Split into two different posts

2020-07-21 17:38:18 +02:00 · 2020-07-21 17:38:18 +02:00 · 5be4981b16
commit 5be4981b16
parent 44f662be42
2 changed files with 249 additions and 248 deletions
--- a/posts/dyalog-apl-competition-2020-phase-1.org
+++ b/posts/dyalog-apl-competition-2020-phase-1.org
@ -1,17 +1,15 @@
 ---
-title: "Dyalog APL Problem Solving Competition 2020"
+title: "Dyalog APL Problem Solving Competition 2020 — Phase I"
 subtitle: "Annotated Solutions"
 date: 2020-07-31
 toc: true
 ---
 * Phase I
 #+begin_src default
  :Namespace Phase1
 #+end_src
-** 1. Let's Split!
+* 1. Let's Split!
 #+begin_quote
 Write a function that, given a right argument ~Y~ which is a scalar or
@ -43,7 +41,7 @@ The second train ~(0>⊣)~ will return 1 if its left argument is
 positive. From this, we can use [[https://help.dyalog.com/18.0/index.htm#Language/Primitive%20Functions/Rotate.htm][Rotate]] (~⌽~) to correctly order the
 nested array, in the last train.
-** 2. Character Building
+* 2. Character Building
 #+begin_quote
 UTF-8 encodes Unicode characters using 1-4 integers for each
@ -85,7 +83,7 @@ continuation character as 0, and all the others as 1. Next, we can use
 this binary array with [[https://help.dyalog.com/latest/#Language/Primitive%20Functions/Partitioned%20Enclose.htm][Partitioned Enclose]] (~⊂~) to return the correct
 output.
-** 3. Excel-lent Columns
+* 3. Excel-lent Columns
 #+begin_quote
 A Microsoft Excel spreadsheet numbers its rows counting up
@ -106,7 +104,7 @@ the alphabet of every character. As a train, this can be done by
 letter from 1 to 26. The [[https://help.dyalog.com/latest/#Language/Primitive%20Functions/Decode.htm][Decode]] (~⊥~) function can then turn this
 base-26 number into the expected result.
-** 4. Take a Leap
+* 4. Take a Leap
 #+begin_quote
 Write a function that, given a right argument which is an integer
@ -130,7 +128,7 @@ divisible by one of these numbers. If the count is 1 or 3, it is a
 leap year. Note that we use [[https://help.dyalog.com/latest/#Language/Primitive%20Operators/Commute.htm][Commute]] (~⍨~) to keep the dfn as a train,
 and to preserve the natural right-to-left reading of the algorithm.
-** 5. Stepping in the Proper Direction
+* 5. Stepping in the Proper Direction
 #+begin_quote
 Write a function that, given a right argument of 2 integers, returns a
@ -151,7 +149,7 @@ decreasing if needed, so we multiply it by the opposite of the sign of
 ~-/⍵~. Finally, we just have to start the sequence at the first
 element of ~⍵~.
-** 6. Please Move to the Front
+* 6. Please Move to the Front
 #+begin_quote
 Write a function that, given a right argument which is an integer
@ -166,7 +164,7 @@ while all other elements keep their order.
 the left argument. Using this index to sort in the usual way with
 [[https://help.dyalog.com/latest/#Language/Primitive%20Functions/Grade%20Up%20Monadic.htm][Grade Up]] will return the expected result.
-** 7. See You in a Bit
+* 7. See You in a Bit
 #+begin_quote
 A common technique for encoding a set of on/off states is to use a
@ -198,7 +196,7 @@ case). That is what the function ~f~ does.
 Next, we just need to check that all elements of ~f⍺~ are also in
 ~f⍵~.
-** 8. Zigzag Numbers
+* 8. Zigzag Numbers
 #+begin_quote
 A zigzag number is an integer in which the difference in magnitude of
@ -217,7 +215,7 @@ First, we decompose a number into an array of digits, using
 compute the difference between each pair of digits, take the sign, and
 ensure that the signs are indeed alternating.
