urbit/f/host.c
2013-09-28 13:21:18 -07:00

1084 lines
25 KiB
C

/* f/host.c: driver system.
**
** This file is in the public domain.
*/
#include "all.h"
extern void u2_lo_show(c3_c*, u2_noun);
/** Global structures.
**/
/* Suppress warnings. Set after the first.
*/
c3_t JetSuppress;
/* Hangar stack; top hangar is active.
*/
u2_ho_hangar *u2_HostHangar;
/** Forward declarations.
**/
/* _ho_explore(): find driver from chip, caching.
*/
static u2_ho_driver*
_ho_explore(u2_ray, u2_noun);
/* _cs_free(): free a cache, freeing.
*/
static void
_cs_free(u2_ho_cash *cas_s)
{
c3_w i_w;
for ( i_w = 0; i_w < 16; i_w++ ) {
if ( u2_none == cas_s->dol_p[i_w].tag ) {
if ( 0 == cas_s->dol_p[i_w].ptr_v ) {
_cs_free(cas_s->dol_p[i_w].ptr_v);
free(cas_s->dol_p[i_w].ptr_v);
}
}
}
}
/* _cs_init(): initialize an empty cache.
*/
static void
_cs_init(u2_ho_cash *cas_s)
{
c3_w i_w;
for ( i_w = 0; i_w < 16; i_w++ ) {
cas_s->dol_p[i_w].tag = u2_none;
cas_s->dol_p[i_w].ptr_v = 0;
}
}
/* _ho_cash_find(): find a pointer in a cache, or return 0.
*/
static void*
_ho_cash_find(u2_ho_cash *cas_s,
u2_noun som)
{
c3_w mug_w = u2_mug(som);
c3_w off_w = 0;
while ( 1 ) {
if ( off_w == 32 ) {
c3_w i_w;
for ( i_w = 0; i_w < 16; i_w++ ) {
u2_ho_pear* per_p = &cas_s->dol_p[i_w];
u2_noun tag = per_p->tag;
if ( (u2_none != tag) && (u2_yes == u2_sing(som, tag)) ) {
return per_p->ptr_v;
}
}
return 0;
}
else {
c3_w fat_w = (mug_w >> off_w) & 15;
u2_ho_pear* per_p = &cas_s->dol_p[fat_w];
u2_noun tag = per_p->tag;
if ( u2_none == tag ) {
cas_s = per_p->ptr_v;
if ( 0 == cas_s ) {
return 0;
} else {
off_w += 4;
continue;
}
}
else if ( u2_yes == u2_sing(som, tag) ) {
return per_p->ptr_v;
}
else return 0;
}
}
}
/* _cs_save(): as _ho_cash_save(), with mug and offset.
*/
static void
_cs_save(u2_ho_cash* cas_s,
u2_noun som,
void* ptr_v,
c3_w mug_w,
c3_w off_w)
{
while ( 1 ) {
if ( off_w == 32 ) {
/* Linear search in a list of 16 total collisions.
** Overflow probability: (n/(2^31))^15 ~= 0.
*/
c3_w i_w;
for ( i_w = 0; i_w < 16; i_w++ ) {
u2_ho_pear* per_p = &cas_s->dol_p[i_w];
u2_noun tag = per_p->tag;
if ( u2_none != tag ) {
/* Duplicate entry - no need to save it.
*/
return;
}
else {
per_p->tag = som;
per_p->ptr_v = ptr_v;
}
}
return;
}
else {
c3_w fat_w = (mug_w >> off_w) & 15;
u2_ho_pear* per_p = &cas_s->dol_p[fat_w];
u2_noun tag = per_p->tag;
if ( u2_none == tag ) {
cas_s = per_p->ptr_v;
if ( 0 == cas_s ) {
per_p->tag = som;
per_p->ptr_v = ptr_v;
return;
}
else {
off_w += 4;
continue;
}
}
else {
void* qtr_v = per_p->ptr_v;
u2_ho_cash* cax_s;
if ( 0 == (cax_s = malloc(sizeof(*cax_s))) ) {
return;
}
_cs_init(cax_s);
_cs_save(cax_s, tag, qtr_v, u2_mug(tag), 4+off_w);
_cs_save(cax_s, som, ptr_v, mug_w, 4+off_w);
per_p->tag = u2_none;
per_p->ptr_v = cax_s;
return;
}
}
}
}
/* _ho_cash_save(): save a noun in a cache.
