X-Git-Url: http://git.scottworley.com/planeteer/blobdiff_plain/fcdc120bb1d01853dc3402284c2e33537cac14b4..HEAD:/planeteer.go

diff --git a/planeteer.go b/planeteer.go
index 060456d..cf00d56 100644
--- a/planeteer.go
+++ b/planeteer.go
@@ -3,8 +3,7 @@
  *
  * This program is free software: you can redistribute it and/or modify
  * it under the terms of the GNU Affero General Public License as
- * published by the Free Software Foundation, either version 3 of the
- * License, or (at your option) any later version.
+ * published by the Free Software Foundation, version 3.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
@@ -19,8 +18,9 @@ package main
 
 import "flag"
 import "fmt"
-import "json"
+import "encoding/json"
 import "os"
+import "runtime/pprof"
 import "strings"
 
 var funds = flag.Int("funds", 0,
@@ -42,6 +42,8 @@ var fuel = flag.Int("fuel", 16, "Hyper Jump power left")
 
 var hold = flag.Int("hold", 300, "Size of your cargo hold")
 
+var start_hold = flag.String("start_hold", "", "Start with a hold full of cargo")
+
 var start_edens = flag.Int("start_edens", 0,
 	"How many Eden Warp Units are you starting with?")
 
@@ -62,29 +64,52 @@ var battery_price = flag.Int("battery_price", 0, "Today's Shield Battery price")
 var visit_string = flag.String("visit", "",
 	"A comma-separated list of planets to make sure to visit")
 
+var tomorrow_weight = flag.Float64("tomorrow_weight", 1.0,
+	"Weight for the expected value of tomorrow's trading.  0.0 - 1.0")
+
+var extra_stats = flag.Bool("extra_stats", true,
+	"Show additional information of possible interest")
+
+var cpuprofile = flag.String("cpuprofile", "", "write cpu profile to file")
+
+var visit_cache []string
+
 func visit() []string {
-	if *visit_string == "" {
-		return nil
+	if visit_cache == nil {
+		if *visit_string == "" {
+			return nil
+		}
+		visit_cache = strings.Split(*visit_string, ",")
 	}
-	return strings.Split(*visit_string, ",")
+	return visit_cache
 }
 
+var flight_plan_cache []string
+
 func flight_plan() []string {
-	if *flight_plan_string == "" {
-		return nil
+	if flight_plan_cache == nil {
+		if *flight_plan_string == "" {
+			return nil
+		}
+		flight_plan_cache = strings.Split(*flight_plan_string, ",")
 	}
-	return strings.Split(*flight_plan_string, ",")
+	return flight_plan_cache
 }
 
+var end_cache map[string]bool
+
 func end() map[string]bool {
-	if *end_string == "" {
-		return nil
-	}
-	m := make(map[string]bool)
-	for _, p := range strings.Split(*end_string, ",") {
-		m[p] = true
+	if end_cache == nil {
+		if *end_string == "" {
+			return nil
+		}
+		m := make(map[string]bool)
+		for _, p := range strings.Split(*end_string, ",") {
+			m[p] = true
+		}
+		end_cache = m
 	}
-	return m
+	return end_cache
 }
 
 type Commodity struct {
@@ -93,7 +118,9 @@ type Commodity struct {
 	Limit     int
 }
 type Planet struct {
-	BeaconOn bool
+	BeaconOn      bool
+	Private       bool
+	TomorrowValue int
 	/* Use relative prices rather than absolute prices because you
 	   can get relative prices without traveling to each planet. */
 	RelativePrices map[string]int
@@ -105,17 +132,26 @@ type planet_data struct {
 	i2p, i2c    []string       // Generated; not read from file
 }
 
-func ReadData() (data planet_data) {
-	f, err := os.Open(*planet_data_file)
+func json_slurp(filename string, receptacle interface{}) error {
+	f, err := os.Open(filename)
 	if err != nil {
-		panic(err)
+		return err
 	}
 	defer f.Close()
-	err = json.NewDecoder(f).Decode(&data)
+	err = json.NewDecoder(f).Decode(receptacle)
+	if err != nil {
+		return err
+	}
+	return nil
+}
+
+func ReadData() planet_data {
+	var data planet_data
+	err := json_slurp(*planet_data_file, &data)
 	if err != nil {
 		panic(err)
 	}
-	return
+	return data
 }
 
 /* This program operates by filling in a state table representing the best
@@ -142,34 +178,37 @@ func ReadData() (data planet_data) {
  * independent -- some combinations are illegal and not used.  They are
  * handled as three dimensions rather than one for simplicity.  Placing
  * these dimensions first causes the unused cells in the table to be
- * grouped together in large blocks.  This keeps them from polluting
- * cache lines, and if they are large enough, prevent the memory manager
- * from allocating pages for these areas at all.
+ * grouped together in large blocks.  This keeps the unused cells from
+ * polluting cache lines, and if the spans of unused cells are large
+ * enough, allows the memory manager to swap out entire pages.
  *
  * If the table gets too big to fit in RAM:
  *    * Combine the Edens, Cloaks, and UnusedCargo dimensions.  Of the
  *      24 combinations, only 15 are legal: a 38% savings.
- *    * Reduce the size of the Fuel dimension to 3.  We only ever look
- *      backwards 2 units, so just rotate the logical values through
- *      the same 3 physical addresses.  This is good for an 82% savings.
+ *    * Reduce the size of the Fuel dimension to 3.  Explicit iteration
+ *      only ever needs to look backwards 2 units, so the logical values
+ *      can rotate through the same 3 physical addresses.  This would be
+ *      good for an 82% savings.  Note that explicit iteration went away
+ *      in 0372f045.
  *    * Reduce the size of the Edens dimension from 3 to 2, for the
  *      same reasons as Fuel above.  33% savings.
  *    * Buy more ram.  (Just sayin'.  It's cheaper than you think.)
- *      
+ *
  */
 
