urbit/noun/vortex.c
Joe Bryan 2ed422e11f boots with lifecycle formula, without persistent kernel formula
removes now-unused vortex functions
2018-12-04 02:54:06 -05:00

493 lines
8.6 KiB
C

/* g/v.c
**
*/
#include <stdio.h>
#include "all.h"
#define _CVX_WISH 4
#define _CVX_POKE 10
#define _CVX_PEEK 47
int WISH;
/* _cv_nock_wish(): call wish through hardcoded interface.
*/
static u3_noun
_cv_nock_wish(u3_noun txt)
{
u3_noun fun, pro;
WISH = 1;
fun = u3n_nock_on(u3k(u3A->roc), u3k(u3x_at(_CVX_WISH, u3A->roc)));
pro = u3n_slam_on(fun, txt);
WISH = 0;
return pro;
}
/* u3v_boot(): evaluate boot sequence, making a kernel
*/
void
u3v_boot(u3_noun eve)
{
// ensure zero-initialized kernel
//
// So that u3t_slog won't try to print tanks.
//
u3A->roc = 0;
// lifecycle formula
//
u3_noun lyf = u3nt(2, u3nc(0, 3), u3nc(0, 2));
u3_noun cor = u3n_nock_on(eve, lyf);
// save the Arvo core (at +7 of the Arvo gate)
//
u3A->roc = u3k(u3x_at(7, cor));
u3z(cor);
}
/* u3v_hose(): clear initial ovum queue.
*/
void
u3v_hose(void)
{
u3p(u3v_cart) egg_p = u3A->ova.egg_p;
while ( egg_p ) {
u3v_cart* egg_u = u3to(u3v_cart, egg_p);
u3p(u3v_cart) nex_p = egg_u->nex_p;
u3a_lose(egg_u->vir);
u3a_free(egg_u);
egg_p = nex_p;
}
u3A->ova.egg_p = u3A->ova.geg_p = 0;
u3z(u3A->roe);
u3A->roe = u3_nul;
}
/* u3v_start(): start time.
*/
void
u3v_start(u3_noun now)
{
u3v_time(now);
u3v_numb();
u3A->sac = u3_nul;
{
c3_c* wen_c = u3r_string(u3A->wen);
printf("arvo: time: %s\n", wen_c);
free(wen_c);
}
}
/* u3v_wish(): text expression with cache.
*/
u3_noun
u3v_wish(const c3_c* str_c)
{
u3_noun txt = u3i_string(str_c);
u3_weak exp = u3kdb_get(u3k(u3A->yot), u3k(txt));
if ( u3_none == exp ) {
exp = _cv_nock_wish(u3k(txt));
// It's probably not a good idea to use u3v_wish()
// outside the top level... (as the result is uncached)
//
if ( u3R == &u3H->rod_u ) {
u3A->yot = u3kdb_put(u3A->yot, u3k(txt), u3k(exp));
}
}
u3z(txt);
return exp;
}
/* _cv_mung(): formula wrapper with gate and sample.
*/
static u3_noun
_cv_mung_in(u3_noun gam)
{
u3_noun pro = u3n_slam_on(u3k(u3h(gam)), u3k(u3t(gam)));
u3z(gam); return pro;
}
static u3_noun
_cv_mung(c3_w sec_w, u3_noun gat, u3_noun sam)
{
u3_noun gam = u3nc(gat, sam);
return u3m_soft(0, _cv_mung_in, gam);
}
/* u3v_pike(): poke with floating core.
*/
u3_noun
u3v_pike(u3_noun ovo, u3_noun cor)
{
u3_noun fun = u3n_nock_on(cor, u3k(u3x_at(_CVX_POKE, cor)));
u3_noun sam = u3nc(u3k(u3A->now), ovo);
return _cv_mung(0, fun, sam);
}
/* u3v_nick(): transform enveloped packets, [vir cor].