*/
static void
_ho_cash_save(u2_ho_cash *cas_s,
u2_noun som,
void* ptr_v)
{
_cs_save(cas_s, som, ptr_v, u2_mug(som), 0);
}
/* _ho_mop_decimal(): measure/print decimal number.
*/
static c3_w
_ho_mop_decimal(c3_c *buf_c, u2_noun num)
{
if ( u2_no == u2_stud(num) ) {
return 0;
} else {
if ( 0 == num ) {
if ( buf_c ) *buf_c = '0';
return 1;
} else {
mpz_t num_mp;
c3_w len_w;
mpz_init(num_mp);
u2_mp(num_mp, num);
len_w = mpz_sizeinbase(num_mp, 10);
if ( buf_c ) {
gmp_sprintf(buf_c, "%Zu", num_mp);
}
mpz_clear(num_mp);
return len_w;
}
}
}
/* _ho_mop_term(): measure/print term.
*/
static c3_w
_ho_mop_term(c3_c *buf_c, u2_noun tam)
{
if ( u2_no == u2_stud(tam) ) {
return 0;
}
else {
c3_w len_w = u2_met(3, tam);
if ( buf_c ) {
u2_bytes(0, len_w, (c3_y *)buf_c, tam);
{
c3_w i_w;
for ( i_w = 0; i_w < len_w; i_w++ ) {
if ( !((buf_c[i_w] >= 'a') && (buf_c[i_w] <= 'z')) ) {
buf_c[i_w] = '_';
}
}
}
}
return len_w;
}
}
/* _ho_mop_version(): measure/print version.
*/
static c3_w
_ho_mop_version(c3_c *buf_c, u2_noun ver)
{
if ( u2_no == u2_dust(ver) ) {
return _ho_mop_decimal(buf_c, ver);
}
else {
c3_w len_w = _ho_mop_decimal(buf_c, u2_h(ver));
if ( buf_c ) buf_c += len_w;
len_w++;
if ( buf_c ) *buf_c++ = 'x';
return (len_w + _ho_mop_decimal(buf_c, u2_t(ver)));
}
}
/* _ho_mop_seal(): measure/print identity declaration.
*/
static c3_w
_ho_mop_seal(c3_c *buf_c, u2_noun mek)
{
u2_noun std, ven, pro, ver, kel;
c3_w len_w, lan_w, lon_w, lin_w;
if ( u2_yes == u2_as_qual(mek, &ven, &pro, &ver, &kel) ) {
len_w = _ho_mop_term(buf_c, ven);
if ( buf_c ) buf_c += len_w;
len_w++;
if ( buf_c ) *buf_c++ = '_';
lan_w = _ho_mop_term(buf_c, pro);
if ( buf_c ) buf_c += lan_w;
lan_w++;
if ( buf_c ) *buf_c++ = '_';
lon_w = _ho_mop_version(buf_c, ver);
if ( buf_c ) buf_c += lon_w;
lon_w++;
if ( buf_c ) *buf_c++ = '_';
lin_w = _ho_mop_decimal(buf_c, kel);
if ( buf_c ) buf_c += lin_w;
return (len_w + lan_w + lon_w + lin_w);
}
else if ( u2_yes == u2_as_trel(mek, &ven, &pro, &kel) ) {
len_w = _ho_mop_term(buf_c, ven);
if ( buf_c ) buf_c += len_w;
len_w++;
if ( buf_c ) *buf_c++ = '_';
lan_w = _ho_mop_term(buf_c, pro);
if ( buf_c ) buf_c += lan_w;
lan_w++;
if ( buf_c ) *buf_c++ = '_';
lon_w = _ho_mop_decimal(buf_c, kel);
if ( buf_c ) buf_c += lon_w;
lon_w++;
if ( buf_c ) *buf_c++ = '_';
return (len_w + lan_w + lon_w);
}
else if ( u2_yes == u2_as_cell(mek, &std, &kel) ) {
len_w = _ho_mop_term(buf_c, std);
if ( buf_c ) buf_c += len_w;
len_w++;
if ( buf_c ) *buf_c++ = '_';
lan_w = _ho_mop_decimal(buf_c, kel);
if ( buf_c ) buf_c += lan_w;
return (len_w + lan_w);
}
else {
len_w = _ho_mop_term(buf_c, mek);
return len_w;
}
}
/* _ho_mop_chip(): measure/print control string, from chip.