 // The official list of dimensions:
 const (
-	// Name                Num  Size  Description
-	Edens        = iota //   1     3  # of Eden warp units (0 - 2 typically)
-	Cloaks              //   2     2  # of Devices of Cloaking (0 or 1)
-	UnusedCargo         //   3     4  # of unused cargo spaces (0 - 3 typically)
-	Fuel                //   4    17  Hyper jump power left (0 - 16)
-	Location            //   5    26  Location (which planet)
-	Hold                //   6    15  Cargo bay contents (a *Commodity or nil)
-	BuyFighters         //   7     2  Errand: Buy fighter drones
-	BuyShields          //   8     2  Errand: Buy shield batteries
-	Visit               //   9  2**N  Visit: Stop by these N planets in the route
+	// Name                Num   Size  Description
+	Edens       = iota //   1      3  # of Eden warp units (0 - 2 typically)
+	Cloaks             //   2    1-2  # of Devices of Cloaking (0 or 1)
+	UnusedCargo        //   3      4  # of unused cargo spaces (0 - 3 typically)
+	Fuel               //   4     17  Hyper jump power left (0 - 16)
+	Location           //   5     26  Location (which planet)
+	Hold               //   6     15  Cargo bay contents (a *Commodity or nil)
+	Traded             //   7      2  Traded yet?
+	BuyFighters        //   8    1-2  Errand: Buy fighter drones
+	BuyShields         //   9    1-2  Errand: Buy shield batteries
+	Visit              //  10 1-2**N  Visit: Stop by these N planets in the route
 
 	NumDimensions
 )
@@ -181,19 +220,20 @@ func bint(b bool) int {
 	return 0
 }
 
-func DimensionSizes(data planet_data) []int {
+func DimensionSizes(data planet_data) LogicalIndex {
 	eden_capacity := data.Commodities["Eden Warp Units"].Limit
 	if *start_edens > eden_capacity {
 		eden_capacity = *start_edens
 	}
 	cloak_capacity := bint(*cloak)
-	dims := make([]int, NumDimensions)
+	dims := make(LogicalIndex, NumDimensions)
 	dims[Edens] = eden_capacity + 1
 	dims[Cloaks] = cloak_capacity + 1
 	dims[UnusedCargo] = eden_capacity + cloak_capacity + 1
 	dims[Fuel] = *fuel + 1
 	dims[Location] = len(data.Planets)
 	dims[Hold] = len(data.Commodities) + 1
+	dims[Traded] = 2
 	dims[BuyFighters] = bint(*drones > 0) + 1
 	dims[BuyShields] = bint(*batteries > 0) + 1
 	dims[Visit] = 1 << uint(len(visit()))
@@ -207,7 +247,11 @@ func DimensionSizes(data planet_data) []int {
 	return dims
 }
 
-func StateTableSize(dims []int) int {
+type Value int32
+type PhysicalIndex int32
+type LogicalIndex []int
+
+func StateTableSize(dims LogicalIndex) int {
 	product := 1
 	for _, size := range dims {
 		product *= size
@@ -216,178 +260,220 @@ func StateTableSize(dims []int) int {
 }
 
 type State struct {
-	value, from int
+	value Value
+	from  PhysicalIndex
 }
 
-func EncodeIndex(dims, addr []int) int {
+const (
+	FROM_ROOT = -2147483647 + iota
+	FROM_UNINITIALIZED
+	VALUE_UNINITIALIZED
+	VALUE_BEING_EVALUATED
+	VALUE_RUBISH
+)
+
+func EncodeIndex(dims, addr LogicalIndex) PhysicalIndex {
 	index := addr[0]
 	if addr[0] > dims[0] {
 		panic(0)
 	}
 	for i := 1; i < NumDimensions; i++ {
-		if addr[i] < 0 || addr[i] > dims[i] {
+		if addr[i] < 0 || addr[i] >= dims[i] {
 			panic(i)
 		}
 		index = index*dims[i] + addr[i]
 	}
-	return index
+	return PhysicalIndex(index)
 }
 
-func DecodeIndex(dims []int, index int) []int {
-	addr := make([]int, NumDimensions)
+func DecodeIndex(dims LogicalIndex, index PhysicalIndex) LogicalIndex {
+	scratch := int(index)
+	addr := make(LogicalIndex, NumDimensions)
 	for i := NumDimensions - 1; i > 0; i-- {
-		addr[i] = index % dims[i]
-		index /= dims[i]
+		addr[i] = scratch % dims[i]
+		scratch /= dims[i]
 	}
-	addr[0] = index
+	addr[0] = scratch
 	return addr
 }
 