-** 9. Rise and Fall
+* 9. Rise and Fall
 #+begin_quote
 Write a function that, given a right argument which is an integer
@ -256,7 +254,7 @@ Next, ~(⍳∘≢≡⍋)~ on each of the two vectors will test if they are
 non-decreasing (i.e. if the ranks of all the elements correspond to a
 simple range from 1 to the size of the vector).
-** 10. Stacking It Up
+* 10. Stacking It Up
 #+begin_quote
 Write a function that takes as its right argument a vector of simple
@ -317,238 +315,3 @@ final result.
  :EndNamespace
 #+end_src
 * Phase II
 #+begin_src default
  :Namespace Contest2020
 	  :Namespace Problems
 		  (⎕IO ⎕ML ⎕WX)←1 1 3
 #+end_src
 ** Problem 1 -- Take a Dive
 #+begin_src default
  ∇ score←dd DiveScore scores
    :If 7=≢scores
 	    scores←scores[¯2↓2↓⍋scores]
    :ElseIf 5=≢scores
 	    scores←scores[¯1↓1↓⍋scores]
    :Else
 	    scores←scores
    :EndIf
    score←2(⍎⍕)dd×+/scores
  ∇
 #+end_src
 ** Problem 2 -- Another Step in the Proper Direction
 #+begin_src default
  ∇ steps←{p}Steps fromTo;segments;width
    width←|-/fromTo
    :If 0=⎕NC'p' ⍝ No left argument: same as Problem 5 of Phase I
 	    segments←0,⍳width
    :ElseIf p<0 ⍝ -⌊p is the number of equally-sized steps to take
 	    segments←(-⌊p){0,⍵×⍺÷⍨⍳⍺}width
    :ElseIf p>0 ⍝ p is the step size
 	    segments←p{⍵⌊⍺×0,⍳⌈⍵÷⍺}width
    :ElseIf p=0 ⍝ As if we took zero step
 	    segments←0
    :EndIf
    ⍝ Take into account the start point and the direction.
    steps←fromTo{(⊃⍺)+(-×-/⍺)×⍵}segments
  ∇
 #+end_src
 ** Problem 3 -- Past Tasks Blast
 #+begin_src default
  ∇ urls←PastTasks url;r;paths
    r←HttpCommand.Get url
    paths←('[a-zA-Z0-9_/]+\.pdf'⎕S'&')r.Data
    urls←('https://www.dyalog.com/'∘,)¨paths
  ∇
 #+end_src
 ** Problem 4 -- Bioinformatics
 #+begin_src default
  ⍝ Test if a DNA string is a reverse palindrome.
  isrevp←{⍵≡⌽'TAGC'['ATCG'⍳⍵]}
  ⍝ Generate all subarrays (position, length) pairs, for
  ⍝ 4 ≤ length ≤ 12.
  subarrays←{⊃,/(⍳⍵),¨¨3↓¨⍳¨12⌊1+⍵-⍳⍵}
  ∇ r←revp dna;positions
    positions←subarrays⍴dna
    ⍝ Filter subarrays which are reverse palindromes.
    r←↑({isrevp dna[¯1+⍵[1]+⍳⍵[2]]}¨positions)/positions
  ∇
 #+end_src
 #+begin_src default
  sset←{((1E6|2∘×)⍣⍵)1}
 #+end_src
 ** Problem 5 -- Future and Present Value
 #+begin_src default
  ⍝ First solution: ((1+⊢)⊥⊣) computes the total return
  ⍝ for a vector of amounts ⍺ and a vector of rates
  ⍝ ⍵. It is applied to every prefix subarray of amounts
  ⍝ and rates to get all intermediate values. However,
  ⍝ this has quadratic complexity.
