path: root/src/map/magic-expr.c



#include "magic-expr.h"
#include "magic-expr-eval.h"
#include "itemdb.h"
#include <math.h>

#define IS_SOLID(c) ((c) == 1 || (c) == 5)

int
map_is_solid(int m, int x, int y)
{
    return (IS_SOLID(map_getcell(m, x, y)));
}

#undef IS_SOLID

static void
free_area(area_t *area)
{
        if (!area)
                return;

        switch (area->ty) {
        case AREA_UNION:
                free_area(area->a.a_union[0]);
                free_area(area->a.a_union[1]);
                break;
        default: break;
        }

        free(area);
}

static area_t *
dup_area(area_t *area)
{
        area_t *retval = malloc(sizeof(area_t));
        *retval = *area;

        switch (area->ty) {
        case AREA_UNION:
                retval->a.a_union[0] = dup_area(retval->a.a_union[0]);
                retval->a.a_union[1] = dup_area(retval->a.a_union[1]);
                break;
        default: break;
        }

        return retval;
}

void
magic_copy_var(val_t *dest, val_t *src)
{
        *dest = *src;

        switch (dest->ty) {
        case TY_STRING: dest->v.v_string = strdup(dest->v.v_string);
                break;
        case TY_AREA: dest->v.v_area = dup_area(dest->v.v_area);
                break;
        default: break;
        }
        
}

void
magic_clear_var(val_t *v)
{
        switch (v->ty) {
        case TY_STRING: free(v->v.v_string);
                break;
        case TY_AREA: free_area(v->v.v_area);
                break;
        default: break;
        }
}

static char *
show_entity(entity_t *entity)
{
        switch (entity->type) {
        case BL_PC:
                return ((struct map_session_data *)entity)->status.name;
        case BL_NPC:
                return ((struct npc_data *)entity)->name;
        case BL_MOB:
                return ((struct mob_data *)entity)->name;
        case BL_ITEM:
                /* Sorry about this one... */
                return ((struct item_data *)(&((struct flooritem_data *)entity)->item_data))->name;
        case BL_SKILL:
                return "%skill";
        case BL_PET:
                return ((struct pet_data *)entity)->name;
        case BL_SPELL:
                return "%invocation(ERROR:this-should-not-be-an-entity)";
        default:
                return "%unknown-entity";
        }
}

static void
stringify(val_t *v, int within_op)
{
        static char *dirs[8] = {"S", "SW", "W", "NW", "N", "NE", "E", "SE"};
        char *buf;

        switch (v->ty) {
        case TY_UNDEF:
                buf = strdup("UNDEF");
                break;

        case TY_INT:
                buf = malloc(32);
                sprintf(buf, "%i", v->v.v_int);
                break;

        case TY_STRING:
                return;

        case TY_DIR:
                buf = strdup(dirs[v->v.v_int]);
                break;

        case TY_ENTITY:
                buf = strdup(show_entity(v->v.v_entity));
                break;

        case TY_LOCATION:
                buf = malloc(128);
                sprintf(buf, "<\"%s\", %d, %d>", map[v->v.v_location.m].name,
                        v->v.v_location.x, v->v.v_location.y);
                break;

        case TY_AREA:
                buf = strdup("%area");
                free_area(v->v.v_area);
                break;

        case TY_SPELL:
                buf = strdup(v->v.v_spell->name);
                break;

        case TY_INVOCATION: {
                invocation_t *invocation = within_op
                                         ? v->v.v_invocation
                                         : (invocation_t *) map_id2bl(v->v.v_int);
                buf = strdup(invocation->spell->name);
        }
                break;

        default:
                fprintf(stderr, "[magic] INTERNAL ERROR: Cannot stringify %d\n", v->ty);
                return;
        }

        v->v.v_string = buf;
        v->ty = TY_STRING;
}

static void
intify(val_t *v)
{
        if (v->ty == TY_INT)
                return;

        magic_clear_var(v);
        v->ty = TY_INT;
        v->v.v_int = 1;
}


area_t *
area_new(int ty)
{
        area_t *retval = (area_t *)aCalloc(sizeof(area_t), 1);
        retval->ty = ty;
        return retval;
}

area_t *
area_union(area_t *area, area_t *other_area)
{
        area_t *retval = area_new(AREA_UNION);
        retval->a.a_union[0] = area;
        retval->a.a_union[1] = other_area;
        retval->size = area->size + other_area->size; /* Assume no overlap */
        return retval;
}

/**
 * Turns location into area, leaves other types untouched
 */
static void
make_area(val_t *v)
{
        if (v->ty == TY_LOCATION) {
                area_t *a = malloc(sizeof (area_t));
                v->ty = TY_AREA;
                a->ty = AREA_LOCATION;
                a->a.a_loc = v->v.v_location;
                v->v.v_area = a;
        }
}

static void
make_location(val_t *v)
{
        if (v->ty == TY_AREA &&
            v->v.v_area->ty == AREA_LOCATION) {
                location_t location = v->v.v_area->a.a_loc;
                free_area(v->v.v_area);
                v->ty = TY_LOCATION;
                v->v.v_location = location;
        }
}

static void
make_spell(val_t *v)
{
        if (v->ty == TY_INVOCATION) {
                invocation_t *invoc = v->v.v_invocation; //(invocation_t *) map_id2bl(v->v.v_int);
                if (!invoc)
                        v->ty = TY_FAIL;
                else {
                        v->ty = TY_SPELL;
                        v->v.v_spell = invoc->spell;
                }
        }
}

static int
fun_add(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_INT  && TY(1) == TY_INT) {
                /* Integer addition */
                RESULTINT = ARGINT(0) + ARGINT(1);
                result->ty = TY_INT;
        } else if (ARG_MAY_BE_AREA(0) && ARG_MAY_BE_AREA(1)) {
                /* Area union */
                make_area(&args[0]);
                make_area(&args[1]);
                RESULTAREA = area_union(ARGAREA(0), ARGAREA(1));
                ARGAREA(0) = NULL;
                ARGAREA(1) = NULL;
                result->ty = TY_AREA;
        } else {
                /* Anything else -> string concatenation */
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                /* Yes, we could speed this up. */
                RESULTSTR = (char *) malloc(1 + strlen(ARGSTR(0)) + strlen(ARGSTR(1)));
                strcpy(RESULTSTR, ARGSTR(0));
                strcat(RESULTSTR, ARGSTR(1));
                result->ty = TY_STRING;
        }
        return 0;
}

static int
fun_sub(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) - ARGINT(1);
        return 0;
}


static int
fun_mul(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) * ARGINT(1);
        return 0;
}


static int
fun_div(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (!ARGINT(1))
                return 1; /* division by zero */
        RESULTINT = ARGINT(0) / ARGINT(1);
        return 0;
}

static int
fun_mod(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (!ARGINT(1))
                return 1; /* division by zero */
        RESULTINT = ARGINT(0) % ARGINT(1);
        return 0;
}

static int
fun_or(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) || ARGINT(1);
        return 0;
}

static int
fun_and(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) && ARGINT(1);
        return 0;
}

static int
fun_not(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = !ARGINT(0);
        return 0;
}

static int
fun_gte(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) >= 0;
        } else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) >= ARGINT(1);
        }
        return 0;
}

static int
fun_gt(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) > 0;
        } else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) > ARGINT(1);
        }
        return 0;
}


static int
fun_eq(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) == 0;
        } else if (TY(0) == TY_DIR && TY(1) == TY_DIR)
                RESULTINT = ARGDIR(0) == ARGDIR(1);
        else if (TY(0) == TY_ENTITY && TY(1) == TY_ENTITY)
                RESULTINT = ARGENTITY(0) == ARGENTITY(1);
        else if (TY(0) == TY_LOCATION && TY(1) == TY_LOCATION)
                RESULTINT = (ARGLOCATION(0).x == ARGLOCATION(1).x
                             && ARGLOCATION(0).y == ARGLOCATION(1).y
                             && ARGLOCATION(0).m == ARGLOCATION(1).m);
        else if (TY(0) == TY_AREA && TY(1) == TY_AREA)
                RESULTINT = ARGAREA(0) == ARGAREA(1); /* Probably not that great an idea... */
        else if (TY(0) == TY_SPELL && TY(1) == TY_SPELL)
                RESULTINT = ARGSPELL(0) == ARGSPELL(1);
        else if (TY(0) == TY_INVOCATION && TY(1) == TY_INVOCATION)
                RESULTINT = ARGINVOCATION(0) == ARGINVOCATION(1);
        else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) == ARGINT(1);
        }
        return 0;
}

static int
fun_bitand(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) & ARGINT(1);
        return 0;
}

static int
fun_bitor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) | ARGINT(1);
        return 0;
}

static int
fun_bitxor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) ^ ARGINT(1);
        return 0;
}

static int
fun_bitshl(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) << ARGINT(1);
        return 0;
}

static int
fun_bitshr(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) >> ARGINT(1);
        return 0;
}

static int
fun_max(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = MAX(ARGINT(0), ARGINT(1));
        return 0;
}

static int
fun_min(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = MIN(ARGINT(0), ARGINT(1));
        return 0;
}