-func InitializeStateTable(data planet_data, dims []int) []State {
+func PlanetIndex(data planet_data, name string) int {
+	index, ok := data.p2i[name]
+	if !ok {
+		panic("Unknown planet " + name)
+	}
+	return index
+}
+
+func CommodityIndex(data planet_data, name string) int {
+	index, ok := data.c2i[name]
+	if !ok {
+		panic("Unknown commodity " + name)
+	}
+	return index
+}
+
+func CreateStateTable(data planet_data, dims LogicalIndex) []State {
 	table := make([]State, StateTableSize(dims))
+	for i := range table {
+		table[i].value = VALUE_UNINITIALIZED
+		table[i].from = FROM_UNINITIALIZED
+	}
 
-	addr := make([]int, NumDimensions)
+	addr := make(LogicalIndex, NumDimensions)
 	addr[Fuel] = *fuel
 	addr[Edens] = *start_edens
-	addr[Location] = data.p2i[*start]
-	table[EncodeIndex(dims, addr)].value = *funds
+	addr[Location] = PlanetIndex(data, *start)
+	if *start_hold != "" {
+		addr[Hold] = CommodityIndex(data, *start_hold)
+	}
+	start_index := EncodeIndex(dims, addr)
+	table[start_index].value = Value(*funds)
+	table[start_index].from = FROM_ROOT
 
 	return table
 }
 
-/* These four fill procedures fill in the cell at address addr by
- * looking at all the possible ways to reach this cell and selecting
- * the best one.
- *
- * The other obvious implementation choice is to do this the other way
- * around -- for each cell, conditionally overwrite all the other cells
- * that are reachable *from* the considered cell.  We choose gathering
- * reads over scattering writes to avoid having to take a bunch of locks.
- */
+/* CellValue fills in the one cell at address addr by looking at all
+ * the possible ways to reach this cell and selecting the best one. */
 
-func UpdateCell(table []State, here, there, value_difference int) {
-	possible_value := table[there].value + value_difference
-	if table[there].value > 0 && possible_value > table[here].value {
-		table[here].value = possible_value
-		table[here].from = there
+func Consider(data planet_data, dims LogicalIndex, table []State, there LogicalIndex, value_difference int, best_value *Value, best_source LogicalIndex) {
+	there_value := CellValue(data, dims, table, there)
+	if value_difference < 0 && Value(-value_difference) > there_value {
+		/* Can't afford this transition */
+		return
+	}
+	possible_value := there_value + Value(value_difference)
+	if possible_value > *best_value {
+		*best_value = possible_value
+		copy(best_source, there)
 	}
 }
 
-func FillCellByArriving(data planet_data, dims []int, table []State, addr []int) {
+var cell_filled_count int
+
+func CellValue(data planet_data, dims LogicalIndex, table []State, addr LogicalIndex) Value {
 	my_index := EncodeIndex(dims, addr)
-	other := make([]int, NumDimensions)
+	if table[my_index].value == VALUE_BEING_EVALUATED {
+		panic("Circular dependency")
+	}
+	if table[my_index].value != VALUE_UNINITIALIZED {
+		return table[my_index].value
+	}
+	table[my_index].value = VALUE_BEING_EVALUATED
+
+	best_value := Value(VALUE_RUBISH)
+	best_source := make(LogicalIndex, NumDimensions)
+	other := make(LogicalIndex, NumDimensions)
 	copy(other, addr)
+	planet := data.i2p[addr[Location]]
 
-	/* Travel here via a 2-fuel unit jump */
-	if addr[Fuel]+2 < dims[Fuel] {
-		other[Fuel] = addr[Fuel] + 2
-		for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
-			if data.Planets[data.i2p[addr[Location]]].BeaconOn {
-				UpdateCell(table, my_index, EncodeIndex(dims, other), 0)
+	/* Travel here */
+	if addr[Traded] == 0 { /* Can't have traded immediately after traveling. */
+		other[Traded] = 1 /* Travel from states that have done trading. */
+
+		/* Travel here via a 2-fuel unit jump */
+		if data.Planets[data.i2p[addr[Location]]].BeaconOn && addr[Fuel]+2 < dims[Fuel] {
+			other[Fuel] = addr[Fuel] + 2
+			hole_index := (dims[Fuel] - 1) - (addr[Fuel] + 2)
+			if hole_index >= len(flight_plan()) || addr[Location] != PlanetIndex(data, flight_plan()[hole_index]) {
+				for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
+					Consider(data, dims, table, other, 0, &best_value, best_source)
+				}
 			}
+			other[Location] = addr[Location]
+			other[Fuel] = addr[Fuel]
 		}
-		other[Location] = addr[Location]
-		other[Fuel] = addr[Fuel]
-	}
 
