ep += 4;
*ep = funp->arity;
ep += 1;
sys_memcpy(ep, funp->fe->uniq, 16);
ep += 16;
put_int32(funp->fe->index, ep);
ep += 4;
put_int32(funp->num_free, ep);
ep += 4;
ep = enc_atom(acmp, funp->fe->module, ep, dflags);
ep = enc_term(acmp, make_small(funp->fe->old_index), ep, dflags);
ep = enc_term(acmp, make_small(funp->fe->old_uniq), ep, dflags);
ep = enc_pid(acmp, funp->creator, ep, dflags);
fun_env:
for (ei = funp->num_free-1; ei > 0; ei--) {
WSTACK_PUSH(s, ENC_TERM);
WSTACK_PUSH(s, (UWord) funp->env[ei]);
}
if (funp->num_free != 0) {
obj = funp->env[0];
goto L_jump_start;
}
} else {
/*
* Communicating with an obsolete erl_interface or
* jinterface node. Convert the fun to a tuple to
* avoid crasching.
*/
/* Tag, arity */
*ep++ = SMALL_TUPLE_EXT;
put_int8(5, ep);
ep += 1;
/* 'fun' */
ep = enc_atom(acmp, am_fun, ep, dflags);
/* Module name */
ep = enc_atom(acmp, funp->fe->module, ep, dflags);
/* Index, Uniq */
*ep++ = INTEGER_EXT;
put_int32(funp->fe->old_index, ep);
ep += 4;
*ep++ = INTEGER_EXT;
put_int32(funp->fe->old_uniq, ep);
ep += 4;
/* Environment sub-tuple arity */
ASSERT(funp->num_free < MAX_ARG);
*ep++ = SMALL_TUPLE_EXT;
put_int8(funp->num_free, ep);
ep += 1;
goto fun_env;
}
}
break;
}
}
DESTROY_WSTACK(s);
return ep;
}
static Uint
is_external_string(Eterm list, int* p_is_string)
{
Uint len = 0;
/*
* Calculate the length of the list as long as all characters
* are integers from 0 through 255.
*/
while (is_list(list)) {
Eterm* consp = list_val(list);
Eterm hd = CAR(consp);
if (!is_byte(hd)) {
break;
}
len++;
list = CDR(consp);
}
/*
* If we have reached the end of the list, and we have
* not exceeded the maximum length of a string, this
* is a string.
*/
*p_is_string = is_nil(list) && len < MAX_STRING_LEN;
/*
* Continue to calculate the length.
*/
while (is_list(list)) {
Eterm* consp = list_val(list);
len++;
list = CDR(consp);
}
return len;
}
/* Assumes that the ones to undo are preluding the lists. */
static void
undo_offheap_in_area(ErlOffHeap* off_heap, Eterm* start, Eterm* end)
{
const Uint area_sz = (end - start) * sizeof(Eterm);
struct proc_bin* mso;
struct proc_bin** mso_nextp = NULL;
#ifndef HYBRID /* FIND ME! */
struct erl_fun_thing* funs;
struct erl_fun_thing** funs_nextp = NULL;
#endif
struct external_thing_* ext;
struct external_thing_** ext_nextp = NULL;
for (mso = off_heap->mso; ; mso=mso->next) {
if (!in_area(mso, start, area_sz)) {
if (mso_nextp != NULL) {
*mso_nextp = NULL;
erts_cleanup_mso(off_heap->mso);
off_heap->mso = mso;
}
break;
}
mso_nextp = &mso->next;
}
#ifndef HYBRID /* FIND ME! */
for (funs = off_heap->funs; ; funs=funs->next) {
if (!in_area(funs, start, area_sz)) {
if (funs_nextp != NULL) {
*funs_nextp = NULL;
erts_cleanup_funs(off_heap->funs);
off_heap->funs = funs;
}
break;
}
funs_nextp = &funs->next;
}
#endif
for (ext = off_heap->externals; ; ext=ext->next) {
if (!in_area(ext, start, area_sz)) {
if (ext_nextp != NULL) {
*ext_nextp = NULL;
erts_cleanup_externals(off_heap->externals);
off_heap->externals = ext;
}
break;
}
ext_nextp = &ext->next;
}
/* Assert that the ones to undo were indeed preluding the lists. */
#ifdef DEBUG
for (mso = off_heap->mso; mso != NULL; mso=mso->next) {
ASSERT(!in_area(mso, start, area_sz));
}
# ifndef HYBRID /* FIND ME! */
for (funs = off_heap->funs; funs != NULL; funs=funs->next) {
ASSERT(!in_area(funs, start, area_sz));
}
# endif
for (ext = off_heap->externals; ext != NULL; ext=ext->next) {
ASSERT(!in_area(ext, start, area_sz));
}
#endif /* DEBUG */
}
/* Decode term from external format into *objp.