static int
fun_if_then_else(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGINT(0))
                magic_copy_var(result, &args[1]);
        else
                magic_copy_var(result, &args[2]);
        return 0;
}

void
magic_area_rect(int *m, int *x, int *y, int *width, int *height, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION: break;

        case AREA_LOCATION:
                *m = area->a.a_loc.m;
                *x = area->a.a_loc.x;
                *y = area->a.a_loc.y;
                *width = 1;
                *height = 1;
                break;

        case AREA_RECT:
                *m = area->a.a_rect.loc.m;
                *x = area->a.a_rect.loc.x;
                *y = area->a.a_rect.loc.y;
                *width = area->a.a_rect.width;
                *height = area->a.a_rect.height;
                break;

        case AREA_BAR: {
                int tx = area->a.a_bar.loc.x;
                int ty = area->a.a_bar.loc.y;
                int twidth = area->a.a_bar.width;
                int tdepth = area->a.a_bar.width;
                *m = area->a.a_bar.loc.m;

                switch (area->a.a_bar.dir) {
                case DIR_S:
                        *x = tx - twidth;
                        *y = ty;
                        *width = twidth * 2 + 1;
                        *height = tdepth;
                        break;

                case DIR_W:
                        *x = tx - tdepth;
                        *y = ty - twidth;
                        *width = tdepth;
                        *height = twidth * 2 + 1;
                        break;

                case DIR_N:
                        *x = tx - twidth;
                        *y = ty - tdepth;
                        *width = twidth * 2 + 1;
                        *height = tdepth;
                        break;

                case DIR_E:
                        *x = tx;
                        *y = ty - twidth;
                        *width = tdepth;
                        *height = twidth * 2 + 1;
                        break;

                default:
                        fprintf(stderr, "Error: Trying to compute area of NE/SE/NW/SW-facing bar");
                        *x = tx; *y = ty; *width = *height = 1;
                }
                break;
        }        
        }
}

static int
location_in_area(int m, int x, int y, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION:
                return location_in_area(m, x, y, area->a.a_union[0])
                        || location_in_area(m, x, y, area->a.a_union[1]);
        case AREA_LOCATION:
        case AREA_RECT:
        case AREA_BAR: {
                int am;
                int ax, ay, awidth, aheight;
                magic_area_rect(&am, &ax, &ay, &awidth, &aheight, area);
                return (am == m
                        && (x >= ax) && (y >= ay)
                        && (x < ax + awidth) && (y < ay + aheight));
        }
        default:
                fprintf(stderr, "INTERNAL ERROR: Invalid area\n");
                return 0;
        }
}


static int
fun_is_in(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = location_in_area(ARGLOCATION(0).m,
                                     ARGLOCATION(0).x,
                                     ARGLOCATION(0).y,
                                     ARGAREA(1));
        return 0;
}

static int
fun_skill(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) != BL_PC
            || ARGINT(1) < 0
            || ARGINT(1) >= MAX_SKILL
            || ARGPC(0)->status.skill[ARGINT(1)].id != ARGINT(1))
                RESULTINT = 0;
        else
                RESULTINT = ARGPC(0)->status.skill[ARGINT(1)].lv;
        return 0;
}

static int
fun_has_shroud(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = (ETY(0) == BL_PC
                     && ARGPC(0)->state.shroud_active);
        return 0;
}

#define BATTLE_GETTER(name) static int fun_get_##name(env_t *env, int args_nr, val_t *result, val_t *args) { RESULTINT = battle_get_##name(ARGENTITY(0)); return 0; }

BATTLE_GETTER(str);
BATTLE_GETTER(agi);
BATTLE_GETTER(vit);
BATTLE_GETTER(dex);
BATTLE_GETTER(luk);
BATTLE_GETTER(int);
BATTLE_GETTER(lv);
BATTLE_GETTER(hp);
BATTLE_GETTER(max_hp);
BATTLE_GETTER(dir);

#define MMO_GETTER(name) static int fun_get_##name(env_t *env, int args_nr, val_t *result, val_t *args) {	\
                if (ETY(0) == BL_PC)								\
                	RESULTINT = ARGPC(0)->status.name;					\
		else										\
		        RESULTINT = 0;								\
		return 0; }									

MMO_GETTER(sp);
MMO_GETTER(max_sp);

static int
fun_name_of(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_ENTITY) {
                RESULTSTR = strdup(show_entity(ARGENTITY(0)));
                return 0;
        } else if (TY(0) == TY_SPELL) {
                RESULTSTR = strdup(ARGSPELL(0)->name);
                return 0;
        } else if (TY(0) == TY_INVOCATION) {
                RESULTSTR = strdup(ARGINVOCATION(0)->spell->name);
                return 0;
        }
        return 1;
}

#define COPY_LOCATION(dest, src) (dest).x = (src).x; (dest).y = (src).y; (dest).m = (src).m;

static int
fun_location(env_t *env, int args_nr, val_t *result, val_t *args)
{
        COPY_LOCATION(RESULTLOCATION, *(ARGENTITY(0)));
        return 0;
}

/* Recall that glibc's rand() isnt' too bad in the lower bits */

static int
fun_random(env_t *env, int args_nr, val_t *result, val_t *args)
{
        int delta = ARGINT(0);
        if (delta < 0)
                delta = -delta;
        if (delta == 0) {
                RESULTINT = 0;
                return 0;
        }
        RESULTINT = rand() % delta;
        if (ARGINT(0) < 0)
                RESULTINT = -RESULTINT;
        return 0;
}

static int
fun_random_dir(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGINT(0))
                RESULTDIR = rand() & 0x7;
        else
                RESULTDIR = (rand() & 0x3) * 2;
        return 0;
}

static int
fun_hash_entity(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGENTITY(0)->id;
        return 0;
}

int // ret -1: not a string, ret 1: no such item, ret 0: OK
magic_find_item(val_t *args, int index, struct item *item, int *stackable)
{
        struct item_data *item_data;
        int must_add_sequentially;

        if (TY(index) == TY_INT)
                item_data = itemdb_exists(ARGINT(index));
        else if (TY(index) == TY_STRING)
                item_data = itemdb_searchname(ARGSTR(index));
        else
                return -1;

        if (!item_data)
                return 1;

        must_add_sequentially = (item_data->type == 4
                                 || item_data->type == 5
                                 || item_data->type == 7
                                 || item_data->type == 8); /* Very elegant. */


        if (stackable)
            *stackable = !must_add_sequentially;

        memset(item, 0, sizeof(struct item));
        item->nameid = item_data->nameid;
        item->identify = 1;

        return 0;
}

static int
fun_count_item(env_t *env, int args_nr, val_t *result, val_t *args)
{
        character_t *chr = (ETY(0) == BL_PC) ? ARGPC(0) : NULL;
        int stackable;
        struct item item;

        GET_ARG_ITEM(1, item, stackable);

        if (!chr)
                return 1;

        RESULTINT = pc_count_all_items(chr, item.id);
        return 0;
}

static int
fun_equipped(env_t *env, int args_nr, val_t *result, val_t *args)
{
        character_t *chr = (ETY(0) == BL_PC) ? ARGPC(0) : NULL;
        int stackable;
        struct item item;

        GET_ARG_ITEM(1, item, stackable);

        if (!chr)
                return 1;

        RESULTINT = pc_checkequip(chr, item.id);
        return 0;
}

static int
fun_is_married(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = (ETY(0) == BL_PC
                     && ARGPC(0)->status.partner_id);
        return 0;
}

static int
fun_partner(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) == BL_PC
            && ARGPC(0)->status.partner_id) {
                RESULTENTITY = (entity_t *) map_nick2sd(map_charid2nick(ARGPC(0)->status.partner_id));
                return 0;
        } else
                return 1;
}

static int
fun_awayfrom(env_t *env, int args_nr, val_t *result, val_t *args)
{
        location_t *loc = &ARGLOCATION(0);
        int dx = heading_x[ARGDIR(1)];
        int dy = heading_y[ARGDIR(1)];
        int distance = ARGINT(2);
        while (distance-- && !map_is_solid(loc->m, loc->x + dx, loc->y + dy)) {
                loc->x += dx;
                loc->y += dy;
        }

        RESULTLOCATION = *loc;
        return 0;
}

static int
fun_failed(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = TY(0) == TY_FAIL;
        return 0;
}

static int
fun_npc(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTENTITY = (entity_t *)npc_name2id(ARGSTR(0));
        return RESULTENTITY == NULL;
}

static int
fun_pc(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTENTITY = (entity_t *)map_nick2sd(ARGSTR(0));
        return RESULTENTITY == NULL;
}

static int
fun_distance(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGLOCATION(0).m != ARGLOCATION(1).m)
                RESULTINT = INT_MAX;
        else
                RESULTINT = MAX(abs(ARGLOCATION(0).x - ARGLOCATION(1).x),
                                abs(ARGLOCATION(0).y - ARGLOCATION(1).y));
        return 0;
}


static int
fun_rdistance(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGLOCATION(0).m != ARGLOCATION(1).m)
                RESULTINT = INT_MAX;
        else {
                int dx = ARGLOCATION(0).x - ARGLOCATION(1).x;
                int dy = ARGLOCATION(0).y - ARGLOCATION(1).y;
                RESULTINT = (int) (sqrt((dx*dx) + (dy*dy)));
        }
        return 0;
}


static int
fun_anchor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        teleport_anchor_t *anchor = magic_find_anchor(ARGSTR(0));

        if (!anchor)
                return 1;

        magic_eval(env, result, anchor->location);

        make_area(result);
        if (result->ty != TY_AREA) {
                magic_clear_var(result);
                return 1;
        } 

        return 0;
}


static int
fun_line_of_sight(env_t *env, int args_nr, val_t *result, val_t *args)
{
        entity_t e1, e2;