-	/* Travel here via a hyper hole */
-	if addr[Fuel]+1 < dims[Fuel] {
-		hole_index := (dims[Fuel] - 1) - (addr[Fuel] + 1)
-		if hole_index < len(flight_plan()) && addr[Location] == data.p2i[flight_plan()[hole_index]] {
-			other[Fuel] = addr[Fuel] + 1
-			for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
-				UpdateCell(table, my_index, EncodeIndex(dims, other), 0)
+		/* Travel here via a 1-fuel unit jump (a hyper hole) */
+		if addr[Fuel]+1 < dims[Fuel] {
+			hole_index := (dims[Fuel] - 1) - (addr[Fuel] + 1)
+			if hole_index < len(flight_plan()) && addr[Location] == PlanetIndex(data, flight_plan()[hole_index]) {
+				other[Fuel] = addr[Fuel] + 1
+				for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
+					Consider(data, dims, table, other, 0, &best_value, best_source)
+				}
+				other[Location] = addr[Location]
+				other[Fuel] = addr[Fuel]
 			}
-			other[Location] = addr[Location]
-			other[Fuel] = addr[Fuel]
 		}
-	}
 
-	/* Travel here via Eden Warp Unit */
-	if addr[Edens]+1 < dims[Edens] && addr[UnusedCargo] > 1 {
-		_, available := data.Planets[data.i2p[addr[Location]]].RelativePrices["Eden Warp Units"]
-		if !available {
-			other[Edens] = addr[Edens] + 1
-			other[UnusedCargo] = addr[UnusedCargo] - 1
-			for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
-				UpdateCell(table, my_index, EncodeIndex(dims, other), 0)
+		/* Travel here via Eden Warp Unit */
+		if addr[Edens]+1 < dims[Edens] && (addr[Hold] == 0 || addr[UnusedCargo] > 0) {
+			_, available := data.Planets[data.i2p[addr[Location]]].RelativePrices["Eden Warp Units"]
+			if !available {
+				other[Edens] = addr[Edens] + 1
+				if other[Hold] != 0 {
+					other[UnusedCargo] = addr[UnusedCargo] - 1
+				}
+				for other[Location] = 0; other[Location] < dims[Location]; other[Location]++ {
+					Consider(data, dims, table, other, 0, &best_value, best_source)
+				}
+				other[Location] = addr[Location]
+				other[UnusedCargo] = addr[UnusedCargo]
+				other[Edens] = addr[Edens]
 			}
-			other[Location] = addr[Location]
-			other[UnusedCargo] = addr[UnusedCargo]
-			other[Edens] = addr[Edens]
 		}
+		other[Traded] = addr[Traded]
 	}
-}
 
-func FillCellBySelling(data planet_data, dims []int, table []State, addr []int) {
-	if addr[Hold] > 0 {
-		// Can't sell and still have cargo
-		return
-	}
-	if addr[UnusedCargo] > 0 {
-		// Can't sell everything and still have 'unused' holds
-		return
-	}
-	my_index := EncodeIndex(dims, addr)
-	other := make([]int, NumDimensions)
-	copy(other, addr)
-	planet := data.i2p[addr[Location]]
-	for other[Hold] = 0; other[Hold] < dims[Hold]; other[Hold]++ {
-		commodity := data.i2c[other[Hold]]
-		if !data.Commodities[commodity].CanSell {
-			// TODO: Dump cargo
-			continue
-		}
-		relative_price, available := data.Planets[planet].RelativePrices[commodity]
-		if !available {
-			continue
-		}
-		base_price := data.Commodities[commodity].BasePrice
-		absolute_price := float64(base_price) * float64(relative_price) / 100.0
-		sell_price := int(absolute_price * 0.9)
+	/* Trade */
+	if addr[Traded] == 1 {
+		other[Traded] = 0
 
-		for other[UnusedCargo] = 0; other[UnusedCargo] < dims[UnusedCargo]; other[UnusedCargo]++ {
+		/* Consider not trading */
+		Consider(data, dims, table, other, 0, &best_value, best_source)
 
-			quantity := *hold - (other[UnusedCargo] + other[Cloaks] + other[Edens])
-			sale_value := quantity * sell_price
-			UpdateCell(table, my_index, EncodeIndex(dims, other), sale_value)
-		}
-	}
-	other[UnusedCargo] = addr[UnusedCargo]
-}
+		if !data.Planets[data.i2p[addr[Location]]].Private {
 
-func FillCellByBuying(data planet_data, dims []int, table []State, addr []int) {
-	if addr[Hold] == 0 {
-		// Can't buy and then have nothing
-		return
-	}
-	my_index := EncodeIndex(dims, addr)
-	other := make([]int, NumDimensions)
-	copy(other, addr)
-	planet := data.i2p[addr[Location]]
-	commodity := data.i2c[addr[Hold]]
-	if !data.Commodities[commodity].CanSell {
-		return
-	}
-	relative_price, available := data.Planets[planet].RelativePrices[commodity]
-	if !available {
-		return
-	}
-	base_price := data.Commodities[commodity].BasePrice
-	absolute_price := int(float64(base_price) * float64(relative_price) / 100.0)
-	quantity := *hold - (addr[UnusedCargo] + addr[Cloaks] + addr[Edens])
-	total_price := quantity * absolute_price
-	other[Hold] = 0
-	other[UnusedCargo] = 0
-	UpdateCell(table, my_index, EncodeIndex(dims, other), -total_price)
-	other[UnusedCargo] = addr[UnusedCargo]
-	other[Hold] = addr[Hold]
-}
+			/* Sell */
+			if addr[Hold] == 0 && addr[UnusedCargo] == 0 {
+				for other[Hold] = 0; other[Hold] < dims[Hold]; other[Hold]++ {
+					commodity := data.i2c[other[Hold]]
+					if !data.Commodities[commodity].CanSell {
+						continue
+					}
+					relative_price, available := data.Planets[planet].RelativePrices[commodity]
+					if !available {
+						// TODO: Dump cargo
+						continue
+					}
+					base_price := data.Commodities[commodity].BasePrice
+					absolute_price := float64(base_price) * float64(relative_price) / 100.0
+					sell_price := int(absolute_price * 0.9)
+
+					for other[UnusedCargo] = 0; other[UnusedCargo] < dims[UnusedCargo]; other[UnusedCargo]++ {
+						quantity := *hold - (other[UnusedCargo] + other[Cloaks] + other[Edens])
+						sale_value := quantity * sell_price
+						Consider(data, dims, table, other, sale_value, &best_value, best_source)
+					}
+				}
+				other[UnusedCargo] = addr[UnusedCargo]
+				other[Hold] = addr[Hold]
+			}
 