*/
u3_noun
u3v_nick(u3_noun vir, u3_noun cor)
{
if ( u3_nul == vir ) {
return u3nt(u3_blip, vir, cor);
}
else {
u3_noun i_vir = u3h(vir);
u3_noun pi_vir, qi_vir;
u3_noun vix;
if ( (c3y == u3r_cell((i_vir=u3h(vir)), &pi_vir, &qi_vir)) &&
(c3y == u3du(qi_vir)) &&
(c3__hear == u3h(qi_vir)) )
{
u3_noun gon;
gon = u3v_pike(u3k(i_vir), cor);
if ( u3_blip != u3h(gon) ) {
u3z(vir);
return gon;
}
else {
u3_noun viz;
vix = u3k(u3h(u3t(gon)));
cor = u3k(u3t(u3t(gon)));
u3z(gon);
viz = u3kb_weld(vix, u3k(u3t(vir)));
u3z(vir);
return u3v_nick(viz, cor);
}
}
else {
u3_noun nez = u3v_nick(u3k(u3t(vir)), cor);
if ( u3_blip != u3h(nez) ) {
u3z(vir);
return nez;
} else {
u3_noun viz;
viz = u3nc(u3k(i_vir), u3k(u3h(u3t(nez))));
cor = u3k(u3t(u3t(nez)));
u3z(vir);
u3z(nez);
return u3nt(u3_blip, viz, cor);
}
}
}
}
/* _cv_nock_poke(): call poke through hardcoded interface.
*/
static u3_noun
_cv_nock_poke(u3_noun ovo)
{
u3_noun fun = u3n_nock_on(u3k(u3A->roc), u3k(u3x_at(_CVX_POKE, u3A->roc)));
u3_noun sam, pro;
u3_noun cod_w;
sam = u3nc(u3k(u3A->now), ovo);
#if 0
{
c3_c* ovi_c = u3r_string(u3h(u3t(ovo)));
u3_noun tox = u3do("spat", u3k(u3h(ovo)));
c3_c* tox_c = u3r_string(tox);
printf("poke: %%%s (%x) on %s\r\n", ovi_c, u3r_mug(ovo), tox_c);
free(tox_c); free(ovi_c); u3z(tox);
}
#endif
cod_w = u3a_lush(u3h(u3t(ovo)));
pro = u3n_slam_on(fun, sam);
u3a_lop(cod_w);
#if 0
{
c3_c* ovi_c = u3r_string(u3h(u3t(ovo)));
printf("poked: %s\r\n", ovi_c);
free(ovi_c);
}
#endif
return pro;
}
/* _cv_nock_peek(): call peek through hardcoded interface.
*/
static u3_noun
_cv_nock_peek(u3_noun hap)
{
u3_noun fun = u3n_nock_on(u3k(u3A->roc), u3k(u3x_at(_CVX_PEEK, u3A->roc)));
u3_noun sam = u3nc(u3k(u3A->now), hap);
return u3n_slam_on(fun, sam);
}
/* u3v_do(): use a kernel gate.
*/
u3_noun
u3v_do(const c3_c* txt_c, u3_noun sam)
{
u3_noun gat = u3v_wish(txt_c);
u3_noun pro;
#if 0
if ( &u3H->rod_u == u3R ) {
pro = u3m_soft_slam(gat, sam);
}
else {
pro = u3n_slam_on(gat, sam);
}
#else
pro = u3n_slam_on(gat, sam);
#endif
return pro;
}
/* _cv_scot(): print atom.
*/
static u3_noun
_cv_scot(u3_noun dim)
{
return u3do("scot", dim);
}
/* u3v_time(): set the reck time.
*/
void
u3v_time(u3_noun now)
{
u3z(u3A->now);
u3A->now = now;
u3z(u3A->wen);
u3A->wen = _cv_scot(u3nc(c3__da, u3k(u3A->now)));
}
/* u3v_numb(): set the instance number.
*/
void
u3v_numb()
{
u3A->sev_l = u3r_mug(u3A->now);
u3z(u3A->sen);
u3A->sen = _cv_scot(u3nc(c3__uv, u3A->sev_l));
}
#if 0
/* _cv_time_bump(): advance the reck time by a small increment.
*/
static void
_cv_time_bump(u3_reck* rec_u)
{
c3_d bum_d = (1ULL << 48ULL);
u3A->now = u3ka_add(u3A->now, u3i_chubs(1, &bum_d));
}
#endif
/* u3v_peek(): query the reck namespace (protected).
*/
u3_noun
u3v_peek(u3_noun hap)
{
return u3m_soft_sure(_cv_nock_peek, hap);
}
#if 0
/* _cv_mole(): parse simple atomic mole.
