strm_state*
strm_ns_create(strm_state* state, strm_string name)
{
strm_state* s = strm_ns_get(name);
if (!s) {
int r;
khiter_t k;
if (!nstbl) {
nstbl = kh_init(ns);
}
k = kh_put(ns, nstbl, (intptr_t)name, &r);
if (r < 0) { /* r<0 operation failed */
return NULL;
}
if (r == 0) { /* r=0 ns already exists */
if (kh_value(nstbl, k))
return NULL;
}
s = malloc(sizeof(strm_state));
if (s) {
*s = szero;
s->prev = state;
}
kh_value(nstbl, k) = s;
}
return s;
}
static int
exec_expr(strm_stream* strm, strm_state* state, node* np, strm_value* val)
{
int n;
if (np == NULL) {
return STRM_NG;
}
switch (np->type) {
/*
case NODE_ARGS:
break;
*/
case NODE_NS:
{
node_ns* ns = (node_ns*)np;
strm_state* s = strm_ns_find(state, node_to_sym(ns->name));
if (!s) {
strm_raise(strm, "failed to create namespace");
return STRM_NG;
}
return exec_expr(strm, s, ns->body, val);
}
case NODE_IMPORT:
{
node_import *ns = (node_import*)np;
strm_state* s = strm_ns_get(node_to_sym(ns->name));
if (!s) {
strm_raise(strm, "no such namespace");
return STRM_NG;
}
n = strm_env_copy(state, s);
if (n) {
strm_raise(strm, "failed to import");
return n;
}
return STRM_OK;
}
break;
case NODE_SKIP:
strm_set_exc(strm, NODE_ERROR_SKIP, strm_nil_value());
return STRM_OK;
case NODE_EMIT:
{
int i, n;
node_array* v0;
v0 = (node_array*)((node_emit*)np)->emit;
if (!v0) {
strm_emit(strm, strm_nil_value(), NULL);
}
else {
for (i = 0; i < v0->len; i++) {
n = exec_expr(strm, state, v0->data[i], val);
if (n) return n;
strm_emit(strm, *val, NULL);
}
}
return STRM_OK;
}
break;
case NODE_LET:
{
node_let *nlet = (node_let*)np;
n = exec_expr(strm, state, nlet->rhs, val);
if (n) {
strm_raise(strm, "failed to assign");
return n;
}
return strm_var_set(state, node_to_sym(nlet->lhs), *val);
}
case NODE_ARRAY:
{
node_array* v0 = (node_array*)np;
strm_array arr = strm_ary_new(NULL, v0->len);
strm_value *ptr = (strm_value*)strm_ary_ptr(arr);
int i=0;
for (i = 0; i < v0->len; i++, ptr++) {
n = exec_expr(strm, state, v0->data[i], ptr);
if (n) return n;
}
if (v0->headers) {
strm_ary_headers(arr) = ary_headers(v0->headers, v0->len);
}
if (v0->ns) {
strm_ary_ns(arr) = strm_ns_get(node_to_sym(v0->ns));
}
else {
strm_ary_ns(arr) = strm_str_null;
}
*val = strm_ary_value(arr);
return STRM_OK;
}
case NODE_IDENT:
{
node_ident* ni = (node_ident*)np;
n = strm_var_get(state, node_to_sym(ni->name), val);
if (n) {
strm_raise(strm, "failed to reference variable");
}
return n;
}
case NODE_IF:
{
strm_value v;
node_if* nif = (node_if*)np;
n = exec_expr(strm, state, nif->cond, &v);
if (n) return n;
if (strm_bool_p(v) && strm_value_bool(v)) {
return exec_expr(strm, state, nif->then, val);
}
else if (nif->opt_else != NULL) {
return exec_expr(strm, state, nif->opt_else, val);
}
else {
*val = strm_nil_value();
return STRM_OK;
}
}
break;
case NODE_OP:
{
node_op* nop = (node_op*)np;
strm_value args[2];
int i=0;
if (nop->lhs) {
n = exec_expr(strm, state, nop->lhs, &args[i++]);
if (n) return n;
}
if (nop->rhs) {
n = exec_expr(strm, state, nop->rhs, &args[i++]);
if (n) return n;
}
return exec_call(strm, state, node_to_sym(nop->op), i, args, val);
}
break;
case NODE_LAMBDA:
{
strm_lambda lambda = malloc(sizeof(struct strm_lambda));
if (!lambda) return STRM_NG;
lambda->type = STRM_PTR_LAMBDA;
lambda->body = (node_lambda*)np;
lambda->state = state;
*val = strm_ptr_value(lambda);
return STRM_OK;
}
break;
case NODE_CALL:
{
/* TODO: wip code of ident */
node_call* ncall = (node_call*)np;
int i;
node_nodes* v0 = (node_nodes*)ncall->args;
strm_value *args = malloc(sizeof(strm_value)*v0->len);
for (i = 0; i < v0->len; i++) {
n = exec_expr(strm, state, v0->data[i], &args[i]);
if (n) return n;
}
return exec_call(strm, state, node_to_sym(ncall->ident), i, args, val);
}
break;
case NODE_RETURN:
{
node_return* nreturn = (node_return*)np;
node_nodes* args = (node_nodes*)nreturn->rv;
strm_value arg;
if (!args) {
arg = strm_nil_value();
}
else {
switch (args->len) {
case 0:
arg = strm_nil_value();
break;
case 1:
n = exec_expr(strm, state, args->data[0], &arg);
if (n) return n;
break;
default:
{
strm_array ary = strm_ary_new(NULL, args->len);
strm_int i;
for (i=0; i<args->len; i++) {
n = exec_expr(strm, state, args->data[i], (strm_value*)&strm_ary_ptr(ary)[i]);
if (n) return n;
}
}
break;
}
}
strm_set_exc(strm, NODE_ERROR_RETURN, arg);
return STRM_OK;
}
break;
case NODE_NODES:
{
int i;
node_nodes* v = (node_nodes*)np;
for (i = 0; i < v->len; i++) {
n = exec_expr(strm, state, v->data[i], val);
if (n) {
if (strm) {
node_error* exc = strm->exc;
if (exc != NULL) {
node* n = v->data[i];
exc->fname = n->fname;
exc->lineno = n->lineno;
}
}
return n;
}
}
}
return STRM_OK;
case NODE_INT:
*val = strm_int_value(((node_int*)np)->value);
return STRM_OK;
case NODE_FLOAT:
*val = strm_int_value(((node_float*)np)->value);
return STRM_OK;
case NODE_BOOL:
*val = strm_bool_value(((node_bool*)np)->value);
return STRM_OK;
case NODE_NIL:
*val = strm_nil_value();
return STRM_OK;
case NODE_STR:
*val = strm_str_value(node_to_str(((node_str*)np)->value));
return STRM_OK;
default:
break;
}
return STRM_NG;
}