-func FillCellByMisc(data planet_data, dims []int, table []State, addr []int) {
-	my_index := EncodeIndex(dims, addr)
-	other := make([]int, NumDimensions)
-	copy(other, addr)
+			/* Buy */
+			other[Traded] = addr[Traded] /* Buy after selling */
+			if addr[Hold] != 0 {
+				commodity := data.i2c[addr[Hold]]
+				if data.Commodities[commodity].CanSell {
+					relative_price, available := data.Planets[planet].RelativePrices[commodity]
+					if available {
+						base_price := data.Commodities[commodity].BasePrice
+						absolute_price := int(float64(base_price) * float64(relative_price) / 100.0)
+						quantity := *hold - (addr[UnusedCargo] + addr[Cloaks] + addr[Edens])
+						total_price := quantity * absolute_price
+						other[Hold] = 0
+						other[UnusedCargo] = 0
+						Consider(data, dims, table, other, -total_price, &best_value, best_source)
+						other[UnusedCargo] = addr[UnusedCargo]
+						other[Hold] = addr[Hold]
+					}
+				}
+			}
+		}
+		other[Traded] = addr[Traded]
+	}
 
 	/* Buy a Device of Cloaking */
 	if addr[Cloaks] == 1 && addr[UnusedCargo] < dims[UnusedCargo]-1 {
@@ -398,21 +484,19 @@ func FillCellByMisc(data planet_data, dims []int, table []State, addr []int) {
 			if other[Hold] != 0 {
 				other[UnusedCargo] = addr[UnusedCargo] + 1
 			}
-			UpdateCell(table, my_index, EncodeIndex(dims, other), -absolute_price)
+			Consider(data, dims, table, other, -absolute_price, &best_value, best_source)
 			other[UnusedCargo] = addr[UnusedCargo]
 			other[Cloaks] = addr[Cloaks]
 		}
 	}
 
-	/* Silly: Dump a Device of Cloaking */
-
 	/* Buy Fighter Drones */
 	if addr[BuyFighters] == 1 {
 		relative_price, available := data.Planets[data.i2p[addr[Location]]].RelativePrices["Fighter Drones"]
 		if available {
 			absolute_price := int(float64(data.Commodities["Fighter Drones"].BasePrice) * float64(relative_price) / 100.0)
 			other[BuyFighters] = 0
-			UpdateCell(table, my_index, EncodeIndex(dims, other), -absolute_price * *drones)
+			Consider(data, dims, table, other, -absolute_price**drones, &best_value, best_source)
 			other[BuyFighters] = addr[BuyFighters]
 		}
 	}
@@ -423,19 +507,19 @@ func FillCellByMisc(data planet_data, dims []int, table []State, addr []int) {
 		if available {
 			absolute_price := int(float64(data.Commodities["Shield Batterys"].BasePrice) * float64(relative_price) / 100.0)
 			other[BuyShields] = 0
-			UpdateCell(table, my_index, EncodeIndex(dims, other), -absolute_price * *batteries)
+			Consider(data, dims, table, other, -absolute_price**batteries, &best_value, best_source)
 			other[BuyShields] = addr[BuyShields]
 		}
 	}
 
 	/* Visit this planet */
-
-}
-
-func FillCellByBuyingEdens(data planet_data, dims []int, table []State, addr []int) {
-	my_index := EncodeIndex(dims, addr)
-	other := make([]int, NumDimensions)
-	copy(other, addr)
+	for i := uint(0); i < uint(len(visit())); i++ {
+		if addr[Visit]&(1<<i) != 0 && visit()[i] == data.i2p[addr[Location]] {
+			other[Visit] = addr[Visit] & ^(1 << i)
+			Consider(data, dims, table, other, 0, &best_value, best_source)
+		}
+	}
+	other[Visit] = addr[Visit]
 