*/
static c3_w
_ho_mop_chip(c3_c *buf_c, u2_noun xip)
{
u2_noun dac = u2_h(xip);
u2_noun pit = u2_t(u2_t(xip));
if ( u2_nul == pit ) {
return _ho_mop_seal(buf_c, u2_h(dac));
}
else {
c3_w len_w = _ho_mop_chip(buf_c, u2_t(pit));
if ( buf_c ) {
buf_c += len_w;
*buf_c++ = '_';
*buf_c++ = '_';
}
return (len_w + 2 + _ho_mop_seal(buf_c, u2_h(dac)));
}
}
/* u2_ho_cstring(): return malloced control string for `xip`.
*/
c3_c* // produce
u2_ho_cstring(u2_noun xip) // retain
{
c3_w len_w = _ho_mop_chip(0, xip);
c3_c *cos_c;
if ( !(cos_c = malloc(len_w + 1)) ) abort();
_ho_mop_chip(cos_c, xip);
cos_c[len_w] = 0;
return cos_c;
}
/* u2_ho_boot():
**
** Boot driver system. Note that all chips and
** tools are considered permanent between reboots.
*/
static void
_ho_boot(u2_ho_hangar *hag)
{
_cs_init(&hag->bad_s);
}
/* _ho_down():
**
** Release all resources in `hag`.
*/
static void
_ho_down(u2_ho_hangar *hag)
{
_cs_free(&hag->bad_s);
}
/* u2_ho_push():
**
** Push a driver hangar (corresponding to a jet shed).
*/
void
u2_ho_push(void)
{
u2_ho_hangar *hag = malloc(sizeof(u2_ho_hangar));
_ho_boot(hag);
hag->nex_h = u2_HostHangar;
u2_HostHangar = hag;
}
/* u2_ho_popp():
**
** Pop a hangar.
*/
void
u2_ho_popp(void)
{
u2_ho_hangar *hag = u2_HostHangar;
u2_ho_hangar *nex_h = hag->nex_h;
_ho_down(hag);
free(hag);
u2_HostHangar = nex_h;
}
/* u2_ho_klar():
**
** Clear and release all hangars.
*/
void
u2_ho_klar(void)
{
while ( u2_HostHangar ) {
u2_ho_popp();
}
}
/* u2_ho_warn(): report a warning, file and line.
*/
void
u2_ho_warn(const c3_c* fil_c,
c3_w lyn_w)
{
if ( !JetSuppress ) {
fprintf(stderr, "ho: warn: %s:%u\n", fil_c, lyn_w);
JetSuppress = 1;
}
}
/* _ho_abstract(): compute 31-bit jet axis in core battery.
*/
static c3_l
_ho_abstract(u2_noun xip, // retain
const c3_c *fcs_c) // retain
{
if ( *fcs_c == '.' ) {
c3_d axe_d = 0;
c3_l axe_l = 0;
sscanf(fcs_c+1, "%llu", &axe_d);
if ( axe_d >> 32ULL ||
((1 << 31) & (axe_l = (c3_w)axe_d)) ||
(axe_l < 2) )
{
u2_ho_warn_here();
return 0;
}
// return u2_ax_mas(axe_l);
return axe_l;
}
else {
u2_noun nut = u2_t(u2_h(xip));
while ( _0 != nut ) {
u2_noun i_nut = u2_h(nut);
if ( (u2_yes == u2_sing_c(fcs_c, u2_h(i_nut))) ) {
u2_noun fal = u2_t(i_nut);
while ( (u2_yes == u2_dust(fal)) && (u2_nock_hint == u2_h(fal)) ) {
fal = u2_t(u2_t(fal));
}
/* `fal` must match `[9 x [0 1]]`
*/
if ( (u2_yes == u2_dust(fal)) && (u2_nock_kick == u2_h(fal)) ) {
u2_noun t_fal = u2_t(fal);
if ( u2_yes == u2_dust(t_fal) ) {
u2_noun ht_fal = u2_h(t_fal);
u2_noun tt_fal = u2_t(t_fal);
if ( (u2_yes == u2_stud(ht_fal)) &&
(u2_yes == u2_dust(tt_fal)) &&
(_0 == u2_h(tt_fal)) &&
(_1 == u2_t(tt_fal)) )
{
u2_atom axe = ht_fal;
if ( !u2_fly_is_cat(axe) ) {
u2_ho_warn_here();
}
// return u2_ax_mas(axe);
return axe;
}
}
}
printf("weird! cos_c %s\n", u2_ho_cstring(xip));
u2_ho_warn_here();
return 0;
}
nut = u2_t(nut);
}
printf("wacky! cos_c %s, fcs_c %s\n", u2_ho_cstring(xip), fcs_c);
u2_ho_warn_here();
return 0;
}
}
/* _ho_attach(): process static driver for execution.