** On failure return NULL and (R13B04) *hpp will be unchanged.
*/
static byte*
dec_term(ErtsDistExternal *edep, Eterm** hpp, byte* ep, ErlOffHeap* off_heap, Eterm* objp)
{
Eterm* hp_saved = *hpp;
int n;
register Eterm* hp = *hpp; /* Please don't take the address of hp */
Eterm* next = objp;
*next = (Eterm) NULL;
while (next != NULL) {
objp = next;
next = (Eterm *) EXPAND_POINTER(*objp);
switch (*ep++) {
case INTEGER_EXT:
{
Sint sn = get_int32(ep);
ep += 4;
#if defined(ARCH_64) && !HALFWORD_HEAP
*objp = make_small(sn);
#else
if (MY_IS_SSMALL(sn)) {
*objp = make_small(sn);
} else {
*objp = small_to_big(sn, hp);
hp += BIG_UINT_HEAP_SIZE;
}
#endif
break;
}
case SMALL_INTEGER_EXT:
n = get_int8(ep);
ep++;
*objp = make_small(n);
break;
case SMALL_BIG_EXT:
n = get_int8(ep);
ep++;
goto big_loop;
case LARGE_BIG_EXT:
n = get_int32(ep);
ep += 4;
big_loop:
{
Eterm big;
byte* first;
byte* last;
Uint neg;
neg = get_int8(ep); /* Sign bit */
ep++;
/*
* Strip away leading zeroes to avoid creating illegal bignums.
*/
first = ep;
last = ep + n;
ep += n;
do {
--last;
} while (first <= last && *last == 0);
if ((n = last - first + 1) == 0) {
/* Zero width bignum defaults to zero */
big = make_small(0);
} else {
big = bytes_to_big(first, n, neg, hp);
if (is_big(big)) {
hp += big_arity(big) + 1;
}
}
*objp = big;
break;
}
case ATOM_CACHE_REF:
if (edep == 0 || (edep->flags & ERTS_DIST_EXT_ATOM_TRANS_TAB) == 0) {
goto error;
}
n = get_int8(ep);
ep++;
if (n >= edep->attab.size)
goto error;
ASSERT(is_atom(edep->attab.atom[n]));
*objp = edep->attab.atom[n];
break;
case ATOM_EXT:
n = get_int16(ep);
ep += 2;
goto dec_term_atom_common;
case SMALL_ATOM_EXT:
n = get_int8(ep);
ep++;
dec_term_atom_common:
if (edep && (edep->flags & ERTS_DIST_EXT_BTT_SAFE)) {
if (!erts_atom_get((char*)ep, n, objp)) {
goto error;
}
} else {
*objp = am_atom_put((char*)ep, n);
}
ep += n;
break;
case LARGE_TUPLE_EXT:
n = get_int32(ep);
ep += 4;
goto tuple_loop;
case SMALL_TUPLE_EXT:
n = get_int8(ep);
ep++;
tuple_loop:
*objp = make_tuple(hp);
*hp++ = make_arityval(n);
hp += n;
objp = hp - 1;
while (n-- > 0) {
objp[0] = (Eterm) COMPRESS_POINTER(next);
next = objp;
objp--;
}
break;
case NIL_EXT:
*objp = NIL;
break;
case LIST_EXT:
n = get_int32(ep);
ep += 4;
if (n == 0) {
next = objp;
break;
}
*objp = make_list(hp);
hp += 2*n;
objp = hp - 2;
objp[0] = (Eterm) COMPRESS_POINTER((objp+1));
objp[1] = (Eterm) COMPRESS_POINTER(next);
next = objp;
objp -= 2;
while (--n > 0) {
objp[0] = (Eterm) COMPRESS_POINTER(next);
objp[1] = make_list(objp + 2);
next = objp;
objp -= 2;
}
break;
case STRING_EXT:
n = get_int16(ep);
ep += 2;
if (n == 0) {
*objp = NIL;
break;
}
*objp = make_list(hp);
while (n-- > 0) {
hp[0] = make_small(*ep++);
hp[1] = make_list(hp+2);
hp += 2;
}
hp[-1] = NIL;
break;
case FLOAT_EXT:
{
FloatDef ff;
if (sys_chars_to_double((char*)ep, &ff.fd) != 0) {
goto error;
}
ep += 31;