 	/* Buy Eden warp units */
 	eden_limit := data.Commodities["Eden Warp Units"].Limit
@@ -449,124 +533,84 @@ func FillCellByBuyingEdens(data planet_data, dims []int, table []State, addr []i
 					other[UnusedCargo] = addr[UnusedCargo] + quantity
 				}
 				if other[UnusedCargo] < dims[UnusedCargo] {
-					UpdateCell(table, my_index, EncodeIndex(dims, other), -absolute_price * quantity)
+					Consider(data, dims, table, other, -absolute_price*quantity, &best_value, best_source)
 				}
 			}
 			other[Edens] = addr[Edens]
 			other[UnusedCargo] = addr[UnusedCargo]
 		}
 	}
-}
 
-func FillStateTable2Iteration(data planet_data, dims []int, table []State,
-addr []int, f func(planet_data, []int, []State, []int)) {
-	/* TODO: Justify the safety of the combination of this dimension
-	 * iteration and the various phases f.  */
-	for addr[Hold] = 0; addr[Hold] < dims[Hold]; addr[Hold]++ {
-		for addr[Cloaks] = 0; addr[Cloaks] < dims[Cloaks]; addr[Cloaks]++ {
-			for addr[UnusedCargo] = 0; addr[UnusedCargo] < dims[UnusedCargo]; addr[UnusedCargo]++ {
-				for addr[BuyFighters] = 0; addr[BuyFighters] < dims[BuyFighters]; addr[BuyFighters]++ {
-					for addr[BuyShields] = 0; addr[BuyShields] < dims[BuyShields]; addr[BuyShields]++ {
-						for addr[Visit] = 0; addr[Visit] < dims[Visit]; addr[Visit]++ {
-							f(data, dims, table, addr)
-						}
-					}
-				}
-			}
+	// Check that we didn't lose track of any temporary modifications to other.
+	for i := 0; i < NumDimensions; i++ {
+		if addr[i] != other[i] {
+			panic(i)
 		}
 	}
-}
 
-func FillStateTable2(data planet_data, dims []int, table []State,
-addr []int, barrier chan<- bool) {
-	FillStateTable2Iteration(data, dims, table, addr, FillCellByArriving)
-	FillStateTable2Iteration(data, dims, table, addr, FillCellBySelling)
-	FillStateTable2Iteration(data, dims, table, addr, FillCellByBuying)
-	FillStateTable2Iteration(data, dims, table, addr, FillCellByMisc)
-	FillStateTable2Iteration(data, dims, table, addr, FillCellByBuyingEdens)
-	if barrier != nil {
-		barrier <- true
+	// Sanity check: This cell was in state BEING_EVALUATED
+	// the whole time that it was being evaluated.
+	if table[my_index].value != VALUE_BEING_EVALUATED {
+		panic(my_index)
 	}
-}
 
-/* Filling the state table is a set of nested for loops NumDimensions deep.
- * We split this into two procedures: 1 and 2.  #1 is the outer, slowest-
- * changing indexes.  #1 fires off many calls to #2 that run in parallel.
- * The order of the nesting of the dimensions, the order of iteration within
- * each dimension, and where the 1 / 2 split is placed are carefully chosen 
- * to make this arrangement safe.
- *
- * Outermost two layers: Go from high-energy states (lots of fuel, edens) to
- * low-energy state.  These must be processed sequentially and in this order
- * because you travel through high-energy states to get to the low-energy
- * states.
- *
- * Third layer: Planet.  This is a good layer to parallelize on.  There's
- * high enough cardinality that we don't have to mess with parallelizing
- * multiple layers for good utilization (on 2011 machines).  Each thread
- * works on one planet's states and need not synchronize with peer threads.
- */
-func FillStateTable1(data planet_data, dims []int, table []State) {
-	barrier := make(chan bool, len(data.Planets))
-	eden_capacity := data.Commodities["Eden Warp Units"].Limit
-	work_units := (float64(*fuel) + 1) * (float64(eden_capacity) + 1)
-	work_done := 0.0
-	for fuel_remaining := *fuel; fuel_remaining >= 0; fuel_remaining-- {
-		/* Make an Eden-buying pass (Eden vendors' energy gradient
-		 * along the Edens dimension runs backwards) */
-		for edens_remaining := 0; edens_remaining <= eden_capacity; edens_remaining++ {
-			for planet := range data.Planets {
-				if _, available := data.Planets[planet].RelativePrices["Eden Warp Units"]; available {
-					addr := make([]int, len(dims))
-					addr[Edens] = edens_remaining
-					addr[Fuel] = fuel_remaining
-					addr[Location] = data.p2i[planet]
-					FillStateTable2(data, dims, table, addr, nil)
-				}
-			}
-		}
-		for edens_remaining := eden_capacity; edens_remaining >= 0; edens_remaining-- {
-			/* Do the brunt of the work */
-			for planet := range data.Planets {
-				addr := make([]int, len(dims))
-				addr[Edens] = edens_remaining
-				addr[Fuel] = fuel_remaining
-				addr[Location] = data.p2i[planet]
-				go FillStateTable2(data, dims, table, addr, barrier)
-			}
-			for _ = range data.Planets {
-				<-barrier
-			}
-			work_done++
-			print(fmt.Sprintf("\r%3.0f%%", 100*work_done/work_units))
-		}
+	// Record our findings
+	table[my_index].value = best_value
+	table[my_index].from = EncodeIndex(dims, best_source)
+
+	// UI: Progress bar
+	cell_filled_count++
+	if cell_filled_count&0xfff == 0 {
+		print(fmt.Sprintf("\r%3.1f%%", 100*float64(cell_filled_count)/float64(StateTableSize(dims))))
 	}
-	print("\n")
+
+	return table[my_index].value
 }
 