  ⍝ rr←(,\⊣)((1+⊢)⊥⊣)¨(,\⊢)
  ⍝ Second solution: We want to be able to use the
  ⍝ recurrence relation (recur) and scan through the
  ⍝ vectors of amounts and rates, accumulating the total
  ⍝ value at every time step. However, APL evaluation is
  ⍝ right-associative, so a simple Scan
  ⍝ (recur\amounts,¨values) would not give the correct
  ⍝ result, since recur is not associative and we need
  ⍝ to evaluate it left-to-right. (In any case, in this
  ⍝ case, Scan would have quadratic complexity, so would
  ⍝ not bring any benefit over the previous solution.)
  ⍝ What we need is something akin to Haskell's scanl
  ⍝ function, which would evaluate left to right in O(n)
  ⍝ time. This is what we do here, accumulating values
  ⍝ from left to right. (This is inspired from
  ⍝ dfns.ascan, although heavily simplified.)
  rr←{recur←{⍵[1]+⍺×1+⍵[2]} ⋄ 1↓⌽⊃{(⊂(⊃⍵)recur⍺),⍵}/⌽⍺,¨⍵}
 #+end_src
 #+begin_src default
  ⍝ Simply apply the formula for cashflow calculations.
  pv←{+/⍺÷×\1+⍵}
 #+end_src
 ** Problem 6 -- Merge
 #+begin_src default
  ∇ val←ns getval var
    :If ''≡var ⍝ literal '@'
 	    val←'@'
    :ElseIf (⊂var)∊ns.⎕NL ¯2
 	    val←⍕ns⍎var
    :Else
 	    val←'???'
    :EndIf
  ∇
 #+end_src
 #+begin_src default
  ∇ text←templateFile Merge jsonFile;template;ns
    template←⊃⎕NGET templateFile 1
    ns←⎕JSON⊃⎕NGET jsonFile
    ⍝ We use a simple regex search and replace on the
    ⍝ template.
    text←↑('@[a-zA-Z]*@'⎕R{ns getval ¯1↓1↓⍵.Match})template
  ∇
 #+end_src
 ** Problem 7 -- UPC
 #+begin_src default
  CheckDigit←{10|-⍵+.×11⍴3 1}
 #+end_src
 #+begin_src default
  ⍝ Left and right representations of digits. Decoding
  ⍝ the binary representation from decimal is more
  ⍝ compact than writing everything explicitly.
  lrepr←⍉(7⍴2)⊤13 25 19 61 35 49 47 59 55 11
  rrepr←~¨lrepr
 #+end_src
 #+begin_src default
  ∇ bits←WriteUPC digits;left;right
    :If (11=≢digits)∧∧/digits∊0,⍳9
 	    left←,lrepr[1+6↑digits;]
 	    right←,rrepr[1+6↓digits,CheckDigit digits;]
 	    bits←1 0 1,left,0 1 0 1 0,right,1 0 1
    :Else
 	    bits←¯1
    :EndIf
  ∇
 #+end_src
 #+begin_src default
  ∇ digits←ReadUPC bits
    :If 95≠⍴bits ⍝ incorrect number of bits
 	    digits←¯1
    :Else
 	    ⍝ Test if the barcode was scanned right-to-left.
 	    :If 0=2|+/bits[3+⍳7]
 		    bits←⌽bits
 	    :EndIf
 	    digits←({¯1+lrepr⍳⍵}¨(7/⍳6)⊆42↑3↓bits),{¯1+rrepr⍳⍵}¨(7/⍳6)⊆¯42↑¯3↓bits
 	    :If ~∧/digits∊0,⍳9 ⍝ incorrect parity
 		    digits←¯1
 	    :ElseIf (⊃⌽digits)≠CheckDigit ¯1↓digits ⍝ incorrect check digit
 		    digits←¯1
 	    :EndIf
    :EndIf
  ∇
 #+end_src
 ** Problem 8 -- Balancing the Scales
 #+begin_src default
  ∇ parts←Balance nums;subsets;partitions
    ⍝ This is a brute force solution, running in
    ⍝ exponential time. We generate all the possible
    ⍝ partitions, filter out those which are not
    ⍝ balanced, and return the first matching one. There
    ⍝ are more advanced approach running in
    ⍝ pseudo-polynomial time (based on dynamic
    ⍝ programming, see the "Partition problem" Wikipedia
    ⍝ page), but they are not warranted here, as the
    ⍝ input size remains fairly small.
