AOC2022/day19/day19.go

package main

import (
	"AOC2022/helper"
	"fmt"
	"strconv"
	"strings"
)

type State struct {
	currentRessources [4]int
	currentProduction [4]int
	runtime           int
}

type Blueprint struct {
	oreRoboterCost        int
	clayRoboterCost       int
	obsidianRobototerCost [2]int
	geodeRoboterCost      [2]int
}

func main() {
	//args := os.Args[1:]
	lines := helper.ReadTextFile("day19/input")
	highestGeode := make([]int, len(lines))
	for i, line := range lines {
		blueprint := getBluePrint(line)
		startStates := []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}
		fastestTime := getFastestTimeToElementN(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2)
		startStates = getAllPossibleCombinationsWithFastestTime(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2, fastestTime)
		tmpStates := getAllPossibleCombinationsWithFastestTime(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2, fastestTime)
		fastestTime = getFastestTimeToElementN(blueprint, tmpStates, 3)
		startStates = getAllPossibleCombinationsWithFastestTime(blueprint, startStates, 3, fastestTime)
		highestGeode[i] = getHighestGeode(blueprint, startStates)
	}
	sum := 0
	for i, score := range highestGeode {
		sum += (i + 1) * score
	}
	fmt.Println(sum)

}

func getHighestGeode(blueprint Blueprint, startStates []State) int {
	activeStates := startStates
	endStates := []State{}
	for len(activeStates) > 0 {
		stepHighestGeode(&activeStates, &endStates, &blueprint)
	}
	highestgeode := 0
	for _, state := range endStates {
		if state.currentRessources[3] > highestgeode && state.runtime < 25 {
			highestgeode = state.currentRessources[3]
		}
	}
	return highestgeode
}

func getFastestTimeToElementN(blueprint Blueprint, startStates []State, untilElementN int) int {
	activeStates := startStates
	fastestTimeToObsidianState := State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 26}
	for len(activeStates) > 0 {
		step(&activeStates, &fastestTimeToObsidianState, untilElementN, &blueprint)
	}
	return fastestTimeToObsidianState.runtime
}

func getAllPossibleCombinationsWithFastestTime(blueprint Blueprint, startStates []State, untilElementN int, fastestTime int) []State {
	activeStates := startStates
	fastestTimeToObsidianState := map[[8]int]State{}
	for len(activeStates) > 0 {
		stepFindAllFastestTime(&activeStates, &fastestTimeToObsidianState, untilElementN, fastestTime, &blueprint)
	}
	returnStates := []State{}
	for _, val := range fastestTimeToObsidianState {
		returnStates = append(returnStates, val)
	}
	return returnStates
}

func step(activeStates *[]State, fastestTImeToObsidian *State, untilElementN int, blueprint *Blueprint) {
	activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)
	for _, tmpState := range newTmpStates {
		if tmpState.currentProduction[untilElementN] > 0 && (*fastestTImeToObsidian).runtime > tmpState.runtime {
			*fastestTImeToObsidian = tmpState
		}
		if tmpState.currentProduction[untilElementN] == 0 && tmpState.runtime < (*fastestTImeToObsidian).runtime {
			*activeStates = append(*activeStates, tmpState)
		}
	}
}

func stepHighestGeode(activeStates *[]State, endStates *[]State, blueprint *Blueprint) {
	activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)
	for _, tmpState := range newTmpStates {
		if tmpState.runtime < 24 {
			*activeStates = append(*activeStates, tmpState)
		} else {
			*endStates = append(*endStates, tmpState)
		}
	}
}

func stepFindAllFastestTime(activeStates *[]State, fastestTImeStates *map[[8]int]State, untilElementN int, fastestTime int, blueprint *Blueprint) {
	activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)
	for _, tmpState := range newTmpStates {
		if tmpState.currentProduction[untilElementN] > 0 && fastestTime >= tmpState.runtime {
			identifier := [8]int{}
			copy(identifier[:], append(tmpState.currentRessources[:], tmpState.currentProduction[:]...)[:8])
			(*fastestTImeStates)[identifier] = tmpState
		}
		if tmpState.currentProduction[untilElementN] == 0 && tmpState.runtime < fastestTime {
			*activeStates = append(*activeStates, tmpState)
		}
	}
}