        COPY_LOCATION(e1, ARGLOCATION(0));
        COPY_LOCATION(e2, ARGLOCATION(1));

        RESULTINT = battle_check_range(&e1, &e2, 0);

        return 0;
}

void
magic_random_location(location_t *dest, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION: {
                int rv = rand() % area->size;
                if (rv < area->a.a_union[0]->size)
                        magic_random_location(dest, area->a.a_union[0]);
                else
                        magic_random_location(dest, area->a.a_union[1]);
                break;
        }

        case AREA_LOCATION:
        case AREA_RECT:
        case AREA_BAR: {
                int m, x, y, w, h;
                magic_area_rect(&m, &x, &y, &w, &h, area);

                if (w <= 1)
                        w = 1;

                if (h <= 1)
                        h = 1;

                x += rand() % w;
                y += rand() % h;

                if (!map_is_solid(m, x, y)) {
                        int start_x = x;
                        int start_y = y;
                        int i;
                        int initial_dir = rand() & 0x7;
                        int dir = initial_dir;

                        /* try all directions, up to a distance to 10, for a free slot */
                        do {
                                x = start_x;
                                y = start_y;

                                for (i = 0; i < 10 && map_is_solid(m, x, y); i++) {
                                        x += heading_x[dir];
                                        y += heading_y[dir];
                                }

                                dir = (dir + 1) & 0x7;
                        } while (map_is_solid(m, x, y) && dir != initial_dir);

                }
                /* We've tried our best.  If the map is still solid, the engine will automatically randomise the target location if we try to warp. */

                dest->m = m;
                dest->x = x;
                dest->y = y;
                break;
        }

        default:
                fprintf(stderr, "Unknown area type %d\n", area->ty);
        }
}

static int
fun_pick_location(env_t *env, int args_nr, val_t *result, val_t *args)
{
        magic_random_location(&result->v.v_location, ARGAREA(0));
        return 0;
}

static int
fun_read_script_int(env_t *env, int args_nr, val_t *result, val_t *args)
{
        entity_t *subject_p = ARGENTITY(0);
        char *var_name = ARGSTR(1);

        if (subject_p->type != BL_PC)
                return 1;

        RESULTINT = pc_readglobalreg((character_t *) subject_p, var_name);
        return 0;
}

static int
fun_rbox(env_t *env, int args_nr, val_t *result, val_t *args)
{
        location_t loc = ARGLOCATION(0);
        int radius = ARGINT(1);

        RESULTAREA = area_new(AREA_RECT);
        RESULTAREA->a.a_rect.loc.m = loc.m;
        RESULTAREA->a.a_rect.loc.x = loc.x - radius;
        RESULTAREA->a.a_rect.loc.y = loc.y - radius;
        RESULTAREA->a.a_rect.width = radius * 2 + 1;
        RESULTAREA->a.a_rect.height = radius * 2 + 1;

        return 0;
}

static int
fun_running_status_update(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) != BL_PC)
                return 1;

        RESULTINT = battle_get_sc_data(ARGENTITY(0))[ARGINT(1)].timer != -1;
        return 0;
}

static int
fun_element(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = battle_get_element(ARGENTITY(0)) % 10;
        return 0;
}

static int
fun_element_level(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = battle_get_element(ARGENTITY(0)) / 10;
        return 0;
}

static int
fun_index(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGSPELL(0)->index;
        return 0;
}

#define BATTLE_RECORD2(sname, name) { sname, "e", 'i', fun_get_##name }
#define BATTLE_RECORD(name) BATTLE_RECORD2(#name, name)
static fun_t functions[] = {
        { "+", "..", '.', fun_add },
        { "-", "ii", 'i', fun_sub },
        { "*", "ii", 'i', fun_mul },
        { "/", "ii", 'i', fun_div },
        { "%", "ii", 'i', fun_mod },
        { "||", "ii", 'i', fun_or },
        { "&&", "ii", 'i', fun_and },
        { ">", "..", 'i', fun_gt },
        { ">=", "..", 'i', fun_gte },
        { "=", "..", 'i', fun_eq },
        { "|", "..", 'i', fun_bitor },
        { "&", "ii", 'i', fun_bitand },
        { "^", "ii", 'i', fun_bitxor },
        { "<<", "ii", 'i', fun_bitshl },
        { ">>", "ii", 'i', fun_bitshr },
        { "not", "i", 'i', fun_not },
        { "max", "ii", 'i', fun_max },
        { "min", "ii", 'i', fun_min },
        { "is_in", "la", 'i', fun_is_in },
        { "if_then_else", "i__", '_', fun_if_then_else },
        { "skill", "ei", 'i', fun_skill },
        BATTLE_RECORD(str),
        BATTLE_RECORD(agi),
        BATTLE_RECORD(vit),
        BATTLE_RECORD(dex),
        BATTLE_RECORD(luk),
        BATTLE_RECORD(int),
        BATTLE_RECORD2("level", lv),
        BATTLE_RECORD(hp),
        BATTLE_RECORD(max_hp),
        BATTLE_RECORD(sp),
        BATTLE_RECORD(max_sp),
        { "dir", "e", 'd', fun_get_dir },
        { "name_of", ".", 's', fun_name_of },
        { "location", "e", 'l', fun_location },
        { "random", "i", 'i', fun_random },
        { "random_dir", "i", 'd', fun_random_dir },
        { "hash_entity", "e", 'i', fun_hash_entity },
        { "is_married", "e", 'i', fun_is_married },
        { "partner", "e", 'e', fun_partner },
        { "awayfrom", "ldi", 'l', fun_awayfrom },
        { "failed", "_", 'i', fun_failed },
        { "pc", "s", 'e', fun_pc },
        { "npc", "s", 'e', fun_npc },
        { "distance", "ll", 'i', fun_distance },
        { "rdistance", "ll", 'i', fun_rdistance },
        { "anchor", "s", 'a', fun_anchor },
        { "random_location", "a", 'l', fun_pick_location },
        { "script_int", "es", 'i', fun_read_script_int },
        { "rbox", "li", 'a', fun_rbox },
        { "count_item", "e.", 'i', fun_count_item },
        { "line_of_sight", "ll", 'i', fun_line_of_sight },
        { "running_status_update", "ei", 'i', fun_running_status_update },
        { "element", "e", 'i', fun_element },
        { "element_level", "e", 'i', fun_element_level },
        { "has_shroud", "e", 'i', fun_has_shroud },
        { "equipped", "e.", 'i', fun_equipped },
        { "spell_index", "S", 'i', fun_index },
        { NULL, NULL, '.', NULL }
};

static int functions_are_sorted = 0;

int
compare_fun(const void *lhs, const void *rhs)
{
        return strcmp(((fun_t *)lhs)->name,
                      ((fun_t *)rhs)->name);
}

fun_t *
magic_get_fun(char *name, int *index)
{
        static int functions_nr;
        fun_t *result;
        fun_t key;

        if (!functions_are_sorted) {
                fun_t *it = functions;

                while (it->name) ++it;
                functions_nr = it - functions;
                
                qsort(functions, functions_nr, sizeof(fun_t),
                      compare_fun);
                functions_are_sorted = 1;
        }

        key.name = name;
        result = (fun_t *) bsearch(&key, functions, functions_nr, sizeof(fun_t),
                                   compare_fun);

        if (result && index)
                *index = result - functions;

        return result;
}

static int // 1 on failure
eval_location(env_t *env, location_t *dest, e_location_t *expr)
{
        val_t m, x, y;
        magic_eval(env, &m, expr->m);
        magic_eval(env, &x, expr->x);
        magic_eval(env, &y, expr->y);

        if (CHECK_TYPE(&m, TY_STRING)
            && CHECK_TYPE(&x, TY_INT)
            && CHECK_TYPE(&y, TY_INT)) {
                int map_id = map_mapname2mapid(m.v.v_string);
                magic_clear_var(&m);
                if (map_id < 0)
                        return 1;
                dest->m = map_id;
                dest->x = x.v.v_int;
                dest->y = y.v.v_int;
                return 0;
        } else {
                magic_clear_var(&m);
                magic_clear_var(&x);
                magic_clear_var(&y);
                return 1;
        }
}

static area_t *
eval_area(env_t *env, e_area_t *expr)
{
        area_t *area = malloc(sizeof(area_t));
        area->ty = expr->ty;

        switch (expr->ty) {
        case AREA_LOCATION:
                area->size = 1;
                if (eval_location(env, &area->a.a_loc, &expr->a.a_loc)) {
                        free(area);
                        return NULL;
                } else
                        return area;