    ⍝ Generate all partitions of a vector of a given
    ⍝ size, as binary mask vectors.
    subsets←{1↓2⊥⍣¯1⍳2*⍵}
    ⍝ Keep only the subsets whose sum is exactly
    ⍝ (+/nums)÷2.
    partitions←nums{((2÷⍨+/⍺)=⍺+.×⍵)/⍵}subsets⍴nums
    :If 0=≢,partitions
 	    ⍝ If no partition satisfy the above
 	    ⍝ criterion, we return ⍬.
 	    parts←⍬
    :Else
 	    ⍝ Otherwise, we return the first possible
 	    ⍝ partition.
 	    parts←nums{((⊂,(⊂~))⊃↓⍉⍵)/¨2⍴⊂⍺}partitions
    :EndIf
  ∇
 #+end_src
 ** Problem 9 -- Upwardly Mobile
 #+begin_src default
  ∇ weights←Weights filename;mobile;branches;mat
    ⍝ Put your code and comments below here
    ⍝ Parse the mobile input file.
    mobile←↑⊃⎕NGET filename 1
    branches←⍸mobile∊'┌┴┐'
    ⍝ TODO: Build the matrix of coefficients mat.
    ⍝ Solve the system of equations (arbitrarily setting
    ⍝ the first variable at 1 because the system is
    ⍝ overdetermined), then multiply the coefficients by
    ⍝ their least common multiple to get the smallest
    ⍝ integer weights.
    weights←((1∘,)×(∧/÷))mat[;1]⌹1↓[2]mat
  ∇
 #+end_src
 #+begin_src default
 	  :EndNamespace
  :EndNamespace
 #+end_src
 * General Remarks
--- a/posts/dyalog-apl-competition-2020-phase-2.org
+++ b/posts/dyalog-apl-competition-2020-phase-2.org
@ -0,0 +1,238 @@
 ---
 title: "Dyalog APL Problem Solving Competition 2020 — Phase II"
 subtitle: "Annotated Solutions"
 date: 2020-07-31
 toc: true
 ---
 #+begin_src default
  :Namespace Contest2020
 	  :Namespace Problems
 		  (⎕IO ⎕ML ⎕WX)←1 1 3
 #+end_src
 * Problem 1 -- Take a Dive
 #+begin_src default
  ∇ score←dd DiveScore scores
    :If 7=≢scores
 	    scores←scores[¯2↓2↓⍋scores]
    :ElseIf 5=≢scores
 	    scores←scores[¯1↓1↓⍋scores]
    :Else
 	    scores←scores
    :EndIf
    score←2(⍎⍕)dd×+/scores
  ∇
 #+end_src
 * Problem 2 -- Another Step in the Proper Direction
 #+begin_src default
  ∇ steps←{p}Steps fromTo;segments;width
    width←|-/fromTo
    :If 0=⎕NC'p' ⍝ No left argument: same as Problem 5 of Phase I
 	    segments←0,⍳width
    :ElseIf p<0 ⍝ -⌊p is the number of equally-sized steps to take
 	    segments←(-⌊p){0,⍵×⍺÷⍨⍳⍺}width
    :ElseIf p>0 ⍝ p is the step size
 	    segments←p{⍵⌊⍺×0,⍳⌈⍵÷⍺}width
    :ElseIf p=0 ⍝ As if we took zero step
 	    segments←0
    :EndIf
    ⍝ Take into account the start point and the direction.