*/
static c3_o
_cv_mole(u3_noun fot,
u3_noun san,
c3_d* ato_d)
{
u3_noun uco = u3do("slay", san);
u3_noun p_uco, q_uco, r_uco, s_uco;
if ( (c3n == u3r_qual(uco, &p_uco, &q_uco, &r_uco, &s_uco)) ||
(0 != p_uco) ||
(0 != q_uco) ||
(c3n == u3_sing(fot, r_uco)) )
{
uL(fprintf(uH, "strange mole %s\n", u3r_string(san)));
u3z(fot); u3z(uco); return c3n;
}
else {
*ato_d = u3r_chub(0, s_uco);
u3z(fot); u3z(uco); return c3y;
}
}
/* _cv_lily(): parse little atom.
*/
static c3_o
_cv_lily(u3_noun fot, u3_noun txt, c3_l* tid_l)
{
c3_d ato_d;
if ( c3n == _cv_mole(fot, txt, &ato_d) ) {
return c3n;
} else {
if ( ato_d >= 0x80000000ULL ) {
return c3n;
} else {
*tid_l = (c3_l) ato_d;
return c3y;
}
}
}
#endif
/* u3v_poke(): insert and apply an input ovum (protected).
*/
u3_noun
u3v_poke(u3_noun ovo)
{
return _cv_nock_poke(ovo);
}
/* u3v_http_request(): hear http request on channel (unprotected).
*/
void
u3v_http_request(c3_o sec, u3_noun pox, u3_noun req)
{
// uL(fprintf(uH, "http: request\n"));
u3v_plan(pox, u3nq(c3__this, sec, 0, req));
}
/* u3v_tank(): dump single tank.
*/
void
u3v_tank(u3_noun blu, c3_l tab_l, u3_noun tac)
{
u3v_punt(blu, tab_l, u3nc(tac, u3_nul));
}
/* u3v_punt(): dump tank list.
*/
void
u3v_punt(u3_noun blu, c3_l tab_l, u3_noun tac)
{
#if 0
u3_noun blu = u3_term_get_blew(0);
#endif
c3_l col_l = u3h(blu);
u3_noun cat = tac;
// We are calling nock here, but hopefully need no protection.
//
while ( c3y == u3r_du(cat) ) {
u3_noun wol = u3dc("wash", u3nc(tab_l, col_l), u3k(u3h(cat)));
u3m_wall(wol);
cat = u3t(cat);
}
u3z(tac);
u3z(blu);
}
/* u3v_sway(): print trace.
*/
void
u3v_sway(u3_noun blu, c3_l tab_l, u3_noun tax)
{
u3_noun mok = u3dc("mook", 2, tax);
u3v_punt(blu, tab_l, u3k(u3t(mok)));
u3z(mok);
}
/* u3v_plan(): queue ovum (external).
*/
void
u3v_plan(u3_noun pax, u3_noun fav)
{
u3_noun egg = u3nc(pax, fav);
u3A->roe = u3nc(u3nc(u3_nul, egg), u3A->roe);
}
/* u3v_plow(): queue multiple ova (external).
*/
void
u3v_plow(u3_noun ova)
{
u3_noun ovi = ova;
while ( u3_nul != ovi ) {
u3_noun ovo=u3h(ovi);
u3v_plan(u3k(u3h(ovo)), u3k(u3t(ovo)));
ovi = u3t(ovi);
}
u3z(ova);
}
/* _cv_mark_ova(): mark ova queue.
*/
c3_w
_cv_mark_ova(u3p(u3v_cart) egg_p)
{
c3_w tot_w = 0;
while ( egg_p ) {
u3v_cart* egg_u = u3to(u3v_cart, egg_p);
tot_w += u3a_mark_mptr(egg_u);
tot_w += u3a_mark_noun(egg_u->vir);
egg_p = egg_u->nex_p;
}
return tot_w;
}
/* u3v_mark(): mark arvo kernel.
*/
c3_w
u3v_mark(void)
{
c3_w tot_w = 0;
u3v_arvo* arv_u = &(u3H->arv_u);
tot_w += u3a_mark_noun(arv_u->yot);
tot_w += u3a_mark_noun(arv_u->now);
tot_w += u3a_mark_noun(arv_u->wen);
tot_w += u3a_mark_noun(arv_u->sen);
tot_w += u3a_mark_noun(arv_u->own);
tot_w += u3a_mark_noun(arv_u->roe);
tot_w += u3a_mark_noun(arv_u->key);
tot_w += u3a_mark_noun(arv_u->roc);
tot_w += _cv_mark_ova(arv_u->ova.egg_p);
return tot_w;
}