*/
static void
_ho_attach(u2_rail ral_r,
u2_ho_driver* dry_d) // retain
{
u2_ho_jet* jet_j;
c3_w i_w;
_cs_init(&dry_d->jax_s);
if ( dry_d->fan_j ) {
for ( i_w = 0; (jet_j = &dry_d->fan_j[i_w])->fcs_c; i_w++ ) {
jet_j->xip = dry_d->xip;
jet_j->axe_l = _ho_abstract(dry_d->xip, jet_j->fcs_c);
_ho_cash_save(&dry_d->jax_s, jet_j->axe_l, jet_j);
}
}
}
/* _ho_explore_dummy(): produce dummy driver.
*/
static u2_ho_driver* // produce
_ho_explore_dummy(u2_rail ral_r,
const c3_c* cos_c, // submit
u2_noun xip) // senior
{
u2_ho_driver *dry_d;
if ( !(dry_d = malloc(sizeof(u2_ho_driver))) ) {
abort();
}
dry_d->cos_c = cos_c;
dry_d->sub_d = 0;
dry_d->xip = xip;
if ( !(dry_d->fan_j = malloc(sizeof(u2_ho_jet))) ) {
abort();
}
dry_d->fan_j->fcs_c = 0;
return dry_d;
}
/* _ho_explore_static(): find driver from built-in list, or return 0.
*/
static u2_ho_driver*
_ho_explore_static(u2_rail ral_r,
u2_noun xip,
c3_c* cos_c)
{
c3_w i_w;
for ( i_w=0; HostDriverBase[i_w]; i_w++ ) {
u2_ho_driver *dry_d = HostDriverBase[i_w];
if ( (u2_none == dry_d->xip) && !strcmp(cos_c, dry_d->cos_c) ) {
dry_d->xip = xip;
free(cos_c);
_ho_cash_save(&u2_HostHangar->bad_s, xip, dry_d);
return dry_d;
}
}
return 0;
}
/* _ho_explore_parent(): find driver from parent, or return 0.
*/
static u2_ho_driver*
_ho_explore_parent(u2_rail ral_r,
u2_noun xip,
c3_c* cos_c)
{
u2_noun pet = u2_t(u2_t(xip));
if ( _0 == pet ) {
return 0;
} else {
u2_ho_driver* par_d = _ho_explore(ral_r, u2_t(pet));
c3_w i_w;
c3_assert(par_d);
if ( par_d->sub_d ) {
for ( i_w = 0; par_d->sub_d[i_w].cos_c; i_w++ ) {
#if 0
if ( (u2_none == par_d->sub_d[i_w].xip) &&
!strcmp(cos_c, par_d->sub_d[i_w].cos_c) )
#else
if ( !strcmp(cos_c, par_d->sub_d[i_w].cos_c) )
#endif
{
u2_ho_driver *dry_d = &par_d->sub_d[i_w];
if ( u2_none != dry_d->xip ) {
u2z(dry_d->xip);
}
dry_d->xip = xip;
free(cos_c);
_ho_cash_save(&u2_HostHangar->bad_s, xip, dry_d);
return dry_d;
}
}
}
return 0;
}
}
/* _ho_explore(): find driver from chip, caching.
*/
static u2_ho_driver* // discover
_ho_explore(u2_rail ral_r,
u2_noun xip) // senior
{
u2_ho_driver* dry_d;
if ( 0 != (dry_d = _ho_cash_find(&u2_HostHangar->bad_s, xip)) ) {
return dry_d;
} else {
c3_c* cos_c = u2_ho_cstring(xip);
// fprintf(stderr, "ho_explore: cos_c %s\r\n", cos_c);
if ( 0 != (dry_d = _ho_explore_parent(ral_r, xip, cos_c)) ) {
// fprintf(stderr, "battery: child : %s\r\n", cos_c);
_ho_attach(ral_r, dry_d);
return dry_d;
}
else if ( 0 != (dry_d = _ho_explore_static(ral_r, xip, cos_c)) ) {
// fprintf(stderr, "battery: static: %s\r\n", cos_c);
_ho_attach(ral_r, dry_d);
return dry_d;
}
else {
// fprintf(stderr, "battery: dummy : %s\n", cos_c);
dry_d = _ho_explore_dummy(ral_r, cos_c, xip);
_ho_cash_save(&u2_HostHangar->bad_s, xip, dry_d);
return dry_d;
}
}
}
/* u2_ho_prepare(): prepare jets in `xip`.