        case AREA_UNION: {
                int i, fail = 0;
                for (i = 0; i < 2; i++) {
                        area->a.a_union[i] = eval_area(env, expr->a.a_union[i]);
                        if (!area->a.a_union[i])
                                fail = 1;
                }

                if (fail) {
                        for (i = 0; i < 2; i++) {
                                if (area->a.a_union[i])
                                        free_area(area->a.a_union[i]);
                        }
                        free(area);
                        return NULL;
                }
                area->size = area->a.a_union[0]->size + area->a.a_union[1]->size;
                return area;
        }

        case AREA_RECT: {
                val_t width, height;
                magic_eval(env, &width, expr->a.a_rect.width);
                magic_eval(env, &height, expr->a.a_rect.height);

                area->a.a_rect.width = width.v.v_int;
                area->a.a_rect.height = height.v.v_int;

                if (CHECK_TYPE(&width, TY_INT)
                    && CHECK_TYPE(&height, TY_INT)
                    && !eval_location (env, &(area->a.a_rect.loc), &expr->a.a_rect.loc)) {
                        area->size = area->a.a_rect.width * area->a.a_rect.height;
                        magic_clear_var(&width);
                        magic_clear_var(&height);
                        return area;
                } else {
                        free(area);
                        magic_clear_var(&width);
                        magic_clear_var(&height);
                        return NULL;
                }
        }

        case AREA_BAR: {
                val_t width, depth, dir;
                magic_eval(env, &width, expr->a.a_bar.width);
                magic_eval(env, &depth, expr->a.a_bar.depth);
                magic_eval(env, &dir, expr->a.a_bar.dir);

                area->a.a_bar.width = width.v.v_int;
                area->a.a_bar.depth = depth.v.v_int;
                area->a.a_bar.dir = dir.v.v_int;

                if (CHECK_TYPE(&width, TY_INT)
                    && CHECK_TYPE(&depth, TY_INT)
                    && CHECK_TYPE(&dir, TY_DIR)
                    && !eval_location (env, &area->a.a_bar.loc, &expr->a.a_bar.loc)) {
                        area->size = (area->a.a_bar.width * 2 + 1) * area->a.a_bar.depth;
                        magic_clear_var(&width);
                        magic_clear_var(&depth);
                        magic_clear_var(&dir);
                        return area;
                } else {
                        free(area);
                        magic_clear_var(&width);
                        magic_clear_var(&depth);
                        magic_clear_var(&dir);
                        return NULL;
                }
        }

        default:
                fprintf(stderr, "INTERNAL ERROR: Unknown area type %d\n", area->ty);
                free(area);
                return NULL;
        }
}

static int
type_key(char ty_key)
{
        switch (ty_key) {
        case 'i': return TY_INT;
        case 'd': return TY_DIR;
        case 's': return TY_STRING;
        case 'e': return TY_ENTITY;
        case 'l': return TY_LOCATION;
        case 'a': return TY_AREA;
        case 'S': return TY_SPELL;
        case 'I': return TY_INVOCATION;
        default: return -1;
        }
}

int
magic_signature_check(char *opname, char *funname, char *signature, int args_nr, val_t *args, int line, int column)
{
        int i;
        for (i = 0; i < args_nr; i++) {
                val_t *arg = &args[i];
                char ty_key = signature[i];
                int ty = arg->ty;
                int desired_ty = type_key(ty_key);

                if (ty == TY_ENTITY) {
                        /* Dereference entities in preparation for calling function */
                        arg->v.v_entity = map_id2bl(arg->v.v_int);
                        if (!arg->v.v_entity)
                                ty = arg->ty = TY_FAIL;
                } else if (ty == TY_INVOCATION) {
                        arg->v.v_invocation = (invocation_t *) map_id2bl(arg->v.v_int);
                        if (!arg->v.v_entity)
                                ty = arg->ty = TY_FAIL;
                }

                if (!ty_key) {
                        fprintf(stderr, "[magic-eval]:  L%d:%d: Too many arguments (%d) to %s `%s'\n",
                                line, column, args_nr, opname, funname);
                        return 1;
                }

                if (ty == TY_FAIL
                    && ty_key != '_')
                        return 1; /* Fail `in a sane way':  This is a perfectly permissible error */

                if (ty == desired_ty
                    || desired_ty < 0 /* `dontcare' */)
                        continue;

                if (ty == TY_UNDEF) {
                        fprintf(stderr, "[magic-eval]:  L%d:%d: Argument #%d to %s `%s' undefined\n",
                                line, column, i + 1, opname, funname);
                        return 1;
                }

                /* If we are here, we have a type mismatch but no failure _yet_.  Try to coerce. */
                switch (desired_ty) {
                case TY_INT:	intify(arg); break; /* 100% success rate */
                case TY_STRING:	stringify(arg, 1); break; /* 100% success rate */
                case TY_AREA:	make_area(arg); break; /* Only works for locations */
                case TY_LOCATION: make_location(arg); break; /* Only works for some areas */
                case TY_SPELL:	make_spell(arg); break; /* Only works for still-active invocatoins */
                default: break; /* We'll fail right below */
                }

                ty = arg->ty;
                if (ty != desired_ty) { /* Coercion failed? */
                        if (ty != TY_FAIL)
                                fprintf(stderr, "[magic-eval]:  L%d:%d: Argument #%d to %s `%s' of incorrect type (%d)\n",
                                        line, column, i + 1, opname, funname, ty);
                        return 1;
                }
        }

        return 0;
}

void
magic_eval(env_t *env, val_t *dest, expr_t *expr)
{
        switch (expr->ty) {
        case EXPR_VAL:
                magic_copy_var(dest, &expr->e.e_val);
                break;

        case EXPR_LOCATION:
                if (eval_location(env, &dest->v.v_location, &expr->e.e_location))
                        dest->ty = TY_FAIL;
                else
                        dest->ty = TY_LOCATION;
                break;

        case EXPR_AREA:
                if ((dest->v.v_area = eval_area(env, &expr->e.e_area)))
                        dest->ty = TY_AREA;
                else
                        dest->ty = TY_FAIL;
                break;

        case EXPR_FUNAPP: {
                val_t arguments[MAX_ARGS];
                int args_nr = expr->e.e_funapp.args_nr;
                int i;
                fun_t *f = functions + expr->e.e_funapp.id;

                for (i = 0; i < args_nr; ++i)
                        magic_eval(env, &arguments[i], expr->e.e_funapp.args[i]);
                if (magic_signature_check("function", f->name, f->signature, args_nr, arguments,
                                          expr->e.e_funapp.line_nr, expr->e.e_funapp.column)
                    || f->fun(env, args_nr, dest, arguments))
                        dest->ty = TY_FAIL;
                else {
                        int dest_ty = type_key(f->ret_ty);
                        if (dest_ty != -1)
                                dest->ty = dest_ty;

                        /* translate entity back into persistent int */
                        if (dest->ty == TY_ENTITY) {
                                if (dest->v.v_entity)
                                        dest->v.v_int = dest->v.v_entity->id;
                                else
                                        dest->ty = TY_FAIL;
                        }
                }

                for (i = 0; i < args_nr; ++i)
                        magic_clear_var(&arguments[i]);
                break;
        }

        case EXPR_ID: {
                val_t v = VAR(expr->e.e_id);
                magic_copy_var(dest, &v);
                break;
        }

        case EXPR_SPELLFIELD: {
                val_t v;
                int id = expr->e.e_field.id;
                magic_eval(env, &v, expr->e.e_field.expr);

                if (v.ty == TY_INVOCATION) {
                        invocation_t *t = (invocation_t *) map_id2bl(v.v.v_int);

                        if (!t)
                                dest->ty = TY_UNDEF;
                        else {
                                env_t *env = t->env;
                                val_t v = VAR(id);
                                magic_copy_var(dest, &v);
                        }
                } else {
                        fprintf(stderr, "[magic] Attempt to access field %s on non-spell\n", env->base_env->var_name[id]);
                        dest->ty = TY_FAIL;
                }
                break;
        }

        default:
                fprintf(stderr, "[magic] INTERNAL ERROR: Unknown expression type %d\n", expr->ty);
                break;
        }
}

int
magic_eval_int(env_t *env, expr_t *expr)
{
        val_t result;
        magic_eval(env, &result, expr);

        if (result.ty == TY_FAIL
            || result.ty == TY_UNDEF)
                return 0;

        intify(&result);

        return result.v.v_int;
}

char *
magic_eval_str(env_t *env, expr_t *expr)
{
        val_t result;
        magic_eval(env, &result, expr);

        if (result.ty == TY_FAIL
            || result.ty == TY_UNDEF)
                return strdup("?");

        stringify(&result, 0);

        return result.v.v_string;
}

expr_t *
magic_new_expr(int ty)
{
        expr_t *expr = (expr_t *)malloc(sizeof(expr_t));
        expr->ty = ty;
        return expr;
}
#include "magic-expr.h"
#include "magic-expr-eval.h"
#include "itemdb.h"
#include <math.h>

#define IS_SOLID(c) ((c) == 1 || (c) == 5)

int
map_is_solid(int m, int x, int y)
{
    return (IS_SOLID(map_getcell(m, x, y)));
}