*objp = make_float(hp);
PUT_DOUBLE(ff, hp);
hp += FLOAT_SIZE_OBJECT;
break;
}
case NEW_FLOAT_EXT:
{
FloatDef ff;
#ifndef NO_FPE_SIGNALS
volatile unsigned long *fpexnp = erts_get_current_fp_exception();
#endif
#ifdef WORDS_BIGENDIAN
ff.fw[0] = get_int32(ep);
ep += 4;
ff.fw[1] = get_int32(ep);
ep += 4;
#else
ff.fw[1] = get_int32(ep);
ep += 4;
ff.fw[0] = get_int32(ep);
ep += 4;
#endif
__ERTS_FP_CHECK_INIT(fpexnp);
__ERTS_FP_ERROR_THOROUGH(fpexnp, ff.fd, goto error);
*objp = make_float(hp);
PUT_DOUBLE(ff, hp);
hp += FLOAT_SIZE_OBJECT;
break;
}
case PID_EXT:
*hpp = hp;
ep = dec_pid(edep, hpp, ep, off_heap, objp);
hp = *hpp;
if (ep == NULL) {
goto error;
}
break;
case PORT_EXT:
{
Eterm sysname;
ErlNode *node;
Uint num;
Uint cre;
if ((ep = dec_atom(edep, ep, &sysname)) == NULL) {
goto error;
}
if ((num = get_int32(ep)) > ERTS_MAX_PORT_NUMBER) {
goto error;
}
ep += 4;
if ((cre = get_int8(ep)) >= MAX_CREATION) {
goto error;
}
ep++;
cre = dec_set_creation(sysname,cre);
node = erts_find_or_insert_node(sysname, cre);
if(node == erts_this_node) {
*objp = make_internal_port(num);
}
else {
ExternalThing *etp = (ExternalThing *) hp;
hp += EXTERNAL_THING_HEAD_SIZE + 1;
etp->header = make_external_port_header(1);
etp->next = off_heap->externals;
etp->node = node;
etp->data.ui[0] = num;
off_heap->externals = etp;
*objp = make_external_port(etp);
}
break;
}
case REFERENCE_EXT:
{
Eterm sysname;
ErlNode *node;
int i;
Uint cre;
Uint32 *ref_num;
Uint32 r0;
Uint ref_words;
ref_words = 1;
if ((ep = dec_atom(edep, ep, &sysname)) == NULL)
goto error;
if ((r0 = get_int32(ep)) >= MAX_REFERENCE )
goto error;
ep += 4;
if ((cre = get_int8(ep)) >= MAX_CREATION)
goto error;
ep += 1;
goto ref_ext_common;
case NEW_REFERENCE_EXT:
ref_words = get_int16(ep);
ep += 2;
if (ref_words > ERTS_MAX_REF_NUMBERS)
goto error;
if ((ep = dec_atom(edep, ep, &sysname)) == NULL)
goto error;
if ((cre = get_int8(ep)) >= MAX_CREATION)
goto error;
ep += 1;
r0 = get_int32(ep);
ep += 4;
if (r0 >= MAX_REFERENCE)
goto error;
ref_ext_common:
cre = dec_set_creation(sysname, cre);
node = erts_find_or_insert_node(sysname, cre);
if(node == erts_this_node) {
RefThing *rtp = (RefThing *) hp;
ref_num = (Uint32 *) (hp + REF_THING_HEAD_SIZE);
#if defined(ARCH_64) && !HALFWORD_HEAP
hp += REF_THING_HEAD_SIZE + ref_words/2 + 1;
rtp->header = make_ref_thing_header(ref_words/2 + 1);
#else
hp += REF_THING_HEAD_SIZE + ref_words;
rtp->header = make_ref_thing_header(ref_words);
#endif
*objp = make_internal_ref(rtp);
}
else {
ExternalThing *etp = (ExternalThing *) hp;
#if defined(ARCH_64) && !HALFWORD_HEAP
hp += EXTERNAL_THING_HEAD_SIZE + ref_words/2 + 1;
#else
hp += EXTERNAL_THING_HEAD_SIZE + ref_words;
#endif
#if defined(ARCH_64) && !HALFWORD_HEAP
etp->header = make_external_ref_header(ref_words/2 + 1);
#else
etp->header = make_external_ref_header(ref_words);
#endif
etp->next = off_heap->externals;
etp->node = node;