func generatePossibleTmpStates(activeStates *[]State, blueprint *Blueprint) (*[]State, []State) {
	activeState := (*activeStates)[len(*activeStates)-1]
	*activeStates = (*activeStates)[:len(*activeStates)-1]
	possibleProductions := activeState.getPossibleProductions(blueprint)
	newTmpStates := []State{}
	for i := -1; i < len(possibleProductions); i++ {
		if i == -1 || possibleProductions[i] == 1 {
			tmpState := activeState
			tmpState.produceRessources()
			tmpState.produceRoboter(blueprint, i)
			tmpState.runtime++
			newTmpStates = append(newTmpStates, tmpState)
		}
	}
	return activeStates, newTmpStates
}

func (state *State) produceRoboter(blueprint *Blueprint, roboter int) {
	switch roboter {
	case 0:
		state.currentProduction[0]++
		state.currentRessources[0] -= blueprint.oreRoboterCost
	case 1:
		state.currentProduction[1]++
		state.currentRessources[0] -= blueprint.clayRoboterCost
	case 2:
		state.currentProduction[2]++
		state.currentRessources[0] -= blueprint.obsidianRobototerCost[0]
		state.currentRessources[1] -= blueprint.obsidianRobototerCost[1]
	case 3:
		state.currentProduction[3]++
		state.currentRessources[0] -= blueprint.geodeRoboterCost[0]
		state.currentRessources[2] -= blueprint.geodeRoboterCost[1]
	default:

	}
}

func (state *State) produceRessources() {
	for i := 0; i < 4; i++ {
		state.currentRessources[i] += state.currentProduction[i]
	}
}

func (state State) getPossibleProductions(blueprint *Blueprint) [4]int {
	possibleProductions := [4]int{0, 0, 0, 0}
	if state.currentRessources[0] >= blueprint.oreRoboterCost {
		possibleProductions[0] = 1
	}
	if state.currentRessources[0] >= blueprint.clayRoboterCost {
		possibleProductions[1] = 1
	}
	if state.currentRessources[0] >= blueprint.obsidianRobototerCost[0] && state.currentRessources[1] >= blueprint.obsidianRobototerCost[1] {
		possibleProductions[2] = 1
	}
	if state.currentRessources[0] >= blueprint.geodeRoboterCost[0] && state.currentRessources[2] >= blueprint.geodeRoboterCost[1] {
		possibleProductions[3] = 1
	}
	return possibleProductions
}

func getBluePrint(line string) Blueprint {
	productionCostStrings := strings.Split(strings.Split(line, ":")[1], ". ")
	oreCostString := strings.ReplaceAll(productionCostStrings[0], " ore", "")[18:]
	oreCost, _ := strconv.Atoi(oreCostString)
	clayCostString := strings.ReplaceAll(productionCostStrings[1], " ore", "")[22:]
	claycost, _ := strconv.Atoi(clayCostString)
	obsidiancostString := strings.ReplaceAll(productionCostStrings[2], "ore and ", "")[26:]
	obsidianCost := helper.StringSliceToIntSlice(strings.Split(obsidiancostString[:len(obsidiancostString)-5], " "))
	geodeCostString := strings.ReplaceAll(productionCostStrings[3], "ore and ", "")[23:]
	geodeCost := helper.StringSliceToIntSlice(strings.Split(geodeCostString[:len(geodeCostString)-10], " "))
	return Blueprint{oreCost, claycost, [2]int{obsidianCost[0], obsidianCost[1]}, [2]int{geodeCost[0], geodeCost[1]}}
}
Zwischenstand 2022-12-19 23:39:38 +01:00			`package main`

			`import (`
			`"AOC2022/helper"`
			`"fmt"`
			`"strconv"`
			`"strings"`
			`)`

			`type State struct {`
			`currentRessources [4]int`
			`currentProduction [4]int`
			`runtime int`
			`}`

			`type Blueprint struct {`
			`oreRoboterCost int`
			`clayRoboterCost int`
			`obsidianRobototerCost [2]int`
			`geodeRoboterCost [2]int`
			`}`