#undef IS_SOLID

static void
free_area(area_t *area)
{
        if (!area)
                return;

        switch (area->ty) {
        case AREA_UNION:
                free_area(area->a.a_union[0]);
                free_area(area->a.a_union[1]);
                break;
        default: break;
        }

        free(area);
}

static area_t *
dup_area(area_t *area)
{
        area_t *retval = malloc(sizeof(area_t));
        *retval = *area;

        switch (area->ty) {
        case AREA_UNION:
                retval->a.a_union[0] = dup_area(retval->a.a_union[0]);
                retval->a.a_union[1] = dup_area(retval->a.a_union[1]);
                break;
        default: break;
        }

        return retval;
}

void
magic_copy_var(val_t *dest, val_t *src)
{
        *dest = *src;

        switch (dest->ty) {
        case TY_STRING: dest->v.v_string = strdup(dest->v.v_string);
                break;
        case TY_AREA: dest->v.v_area = dup_area(dest->v.v_area);
                break;
        default: break;
        }
        
}

void
magic_clear_var(val_t *v)
{
        switch (v->ty) {
        case TY_STRING: free(v->v.v_string);
                break;
        case TY_AREA: free_area(v->v.v_area);
                break;
        default: break;
        }
}

static char *
show_entity(entity_t *entity)
{
        switch (entity->type) {
        case BL_PC:
                return ((struct map_session_data *)entity)->status.name;
        case BL_NPC:
                return ((struct npc_data *)entity)->name;
        case BL_MOB:
                return ((struct mob_data *)entity)->name;
        case BL_ITEM:
                /* Sorry about this one... */
                return ((struct item_data *)(&((struct flooritem_data *)entity)->item_data))->name;
        case BL_SKILL:
                return "%skill";
        case BL_PET:
                return ((struct pet_data *)entity)->name;
        case BL_SPELL:
                return "%invocation(ERROR:this-should-not-be-an-entity)";
        default:
                return "%unknown-entity";
        }
}

static void
stringify(val_t *v, int within_op)
{
        static char *dirs[8] = {"S", "SW", "W", "NW", "N", "NE", "E", "SE"};
        char *buf;

        switch (v->ty) {
        case TY_UNDEF:
                buf = strdup("UNDEF");
                break;

        case TY_INT:
                buf = malloc(32);
                sprintf(buf, "%i", v->v.v_int);
                break;

        case TY_STRING:
                return;

        case TY_DIR:
                buf = strdup(dirs[v->v.v_int]);
                break;

        case TY_ENTITY:
                buf = strdup(show_entity(v->v.v_entity));
                break;

        case TY_LOCATION:
                buf = malloc(128);
                sprintf(buf, "<\"%s\", %d, %d>", map[v->v.v_location.m].name,
                        v->v.v_location.x, v->v.v_location.y);
                break;

        case TY_AREA:
                buf = strdup("%area");
                free_area(v->v.v_area);
                break;

        case TY_SPELL:
                buf = strdup(v->v.v_spell->name);
                break;

        case TY_INVOCATION: {
                invocation_t *invocation = within_op
                                         ? v->v.v_invocation
                                         : (invocation_t *) map_id2bl(v->v.v_int);
                buf = strdup(invocation->spell->name);
        }
                break;

        default:
                fprintf(stderr, "[magic] INTERNAL ERROR: Cannot stringify %d\n", v->ty);
                return;
        }

        v->v.v_string = buf;
        v->ty = TY_STRING;
}

static void
intify(val_t *v)
{
        if (v->ty == TY_INT)
                return;

        magic_clear_var(v);
        v->ty = TY_INT;
        v->v.v_int = 1;
}


area_t *
area_new(int ty)
{
        area_t *retval = (area_t *)aCalloc(sizeof(area_t), 1);
        retval->ty = ty;
        return retval;
}

area_t *
area_union(area_t *area, area_t *other_area)
{
        area_t *retval = area_new(AREA_UNION);
        retval->a.a_union[0] = area;
        retval->a.a_union[1] = other_area;
        retval->size = area->size + other_area->size; /* Assume no overlap */
        return retval;
}

/**
 * Turns location into area, leaves other types untouched
 */
static void
make_area(val_t *v)
{
        if (v->ty == TY_LOCATION) {
                area_t *a = malloc(sizeof (area_t));
                v->ty = TY_AREA;
                a->ty = AREA_LOCATION;
                a->a.a_loc = v->v.v_location;
                v->v.v_area = a;
        }
}

static void
make_location(val_t *v)
{
        if (v->ty == TY_AREA &&
            v->v.v_area->ty == AREA_LOCATION) {
                location_t location = v->v.v_area->a.a_loc;
                free_area(v->v.v_area);
                v->ty = TY_LOCATION;
                v->v.v_location = location;
        }
}

static void
make_spell(val_t *v)
{
        if (v->ty == TY_INVOCATION) {
                invocation_t *invoc = v->v.v_invocation; //(invocation_t *) map_id2bl(v->v.v_int);
                if (!invoc)
                        v->ty = TY_FAIL;
                else {
                        v->ty = TY_SPELL;
                        v->v.v_spell = invoc->spell;
                }
        }
}

static int
fun_add(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_INT  && TY(1) == TY_INT) {
                /* Integer addition */
                RESULTINT = ARGINT(0) + ARGINT(1);
                result->ty = TY_INT;
        } else if (ARG_MAY_BE_AREA(0) && ARG_MAY_BE_AREA(1)) {
                /* Area union */
                make_area(&args[0]);
                make_area(&args[1]);
                RESULTAREA = area_union(ARGAREA(0), ARGAREA(1));
                ARGAREA(0) = NULL;
                ARGAREA(1) = NULL;
                result->ty = TY_AREA;
        } else {
                /* Anything else -> string concatenation */
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                /* Yes, we could speed this up. */
                RESULTSTR = (char *) malloc(1 + strlen(ARGSTR(0)) + strlen(ARGSTR(1)));
                strcpy(RESULTSTR, ARGSTR(0));
                strcat(RESULTSTR, ARGSTR(1));
                result->ty = TY_STRING;
        }
        return 0;
}

static int
fun_sub(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) - ARGINT(1);
        return 0;
}


static int
fun_mul(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) * ARGINT(1);
        return 0;
}


static int
fun_div(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (!ARGINT(1))
                return 1; /* division by zero */
        RESULTINT = ARGINT(0) / ARGINT(1);
        return 0;
}

static int
fun_mod(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (!ARGINT(1))
                return 1; /* division by zero */
        RESULTINT = ARGINT(0) % ARGINT(1);
        return 0;
}

static int
fun_or(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) || ARGINT(1);
        return 0;
}

static int
fun_and(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) && ARGINT(1);
        return 0;
}

static int
fun_not(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = !ARGINT(0);
        return 0;
}

static int
fun_gte(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) >= 0;
        } else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) >= ARGINT(1);
        }
        return 0;
}

static int
fun_gt(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) > 0;
        } else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) > ARGINT(1);
        }
        return 0;
}


static int
fun_eq(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_STRING || TY(1) == TY_STRING) {
                stringify(&args[0], 1);
                stringify(&args[1], 1);
                RESULTINT = strcmp(ARGSTR(0), ARGSTR(1)) == 0;
        } else if (TY(0) == TY_DIR && TY(1) == TY_DIR)
                RESULTINT = ARGDIR(0) == ARGDIR(1);
        else if (TY(0) == TY_ENTITY && TY(1) == TY_ENTITY)
                RESULTINT = ARGENTITY(0) == ARGENTITY(1);
        else if (TY(0) == TY_LOCATION && TY(1) == TY_LOCATION)
                RESULTINT = (ARGLOCATION(0).x == ARGLOCATION(1).x
                             && ARGLOCATION(0).y == ARGLOCATION(1).y
                             && ARGLOCATION(0).m == ARGLOCATION(1).m);
        else if (TY(0) == TY_AREA && TY(1) == TY_AREA)
                RESULTINT = ARGAREA(0) == ARGAREA(1); /* Probably not that great an idea... */
        else if (TY(0) == TY_SPELL && TY(1) == TY_SPELL)
                RESULTINT = ARGSPELL(0) == ARGSPELL(1);
        else if (TY(0) == TY_INVOCATION && TY(1) == TY_INVOCATION)
                RESULTINT = ARGINVOCATION(0) == ARGINVOCATION(1);
        else {
                intify(&args[0]);
                intify(&args[1]);
                RESULTINT = ARGINT(0) == ARGINT(1);
        }
        return 0;
}

static int
fun_bitand(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) & ARGINT(1);
        return 0;
}

static int
fun_bitor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) | ARGINT(1);
        return 0;
}

static int
fun_bitxor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) ^ ARGINT(1);
        return 0;
}

static int
fun_bitshl(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) << ARGINT(1);
        return 0;
}

static int
fun_bitshr(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGINT(0) >> ARGINT(1);
        return 0;
}

static int
fun_max(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = MAX(ARGINT(0), ARGINT(1));
        return 0;
}

static int
fun_min(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = MIN(ARGINT(0), ARGINT(1));
        return 0;
}