off_heap->externals = etp;
*objp = make_external_ref(etp);
ref_num = &(etp->data.ui32[0]);
}
#if defined(ARCH_64) && !HALFWORD_HEAP
*(ref_num++) = ref_words /* 32-bit arity */;
#endif
ref_num[0] = r0;
for(i = 1; i < ref_words; i++) {
ref_num[i] = get_int32(ep);
ep += 4;
}
#if defined(ARCH_64) && !HALFWORD_HEAP
if ((1 + ref_words) % 2)
ref_num[ref_words] = 0;
#endif
break;
}
case BINARY_EXT:
{
n = get_int32(ep);
ep += 4;
if (n <= ERL_ONHEAP_BIN_LIMIT || off_heap == NULL) {
ErlHeapBin* hb = (ErlHeapBin *) hp;
hb->thing_word = header_heap_bin(n);
hb->size = n;
hp += heap_bin_size(n);
sys_memcpy(hb->data, ep, n);
*objp = make_binary(hb);
} else {
Binary* dbin = erts_bin_nrml_alloc(n);
ProcBin* pb;
dbin->flags = 0;
dbin->orig_size = n;
erts_refc_init(&dbin->refc, 1);
sys_memcpy(dbin->orig_bytes, ep, n);
pb = (ProcBin *) hp;
hp += PROC_BIN_SIZE;
pb->thing_word = HEADER_PROC_BIN;
pb->size = n;
pb->next = off_heap->mso;
off_heap->mso = pb;
pb->val = dbin;
pb->bytes = (byte*) dbin->orig_bytes;
pb->flags = 0;
*objp = make_binary(pb);
}
ep += n;
break;
}
case BIT_BINARY_EXT:
{
Eterm bin;
ErlSubBin* sb;
Uint bitsize;
n = get_int32(ep);
bitsize = ep[4];
ep += 5;
if (n <= ERL_ONHEAP_BIN_LIMIT || off_heap == NULL) {
ErlHeapBin* hb = (ErlHeapBin *) hp;
hb->thing_word = header_heap_bin(n);
hb->size = n;
sys_memcpy(hb->data, ep, n);
bin = make_binary(hb);
hp += heap_bin_size(n);
} else {
Binary* dbin = erts_bin_nrml_alloc(n);
ProcBin* pb;
dbin->flags = 0;
dbin->orig_size = n;
erts_refc_init(&dbin->refc, 1);
sys_memcpy(dbin->orig_bytes, ep, n);
pb = (ProcBin *) hp;
pb->thing_word = HEADER_PROC_BIN;
pb->size = n;
pb->next = off_heap->mso;
off_heap->mso = pb;
pb->val = dbin;
pb->bytes = (byte*) dbin->orig_bytes;
pb->flags = 0;
bin = make_binary(pb);
hp += PROC_BIN_SIZE;
}
ep += n;
if (bitsize == 0) {
*objp = bin;
} else {
sb = (ErlSubBin *) hp;
sb->thing_word = HEADER_SUB_BIN;
sb->orig = bin;
sb->size = n - 1;
sb->bitsize = bitsize;
sb->bitoffs = 0;
sb->offs = 0;
sb->is_writable = 0;
*objp = make_binary(sb);
hp += ERL_SUB_BIN_SIZE;
}
break;
}
case EXPORT_EXT:
{
Eterm mod;
Eterm name;
Eterm temp;
Sint arity;
if ((ep = dec_atom(edep, ep, &mod)) == NULL) {
goto error;
}
if ((ep = dec_atom(edep, ep, &name)) == NULL) {
goto error;
}
*hpp = hp;
ep = dec_term(edep, hpp, ep, off_heap, &temp);
hp = *hpp;
if (ep == NULL) {
goto error;
}
if (!is_small(temp)) {
goto error;
}
arity = signed_val(temp);
if (arity < 0) {
goto error;
}
if (edep && (edep->flags & ERTS_DIST_EXT_BTT_SAFE)) {
if (!erts_find_export_entry(mod, name, arity))
goto error;
}
*objp = make_export(hp);
*hp++ = HEADER_EXPORT;
#if HALFWORD_HEAP
*((UWord *) (UWord) hp) = (UWord) erts_export_get_or_make_stub(mod, name, arity);
hp += 2;
#else
*hp++ = (Eterm) erts_export_get_or_make_stub(mod, name, arity);
#endif
break;
}
break;
case NEW_FUN_EXT:
{
ErlFunThing* funp = (ErlFunThing *) hp;
Uint arity;