*/
void
u2_ho_prepare(u2_rail ral_r,
u2_noun xip) // retain
{
_ho_explore(ral_r, xip);
}
/* _ho_conquer(): find jet from xip and axe.
*/
static u2_ho_jet*
_ho_conquer(u2_rail ral_r,
u2_noun xip,
u2_atom axe)
{
u2_ho_driver *dry_d;
if ( 0 == (dry_d = _ho_explore(ral_r, xip)) ) {
return 0;
} else if ( 0 == dry_d->fan_j ) {
return 0;
} else {
if ( 3 == axe ) {
// Linear search - slow, except in this common case.
//
u2_ho_jet *jet_j = dry_d->fan_j;
while ( jet_j->fcs_c ) {
if ( axe == jet_j->axe_l ) {
return jet_j;
}
jet_j++;
}
return 0;
} else {
return _ho_cash_find(&dry_d->jax_s, axe);
}
}
}
#ifdef NOCK6
#define _ho_con u2_cw_con
#define _ho_sam u2_cw_sam
#else
#define _ho_con u2_cv_con
#define _ho_sam u2_cv_sam
#endif
/* u2_ho_test():
**
** Report result of jet test. `had` is native; `sof` is nock.
*/
void
u2_ho_test(u2_wire wir_r,
u2_ho_jet* jet_j,
u2_noun cor, // retain
u2_noun sof, // retain
u2_noun had) // retain
{
if ( (u2_none == cor) ||
((u2_none == had) && (u2_none == sof)) ||
(u2_none == jet_j->xip) )
{
return;
} else {
c3_c* cos_c = u2_ho_cstring(jet_j->xip);
c3_w mug_w = u2_mug(cor);
const c3_c* msg_c;
if ( u2_none == had ) {
msg_c = "bail";
printf("bail: cos_c: %s\r\n", cos_c);
c3_assert(0);
} else if ( u2_none == sof ) {
msg_c = "funk";
printf("funk: cos_c: %s\r\n", cos_c);
c3_assert(0);
} else if ( u2_no == u2_sing(had, sof) ) {
msg_c = "miss";
printf("miss: jet: %s(%s)\r\n", cos_c, jet_j->fcs_c);
u2_lo_show("right", u2k(sof));
u2_lo_show("wrong", u2k(had));
// For detailed debugging, activate/extend this junkheap as needed.
//
c3_assert(0);
#if 0
{
u2_noun gen;
if ( (u2_no == u2_mean(cor, _ho_sam, &gen, 0)) ) {
c3_assert(0);
} else {
u2_err(wir_r, "gen", gen);
}
}
{
u2_noun sut, gen, van;
if ( (u2_no == u2_mean(cor, _ho_con, &van, _ho_sam, &gen, 0)) ||
(u2_none == (sut = u2_frag(_ho_sam, van))) )
{
c3_assert(0);
} else {
u2_err(wir_r, "h_sut", u2_h(sut));
u2_err(wir_r, "gen", gen);
}
}
{
u2_noun sut, ref, van;
if ( (u2_no == u2_mean(cor, _ho_con, &van, _ho_sam, &ref, 0)) ||
(u2_none == (sut = u2_frag(_ho_sam, van))) )
{
c3_assert(0);
} else {
u2_err(wir_r, "sut", sut);
u2_err(wir_r, "ref", ref);
}
}
#endif
// LoomStop = 1;
c3_assert(0);
} else {
msg_c = "nice";
}
if ( strcmp("nice", msg_c) )
{
fprintf(stderr, "%s: %8x: %s\n", msg_c, mug_w, cos_c);
}
free(cos_c);
}
}
/* _ho_run(): execute jet, new simplified style.
