Added 2019 day 14 part 1

2019-12-14 20:32:51 +01:00 · 2019-12-14 20:32:51 +01:00 · fa89caacbf
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 # 2019 Day 14: Space Stoichiometry
 Copyright (c) Eric Wastl
 #### [Direct Link](https://adventofcode.com/2019/day/14)
 ## Part 1
 As you approach the rings of Saturn, your ship's **low fuel** indicator turns on. There isn't any fuel here, but the rings have plenty of raw material. Perhaps your ship's Inter-Stellar Refinery Union brand **nanofactory** can turn these raw materials into fuel.
 You ask the nanofactory to produce a list of the **reactions** it can perform that are relevant to this process (your puzzle input). Every reaction turns some quantities of specific **input chemicals** into some quantity of an **output chemical**. Almost every **chemical** is produced by exactly one reaction; the only exception, `ORE`, is the raw material input to the entire process and is not produced by a reaction.
 You just need to know how much **`ORE`** you'll need to collect before you can produce one unit of **`FUEL`**.
 Each reaction gives specific quantities for its inputs and output; reactions cannot be partially run, so only whole integer multiples of these quantities can be used. (It's okay to have leftover chemicals when you're done, though.) For example, the reaction `1 A, 2 B, 3 C => 2 D` means that exactly 2 units of chemical `D` can be produced by consuming exactly 1 `A`, 2 `B` and 3 `C`. You can run the full reaction as many times as necessary; for example, you could produce 10 `D` by consuming 5 `A`, 10 `B`, and 15 `C`.
 Suppose your nanofactory produces the following list of reactions:
 ```
 10 ORE => 10 A
 1 ORE => 1 B
 7 A, 1 B => 1 C
 7 A, 1 C => 1 D
 7 A, 1 D => 1 E
 7 A, 1 E => 1 FUEL
 ```
 The first two reactions use only `ORE` as inputs; they indicate that you can produce as much of chemical `A` as you want (in increments of 10 units, each 10 costing 10 `ORE`) and as much of chemical `B` as you want (each costing 1 `ORE`). To produce 1 `FUEL`, a total of **31** `ORE` is required: 1 `ORE` to produce 1 `B`, then 30 more `ORE` to produce the 7 + 7 + 7 + 7 = 28 `A` (with 2 extra `A` wasted) required in the reactions to convert the `B` into `C`, `C` into `D`, `D` into `E`, and finally `E` into `FUEL`. (30 `A` is produced because its reaction requires that it is created in increments of 10.)
 Or, suppose you have the following list of reactions:
 ```
 9 ORE => 2 A
 8 ORE => 3 B
 7 ORE => 5 C
 3 A, 4 B => 1 AB
 5 B, 7 C => 1 BC
 4 C, 1 A => 1 CA
 2 AB, 3 BC, 4 CA => 1 FUEL
 ```
 The above list of reactions requires **165** `ORE` to produce 1 `FUEL`:
 - Consume 45 `ORE` to produce 10 `A`.
 - Consume 64 `ORE` to produce 24 `B`.
 - Consume 56 `ORE` to produce 40 `C`.
 - Consume 6 `A`, 8 `B` to produce 2 `AB`.
 - Consume 15 `B`, 21 `C` to produce 3 `BC`.
 - Consume 16 `C`, 4 `A` to produce 4 `CA`.
 - Consume 2 `AB`, 3 `BC`, 4 `CA` to produce 1 `FUEL`.