			`func main() {`
			`//args := os.Args[1:]`
			`lines := helper.ReadTextFile("day19/input")`
			`highestGeode := make([]int, len(lines))`
			`for i, line := range lines {`
			`blueprint := getBluePrint(line)`
			`startStates := []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}`
			`fastestTime := getFastestTimeToElementN(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2)`
			`startStates = getAllPossibleCombinationsWithFastestTime(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2, fastestTime)`
			`tmpStates := getAllPossibleCombinationsWithFastestTime(blueprint, []State{State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 0}}, 2, fastestTime)`
			`fastestTime = getFastestTimeToElementN(blueprint, tmpStates, 3)`
			`startStates = getAllPossibleCombinationsWithFastestTime(blueprint, startStates, 3, fastestTime)`
			`highestGeode[i] = getHighestGeode(blueprint, startStates)`
			`}`
			`sum := 0`
			`for i, score := range highestGeode {`
			`sum += (i + 1) * score`
			`}`
			`fmt.Println(sum)`

			`}`

			`func getHighestGeode(blueprint Blueprint, startStates []State) int {`
			`activeStates := startStates`
			`endStates := []State{}`
			`for len(activeStates) > 0 {`
			`stepHighestGeode(&activeStates, &endStates, &blueprint)`
			`}`
			`highestgeode := 0`
			`for _, state := range endStates {`
			`if state.currentRessources[3] > highestgeode && state.runtime < 25 {`
			`highestgeode = state.currentRessources[3]`
			`}`
			`}`
			`return highestgeode`
			`}`

			`func getFastestTimeToElementN(blueprint Blueprint, startStates []State, untilElementN int) int {`
			`activeStates := startStates`
			`fastestTimeToObsidianState := State{[4]int{0, 0, 0, 0}, [4]int{1, 0, 0, 0}, 26}`
			`for len(activeStates) > 0 {`
			`step(&activeStates, &fastestTimeToObsidianState, untilElementN, &blueprint)`
			`}`
			`return fastestTimeToObsidianState.runtime`
			`}`

			`func getAllPossibleCombinationsWithFastestTime(blueprint Blueprint, startStates []State, untilElementN int, fastestTime int) []State {`
			`activeStates := startStates`
			`fastestTimeToObsidianState := map[[8]int]State{}`
			`for len(activeStates) > 0 {`
			`stepFindAllFastestTime(&activeStates, &fastestTimeToObsidianState, untilElementN, fastestTime, &blueprint)`
			`}`
			`returnStates := []State{}`
			`for _, val := range fastestTimeToObsidianState {`
			`returnStates = append(returnStates, val)`
			`}`
			`return returnStates`
			`}`

			`func step(activeStates []State, fastestTImeToObsidian State, untilElementN int, blueprint *Blueprint) {`
			`activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)`
			`for _, tmpState := range newTmpStates {`
			`if tmpState.currentProduction[untilElementN] > 0 && (*fastestTImeToObsidian).runtime > tmpState.runtime {`
			`*fastestTImeToObsidian = tmpState`
			`}`
			`if tmpState.currentProduction[untilElementN] == 0 && tmpState.runtime < (*fastestTImeToObsidian).runtime {`
			`activeStates = append(activeStates, tmpState)`
			`}`
			`}`
			`}`

			`func stepHighestGeode(activeStates []State, endStates []State, blueprint *Blueprint) {`
			`activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)`
			`for _, tmpState := range newTmpStates {`
			`if tmpState.runtime < 24 {`
			`activeStates = append(activeStates, tmpState)`
			`} else {`
			`endStates = append(endStates, tmpState)`
			`}`
			`}`
			`}`

			`func stepFindAllFastestTime(activeStates []State, fastestTImeStates map[[8]int]State, untilElementN int, fastestTime int, blueprint *Blueprint) {`
			`activeStates, newTmpStates := generatePossibleTmpStates(activeStates, blueprint)`
			`for _, tmpState := range newTmpStates {`
			`if tmpState.currentProduction[untilElementN] > 0 && fastestTime >= tmpState.runtime {`
			`identifier := [8]int{}`
			`copy(identifier[:], append(tmpState.currentRessources[:], tmpState.currentProduction[:]...)[:8])`
			`(*fastestTImeStates)[identifier] = tmpState`
			`}`
			`if tmpState.currentProduction[untilElementN] == 0 && tmpState.runtime < fastestTime {`
			`activeStates = append(activeStates, tmpState)`
			`}`
			`}`
			`}`