*/
static u2_weak // produce
_ho_run(u2_ray wir_r,
u2_ho_jet* jet_j,
u2_noun cor) // retain
{
u2_noun ret;
u2_tx_glu_bit(wir_r, u2_no);
ret = jet_j->fun_f(wir_r, cor);
u2_tx_glu_bit(wir_r, u2_yes);
if ( u2_none == ret ) {
return u2_cm_bail(c3__exit);
}
else return ret;
}
#if 0
/* _ho_run(): execute jet, shedding trace if any is available.
*/
static u2_weak // produce
_ho_run(u2_ray wir_r,
u2_ho_jet* jet_j,
u2_noun cor, // retain
u2_weak *tax) // produce
{
u2_noun ret;
switch ( jet_j->vok_m ) {
default: c3_assert(0); return u2_none;
case c3__lite: {
/* Lite jet: bail prohibited. The lite jet must detect and control
** its own internal errors, freeing stray nouns and returning u2_none
** if and only if nock exits.
**
** u2_b functions may not be used. Trace must be correct.
**
** Pro: lite jets minimize invocation latency.
** Pro: no garbage collection is required on error.
**
** Con: manual programming of large functions in lite mode is difficult.
*/
{
u2_noun hoc = u2_rx(wir_r, u2_wire_tax(wir_r));
u2_ray kit_r = u2_wire_kit_r(wir_r);
u2_noun ret;
u2_wire_kit_r(wir_r) = 0;
u2_tx_glu_bit(wir_r, u2_no);
ret = jet_j->fun_f(wir_r, cor);
u2_tx_glu_bit(wir_r, u2_yes);
u2_wire_kit_r(wir_r) = kit_r;
if ( u2_none == ret ) {
// Restore base trace; shed C-generated trace.
//
*tax = u2_rx(wir_r, u2_wire_tax(wir_r));
u2_wire_tax(wir_r) = hoc;
} else {
// Jet should return base trace.
//
c3_assert(hoc == u2_wire_tax(wir_r));
u2_rz(wir_r, hoc);
*tax = u2_none;
}
return ret;
}
}
case c3__hevy: {
/* Hevy jet: maintains recursive bail context. The hevy jet can
** bail out at any time. The host framework should (but does not
** yet) free stray nouns.
**
** Pro: hevy jets are the easiest to program.
**
** Con: invocation latency is higher.
*/
{
u2_ray kit_r = u2_bl_open(wir_r);
c3_l how_l;
if ( 0 == u2_wire_kit_r(u2_Wire) ) {
c3_assert(0);
}
if ( (how_l = u2_bl_set(wir_r)) ) {
if ( (c3__exit == how_l) || (c3__intr == how_l) ) {
// The jet promises that its trace calculations are correct.
//
*tax = u2_rx(wir_r, u2_wire_tax(wir_r));
u2_wire_tax(wir_r) = u2_rx
(wir_r, u2_kite_tax(u2_wire_kit_r(wir_r)));
}
else {
// Something failed - nothing is promised.
//
*tax = u2_none;
}
u2_bl_done(wir_r, kit_r);
ret = u2_none;
}
else {
u2_tx_glu_bit(wir_r, u2_no);
ret = jet_j->fun_f(wir_r, cor);
u2_tx_glu_bit(wir_r, u2_yes);
*tax = u2_none;
c3_assert(u2_wire_tax(wir_r) == u2_kite_tax(u2_wire_kit_r(wir_r)));
u2_bl_done(wir_r, kit_r);
}
if ( 0 == u2_wire_kit_r(u2_Wire) ) {
c3_assert(0);
}
return ret;
}
}
}
}
#endif
/* u2_ho_use():