static int
fun_if_then_else(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGINT(0))
                magic_copy_var(result, &args[1]);
        else
                magic_copy_var(result, &args[2]);
        return 0;
}

void
magic_area_rect(int *m, int *x, int *y, int *width, int *height, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION: break;

        case AREA_LOCATION:
                *m = area->a.a_loc.m;
                *x = area->a.a_loc.x;
                *y = area->a.a_loc.y;
                *width = 1;
                *height = 1;
                break;

        case AREA_RECT:
                *m = area->a.a_rect.loc.m;
                *x = area->a.a_rect.loc.x;
                *y = area->a.a_rect.loc.y;
                *width = area->a.a_rect.width;
                *height = area->a.a_rect.height;
                break;

        case AREA_BAR: {
                int tx = area->a.a_bar.loc.x;
                int ty = area->a.a_bar.loc.y;
                int twidth = area->a.a_bar.width;
                int tdepth = area->a.a_bar.width;
                *m = area->a.a_bar.loc.m;

                switch (area->a.a_bar.dir) {
                case DIR_S:
                        *x = tx - twidth;
                        *y = ty;
                        *width = twidth * 2 + 1;
                        *height = tdepth;
                        break;

                case DIR_W:
                        *x = tx - tdepth;
                        *y = ty - twidth;
                        *width = tdepth;
                        *height = twidth * 2 + 1;
                        break;

                case DIR_N:
                        *x = tx - twidth;
                        *y = ty - tdepth;
                        *width = twidth * 2 + 1;
                        *height = tdepth;
                        break;

                case DIR_E:
                        *x = tx;
                        *y = ty - twidth;
                        *width = tdepth;
                        *height = twidth * 2 + 1;
                        break;

                default:
                        fprintf(stderr, "Error: Trying to compute area of NE/SE/NW/SW-facing bar");
                        *x = tx; *y = ty; *width = *height = 1;
                }
                break;
        }        
        }
}

static int
location_in_area(int m, int x, int y, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION:
                return location_in_area(m, x, y, area->a.a_union[0])
                        || location_in_area(m, x, y, area->a.a_union[1]);
        case AREA_LOCATION:
        case AREA_RECT:
        case AREA_BAR: {
                int am;
                int ax, ay, awidth, aheight;
                magic_area_rect(&am, &ax, &ay, &awidth, &aheight, area);
                return (am == m
                        && (x >= ax) && (y >= ay)
                        && (x < ax + awidth) && (y < ay + aheight));
        }
        default:
                fprintf(stderr, "INTERNAL ERROR: Invalid area\n");
                return 0;
        }
}


static int
fun_is_in(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = location_in_area(ARGLOCATION(0).m,
                                     ARGLOCATION(0).x,
                                     ARGLOCATION(0).y,
                                     ARGAREA(1));
        return 0;
}

static int
fun_skill(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) != BL_PC
            || ARGINT(1) < 0
            || ARGINT(1) >= MAX_SKILL
            || ARGPC(0)->status.skill[ARGINT(1)].id != ARGINT(1))
                RESULTINT = 0;
        else
                RESULTINT = ARGPC(0)->status.skill[ARGINT(1)].lv;
        return 0;
}

static int
fun_has_shroud(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = (ETY(0) == BL_PC
                     && ARGPC(0)->state.shroud_active);
        return 0;
}

#define BATTLE_GETTER(name) static int fun_get_##name(env_t *env, int args_nr, val_t *result, val_t *args) { RESULTINT = battle_get_##name(ARGENTITY(0)); return 0; }

BATTLE_GETTER(str);
BATTLE_GETTER(agi);
BATTLE_GETTER(vit);
BATTLE_GETTER(dex);
BATTLE_GETTER(luk);
BATTLE_GETTER(int);
BATTLE_GETTER(lv);
BATTLE_GETTER(hp);
BATTLE_GETTER(max_hp);
BATTLE_GETTER(dir);

#define MMO_GETTER(name) static int fun_get_##name(env_t *env, int args_nr, val_t *result, val_t *args) {	\
                if (ETY(0) == BL_PC)								\
                	RESULTINT = ARGPC(0)->status.name;					\
		else										\
		        RESULTINT = 0;								\
		return 0; }									

MMO_GETTER(sp);
MMO_GETTER(max_sp);

static int
fun_name_of(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (TY(0) == TY_ENTITY) {
                RESULTSTR = strdup(show_entity(ARGENTITY(0)));
                return 0;
        } else if (TY(0) == TY_SPELL) {
                RESULTSTR = strdup(ARGSPELL(0)->name);
                return 0;
        } else if (TY(0) == TY_INVOCATION) {
                RESULTSTR = strdup(ARGINVOCATION(0)->spell->name);
                return 0;
        }
        return 1;
}

#define COPY_LOCATION(dest, src) (dest).x = (src).x; (dest).y = (src).y; (dest).m = (src).m;

static int
fun_location(env_t *env, int args_nr, val_t *result, val_t *args)
{
        COPY_LOCATION(RESULTLOCATION, *(ARGENTITY(0)));
        return 0;
}

/* Recall that glibc's rand() isnt' too bad in the lower bits */

static int
fun_random(env_t *env, int args_nr, val_t *result, val_t *args)
{
        int delta = ARGINT(0);
        if (delta < 0)
                delta = -delta;
        if (delta == 0) {
                RESULTINT = 0;
                return 0;
        }
        RESULTINT = rand() % delta;
        if (ARGINT(0) < 0)
                RESULTINT = -RESULTINT;
        return 0;
}

static int
fun_random_dir(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGINT(0))
                RESULTDIR = rand() & 0x7;
        else
                RESULTDIR = (rand() & 0x3) * 2;
        return 0;
}

static int
fun_hash_entity(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGENTITY(0)->id;
        return 0;
}

int // ret -1: not a string, ret 1: no such item, ret 0: OK
magic_find_item(val_t *args, int index, struct item *item, int *stackable)
{
        struct item_data *item_data;
        int must_add_sequentially;

        if (TY(index) == TY_INT)
                item_data = itemdb_exists(ARGINT(index));
        else if (TY(index) == TY_STRING)
                item_data = itemdb_searchname(ARGSTR(index));
        else
                return -1;

        if (!item_data)
                return 1;

        must_add_sequentially = (item_data->type == 4
                                 || item_data->type == 5
                                 || item_data->type == 7
                                 || item_data->type == 8); /* Very elegant. */


        if (stackable)
            *stackable = !must_add_sequentially;

        memset(item, 0, sizeof(struct item));
        item->nameid = item_data->nameid;
        item->identify = 1;

        return 0;
}

static int
fun_count_item(env_t *env, int args_nr, val_t *result, val_t *args)
{
        character_t *chr = (ETY(0) == BL_PC) ? ARGPC(0) : NULL;
        int stackable;
        struct item item;

        GET_ARG_ITEM(1, item, stackable);

        if (!chr)
                return 1;

        RESULTINT = pc_count_all_items(chr, item.id);
        return 0;
}

static int
fun_equipped(env_t *env, int args_nr, val_t *result, val_t *args)
{
        character_t *chr = (ETY(0) == BL_PC) ? ARGPC(0) : NULL;
        int stackable;
        struct item item;

        GET_ARG_ITEM(1, item, stackable);

        if (!chr)
                return 1;

        RESULTINT = pc_checkequip(chr, item.id);
        return 0;
}

static int
fun_is_married(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = (ETY(0) == BL_PC
                     && ARGPC(0)->status.partner_id);
        return 0;
}

static int
fun_partner(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) == BL_PC
            && ARGPC(0)->status.partner_id) {
                RESULTENTITY = (entity_t *) map_nick2sd(map_charid2nick(ARGPC(0)->status.partner_id));
                return 0;
        } else
                return 1;
}

static int
fun_awayfrom(env_t *env, int args_nr, val_t *result, val_t *args)
{
        location_t *loc = &ARGLOCATION(0);
        int dx = heading_x[ARGDIR(1)];
        int dy = heading_y[ARGDIR(1)];
        int distance = ARGINT(2);
        while (distance-- && !map_is_solid(loc->m, loc->x + dx, loc->y + dy)) {
                loc->x += dx;
                loc->y += dy;
        }

        RESULTLOCATION = *loc;
        return 0;
}

static int
fun_failed(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = TY(0) == TY_FAIL;
        return 0;
}

static int
fun_npc(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTENTITY = (entity_t *)npc_name2id(ARGSTR(0));
        return RESULTENTITY == NULL;
}

static int
fun_pc(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTENTITY = (entity_t *)map_nick2sd(ARGSTR(0));
        return RESULTENTITY == NULL;
}

static int
fun_distance(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGLOCATION(0).m != ARGLOCATION(1).m)
                RESULTINT = INT_MAX;
        else
                RESULTINT = MAX(abs(ARGLOCATION(0).x - ARGLOCATION(1).x),
                                abs(ARGLOCATION(0).y - ARGLOCATION(1).y));
        return 0;
}


static int
fun_rdistance(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ARGLOCATION(0).m != ARGLOCATION(1).m)
                RESULTINT = INT_MAX;
        else {
                int dx = ARGLOCATION(0).x - ARGLOCATION(1).x;
                int dy = ARGLOCATION(0).y - ARGLOCATION(1).y;
                RESULTINT = (int) (sqrt((dx*dx) + (dy*dy)));
        }
        return 0;
}


static int
fun_anchor(env_t *env, int args_nr, val_t *result, val_t *args)
{
        teleport_anchor_t *anchor = magic_find_anchor(ARGSTR(0));

        if (!anchor)
                return 1;

        magic_eval(env, result, anchor->location);

        make_area(result);
        if (result->ty != TY_AREA) {
                magic_clear_var(result);
                return 1;
        } 

        return 0;
}


static int
fun_line_of_sight(env_t *env, int args_nr, val_t *result, val_t *args)
{
        entity_t e1, e2;