    steps←fromTo{(⊃⍺)+(-×-/⍺)×⍵}segments
  ∇
 #+end_src
 * Problem 3 -- Past Tasks Blast
 #+begin_src default
  ∇ urls←PastTasks url;r;paths
    r←HttpCommand.Get url
    paths←('[a-zA-Z0-9_/]+\.pdf'⎕S'&')r.Data
    urls←('https://www.dyalog.com/'∘,)¨paths
  ∇
 #+end_src
 * Problem 4 -- Bioinformatics
 #+begin_src default
  ⍝ Test if a DNA string is a reverse palindrome.
  isrevp←{⍵≡⌽'TAGC'['ATCG'⍳⍵]}
  ⍝ Generate all subarrays (position, length) pairs, for
  ⍝ 4 ≤ length ≤ 12.
  subarrays←{⊃,/(⍳⍵),¨¨3↓¨⍳¨12⌊1+⍵-⍳⍵}
  ∇ r←revp dna;positions
    positions←subarrays⍴dna
    ⍝ Filter subarrays which are reverse palindromes.
    r←↑({isrevp dna[¯1+⍵[1]+⍳⍵[2]]}¨positions)/positions
  ∇
 #+end_src
 #+begin_src default
  sset←{((1E6|2∘×)⍣⍵)1}
 #+end_src
 * Problem 5 -- Future and Present Value
 #+begin_src default
  ⍝ First solution: ((1+⊢)⊥⊣) computes the total return
  ⍝ for a vector of amounts ⍺ and a vector of rates
  ⍝ ⍵. It is applied to every prefix subarray of amounts
  ⍝ and rates to get all intermediate values. However,
  ⍝ this has quadratic complexity.
  ⍝ rr←(,\⊣)((1+⊢)⊥⊣)¨(,\⊢)
  ⍝ Second solution: We want to be able to use the
  ⍝ recurrence relation (recur) and scan through the
  ⍝ vectors of amounts and rates, accumulating the total
  ⍝ value at every time step. However, APL evaluation is
  ⍝ right-associative, so a simple Scan
  ⍝ (recur\amounts,¨values) would not give the correct
  ⍝ result, since recur is not associative and we need
  ⍝ to evaluate it left-to-right. (In any case, in this
  ⍝ case, Scan would have quadratic complexity, so would
  ⍝ not bring any benefit over the previous solution.)
  ⍝ What we need is something akin to Haskell's scanl
  ⍝ function, which would evaluate left to right in O(n)
  ⍝ time. This is what we do here, accumulating values
  ⍝ from left to right. (This is inspired from
  ⍝ dfns.ascan, although heavily simplified.)
  rr←{recur←{⍵[1]+⍺×1+⍵[2]} ⋄ 1↓⌽⊃{(⊂(⊃⍵)recur⍺),⍵}/⌽⍺,¨⍵}
 #+end_src
 #+begin_src default
  ⍝ Simply apply the formula for cashflow calculations.
  pv←{+/⍺÷×\1+⍵}
 #+end_src
 * Problem 6 -- Merge
 #+begin_src default
  ∇ val←ns getval var
    :If ''≡var ⍝ literal '@'
 	    val←'@'
    :ElseIf (⊂var)∊ns.⎕NL ¯2
 	    val←⍕ns⍎var
    :Else
 	    val←'???'