-func FindBestState(data planet_data, dims []int, table []State) int {
-	addr := make([]int, NumDimensions)
+func FinalState(dims LogicalIndex) LogicalIndex {
+	addr := make(LogicalIndex, NumDimensions)
 	addr[Edens] = *end_edens
 	addr[Cloaks] = dims[Cloaks] - 1
 	addr[BuyFighters] = dims[BuyFighters] - 1
 	addr[BuyShields] = dims[BuyShields] - 1
 	addr[Visit] = dims[Visit] - 1
-	// Fuel, Hold, UnusedCargo left at 0
-	max_index := -1
-	max_value := 0
-	for addr[Location] = 0; addr[Location] < dims[Location]; addr[Location]++ {
-		if len(end()) == 0 || end()[data.i2p[addr[Location]]] {
-			index := EncodeIndex(dims, addr)
-			if table[index].value > max_value {
-				max_value = table[index].value
-				max_index = index
+	addr[Traded] = 1
+	addr[Hold] = 0
+	addr[UnusedCargo] = 0
+	// Fuel and Location are determined by FindBestState
+	return addr
+}
+
+func FindBestState(data planet_data, dims LogicalIndex, table []State, addr LogicalIndex) PhysicalIndex {
+	max_index := PhysicalIndex(-1)
+	max_value := 0.0
+	max_fuel := 1
+	if *fuel == 0 {
+		max_fuel = 0
+	}
+	for addr[Fuel] = 0; addr[Fuel] <= max_fuel; addr[Fuel]++ {
+		for addr[Location] = 0; addr[Location] < dims[Location]; addr[Location]++ {
+			planet := data.i2p[addr[Location]]
+			if len(end()) == 0 || end()[planet] {
+				index := EncodeIndex(dims, addr)
+				today_value := CellValue(data, dims, table, addr)
+				tomorrow_value := *tomorrow_weight * float64(*hold+data.Planets[planet].TomorrowValue)
+				value := float64(today_value) + tomorrow_value
+				if value > max_value {
+					max_value = value
+					max_index = index
+				}
 			}
 		}
 	}
 	return max_index
 }
 
-func Commas(n int) (s string) {
+func Commas(n Value) string {
+	var s string
+	if n < 0 {
+		panic(n)
+	}
 	r := n % 1000
 	n /= 1000
 	for n > 0 {
@@ -575,11 +619,82 @@ func Commas(n int) (s string) {
 		n /= 1000
 	}
 	s = fmt.Sprint(r) + s
-	return
+	return s
+}
+
+func FighterAndShieldCost(data planet_data, dims LogicalIndex, table []State, best PhysicalIndex) {
+	if *drones == 0 && *batteries == 0 {
+		return
+	}
+	fmt.Println()
+	if *drones > 0 {
+		final_state := FinalState(dims)
+		final_state[BuyFighters] = 0
+		alt_best := FindBestState(data, dims, table, final_state)
+		cost := table[alt_best].value - table[best].value
+		fmt.Printf("\rDrones were %.2f each\n", float64(cost)/float64(*drones))
+	}
+	if *batteries > 0 {
+		final_state := FinalState(dims)
+		final_state[BuyShields] = 0
+		alt_best := FindBestState(data, dims, table, final_state)
+		cost := table[alt_best].value - table[best].value
+		fmt.Printf("\rBatteries were %.2f each\n", float64(cost)/float64(*batteries))
+	}
+}
+
+func EndEdensCost(data planet_data, dims LogicalIndex, table []State, best PhysicalIndex) {
+	if *end_edens == 0 {
+		return
+	}
+	fmt.Println()
+	final_state := FinalState(dims)
+	for extra_edens := 1; extra_edens <= *end_edens; extra_edens++ {
+		final_state[Edens] = *end_edens - extra_edens
+		alt_best := FindBestState(data, dims, table, final_state)
+		extra_funds := table[alt_best].value - table[best].value
+		fmt.Println("\rUse", extra_edens, "extra edens, make an extra",
+			Commas(extra_funds), "(",
+			Commas(extra_funds/Value(extra_edens)), "per eden)")
+	}
 }
 