        COPY_LOCATION(e1, ARGLOCATION(0));
        COPY_LOCATION(e2, ARGLOCATION(1));

        RESULTINT = battle_check_range(&e1, &e2, 0);

        return 0;
}

void
magic_random_location(location_t *dest, area_t *area)
{
        switch (area->ty) {
        case AREA_UNION: {
                int rv = rand() % area->size;
                if (rv < area->a.a_union[0]->size)
                        magic_random_location(dest, area->a.a_union[0]);
                else
                        magic_random_location(dest, area->a.a_union[1]);
                break;
        }

        case AREA_LOCATION:
        case AREA_RECT:
        case AREA_BAR: {
                int m, x, y, w, h;
                magic_area_rect(&m, &x, &y, &w, &h, area);

                if (w <= 1)
                        w = 1;

                if (h <= 1)
                        h = 1;

                x += rand() % w;
                y += rand() % h;

                if (!map_is_solid(m, x, y)) {
                        int start_x = x;
                        int start_y = y;
                        int i;
                        int initial_dir = rand() & 0x7;
                        int dir = initial_dir;

                        /* try all directions, up to a distance to 10, for a free slot */
                        do {
                                x = start_x;
                                y = start_y;

                                for (i = 0; i < 10 && map_is_solid(m, x, y); i++) {
                                        x += heading_x[dir];
                                        y += heading_y[dir];
                                }

                                dir = (dir + 1) & 0x7;
                        } while (map_is_solid(m, x, y) && dir != initial_dir);

                }
                /* We've tried our best.  If the map is still solid, the engine will automatically randomise the target location if we try to warp. */

                dest->m = m;
                dest->x = x;
                dest->y = y;
                break;
        }

        default:
                fprintf(stderr, "Unknown area type %d\n", area->ty);
        }
}

static int
fun_pick_location(env_t *env, int args_nr, val_t *result, val_t *args)
{
        magic_random_location(&result->v.v_location, ARGAREA(0));
        return 0;
}

static int
fun_read_script_int(env_t *env, int args_nr, val_t *result, val_t *args)
{
        entity_t *subject_p = ARGENTITY(0);
        char *var_name = ARGSTR(1);

        if (subject_p->type != BL_PC)
                return 1;

        RESULTINT = pc_readglobalreg((character_t *) subject_p, var_name);
        return 0;
}

static int
fun_rbox(env_t *env, int args_nr, val_t *result, val_t *args)
{
        location_t loc = ARGLOCATION(0);
        int radius = ARGINT(1);

        RESULTAREA = area_new(AREA_RECT);
        RESULTAREA->a.a_rect.loc.m = loc.m;
        RESULTAREA->a.a_rect.loc.x = loc.x - radius;
        RESULTAREA->a.a_rect.loc.y = loc.y - radius;
        RESULTAREA->a.a_rect.width = radius * 2 + 1;
        RESULTAREA->a.a_rect.height = radius * 2 + 1;

        return 0;
}

static int
fun_running_status_update(env_t *env, int args_nr, val_t *result, val_t *args)
{
        if (ETY(0) != BL_PC)
                return 1;

        RESULTINT = battle_get_sc_data(ARGENTITY(0))[ARGINT(1)].timer != -1;
        return 0;
}

static int
fun_element(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = battle_get_element(ARGENTITY(0)) % 10;
        return 0;
}

static int
fun_element_level(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = battle_get_element(ARGENTITY(0)) / 10;
        return 0;
}

static int
fun_index(env_t *env, int args_nr, val_t *result, val_t *args)
{
        RESULTINT = ARGSPELL(0)->index;
        return 0;
}

#define BATTLE_RECORD2(sname, name) { sname, "e", 'i', fun_get_##name }
#define BATTLE_RECORD(name) BATTLE_RECORD2(#name, name)
static fun_t functions[] = {
        { "+", "..", '.', fun_add },
        { "-", "ii", 'i', fun_sub },
        { "*", "ii", 'i', fun_mul },
        { "/", "ii", 'i', fun_div },
        { "%", "ii", 'i', fun_mod },
        { "||", "ii", 'i', fun_or },
        { "&&", "ii", 'i', fun_and },
        { ">", "..", 'i', fun_gt },
        { ">=", "..", 'i', fun_gte },
        { "=", "..", 'i', fun_eq },
        { "|", "..", 'i', fun_bitor },
        { "&", "ii", 'i', fun_bitand },
        { "^", "ii", 'i', fun_bitxor },
        { "<<", "ii", 'i', fun_bitshl },
        { ">>", "ii", 'i', fun_bitshr },
        { "not", "i", 'i', fun_not },
        { "max", "ii", 'i', fun_max },
        { "min", "ii", 'i', fun_min },
        { "is_in", "la", 'i', fun_is_in },
        { "if_then_else", "i__", '_', fun_if_then_else },
        { "skill", "ei", 'i', fun_skill },
        BATTLE_RECORD(str),
        BATTLE_RECORD(agi),
        BATTLE_RECORD(vit),
        BATTLE_RECORD(dex),
        BATTLE_RECORD(luk),
        BATTLE_RECORD(int),
        BATTLE_RECORD2("level", lv),
        BATTLE_RECORD(hp),
        BATTLE_RECORD(max_hp),
        BATTLE_RECORD(sp),
        BATTLE_RECORD(max_sp),
        { "dir", "e", 'd', fun_get_dir },
        { "name_of", ".", 's', fun_name_of },
        { "location", "e", 'l', fun_location },
        { "random", "i", 'i', fun_random },
        { "random_dir", "i", 'd', fun_random_dir },
        { "hash_entity", "e", 'i', fun_hash_entity },
        { "is_married", "e", 'i', fun_is_married },
        { "partner", "e", 'e', fun_partner },
        { "awayfrom", "ldi", 'l', fun_awayfrom },
        { "failed", "_", 'i', fun_failed },
        { "pc", "s", 'e', fun_pc },
        { "npc", "s", 'e', fun_npc },
        { "distance", "ll", 'i', fun_distance },
        { "rdistance", "ll", 'i', fun_rdistance },
        { "anchor", "s", 'a', fun_anchor },
        { "random_location", "a", 'l', fun_pick_location },
        { "script_int", "es", 'i', fun_read_script_int },
        { "rbox", "li", 'a', fun_rbox },
        { "count_item", "e.", 'i', fun_count_item },
        { "line_of_sight", "ll", 'i', fun_line_of_sight },
        { "running_status_update", "ei", 'i', fun_running_status_update },
        { "element", "e", 'i', fun_element },
        { "element_level", "e", 'i', fun_element_level },
        { "has_shroud", "e", 'i', fun_has_shroud },
        { "equipped", "e.", 'i', fun_equipped },
        { "spell_index", "S", 'i', fun_index },
        { NULL, NULL, '.', NULL }
};

static int functions_are_sorted = 0;

int
compare_fun(const void *lhs, const void *rhs)
{
        return strcmp(((fun_t *)lhs)->name,
                      ((fun_t *)rhs)->name);
}

fun_t *
magic_get_fun(char *name, int *index)
{
        static int functions_nr;
        fun_t *result;
        fun_t key;

        if (!functions_are_sorted) {
                fun_t *it = functions;

                while (it->name) ++it;
                functions_nr = it - functions;
                
                qsort(functions, functions_nr, sizeof(fun_t),
                      compare_fun);
                functions_are_sorted = 1;
        }

        key.name = name;
        result = (fun_t *) bsearch(&key, functions, functions_nr, sizeof(fun_t),
                                   compare_fun);

        if (result && index)
                *index = result - functions;

        return result;
}

static int // 1 on failure
eval_location(env_t *env, location_t *dest, e_location_t *expr)
{
        val_t m, x, y;
        magic_eval(env, &m, expr->m);
        magic_eval(env, &x, expr->x);
        magic_eval(env, &y, expr->y);

        if (CHECK_TYPE(&m, TY_STRING)
            && CHECK_TYPE(&x, TY_INT)
            && CHECK_TYPE(&y, TY_INT)) {
                int map_id = map_mapname2mapid(m.v.v_string);
                magic_clear_var(&m);
                if (map_id < 0)
                        return 1;
                dest->m = map_id;
                dest->x = x.v.v_int;
                dest->y = y.v.v_int;
                return 0;
        } else {
                magic_clear_var(&m);
                magic_clear_var(&x);
                magic_clear_var(&y);
                return 1;
        }
}

static area_t *
eval_area(env_t *env, e_area_t *expr)
{
        area_t *area = malloc(sizeof(area_t));
        area->ty = expr->ty;

