/**/
+#include <glpk.h>
+
#include "rscommon.h"
DEBUG_DEFINE_DEBUGF(value);
+typedef struct { int mass, volu; } CommodInfo;
+static int commodstablesz;
+static CommodInfo *commodstable;
+
+static sqlite3_stmt *ss_ipair_dist, *ss_ipair_trades;
+static sqlite3_stmt *ss_ite_buy, *ss_ite_sell;
+
+#define MAX_LEGS (MAX_ROUTELEN-1)
+
typedef struct {
int commodid, src_price, src_qty, dst_price, dst_qty;
} Trade;
} TradesBlock;
typedef struct {
+ double distance_loss_factor;
int ntrades;
TradesBlock *trades;
} IslandPair;
int nislands;
IslandPair ***ipairs; /* ipairs[sislandid][dislandid] */
+typedef struct IslandTradeEnd {
+ struct IslandTradeEnd *next;
+ int commodid, price;
+ int qty;
+ unsigned long generation;
+ int rownum;
+} IslandTradeEnd, *IslandDirnTradeEnds;
+
+typedef struct {
+ int islandid;
+ IslandDirnTradeEnds collect, deliver;
+} IslandTradeEnds;
+
+static LPX *lp;
+static unsigned long generation;
+
+static int nconstraint_rows;
+static int constraint_rows[1+2+3*MAX_LEGS];
+static double constraint_coeffs[1+2+3*MAX_LEGS];
+ /* dummy0, src, dst, for_each_leg( [mass], [volume], [capital] ) */
+
+static void add_constraint(int row, double coefficient) {
+ nconstraint_rows++; /* glpk indices start from 1 !!! */
+ constraint_rows [nconstraint_rows]= row;
+ constraint_coeffs[nconstraint_rows]= coefficient;
+}
+
+static void avail_c(const Trade *t, IslandDirnTradeEnds *trades,
+ int price, const char *srcdst,
+ int islandid, sqlite3_stmt *ss_ite) {
+ /* find row number of trade availability constraint */
+ IslandTradeEnd *search;
+
+ for (search= *trades; search; search=search->next)
+ if (search->commodid==t->commodid && search->price==price)
+ goto found;
+ /* not found, add new row */
+
+ search= mmalloc(sizeof(*search));
+ search->commodid= t->commodid;
+ search->price= price;
+ search->next= *trades;
+ search->generation= 0;
+
+ SQL_MUST( sqlite3_bind_int(ss_ite, 1, islandid) );
+ SQL_MUST( sqlite3_bind_int(ss_ite, 2, t->commodid) );
+ SQL_MUST( sqlite3_bind_int(ss_ite, 3, price) );
+ assert(SQL_STEP(ss_ite));
+ search->qty= sqlite3_column_int(ss_ite, 0);
+ SQL_MUST( sqlite3_reset(ss_ite) );
+
+ *trades= search;
+
+ found:;
+ if (search->generation != generation) {
+ search->rownum= lpx_add_rows(lp, 1);
+ lpx_set_row_bnds(lp, search->rownum, LPX_UP, 0, search->qty);
+
+ if (DEBUGP(value)) {
+ char *name= masprintf("%s_commod%d_price%d",srcdst,t->commodid,price);
+ lpx_set_row_name(lp,search->rownum,name);
+ free(name);
+ }
+ search->generation= generation;
+ }
+
+ add_constraint(search->rownum, 1.0);
+}
+
+static int setup_leg_constraints(double max_thing, int legs, const char *wh) {
+ int leg, startrow;
+ if (max_thing < 0 || !legs) return -1;
+ startrow= lpx_add_rows(lp, legs);
+ for (leg=0; leg<nislands-1; leg++) {
+ int row= leg+startrow;
+ lpx_set_row_bnds(lp, row, LPX_UP, 0, max_thing);
+ if (DEBUGP(value)) {
+ char *name= masprintf("max_leg%d_%s",leg,wh);
+ lpx_set_row_name(lp,row,name);
+ free(name);
+ }
+ }
+ return startrow;
+}
+
+static void add_leg_c(int startrow, int leg, double value) {
+ if (startrow<=0) return;
+ assert(value > 0);
+ add_constraint(startrow+leg, value);
+}
+
static IslandPair *ipair_get(int si, int di) {
IslandPair *ip, **ipa;
}
if ((ip= ipa[di]))
return ip;
-
+
ipa[di]= ip= mmalloc(sizeof(*ip));
ip->ntrades= 0;
ip->trades= 0;
int inblock= TRADES_PER_BLOCK;
TradesBlock *block= 0;
- SQL_MUST( sqlite3_bind_int(ss_ipair, 1, si) );
- SQL_MUST( sqlite3_bind_int(ss_ipair, 2, di) );
+ debugf("VALUE ipair_get(%d,%d) running...\n", si,di);
+ SQL_MUST( sqlite3_bind_int(ss_ipair_dist, 1, si) );
+ SQL_MUST( sqlite3_bind_int(ss_ipair_dist, 2, di) );