-func DescribePath(data planet_data, dims []int, table []State, start int) (description []string) {
-	for index := start; index > 0 && table[index].from > 0; index = table[index].from {
+func VisitCost(data planet_data, dims LogicalIndex, table []State, best PhysicalIndex) {
+	if dims[Visit] == 1 {
+		return
+	}
+	fmt.Println()
+	final_state := FinalState(dims)
+	for i := uint(0); i < uint(len(visit())); i++ {
+		all_bits := dims[Visit] - 1
+		final_state[Visit] = all_bits & ^(1 << i)
+		alt_best := FindBestState(data, dims, table, final_state)
+		cost := table[alt_best].value - table[best].value
+		fmt.Printf("\r%11v Cost to visit %v\n", Commas(cost), visit()[i])
+	}
+}
+
+func EndLocationCost(data planet_data, dims LogicalIndex, table []State, best PhysicalIndex) {
+	if len(end()) == 0 {
+		return
+	}
+	fmt.Println()
+	final_state := FinalState(dims)
+	save_end_string := *end_string
+	*end_string = ""
+	end_cache = nil
+	alt_best := FindBestState(data, dims, table, final_state)
+	cost := table[alt_best].value - table[best].value
+	fmt.Printf("\r%11v Cost of --end %v\n", Commas(cost), save_end_string)
+	*end_string = save_end_string
+}
+
+func DescribePath(data planet_data, dims LogicalIndex, table []State, start PhysicalIndex) []string {
+	var description []string
+	for index := start; table[index].from > FROM_ROOT; index = table[index].from {
+		if table[index].from == FROM_UNINITIALIZED {
+			panic(index)
+		}
 		var line string
 		addr := DecodeIndex(dims, index)
 		prev := DecodeIndex(dims, table[index].from)
@@ -588,7 +703,7 @@ func DescribePath(data planet_data, dims []int, table []State, start int) (descr
 			to := data.i2p[addr[Location]]
 			line += fmt.Sprintf("Jump from %v to %v (%v hyper jump units)", from, to, prev[Fuel]-addr[Fuel])
 		}
-		if addr[Edens] == prev[Edens] - 1 {
+		if addr[Edens] == prev[Edens]-1 {
 			from := data.i2p[prev[Location]]
 			to := data.i2p[addr[Location]]
 			line += fmt.Sprintf("Eden warp from %v to %v", from, to)
@@ -610,7 +725,7 @@ func DescribePath(data planet_data, dims []int, table []State, start int) (descr
 			line += "Buy a Cloak"
 		}
 		if addr[Edens] > prev[Edens] {
-			line += fmt.Sprint("Buy ", addr[Edens] - prev[Edens], " Eden Warp Units")
+			line += fmt.Sprint("Buy ", addr[Edens]-prev[Edens], " Eden Warp Units")
 		}
 		if addr[BuyShields] == 1 && prev[BuyShields] == 0 {
 			line += fmt.Sprint("Buy ", *batteries, " Shield Batterys")
@@ -618,12 +733,21 @@ func DescribePath(data planet_data, dims []int, table []State, start int) (descr
 		if addr[BuyFighters] == 1 && prev[BuyFighters] == 0 {
 			line += fmt.Sprint("Buy ", *drones, " Fighter Drones")
 		}
+		if addr[Visit] != prev[Visit] {
+			// TODO: verify that the bit chat changed is addr[Location]
+			line += fmt.Sprint("Visit ", data.i2p[addr[Location]])
+		}
+		if line == "" && addr[Hold] == prev[Hold] && addr[Traded] != prev[Traded] {
+			// The Traded dimension is for housekeeping.  It doesn't directly
+			// correspond to in-game actions, so don't report transitions.
+			continue
+		}
 		if line == "" {
 			line = fmt.Sprint(prev, " -> ", addr)
 		}
-		description = append(description, fmt.Sprintf("%13v ", Commas(table[index].value)) + line)
+		description = append(description, fmt.Sprintf("%13v ", Commas(table[index].value))+line)
 	}
-	return
+	return description
 }
 
 // (Example of a use case for generics in Go)
@@ -652,6 +776,18 @@ func IndexCommodities(m *map[string]Commodity, start_at int) (map[string]int, []
 
 func main() {
 	flag.Parse()
+	if *start == "" || *funds == 0 {
+		print("--start and --funds are required.  --help for more\n")
+		return
+	}
+	if *cpuprofile != "" {
+		f, err := os.Create(*cpuprofile)
+		if err != nil {
+			panic(err)
+		}
+		pprof.StartCPUProfile(f)
+		defer pprof.StopCPUProfile()
+	}
 	data := ReadData()
 	if *drone_price > 0 {
 		temp := data.Commodities["Fighter Drones"]
@@ -666,15 +802,23 @@ func main() {
 	data.p2i, data.i2p = IndexPlanets(&data.Planets, 0)
 	data.c2i, data.i2c = IndexCommodities(&data.Commodities, 1)
 	dims := DimensionSizes(data)
-	table := InitializeStateTable(data, dims)
-	FillStateTable1(data, dims, table)
-	best := FindBestState(data, dims, table)
+	table := CreateStateTable(data, dims)
+	final_state := FinalState(dims)
+	best := FindBestState(data, dims, table, final_state)
+	print("\n")
 	if best == -1 {
-		print("Cannot acheive success criteria\n")
-	} else {
-		description := DescribePath(data, dims, table, best)
-		for i := len(description) - 1; i >= 0; i-- {
-			fmt.Println(description[i])
-		}
+		print("Cannot achieve success criteria\n")
+		return
+	}
+	description := DescribePath(data, dims, table, best)
+	for i := len(description) - 1; i >= 0; i-- {
+		fmt.Println(description[i])
+	}
+
+	if *extra_stats {
+		FighterAndShieldCost(data, dims, table, best)
+		EndEdensCost(data, dims, table, best)
+		VisitCost(data, dims, table, best)
+		EndLocationCost(data, dims, table, best)
 	}
 }