Eterm module;
byte* uniq;
int index;
Sint old_uniq;
Sint old_index;
unsigned num_free;
int i;
Eterm temp;
ep += 4; /* Skip total size in bytes */
arity = *ep++;
uniq = ep;
ep += 16;
index = get_int32(ep);
ep += 4;
num_free = get_int32(ep);
ep += 4;
hp += ERL_FUN_SIZE;
hp += num_free;
funp->thing_word = HEADER_FUN;
funp->num_free = num_free;
*objp = make_fun(funp);
/* Module */
if ((ep = dec_atom(edep, ep, &module)) == NULL) {
goto error;
}
*hpp = hp;
/* Index */
if ((ep = dec_term(edep, hpp, ep, off_heap, &temp)) == NULL) {
goto error;
}
if (!is_small(temp)) {
goto error;
}
old_index = unsigned_val(temp);
/* Uniq */
if ((ep = dec_term(edep, hpp, ep, off_heap, &temp)) == NULL) {
goto error;
}
if (!is_small(temp)) {
goto error;
}
old_uniq = unsigned_val(temp);
#ifndef HYBRID /* FIND ME! */
/*
* It is safe to link the fun into the fun list only when
* no more validity tests can fail.
*/
funp->next = off_heap->funs;
off_heap->funs = funp;
#endif
funp->fe = erts_put_fun_entry2(module, old_uniq, old_index,
uniq, index, arity);
funp->arity = arity;
#ifdef HIPE
if (funp->fe->native_address == NULL) {
hipe_set_closure_stub(funp->fe, num_free);
}
funp->native_address = funp->fe->native_address;
#endif
hp = *hpp;
/* Environment */
for (i = num_free-1; i >= 0; i--) {
funp->env[i] = (Eterm) COMPRESS_POINTER(next);
next = funp->env + i;
}
/* Creator */
funp->creator = (Eterm) COMPRESS_POINTER(next);
next = &(funp->creator);
break;
}
case FUN_EXT:
{
ErlFunThing* funp = (ErlFunThing *) hp;
Eterm module;
Sint old_uniq;
Sint old_index;
unsigned num_free;
int i;
Eterm temp;
num_free = get_int32(ep);
ep += 4;
hp += ERL_FUN_SIZE;
hp += num_free;
*hpp = hp;
funp->thing_word = HEADER_FUN;
funp->num_free = num_free;
*objp = make_fun(funp);
/* Creator pid */
if (*ep != PID_EXT
|| (ep = dec_pid(edep, hpp, ++ep, off_heap,
&funp->creator))==NULL) {
goto error;
}
/* Module */
if ((ep = dec_atom(edep, ep, &module)) == NULL) {
goto error;
}
/* Index */
if ((ep = dec_term(edep, hpp, ep, off_heap, &temp)) == NULL) {
goto error;
}
if (!is_small(temp)) {
goto error;
}
old_index = unsigned_val(temp);
/* Uniq */
if ((ep = dec_term(edep, hpp, ep, off_heap, &temp)) == NULL) {
goto error;
}
if (!is_small(temp)) {
goto error;
}
#ifndef HYBRID /* FIND ME! */
/*
* It is safe to link the fun into the fun list only when
* no more validity tests can fail.
*/
funp->next = off_heap->funs;
off_heap->funs = funp;
#endif
old_uniq = unsigned_val(temp);
funp->fe = erts_put_fun_entry(module, old_uniq, old_index);
funp->arity = funp->fe->address[-1] - num_free;
#ifdef HIPE
funp->native_address = funp->fe->native_address;
#endif
hp = *hpp;
/* Environment */
for (i = num_free-1; i >= 0; i--) {
funp->env[i] = (Eterm) COMPRESS_POINTER(next);
next = funp->env + i;
}
break;
}
default:
error:
/* UNDO:
* Must unlink all off-heap objects that may have been
* linked into the process.