			`func generatePossibleTmpStates(activeStates []State, blueprint Blueprint) (*[]State, []State) {`
			`activeState := (activeStates)[len(activeStates)-1]`
			`activeStates = (activeStates)[:len(*activeStates)-1]`
			`possibleProductions := activeState.getPossibleProductions(blueprint)`
			`newTmpStates := []State{}`
			`for i := -1; i < len(possibleProductions); i++ {`
			`if i == -1 \|\| possibleProductions[i] == 1 {`
			`tmpState := activeState`
			`tmpState.produceRessources()`
			`tmpState.produceRoboter(blueprint, i)`
			`tmpState.runtime++`
			`newTmpStates = append(newTmpStates, tmpState)`
			`}`
			`}`
			`return activeStates, newTmpStates`
			`}`

			`func (state State) produceRoboter(blueprint Blueprint, roboter int) {`
			`switch roboter {`
			`case 0:`
			`state.currentProduction[0]++`
			`state.currentRessources[0] -= blueprint.oreRoboterCost`
			`case 1:`
			`state.currentProduction[1]++`
			`state.currentRessources[0] -= blueprint.clayRoboterCost`
			`case 2:`
			`state.currentProduction[2]++`
			`state.currentRessources[0] -= blueprint.obsidianRobototerCost[0]`
			`state.currentRessources[1] -= blueprint.obsidianRobototerCost[1]`
			`case 3:`
			`state.currentProduction[3]++`
			`state.currentRessources[0] -= blueprint.geodeRoboterCost[0]`
			`state.currentRessources[2] -= blueprint.geodeRoboterCost[1]`
			`default:`

			`}`
			`}`

			`func (state *State) produceRessources() {`
			`for i := 0; i < 4; i++ {`
			`state.currentRessources[i] += state.currentProduction[i]`
			`}`
			`}`

			`func (state State) getPossibleProductions(blueprint *Blueprint) [4]int {`
			`possibleProductions := [4]int{0, 0, 0, 0}`
			`if state.currentRessources[0] >= blueprint.oreRoboterCost {`
			`possibleProductions[0] = 1`
			`}`
			`if state.currentRessources[0] >= blueprint.clayRoboterCost {`
			`possibleProductions[1] = 1`
			`}`
			`if state.currentRessources[0] >= blueprint.obsidianRobototerCost[0] && state.currentRessources[1] >= blueprint.obsidianRobototerCost[1] {`
			`possibleProductions[2] = 1`
			`}`
			`if state.currentRessources[0] >= blueprint.geodeRoboterCost[0] && state.currentRessources[2] >= blueprint.geodeRoboterCost[1] {`
			`possibleProductions[3] = 1`
			`}`
			`return possibleProductions`
			`}`

			`func getBluePrint(line string) Blueprint {`
			`productionCostStrings := strings.Split(strings.Split(line, ":")[1], ". ")`
			`oreCostString := strings.ReplaceAll(productionCostStrings[0], " ore", "")[18:]`
			`oreCost, _ := strconv.Atoi(oreCostString)`
			`clayCostString := strings.ReplaceAll(productionCostStrings[1], " ore", "")[22:]`
			`claycost, _ := strconv.Atoi(clayCostString)`
			`obsidiancostString := strings.ReplaceAll(productionCostStrings[2], "ore and ", "")[26:]`
			`obsidianCost := helper.StringSliceToIntSlice(strings.Split(obsidiancostString[:len(obsidiancostString)-5], " "))`
			`geodeCostString := strings.ReplaceAll(productionCostStrings[3], "ore and ", "")[23:]`
			`geodeCost := helper.StringSliceToIntSlice(strings.Split(geodeCostString[:len(geodeCostString)-10], " "))`
			`return Blueprint{oreCost, claycost, [2]int{obsidianCost[0], obsidianCost[1]}, [2]int{geodeCost[0], geodeCost[1]}}`
			`}`