**
** Run a jet. Equivalence testing now disabled.
*/
u2_weak // produce
u2_ho_use(u2_ray wir_r,
u2_ho_jet* jet_j,
u2_noun cor, // retain
u2_noun fol) // retain
{
u2_noun pro, key;
if ( !(jet_j->sat_s & u2_jet_live) ) {
if ( (jet_j->sat_s & u2_jet_memo) &&
(u2_none != (key = (jet_j->key_f(wir_r, cor)))) )
{
u2_noun fun_m = jet_j->fun_m;
u2_noun val;
if ( u2_none != (val = u2_rl_find(wir_r, fun_m, key)) ) {
pro = val;
}
else {
pro = u2_cn_nock(u2_rx(wir_r, cor), u2_rx(wir_r, fol));
pro = u2_rl_save(wir_r, fun_m, key, pro);
}
u2_rz(wir_r, key);
}
else {
// printf("use %s\n", u2_ho_cstring(jet_j->xip));
pro = u2_cn_nock(u2_rx(wir_r, cor), u2_rx(wir_r, fol));
}
}
else {
if ( !(jet_j->sat_s & u2_jet_test) ) {
pro = _ho_run(wir_r, jet_j, cor);
}
else {
// c3_assert(!"equivalence testing is currently disabled");
#if 1
u2_noun sof;
jet_j->sat_s &= ~u2_jet_test;
{
if ( !(jet_j->sat_s & u2_jet_leak) ) {
pro = _ho_run(wir_r, jet_j, cor);
} else {
u2_ho_state mem = jet_j->sat_s;
jet_j->sat_s &= ~u2_jet_leak;
jet_j->sat_s &= ~u2_jet_memo;
{
c3_w liv_w = u2_soup_liv_w(u2_rail_rut_r(wir_r));
c3_w nex_w;
pro = _ho_run(wir_r, jet_j, cor);
u2_rz(wir_r, pro);
nex_w = u2_soup_liv_w(u2_rail_rut_r(wir_r));
if ( nex_w > liv_w ) {
fprintf(stderr, "leak: %d, %s\n",
(nex_w - liv_w), u2_ho_cstring(jet_j->xip));
c3_assert(0);
}
pro = _ho_run(wir_r, jet_j, cor);
}
jet_j->sat_s = mem;
}
}
jet_j->sat_s |= u2_jet_test;
jet_j->sat_s &= ~u2_jet_live;
{
sof = u2_nk_soft(wir_r, u2_rx(wir_r, cor), fol);
}
jet_j->sat_s |= u2_jet_live;
// fprintf(stderr, "test %s\n", u2_ho_cstring(jet_j->xip));
u2_ho_test(wir_r, jet_j, cor, sof, pro);
u2_tx_did_tes(wir_r, 1);
u2_rz(wir_r, pro);
pro = sof;
#endif
}
}
return pro;
}
/* u2_ho_kick():
**
** Apply host nock driver on `xip`, `cor`, `fol`.
*/
u2_weak // produce
u2_ho_kick(u2_ray wir_r,
u2_noun xip, // retain
u2_noun cor, // retain
u2_atom axe) // retain
{
u2_noun fol;
u2_ho_jet* jet_j;
if ( u2_none == (fol = u2_frag(axe, cor)) ) {
return u2_none;
}
else {
jet_j = _ho_conquer(wir_r, xip, axe);
if ( 0 == jet_j ) {
#if 0
c3_c* str_c = u2_ho_cstring(xip);
printf("no jet: %s\r\n", str_c);
free(str_c);
#endif
return u2_nk_soft(wir_r, u2_rx(wir_r, cor), fol);
}
else {
u2_tx_did_jet(wir_r, 1);
return u2_ho_use(wir_r, jet_j, cor, fol);
}
}
}
/* u2_ho_kicq(): as u2_ho_kick(), but mocky.
*/
u2_noun // produce
u2_ho_kicq(u2_ray wir_r,
u2_noun xip, // retain
u2_noun cor, // retain
u2_atom axe, // retain
u2_bean *pon) // retain
{
u2_noun hoe;
if ( 0 != (hoe = u2_cm_trap()) ) {
u2_noun pro;
if ( u2h(hoe) == c3__exit ) {
pro = u2k(u2t(hoe));
*pon = 2;
u2z(hoe);
return pro;
}
else if ( u2h(hoe) == c3__need ) {
pro = u2k(u2t(hoe));
*pon = 1;
u2z(hoe);
return pro;
}
else if ( u2h(hoe) == c3__fail ) {
fprintf(stderr, "\r\nfail from %s\n", u2_ho_cstring(xip));
// u2_err(u2_Wire, "hhoe", u2h(hoe));
// c3_assert(0);
return u2_cm_bail(c3__fail);
}
else {
fprintf(stderr, "\r\nbizarre exit from %s\n", u2_ho_cstring(xip));
// u2_err(u2_Wire, "hhoe", u2h(hoe));
c3_assert(0);
return u2_cm_bowl(hoe);
}
}
else {
u2_noun pro = u2_ho_kick(wir_r, xip, cor, axe);
u2_cm_done();
return pro;
}
}