*/
if (hp < *hpp) { /* Sometimes we used hp and sometimes *hpp */
hp = *hpp; /* the largest must be the freshest */
}
undo_offheap_in_area(off_heap, hp_saved, hp);
*hpp = hp_saved;
return NULL;
}
}
*hpp = hp;
return ep;
}
/* returns the number of bytes needed to encode an object
to a sequence of bytes
N.B. That this must agree with to_external2() above!!!
(except for cached atoms) */
static Uint
encode_size_struct2(ErtsAtomCacheMap *acmp, Eterm obj, unsigned dflags)
{
DECLARE_WSTACK(s);
Uint m, i, arity;
Uint result = 0;
#if HALFWORD_HEAP
UWord wobj = 0;
#endif
goto L_jump_start;
outer_loop:
while (!WSTACK_ISEMPTY(s)) {
#if HALFWORD_HEAP
obj = (Eterm) (wobj = WSTACK_POP(s));
#else
obj = WSTACK_POP(s);
#endif
handle_popped_obj:
if (is_CP(obj)) { /* Does not look for CP, looks for "no tag" */
#if HALFWORD_HEAP
Eterm* ptr = (Eterm *) wobj;
#else
Eterm* ptr = (Eterm *) obj;
#endif
/*
* Pointer into a tuple.
*/
obj = *ptr--;
if (!is_header(obj)) {
WSTACK_PUSH(s, (UWord)ptr);
} else {
/* Reached tuple header */
ASSERT(header_is_arityval(obj));
goto outer_loop;
}
} else if (is_list(obj)) {
Eterm* cons = list_val(obj);
Eterm tl;
tl = CDR(cons);
obj = CAR(cons);
WSTACK_PUSH(s, tl);
} else if (is_nil(obj)) {
result++;
goto outer_loop;
} else {
/*
* Other term (in the tail of a non-proper list or
* in a fun's environment).
*/
}
L_jump_start:
switch (tag_val_def(obj)) {
case NIL_DEF:
result++;
break;
case ATOM_DEF: {
int alen = atom_tab(atom_val(obj))->len;
if ((MAX_ATOM_LENGTH <= 255 || alen <= 255)
&& (dflags & DFLAG_SMALL_ATOM_TAGS)) {
/* Make sure a SMALL_ATOM_EXT fits: SMALL_ATOM_EXT l t1 t2... */
result += 1 + 1 + alen;
}
else {
/* Make sure an ATOM_EXT fits: ATOM_EXT l1 l0 t1 t2... */
result += 1 + 2 + alen;
}
insert_acache_map(acmp, obj);
break;
}
case SMALL_DEF:
{
Sint val = signed_val(obj);
if ((Uint)val < 256)
result += 1 + 1; /* SMALL_INTEGER_EXT */
else if (sizeof(Sint) == 4 || IS_SSMALL28(val))
result += 1 + 4; /* INTEGER_EXT */
else {
DeclareTmpHeapNoproc(tmp_big,2);
UseTmpHeapNoproc(2);
i = big_bytes(small_to_big(val, tmp_big));
result += 1 + 1 + 1 + i; /* SMALL_BIG_EXT */
UnUseTmpHeapNoproc(2);
}
}
break;
case BIG_DEF:
if ((i = big_bytes(obj)) < 256)
result += 1 + 1 + 1 + i; /* tag,size,sign,digits */
else
result += 1 + 4 + 1 + i; /* tag,size,sign,digits */
break;
case PID_DEF:
case EXTERNAL_PID_DEF:
result += (1 + encode_size_struct2(acmp, pid_node_name(obj), dflags) +
4 + 4 + 1);
break;
case REF_DEF:
case EXTERNAL_REF_DEF:
ASSERT(dflags & DFLAG_EXTENDED_REFERENCES);
i = ref_no_of_numbers(obj);
result += (1 + 2 + encode_size_struct2(acmp, ref_node_name(obj), dflags) +
1 + 4*i);
break;
case PORT_DEF:
case EXTERNAL_PORT_DEF:
result += (1 + encode_size_struct2(acmp, port_node_name(obj), dflags) +
4 + 1);
break;
case LIST_DEF:
if ((m = is_string(obj)) && (m < MAX_STRING_LEN)) {
result += m + 2 + 1;
} else {
result += 5;
goto handle_popped_obj;
}
break;
case TUPLE_DEF:
{
Eterm* ptr = tuple_val(obj);
arity = arityval(*ptr);
if (arity <= 0xff) {
result += 1 + 1;
} else {
result += 1 + 4;
}
ptr += arity;
#if HALFWORD_HEAP
obj = (Eterm) (wobj = (UWord) ptr);
#else
obj = (Eterm) ptr;
#endif
goto handle_popped_obj;
}
break;
case FLOAT_DEF:
if (dflags & DFLAG_NEW_FLOATS) {
result += 9;
} else {
result += 32; /* Yes, including the tag */
}
break;
case BINARY_DEF:
result += 1 + 4 + binary_size(obj) +
5; /* For unaligned binary */
break;
case FUN_DEF:
{
ErlFunThing* funp = (ErlFunThing *) fun_val(obj);
if ((dflags & DFLAG_NEW_FUN_TAGS) != 0) {
result += 20+1+1+4; /* New ID + Tag */
result += 4; /* Length field (number of free variables */
result += encode_size_struct2(acmp, funp->creator, dflags);
result += encode_size_struct2(acmp, funp->fe->module, dflags);
result += 2 * (1+4); /* Index, Uniq */
} else {
/*
* Size when fun is mapped to a tuple.
