int64_t buzzmsg_deserialize_u16(uint16_t* data,
buzzdarray_t buf,
uint32_t pos) {
if(pos + sizeof(uint16_t) > buzzdarray_size(buf)) return -1;
*data =
buzzdarray_get(buf, pos, uint8_t) +
(buzzdarray_get(buf, pos+1, uint8_t) << 8);
*data = ntohs(*data);
return pos + sizeof(uint16_t);
}
int64_t buzzmsg_deserialize_u32(uint32_t* data,
buzzdarray_t buf,
uint32_t pos) {
if(pos + sizeof(uint32_t) > buzzdarray_size(buf)) return -1;
*data =
buzzdarray_get(buf, pos, uint8_t) +
(buzzdarray_get(buf, pos+1, uint8_t) << 8) +
(buzzdarray_get(buf, pos+2, uint8_t) << 16) +
(buzzdarray_get(buf, pos+3, uint8_t) << 24);
*data = ntohl(*data);
return pos + sizeof(uint32_t);
}
buzzvm_state buzzvm_call(buzzvm_t vm, int isswrm) {
/* Get argument number and pop it */
buzzvm_stack_assert(vm, 1);
buzzvm_type_assert(vm, 1, BUZZTYPE_INT);
int32_t argn = buzzvm_stack_at(vm, 1)->i.value;
buzzvm_pop(vm);
/* Make sure the stack has enough elements */
buzzvm_stack_assert(vm, argn+1);
/* Make sure the closure is where expected */
buzzvm_type_assert(vm, argn+1, BUZZTYPE_CLOSURE);
buzzobj_t c = buzzvm_stack_at(vm, argn+1);
/* Make sure that that data about C closures is correct */
if((!c->c.value.isnative) &&
((c->c.value.ref) >= buzzdarray_size(vm->flist))) {
buzzvm_seterror(vm, BUZZVM_ERROR_FLIST, NULL);
return vm->state;
}
/* Create a new local symbol list copying the parent's */
vm->lsyms =
buzzvm_lsyms_new(isswrm,
buzzdarray_clone(c->c.value.actrec));
buzzdarray_push(vm->lsymts, &(vm->lsyms));
/* Add function arguments to the local symbols */
int32_t i;
for(i = argn; i > 0; --i)
buzzdarray_push(vm->lsyms->syms,
&buzzdarray_get(vm->stack,
buzzdarray_size(vm->stack) - i,
buzzobj_t));
/* Get rid of the function arguments */
for(i = argn+1; i > 0; --i)
buzzdarray_pop(vm->stack);
/* Pop unused self table */
buzzdarray_pop(vm->stack);
/* Push return address */
buzzvm_pushi((vm), vm->pc);
/* Make a new stack for the function */
vm->stack = buzzdarray_new(1, sizeof(buzzobj_t), NULL);
buzzdarray_push(vm->stacks, &(vm->stack));
/* Jump to/execute the function */
if(c->c.value.isnative) {
vm->oldpc = vm->pc;
vm->pc = c->c.value.ref;
}
else buzzdarray_get(vm->flist,
c->c.value.ref,
buzzvm_funp)(vm);
return vm->state;
}
int buzzvm_swarm_id(struct buzzvm_s* vm) {
/* Is the swarm stack empty? */
if(buzzdarray_isempty(vm->swarmstack)) {
/* Yes, no swarm to push, push nil instead */
buzzvm_pushnil(vm);
}
else {
/* Take the stack top by default */
uint16_t stackpos = 1;
/* Do we have an argument? */
if(buzzvm_lnum(vm) > 1) {
buzzvm_lload(vm, 1);
buzzvm_type_assert(vm, 1, BUZZTYPE_INT);
stackpos = buzzvm_stack_at(vm, 1)->i.value;
}
/* Limit stackpos value to avoid out-of-bounds operations */
if(stackpos > buzzdarray_size(vm->swarmstack))
stackpos = buzzdarray_size(vm->swarmstack);
/* Push the swarm id located at stackpos */
buzzvm_pushi(vm,
buzzdarray_get(
vm->swarmstack,
buzzdarray_size(vm->swarmstack) - stackpos,
uint16_t));
}
/* Return the value */
return buzzvm_ret1(vm);
}
int64_t buzzmsg_deserialize_u8(uint8_t* data,
buzzdarray_t buf,
uint32_t pos) {
if(pos + sizeof(uint8_t) > buzzdarray_size(buf)) return -1;
*data = buzzdarray_get(buf, pos, uint8_t);
return pos + sizeof(uint8_t);
}
int buzzneighbors_kin(buzzvm_t vm) {
buzzvm_lnum_assert(vm, 0);
/* Initialize the swarm id to 'unknown' */
int32_t swarmid = -1;