    :EndIf
  ∇
 #+end_src
 #+begin_src default
  ∇ text←templateFile Merge jsonFile;template;ns
    template←⊃⎕NGET templateFile 1
    ns←⎕JSON⊃⎕NGET jsonFile
    ⍝ We use a simple regex search and replace on the
    ⍝ template.
    text←↑('@[a-zA-Z]*@'⎕R{ns getval ¯1↓1↓⍵.Match})template
  ∇
 #+end_src
 * Problem 7 -- UPC
 #+begin_src default
  CheckDigit←{10|-⍵+.×11⍴3 1}
 #+end_src
 #+begin_src default
  ⍝ Left and right representations of digits. Decoding
  ⍝ the binary representation from decimal is more
  ⍝ compact than writing everything explicitly.
  lrepr←⍉(7⍴2)⊤13 25 19 61 35 49 47 59 55 11
  rrepr←~¨lrepr
 #+end_src
 #+begin_src default
  ∇ bits←WriteUPC digits;left;right
    :If (11=≢digits)∧∧/digits∊0,⍳9
 	    left←,lrepr[1+6↑digits;]
 	    right←,rrepr[1+6↓digits,CheckDigit digits;]
 	    bits←1 0 1,left,0 1 0 1 0,right,1 0 1
    :Else
 	    bits←¯1
    :EndIf
  ∇
 #+end_src
 #+begin_src default
  ∇ digits←ReadUPC bits
    :If 95≠⍴bits ⍝ incorrect number of bits
 	    digits←¯1
    :Else
 	    ⍝ Test if the barcode was scanned right-to-left.
 	    :If 0=2|+/bits[3+⍳7]
 		    bits←⌽bits
 	    :EndIf
 	    digits←({¯1+lrepr⍳⍵}¨(7/⍳6)⊆42↑3↓bits),{¯1+rrepr⍳⍵}¨(7/⍳6)⊆¯42↑¯3↓bits
 	    :If ~∧/digits∊0,⍳9 ⍝ incorrect parity
 		    digits←¯1
 	    :ElseIf (⊃⌽digits)≠CheckDigit ¯1↓digits ⍝ incorrect check digit
 		    digits←¯1
 	    :EndIf
    :EndIf
  ∇
 #+end_src
 * Problem 8 -- Balancing the Scales
 #+begin_src default
  ∇ parts←Balance nums;subsets;partitions
    ⍝ This is a brute force solution, running in
    ⍝ exponential time. We generate all the possible
    ⍝ partitions, filter out those which are not
    ⍝ balanced, and return the first matching one. There
    ⍝ are more advanced approach running in
    ⍝ pseudo-polynomial time (based on dynamic
    ⍝ programming, see the "Partition problem" Wikipedia
    ⍝ page), but they are not warranted here, as the
    ⍝ input size remains fairly small.
    ⍝ Generate all partitions of a vector of a given
    ⍝ size, as binary mask vectors.
    subsets←{1↓2⊥⍣¯1⍳2*⍵}
    ⍝ Keep only the subsets whose sum is exactly
    ⍝ (+/nums)÷2.
    partitions←nums{((2÷⍨+/⍺)=⍺+.×⍵)/⍵}subsets⍴nums
    :If 0=≢,partitions
 	    ⍝ If no partition satisfy the above
 	    ⍝ criterion, we return ⍬.
 	    parts←⍬
    :Else
 	    ⍝ Otherwise, we return the first possible
 	    ⍝ partition.
 	    parts←nums{((⊂,(⊂~))⊃↓⍉⍵)/¨2⍴⊂⍺}partitions
    :EndIf
  ∇
 #+end_src
 * Problem 9 -- Upwardly Mobile
 #+begin_src default
  ∇ weights←Weights filename;mobile;branches;mat
    ⍝ Put your code and comments below here
    ⍝ Parse the mobile input file.
    mobile←↑⊃⎕NGET filename 1
    branches←⍸mobile∊'┌┴┐'
    ⍝ TODO: Build the matrix of coefficients mat.
    ⍝ Solve the system of equations (arbitrarily setting
    ⍝ the first variable at 1 because the system is
    ⍝ overdetermined), then multiply the coefficients by
    ⍝ their least common multiple to get the smallest
    ⍝ integer weights.
    weights←((1∘,)×(∧/÷))mat[;1]⌹1↓[2]mat
  ∇
 #+end_src
 #+begin_src default
 	  :EndNamespace
  :EndNamespace
 #+end_src