*/
result += 1 + 1; /* Tuple tag, arity */
result += 1 + 1 + 2 +
atom_tab(atom_val(am_fun))->len; /* 'fun' */
result += 1 + 1 + 2 +
atom_tab(atom_val(funp->fe->module))->len; /* Module name */
result += 2 * (1 + 4); /* Index + Uniq */
result += 1 + (funp->num_free < 0x100 ? 1 : 4);
}
for (i = 1; i < funp->num_free; i++) {
obj = funp->env[i];
if (is_not_list(obj)) {
/* Push any non-list terms on the stack */
WSTACK_PUSH(s, obj);
} else {
/* Lists must be handled specially. */
if ((m = is_string(obj)) && (m < MAX_STRING_LEN)) {
result += m + 2 + 1;
} else {
result += 5;
WSTACK_PUSH(s, obj);
}
}
}
if (funp->num_free != 0) {
obj = funp->env[0];
goto L_jump_start;
}
break;
}
case EXPORT_DEF:
{
Export* ep = *((Export **) (export_val(obj) + 1));
#if HALFWORD_HEAP
result += 2;
#else
result += 1;
#endif
result += encode_size_struct2(acmp, ep->code[0], dflags);
result += encode_size_struct2(acmp, ep->code[1], dflags);
result += encode_size_struct2(acmp, make_small(ep->code[2]), dflags);
}
break;
default:
erl_exit(1,"Internal data structure error (in encode_size_struct2)%x\n",
obj);
}
}
DESTROY_WSTACK(s);
return result;
}
static Sint
decoded_size(byte *ep, byte* endp, int no_refc_bins)
{
int heap_size = 0;
int terms;
int atom_extra_skip = 0;
Uint n;
#define SKIP(sz) \
do { \
if ((sz) <= endp-ep) { \
ep += (sz); \
} else { return -1; }; \
} while (0)
#define SKIP2(sz1, sz2) \
do { \
Uint sz = (sz1) + (sz2); \
if (sz1 < sz && (sz) <= endp-ep) { \
ep += (sz); \
} else { return -1; } \
} while (0)
#define CHKSIZE(sz) \
do { \
if ((sz) > endp-ep) { return -1; } \
} while (0)
#define ADDTERMS(n) \
do { \
int before = terms; \
terms += (n); \
if (terms < before) return -1; \
} while (0)
for (terms=1; terms > 0; terms--) {
int tag;
CHKSIZE(1);
tag = ep++[0];
switch (tag) {
case INTEGER_EXT:
SKIP(4);
heap_size += BIG_UINT_HEAP_SIZE;
break;
case SMALL_INTEGER_EXT:
SKIP(1);
break;
case SMALL_BIG_EXT:
CHKSIZE(1);
n = ep[0]; /* number of bytes */
SKIP2(n, 1+1); /* skip size,sign,digits */
heap_size += 1+(n+sizeof(Eterm)-1)/sizeof(Eterm); /* XXX: 1 too much? */
break;
case LARGE_BIG_EXT:
CHKSIZE(4);
n = get_int32(ep);
SKIP2(n,4+1); /* skip, size,sign,digits */
heap_size += 1+1+(n+sizeof(Eterm)-1)/sizeof(Eterm); /* XXX: 1 too much? */
break;
case ATOM_EXT:
CHKSIZE(2);
n = get_int16(ep);
if (n > MAX_ATOM_LENGTH) {
return -1;
}
SKIP(n+2+atom_extra_skip);
atom_extra_skip = 0;
break;
case SMALL_ATOM_EXT:
CHKSIZE(1);
n = get_int8(ep);
if (n > MAX_ATOM_LENGTH) {