/* If the swarm stack is not empty, look for the swarm id */
if(!buzzdarray_isempty(vm->swarmstack)) {
/* Get position in swarm stack */
uint16_t sstackpos = 1;
if(buzzdarray_size(vm->lsyms->syms) > 1)
sstackpos = buzzdarray_get(vm->lsyms->syms, 1, buzzobj_t)->i.value;
/* Get swarm id */
if(sstackpos <= buzzdarray_size(vm->swarmstack))
swarmid = buzzdarray_get(vm->swarmstack,
buzzdarray_size(vm->swarmstack) - sstackpos,
uint16_t);
}
/* Get the self table */
buzzvm_lload(vm, 0);
buzzvm_type_assert(vm, 1, BUZZTYPE_TABLE);
/* Get the data table */
buzzvm_pushs(vm, buzzvm_string_register(vm, "data", 1));
buzzvm_tget(vm);
buzzobj_t data = buzzvm_stack_at(vm, 1);
/* Create a new table as return value */
buzzobj_t t;
vm->state = make_table(vm, &t);
if(vm->state != BUZZVM_STATE_READY) return vm->state;
/* If data is available, filter it */
if(data->o.type == BUZZTYPE_TABLE) {
/* Create a new data table */
buzzobj_t kindata = buzzheap_newobj(vm->heap, BUZZTYPE_TABLE);
/* Filter the neighbors in data and add them to kindata */
struct neighbor_filter_s fdata = { .vm = vm, .swarm_id = swarmid, .result = kindata->t.value };
buzzdict_foreach(data->t.value, neighbor_filter_kin, &fdata);
/* Add kindata as the "data" field in t */
buzzvm_push(vm, t);
buzzvm_pushs(vm, buzzvm_string_register(vm, "data", 1));
buzzvm_push(vm, kindata);
buzzvm_tput(vm);
}
/* Return the table */
buzzvm_push(vm, t);
return buzzvm_ret1(vm);
}
void buzzvm_dump(buzzvm_t vm) {
int64_t i, j;
fprintf(stderr, "============================================================\n");
fprintf(stderr, "state: %d\terror: %d\n", vm->state, vm->error);
fprintf(stderr, "code size: %u\tpc: %d\n", vm->bcode_size, vm->pc);
fprintf(stderr, "stacks: %" PRId64 "\tcur elem: %" PRId64 " (size %" PRId64 ")\n", buzzdarray_size(vm->stacks), buzzvm_stack_top(vm), buzzvm_stack_top(vm));
for(i = buzzdarray_size(vm->stacks)-1; i >= 0 ; --i) {
fprintf(stderr, "===== stack: %" PRId64 " =====\n", i);
for(j = buzzdarray_size(buzzdarray_get(vm->stacks, i, buzzdarray_t)) - 1; j >= 0; --j) {
fprintf(stderr, "\t%" PRId64 "\t", j);
buzzobj_t o = buzzdarray_get(buzzdarray_get(vm->stacks, i, buzzdarray_t), j, buzzobj_t);
switch(o->o.type) {
case BUZZTYPE_NIL:
fprintf(stderr, "[nil]\n");
break;
case BUZZTYPE_INT:
fprintf(stderr, "[int] %d\n", o->i.value);
break;
case BUZZTYPE_FLOAT:
fprintf(stderr, "[float] %f\n", o->f.value);
break;
case BUZZTYPE_TABLE:
fprintf(stderr, "[table] %d elements\n", buzzdict_size(o->t.value));
break;
case BUZZTYPE_CLOSURE:
if(o->c.value.isnative) {
fprintf(stderr, "[n-closure] %d\n", o->c.value.ref);
}
else {
fprintf(stderr, "[c-closure] %d\n", o->c.value.ref);
}
break;
case BUZZTYPE_STRING:
fprintf(stderr, "[string] %d:'%s'\n", o->s.value.sid, o->s.value.str);
break;
default:
fprintf(stderr, "[TODO] type = %d\n", o->o.type);
}
}
}
fprintf(stderr, "============================================================\n\n");
}
void print_swarm_elem(const void* key, void* data, void* params) {
uint32_t i;
buzzswarm_elem_t e = *(buzzswarm_elem_t*)data;
fprintf(stdout, "ROBOT %u -> R%u:", *(uint16_t*)params, *(uint16_t*)key);
for(i = 0; i < buzzdarray_size(e->swarms); ++i) {
fprintf(stdout,
" %u",
buzzdarray_get(e->swarms, i, uint16_t));
}
fprintf(stdout, "\n");
}
int buzzswarm_members_isrobotin(buzzswarm_members_t m,
uint16_t robot,
uint16_t swarm) {
/* Is an entry for the passed robot present?