+ assert(SQL_STEP(ss_ipair_dist));
+ int dist= sqlite3_column_int(ss_ipair_dist, 0);
+ ip->distance_loss_factor= pow(distance_loss_factor_per_league, dist);
+ sqlite3_reset(ss_ipair_dist);
+
+ SQL_MUST( sqlite3_bind_int(ss_ipair_trades, 1, si) );
+ SQL_MUST( sqlite3_bind_int(ss_ipair_trades, 2, di) );
- while (SQL_STEP(ss_ipair)) {
+ while (SQL_STEP(ss_ipair_trades)) {
if (inblock == TRADES_PER_BLOCK) {
block= mmalloc(sizeof(*block));
block->next= ip->trades;
}
int *irp, i;
for (i=0, irp=&block->t[inblock].commodid; i<5; i++, irp++)
- *irp= sqlite3_column_int(ss_ipair, i);
+ *irp= sqlite3_column_int(ss_ipair_trades, i);
ip->ntrades++;
inblock++;
}
if (inblock < TRADES_PER_BLOCK)
block->t[inblock].commodid= -1;
- sqlite3_reset(ss_ipair);
+ sqlite3_reset(ss_ipair_trades);
return ip;
}
void value_route(int nislands, const int *islands) {
int s,d;
-
+
+ /* We need to construct the LP problem. GLPK talks
+ * about rows and columns, which are numbered from 1.
+ *
+ * Each column is a `structural variable' ie one of the entries in
+ * the objective function. In our case the set of structural
+ * variable is, for each port, the set of Trades which collect at
+ * that island. (We use `port' to mean `specific visit to an
+ * island' so if an island appears more than once so do its trades.)
+ * We don't need to worry about crossing with all the possible
+ * delivery locations as we always deliver on the first port.
+ * We will call such a structural variable a Flow, for brevity.
+ *
+ * We iterate over the possible Flows adding them as columns as we
+ * go, and also adding their entries to the various constraints.
+ *
+ * Each row is an `auxiliary variable' ie one of the constraints.
+ * We have two kinds of constraint:
+ * - mass/volume/capital: one constraint for each sailed leg
+ * (unless relevant constraint is not satisfied)
+ * - quantity of commodity available for collection
+ * or delivery at particular price and island
+ * The former are numbered predictably: we have first all the mass
+ * limits, then all the volume limits, then all the capital limits
+ * (as applicable) - one for each leg, ie one for each entry
+ * in islands except the first.
+ *
+ * The latter are added as needed and the row numbers are stored in
+ * a data structure for later reuse.
+ */
+
+ assert(nislands >= 1);
+ assert(++generation);
+
+ int nites=0;
+ IslandTradeEnds ites[nislands], *iteps[nislands];
+
for (s=0; s<nislands; s++) {
- for (d=s; d<nislands; d++) {
- ipair_get(islands[s], islands[d]);
- }
+ IslandTradeEnds *ite;
+ int si= islands[s];
+ int i;
+ for (i=0, ite=ites; i<nites; i++, ite++)
+ if (ite->islandid==si)
+ goto found;
+ /* not found, add new */
+ assert(ite == &ites[nites]);
+ ite->islandid= si;
+ ite->collect= ite->deliver= 0;
+ nites++;
+ found:
+ iteps[s]= ite;
+ }
+
+ assert(!lp);
+ lp= lpx_create_prob();
+ lpx_set_obj_dir(lp, LPX_MAX);
+ if (DEBUGP(value)) {
+ lpx_set_prob_name(lp,(char*)"value_route");
+ lpx_set_obj_name(lp,(char*)"profit");
}
- //char *tail;
- //struct sqlite_vm *sth;
- //r= sqlite_compile(db, stmt, &tail, &sth,
+ int legs= nislands-1;
+ int mass_constraints= setup_leg_constraints(max_mass, legs, "mass");
+ int volu_constraints= setup_leg_constraints(max_volu, legs, "volu");
+ int capi_constraints= setup_leg_constraints(max_capi, legs, "capi");
+
+ double delay_slot_loss_factor= 1.0;
+ for (s=0;
+ s<nislands;
+ s++, delay_slot_loss_factor *= LOSS_FACTOR_PER_DELAY_SLOT) {
+ int si= islands[s];
+
+ for (d=s; d<nislands; d++) {
+ int di= islands[d];
+ int already_d;
+ for (already_d=s+1; already_d<d; already_d++)