return -1;
}
SKIP(n+1+atom_extra_skip);
atom_extra_skip = 0;
break;
case ATOM_CACHE_REF:
SKIP(1+atom_extra_skip);
atom_extra_skip = 0;
break;
case PID_EXT:
atom_extra_skip = 9;
/* In case it is an external pid */
heap_size += EXTERNAL_THING_HEAD_SIZE + 1;
terms++;
break;
case PORT_EXT:
atom_extra_skip = 5;
/* In case it is an external port */
heap_size += EXTERNAL_THING_HEAD_SIZE + 1;
terms++;
break;
case NEW_REFERENCE_EXT:
{
int id_words;
CHKSIZE(2);
id_words = get_int16(ep);
if (id_words > ERTS_MAX_REF_NUMBERS)
return -1;
ep += 2;
atom_extra_skip = 1 + 4*id_words;
/* In case it is an external ref */
#if defined(ARCH_64) && !HALFWORD_HEAP
heap_size += EXTERNAL_THING_HEAD_SIZE + id_words/2 + 1;
#else
heap_size += EXTERNAL_THING_HEAD_SIZE + id_words;
#endif
terms++;
break;
}
case REFERENCE_EXT:
/* In case it is an external ref */
heap_size += EXTERNAL_THING_HEAD_SIZE + 1;
atom_extra_skip = 5;
terms++;
break;
case NIL_EXT:
break;
case LIST_EXT:
CHKSIZE(4);
n = get_int32(ep);
ep += 4;
ADDTERMS(n);
terms++;
heap_size += 2 * n;
break;
case SMALL_TUPLE_EXT:
CHKSIZE(1);
n = *ep++;
terms += n;
heap_size += n + 1;
break;
case LARGE_TUPLE_EXT:
CHKSIZE(4);
n = get_int32(ep);
ep += 4;
ADDTERMS(n);
heap_size += n + 1;
break;
case STRING_EXT:
CHKSIZE(2);
n = get_int16(ep);
SKIP(n+2);
heap_size += 2 * n;
break;
case FLOAT_EXT:
SKIP(31);
heap_size += FLOAT_SIZE_OBJECT;
break;
case NEW_FLOAT_EXT:
SKIP(8);
heap_size += FLOAT_SIZE_OBJECT;
break;
case BINARY_EXT:
CHKSIZE(4);
n = get_int32(ep);
SKIP2(n, 4);
if (n <= ERL_ONHEAP_BIN_LIMIT || no_refc_bins) {
heap_size += heap_bin_size(n);
} else {
heap_size += PROC_BIN_SIZE;
}
break;
case BIT_BINARY_EXT:
{
CHKSIZE(5);
n = get_int32(ep);
SKIP2(n, 5);
if (n <= ERL_ONHEAP_BIN_LIMIT || no_refc_bins) {
heap_size += heap_bin_size(n) + ERL_SUB_BIN_SIZE;
} else {
heap_size += PROC_BIN_SIZE + ERL_SUB_BIN_SIZE;
}
}
break;
case EXPORT_EXT:
terms += 3;
#if HALFWORD_HEAP
heap_size += 3;
#else
heap_size += 2;
#endif
break;
case NEW_FUN_EXT:
{
unsigned num_free;
Uint total_size;
CHKSIZE(1+16+4+4);
total_size = get_int32(ep);
CHKSIZE(total_size);
ep += 1+16+4+4;
/*FALLTHROUGH*/
case FUN_EXT:
CHKSIZE(4);
num_free = get_int32(ep);
ep += 4;
if (num_free > MAX_ARG) {
return -1;
}
terms += 4 + num_free;
heap_size += ERL_FUN_SIZE + num_free;
break;
}
default:
return -1;
}
}
/* 'terms' may be non-zero if it has wrapped around */
return terms==0 ? heap_size : -1;
#undef SKIP
#undef SKIP2
#undef CHKSIZE
}