 Here are some larger examples:
 - **13312** `ORE` for 1 `FUEL`:
    ```
    157 ORE => 5 NZVS
    165 ORE => 6 DCFZ
    44 XJWVT, 5 KHKGT, 1 QDVJ, 29 NZVS, 9 GPVTF, 48 HKGWZ => 1 FUEL
    12 HKGWZ, 1 GPVTF, 8 PSHF => 9 QDVJ
    179 ORE => 7 PSHF
    177 ORE => 5 HKGWZ
    7 DCFZ, 7 PSHF => 2 XJWVT
    165 ORE => 2 GPVTF
    3 DCFZ, 7 NZVS, 5 HKGWZ, 10 PSHF => 8 KHKGT
    ```
 - **180697** ORE for 1 FUEL:
    ```
    2 VPVL, 7 FWMGM, 2 CXFTF, 11 MNCFX => 1 STKFG
    17 NVRVD, 3 JNWZP => 8 VPVL
    53 STKFG, 6 MNCFX, 46 VJHF, 81 HVMC, 68 CXFTF, 25 GNMV => 1 FUEL
    22 VJHF, 37 MNCFX => 5 FWMGM
    139 ORE => 4 NVRVD
    144 ORE => 7 JNWZP
    5 MNCFX, 7 RFSQX, 2 FWMGM, 2 VPVL, 19 CXFTF => 3 HVMC
    5 VJHF, 7 MNCFX, 9 VPVL, 37 CXFTF => 6 GNMV
    145 ORE => 6 MNCFX
    1 NVRVD => 8 CXFTF
    1 VJHF, 6 MNCFX => 4 RFSQX
    176 ORE => 6 VJHF
    ```
 - **2210736** ORE for 1 FUEL:
    ```
    171 ORE => 8 CNZTR
    7 ZLQW, 3 BMBT, 9 XCVML, 26 XMNCP, 1 WPTQ, 2 MZWV, 1 RJRHP => 4 PLWSL
    114 ORE => 4 BHXH
    14 VRPVC => 6 BMBT
    6 BHXH, 18 KTJDG, 12 WPTQ, 7 PLWSL, 31 FHTLT, 37 ZDVW => 1 FUEL
    6 WPTQ, 2 BMBT, 8 ZLQW, 18 KTJDG, 1 XMNCP, 6 MZWV, 1 RJRHP => 6 FHTLT
    15 XDBXC, 2 LTCX, 1 VRPVC => 6 ZLQW
    13 WPTQ, 10 LTCX, 3 RJRHP, 14 XMNCP, 2 MZWV, 1 ZLQW => 1 ZDVW
    5 BMBT => 4 WPTQ
    189 ORE => 9 KTJDG
    1 MZWV, 17 XDBXC, 3 XCVML => 2 XMNCP
    12 VRPVC, 27 CNZTR => 2 XDBXC
    15 KTJDG, 12 BHXH => 5 XCVML
    3 BHXH, 2 VRPVC => 7 MZWV
    121 ORE => 7 VRPVC
    7 XCVML => 6 RJRHP
    5 BHXH, 4 VRPVC => 5 LTCX
    ```
 Given the list of reactions in your puzzle input, **what is the minimum amount of `ORE` required to produce exactly 1 `FUEL`**?
 ## Part 2
 After collecting `ORE` for a while, you check your cargo hold: **1 trillion** (**1000000000000**) units of `ORE`.
 **With that much ore**, given the examples above:
 - The 13312 `ORE`-per-`FUEL` example could produce **82892753** `FUEL`.
 - The 180697 `ORE`-per-`FUEL` example could produce **5586022** `FUEL`.
 - The 2210736 `ORE`-per-`FUEL` example could produce **460664** `FUEL`.
 Given 1 trillion `ORE`, **what is the maximum amount of FUEL you can produce**?
--- a/2019/14/code.py
+++ b/2019/14/code.py
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 """ https://adventofcode.com/2019/day/14 """
 def readFile():
    with open(f"{__file__.rstrip('code.py')}input.txt", "r") as f:
        return [line[:-1] for line in f.readlines()]
 class Factory:
    def __init__(self):
        self.recipes = dict()
        self.storage = {"ORE": 0}
        self.ores = 0
    def addRecipe(self, recipe):
        left, right = recipe.split(" => ")
        left, right = left.split(", "), right.split()
        self.storage[right[1]] = 0
        self.recipes[right[1]] = {"amount": int(right[0]), "req": {}}
        for l in left:
            l = l.split()
            self.recipes[right[1]]["req"][l[1]] = int(l[0])
    def produce(self, chem="FUEL"):
        if "ORE" in self.recipes[chem]["req"]:
            cur = self.storage["ORE"]
            while self.storage["ORE"] < self.recipes[chem]["req"]["ORE"]:
                self.storage["ORE"] += self.recipes[chem]["req"]["ORE"]
                self.ores += self.recipes[chem]["req"]["ORE"]
            self.storage[chem] += self.recipes[chem]["amount"]
            self.storage["ORE"] -= self.recipes[chem]["req"]["ORE"]