+ if (islands[already_d] == di)
+ /* visited this island already since we left s, uninteresting */
+ goto next_d;
+
+ if (d>s && di==si)
+ /* route has returned to si, no need to think more about s */
+ goto next_s;
+
+ /*----- actually add these trades to the LP problem -----*/
+
+ IslandPair *ip= ipair_get(islands[s], islands[d]);
+ TradesBlock *block= ip->trades;
+ int tradestodo= ip->ntrades;
+ if (!tradestodo)
+ goto next_d;
+
+ int inblock= 0;
+ int col= lpx_add_cols(lp,ip->ntrades);
+
+ double loss_factor= delay_slot_loss_factor * ip->distance_loss_factor;
+
+ while (tradestodo-- >0) {
+ if (inblock >= TRADES_PER_BLOCK) {
+ block= block->next;
+ inblock= 0;
+ }
+ Trade *t= &block->t[inblock++];
+
+ debugf(" TRADE %d#%d..%d#%d %d %d-%d\n",
+ si,s, di,d, t->commodid, t->src_price, t->dst_price);
+
+ nconstraint_rows=0;
+
+ avail_c(t, &iteps[s]->collect, t->src_price,"src", si, ss_ite_sell);
+ avail_c(t, &iteps[d]->deliver, t->dst_price,"dst", di, ss_ite_buy);
+
+ int leg;
+ for (leg=s; leg<d; leg++) {
+ add_leg_c(mass_constraints, leg, commodstable[t->commodid].mass);
+ add_leg_c(volu_constraints, leg, commodstable[t->commodid].volu);
+ add_leg_c(capi_constraints, leg, t->src_price);
+ }
+
+ lpx_set_col_bnds(lp, col, LPX_LO, 0, 0);
+ lpx_set_obj_coef(lp, col,
+ (t->dst_price - t->src_price) * loss_factor);
+ lpx_set_mat_col(lp, col, nconstraint_rows,
+ constraint_rows, constraint_coeffs);
+ if (DEBUGP(value)) {
+ char *name= masprintf("trade_commod%d_port%d_at%d_port%d_at%d",
+ t->commodid, s, t->src_price, d, t->dst_price);
+ lpx_set_col_name(lp, col, name);
+ free(name);
+ }
+ } /* while (tradestodo-- >0) */
+
+ /*----- that's done adding these trades to the LP problem -----*/
+
+ next_d:;
+ } /* for (d) */
+ next_s:;
+ } /* for (s) */
+
+ lpx_delete_prob(lp);
+ lp= 0;
}
void setup_value(void) {
sqlite3_stmt *sst;
+ int i;
- SQL_MUST( sqlite3_prepare(db, "SELECT max(islandid) FROM islands",
- -1,&sst,0) );
- assert( SQL_STEP(sst) );
- nislands= sqlite3_column_int(sst,0);
- nislands++;
- sqlite3_finalize(sst);
+ nislands= sql_single_int("SELECT max(islandid) FROM islands") + 1;
debugf("VALUE nislands=%d\n",nislands);
+ commodstablesz= sql_single_int("SELECT max(commodid) FROM commods") + 1;
+ commodstable= mmalloc(sizeof(*commodstable)*commodstablesz);
+ for (i=0; i<commodstablesz; i++)
+ commodstable[i].mass= commodstable[i].volu= -1;
+
SQL_MUST( sqlite3_prepare(db,
- "SELECT\n"
+ "SELECT commodid,unitmass,unitvolume FROM commods", -1,&sst,0) );
+ while (SQL_STEP(sst)) {
+ int id= sqlite3_column_int(sst,0);
+ assert(id>=0 && id<commodstablesz);
+ commodstable[id].mass= sqlite3_column_int(sst,1);
+ commodstable[id].volu= sqlite3_column_int(sst,2);
+ }
+ sqlite3_finalize(sst);
+
+ SQL_MUST( sqlite3_prepare(db,
+ " SELECT dist from dists where aiid=? and biid=?",
+ -1, &ss_ipair_dist, 0) );
+
+ SQL_MUST( sqlite3_prepare(db,
+ "SELECT DISTINCT\n"
" sell.commodid commodid,\n"
" sell.price src_price,\n"
- " sum(sell.qty) src_qty,\n"
- " buy.price dst_price,\n"
- " sum(buy.qty) dst_qty\n"
+ " buy.price dst_price\n"
" FROM sell JOIN buy\n"
" ON sell.commodid = buy.commodid\n"
" AND buy.price > sell.price\n"
" WHERE sell.islandid=?\n"
- " AND buy.islandid=?\n"
- " GROUP BY sell.commodid, sell.price, buy.price",
- -1, &ss_ipair, 0) );
+ " AND buy.islandid=?",
+ -1, &ss_ipair_trades, 0) );
+
+#define BS(bs) \
+ SQL_MUST( sqlite3_prepare(db, \
+ "SELECT\n" \
+ " sum(qty)\n" \
+ " FROM " #bs "\n" \
+ " WHERE islandid=?\n" \
+ " AND commodid=?\n" \
+ " AND price=?", \
+ -1, &ss_ite_##bs, 0) );
+ BS(buy)
+ BS(sell)
+#undef BS
ipairs= mcalloc(sizeof(*ipairs) * nislands);
}