        switch (expr->ty) {
        case AREA_LOCATION:
                area->size = 1;
                if (eval_location(env, &area->a.a_loc, &expr->a.a_loc)) {
                        free(area);
                        return NULL;
                } else
                        return area;

        case AREA_UNION: {
                int i, fail = 0;
                for (i = 0; i < 2; i++) {
                        area->a.a_union[i] = eval_area(env, expr->a.a_union[i]);
                        if (!area->a.a_union[i])
                                fail = 1;
                }

                if (fail) {
                        for (i = 0; i < 2; i++) {
                                if (area->a.a_union[i])
                                        free_area(area->a.a_union[i]);
                        }
                        free(area);
                        return NULL;
                }
                area->size = area->a.a_union[0]->size + area->a.a_union[1]->size;
                return area;
        }

        case AREA_RECT: {
                val_t width, height;
                magic_eval(env, &width, expr->a.a_rect.width);
                magic_eval(env, &height, expr->a.a_rect.height);

                area->a.a_rect.width = width.v.v_int;
                area->a.a_rect.height = height.v.v_int;

                if (CHECK_TYPE(&width, TY_INT)
                    && CHECK_TYPE(&height, TY_INT)
                    && !eval_location (env, &(area->a.a_rect.loc), &expr->a.a_rect.loc)) {
                        area->size = area->a.a_rect.width * area->a.a_rect.height;
                        magic_clear_var(&width);
                        magic_clear_var(&height);
                        return area;
                } else {
                        free(area);
                        magic_clear_var(&width);
                        magic_clear_var(&height);
                        return NULL;
                }
        }

        case AREA_BAR: {
                val_t width, depth, dir;
                magic_eval(env, &width, expr->a.a_bar.width);
                magic_eval(env, &depth, expr->a.a_bar.depth);
                magic_eval(env, &dir, expr->a.a_bar.dir);

                area->a.a_bar.width = width.v.v_int;
                area->a.a_bar.depth = depth.v.v_int;
                area->a.a_bar.dir = dir.v.v_int;

                if (CHECK_TYPE(&width, TY_INT)
                    && CHECK_TYPE(&depth, TY_INT)
                    && CHECK_TYPE(&dir, TY_DIR)
                    && !eval_location (env, &area->a.a_bar.loc, &expr->a.a_bar.loc)) {
                        area->size = (area->a.a_bar.width * 2 + 1) * area->a.a_bar.depth;
                        magic_clear_var(&width);
                        magic_clear_var(&depth);
                        magic_clear_var(&dir);
                        return area;
                } else {
                        free(area);
                        magic_clear_var(&width);
                        magic_clear_var(&depth);
                        magic_clear_var(&dir);
                        return NULL;
                }
        }

        default:
                fprintf(stderr, "INTERNAL ERROR: Unknown area type %d\n", area->ty);
                free(area);
                return NULL;
        }
}

static int
type_key(char ty_key)
{
        switch (ty_key) {
        case 'i': return TY_INT;
        case 'd': return TY_DIR;
        case 's': return TY_STRING;
        case 'e': return TY_ENTITY;
        case 'l': return TY_LOCATION;
        case 'a': return TY_AREA;
        case 'S': return TY_SPELL;
        case 'I': return TY_INVOCATION;
        default: return -1;
        }
}

int
magic_signature_check(char *opname, char *funname, char *signature, int args_nr, val_t *args, int line, int column)
{
        int i;
        for (i = 0; i < args_nr; i++) {
                val_t *arg = &args[i];
                char ty_key = signature[i];
                int ty = arg->ty;
                int desired_ty = type_key(ty_key);

                if (ty == TY_ENTITY) {
                        /* Dereference entities in preparation for calling function */
                        arg->v.v_entity = map_id2bl(arg->v.v_int);
                        if (!arg->v.v_entity)
                                ty = arg->ty = TY_FAIL;
                } else if (ty == TY_INVOCATION) {
                        arg->v.v_invocation = (invocation_t *) map_id2bl(arg->v.v_int);
                        if (!arg->v.v_entity)
                                ty = arg->ty = TY_FAIL;
                }

                if (!ty_key) {
                        fprintf(stderr, "[magic-eval]:  L%d:%d: Too many arguments (%d) to %s `%s'\n",
                                line, column, args_nr, opname, funname);
                        return 1;
                }

                if (ty == TY_FAIL
                    && ty_key != '_')
                        return 1; /* Fail `in a sane way':  This is a perfectly permissible error */

                if (ty == desired_ty
                    || desired_ty < 0 /* `dontcare' */)
                        continue;

                if (ty == TY_UNDEF) {
                        fprintf(stderr, "[magic-eval]:  L%d:%d: Argument #%d to %s `%s' undefined\n",
                                line, column, i + 1, opname, funname);
                        return 1;
                }

                /* If we are here, we have a type mismatch but no failure _yet_.  Try to coerce. */
                switch (desired_ty) {
                case TY_INT:	intify(arg); break; /* 100% success rate */
                case TY_STRING:	stringify(arg, 1); break; /* 100% success rate */
                case TY_AREA:	make_area(arg); break; /* Only works for locations */
                case TY_LOCATION: make_location(arg); break; /* Only works for some areas */
                case TY_SPELL:	make_spell(arg); break; /* Only works for still-active invocatoins */
                default: break; /* We'll fail right below */
                }

                ty = arg->ty;
                if (ty != desired_ty) { /* Coercion failed? */
                        if (ty != TY_FAIL)
                                fprintf(stderr, "[magic-eval]:  L%d:%d: Argument #%d to %s `%s' of incorrect type (%d)\n",
                                        line, column, i + 1, opname, funname, ty);
                        return 1;
                }
        }

        return 0;
}

void
magic_eval(env_t *env, val_t *dest, expr_t *expr)
{
        switch (expr->ty) {
        case EXPR_VAL:
                magic_copy_var(dest, &expr->e.e_val);
                break;

        case EXPR_LOCATION:
                if (eval_location(env, &dest->v.v_location, &expr->e.e_location))
                        dest->ty = TY_FAIL;
                else
                        dest->ty = TY_LOCATION;
                break;

        case EXPR_AREA:
                if ((dest->v.v_area = eval_area(env, &expr->e.e_area)))
                        dest->ty = TY_AREA;
                else
                        dest->ty = TY_FAIL;
                break;

        case EXPR_FUNAPP: {
                val_t arguments[MAX_ARGS];
                int args_nr = expr->e.e_funapp.args_nr;
                int i;
                fun_t *f = functions + expr->e.e_funapp.id;

                for (i = 0; i < args_nr; ++i)
                        magic_eval(env, &arguments[i], expr->e.e_funapp.args[i]);
                if (magic_signature_check("function", f->name, f->signature, args_nr, arguments,
                                          expr->e.e_funapp.line_nr, expr->e.e_funapp.column)
                    || f->fun(env, args_nr, dest, arguments))
                        dest->ty = TY_FAIL;
                else {
                        int dest_ty = type_key(f->ret_ty);
                        if (dest_ty != -1)
                                dest->ty = dest_ty;

                        /* translate entity back into persistent int */
                        if (dest->ty == TY_ENTITY) {
                                if (dest->v.v_entity)
                                        dest->v.v_int = dest->v.v_entity->id;
                                else
                                        dest->ty = TY_FAIL;
                        }
                }

                for (i = 0; i < args_nr; ++i)
                        magic_clear_var(&arguments[i]);
                break;
        }

        case EXPR_ID: {
                val_t v = VAR(expr->e.e_id);
                magic_copy_var(dest, &v);
                break;
        }

        case EXPR_SPELLFIELD: {
                val_t v;
                int id = expr->e.e_field.id;
                magic_eval(env, &v, expr->e.e_field.expr);

                if (v.ty == TY_INVOCATION) {
                        invocation_t *t = (invocation_t *) map_id2bl(v.v.v_int);

                        if (!t)
                                dest->ty = TY_UNDEF;
                        else {
                                env_t *env = t->env;
                                val_t v = VAR(id);
                                magic_copy_var(dest, &v);
                        }
                } else {
                        fprintf(stderr, "[magic] Attempt to access field %s on non-spell\n", env->base_env->var_name[id]);
                        dest->ty = TY_FAIL;
                }
                break;
        }

        default:
                fprintf(stderr, "[magic] INTERNAL ERROR: Unknown expression type %d\n", expr->ty);
                break;
        }
}

int
magic_eval_int(env_t *env, expr_t *expr)
{
        val_t result;
        magic_eval(env, &result, expr);

        if (result.ty == TY_FAIL
            || result.ty == TY_UNDEF)
                return 0;

        intify(&result);

        return result.v.v_int;
}

char *
magic_eval_str(env_t *env, expr_t *expr)
{
        val_t result;
        magic_eval(env, &result, expr);

        if (result.ty == TY_FAIL
            || result.ty == TY_UNDEF)
                return strdup("?");

        stringify(&result, 0);

        return result.v.v_string;
}

expr_t *
magic_new_expr(int ty)
{
        expr_t *expr = (expr_t *)malloc(sizeof(expr_t));
        expr->ty = ty;
        return expr;
}