        else:
            for r in self.recipes[chem]["req"]:
                while self.storage[r] < self.recipes[chem]["req"][r]:
                    self.produce(r)
            self.storage[chem] += self.recipes[chem]["amount"]
            for r in self.recipes[chem]["req"]:
                self.storage[r] -= self.recipes[chem]["req"][r]
                while self.storage[r] < 0:
                    self.produce(r)
            return
 def part1(vals):
    factory = Factory()
    for val in vals:
        factory.addRecipe(val)
    factory.produce()
    return factory.ores
 def part2(vals):
    pass
 def test():
    assert part1(["10 ORE => 10 A","1 ORE => 1 B","7 A, 1 B => 1 C","7 A, 1 C => 1 D",
        "7 A, 1 D => 1 E","7 A, 1 E => 1 FUEL"]) ==  31
    assert part1(["9 ORE => 2 A","8 ORE => 3 B","7 ORE => 5 C","3 A, 4 B => 1 AB",
        "5 B, 7 C => 1 BC","4 C, 1 A => 1 CA","2 AB, 3 BC, 4 CA => 1 FUEL"]) == 165
    assert part1(["157 ORE => 5 NZVS","165 ORE => 6 DCFZ","44 XJWVT, 5 KHKGT, 1 QDVJ, 29"
        " NZVS, 9 GPVTF, 48 HKGWZ => 1 FUEL","12 HKGWZ, 1 GPVTF, 8 PSHF => 9 QDVJ",
        "179 ORE => 7 PSHF","177 ORE => 5 HKGWZ","7 DCFZ, 7 PSHF => 2 XJWVT",
        "165 ORE => 2 GPVTF","3 DCFZ, 7 NZVS, 5 HKGWZ, 10 PSHF => 8 KHKGT"]) == 13312
 if __name__ == "__main__":
    test()
    vals = readFile()
    print(f"Part 1: {part1(vals)}")
    print(f"Part 2: {part2(vals)}")
--- a/2019/14/input.txt
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 1 JKXFH => 8 KTRZ
 11 TQGT, 9 NGFV, 4 QZBXB => 8 MPGLV
 8 NPDPH, 1 WMXZJ => 7 VCNSK
 1 MPGLV, 6 CWHX => 5 GDRZ
 16 JDFQZ => 2 CJTB
 1 GQNQF, 4 JDFQZ => 5 WJKDC
 2 TXBS, 4 SMGQW, 7 CJTB, 3 NTBQ, 13 CWHX, 25 FLPFX => 1 FUEL
 3 WMXZJ, 14 CJTB => 5 FLPFX
 7 HDCTQ, 1 MPGLV, 2 VFVC => 1 GSVSD
 1 WJKDC => 2 NZSQR
 1 RVKLC, 5 CMJSL, 16 DQTHS, 31 VCNSK, 1 RKBMX, 1 GDRZ => 8 SMGQW
 2 JDFQZ, 2 LGKHR, 2 NZSQR => 9 TSWN
 34 LPXW => 8 PWJFD
 2 HDCTQ, 2 VKWN => 8 ZVBRF
 2 XCTF => 3 QZBXB
 12 NGFV, 3 HTRWR => 5 HDCTQ
 1 TSWN, 2 WRSD, 1 ZVBRF, 1 KFRX, 5 BPVMR, 2 CLBG, 22 NPSLQ, 9 GSVSD => 5 NTBQ
 10 TSWN => 9 VFVC
 141 ORE => 6 MKJDZ
 4 NPSLQ, 43 VCNSK, 4 PSJL, 14 KTRZ, 3 KWCDP, 3 HKBS, 11 WRSD, 3 MXWHS => 8 TXBS
 8 VCNSK, 1 HDCTQ => 7 MXWHS
 3 JDFQZ, 2 GQNQF => 4 XJSQW
 18 NGFV, 4 GSWT => 5 KFRX
 2 CZSJ => 7 GMTW
 5 PHKL, 5 VCNSK, 25 GSVSD => 8 FRWC
 30 FRWC, 17 GKDK, 8 NPSLQ => 3 CLBG
 8 MXWHS, 3 SCKB, 2 NPSLQ => 1 JKXFH
 1 XJSQW, 7 QZBXB => 1 LGKHR
 115 ORE => 6 GQNQF
 12 HTRWR, 24 HDCTQ => 1 RKBMX
 1 DQTHS, 6 XDFWD, 1 MXWHS => 8 VKWN
 129 ORE => 3 XCTF
 6 GQNQF, 7 WJKDC => 5 PHKL
 3 NZSQR => 2 LPXW
 2 FLPFX, 1 MKLP, 4 XDFWD => 8 NPSLQ
 4 DQTHS, 1 VKWN => 1 BPVMR
 7 GMTW => 1 TXMVX
 152 ORE => 8 JDFQZ
 21 LGKHR => 9 NPDPH
 5 CJTB, 1 QZBXB, 3 KFRX => 1 GTPB
 1 MXWHS => 3 CWHX
 3 PHKL => 1 NGFV
 1 WMXZJ => 7 XDFWD
 3 TSWN, 1 VKWN => 8 GKDK
 1 ZVBRF, 16 PWJFD => 8 CMJSL
 3 VCNSK, 7 GDRZ => 4 HKBS
 20 XJSQW, 6 HTRWR, 7 CJTB => 5 WMXZJ
 12 ZVBRF, 10 FRWC, 12 TSWN => 4 WRSD
 16 HDCTQ, 3 GTPB, 10 NGFV => 4 KWCDP
 3 TXMVX, 1 NPDPH => 8 HTRWR
 9 NPDPH, 6 LPXW => 8 GSWT
 4 MKLP => 1 TQGT
 34 GTPB => 3 RVKLC
 25 VFVC, 5 RVKLC => 8 DQTHS
 7 KWCDP => 3 SCKB
 6 LGKHR => 8 MKLP
 39 MKJDZ => 9 CZSJ
 2 TSWN, 1 WMXZJ => 3 PSJL
--- a/2019/14/solution.txt
+++ b/2019/14/solution.txt
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 Part 1: 2486514