* If not, return false */
buzzswarm_elem_t* e = buzzdict_get(m, &robot, buzzswarm_elem_t);
if(!e) return 0;
/* If we get here, an entry is present
* Does it contain the passed swarm id? */
uint32_t i;
for(i = 0; i < buzzdarray_size((*e)->swarms); ++i) {
if(buzzdarray_get((*e)->swarms, i, uint16_t) == swarm) return 1;
}
/* If we get here, it's because we couldn't find the id */
return 0;
}
buzzvm_state buzzvm_pushl(buzzvm_t vm, int32_t addr) {
buzzobj_t o = buzzheap_newobj(vm, BUZZTYPE_CLOSURE);
o->c.value.isnative = 1;
o->c.value.ref = addr;
if(vm->lsyms) {
int i;
for(i = 0; i < buzzdarray_size(vm->lsyms->syms); ++i)
buzzdarray_push(o->c.value.actrec,
&buzzdarray_get(vm->lsyms->syms,
i, buzzobj_t));
}
else {
buzzobj_t nil = buzzheap_newobj(vm, BUZZTYPE_NIL);
buzzdarray_push(o->c.value.actrec,
&nil);
}
return buzzvm_push(vm, o);
}
void buzzswarm_members_leave(buzzswarm_members_t m,
uint16_t robot,
uint16_t swarm) {
/* Is an entry for the passed robot present? */
buzzswarm_elem_t* e = buzzdict_get(m, &robot, buzzswarm_elem_t);
if(e) {
/* Yes, update it */
(*e)->age = 0;
/* Search for the passed id */
uint32_t i;
for(i = 0; i < buzzdarray_size((*e)->swarms); ++i) {
if(buzzdarray_get((*e)->swarms, i, uint16_t) == swarm) break;
}
/* If the element was found, remove it */
if(i < buzzdarray_size((*e)->swarms))
buzzdarray_remove((*e)->swarms, i);
/* If no swarm id is known for this robot, remove the entry altogether */
if(buzzdarray_isempty((*e)->swarms))
buzzdict_remove(m, &robot);
}
/* Nothing to do if you get a 'leave' message for someone you don't know */
}
buzzvm_state buzzvm_tput(buzzvm_t vm) {
buzzvm_stack_assert(vm, 3);
buzzvm_type_assert(vm, 3, BUZZTYPE_TABLE);
buzzobj_t v = buzzvm_stack_at(vm, 1);
buzzobj_t k = buzzvm_stack_at(vm, 2);
buzzobj_t t = buzzvm_stack_at(vm, 3);
buzzvm_pop(vm);
buzzvm_pop(vm);
buzzvm_pop(vm);
if(k->o.type != BUZZTYPE_INT &&
k->o.type != BUZZTYPE_FLOAT &&
k->o.type != BUZZTYPE_STRING) {
buzzvm_seterror(vm, BUZZVM_ERROR_TYPE, "a %s value can't be used as table key", buzztype_desc[k->o.type]);
return vm->state;
}
if(v->o.type == BUZZTYPE_NIL) {
/* Nil, erase entry */
buzzdict_remove(t->t.value, &k);
}
else if(v->o.type == BUZZTYPE_CLOSURE) {
/* Method call */
int i;
buzzobj_t o = buzzheap_newobj(vm, BUZZTYPE_CLOSURE);
o->c.value.isnative = v->c.value.isnative;
o->c.value.ref = v->c.value.ref;
buzzdarray_push(o->c.value.actrec, &t);
for(i = 1; i < buzzdarray_size(v->c.value.actrec); ++i)
buzzdarray_push(o->c.value.actrec,
&buzzdarray_get(v->c.value.actrec,
i, buzzobj_t));
buzzdict_set(t->t.value, &k, &o);
}
else {
buzzdict_set(t->t.value, &k, &v);
}
return BUZZVM_STATE_READY;
}
void buzzswarm_members_join(buzzswarm_members_t m,
uint16_t robot,
uint16_t swarm) {
/* Is an entry for the passed robot already present? */
buzzswarm_elem_t* e = buzzdict_get(m, &robot, buzzswarm_elem_t);
if(e) {
/* Yes, update it */
(*e)->age = 0;
/* Search for the passed id; if found, nothing to do */
uint32_t i;
for(i = 0; i < buzzdarray_size((*e)->swarms); ++i) {
if(buzzdarray_get((*e)->swarms, i, uint16_t) == swarm) return;
}
/* If we get here, it's because we got new information - add it */
buzzdarray_push((*e)->swarms, &swarm);
}
else {
/* No, create it */
buzzswarm_elem_t ne = buzzswarm_elem_new();
buzzdarray_push(ne->swarms, &swarm);
/* Add it to the structure */
buzzdict_set(m, &robot, &ne);
}
}
