--- title: "Dyalog APL Problem Solving Competition 2020" subtitle: "Annotated Solutions" date: 2020-07-31 --- * Phase I #+begin_src default :Namespace Phase1 #+end_src ** 1. Let's Split! #+begin_quote Write a function that, given a right argument ~Y~ which is a scalar or a non-empty vector and a left argument ~X~ which is a single non-zero integer so that its absolute value is less or equal to ~≢Y~, splits ~Y~ into a vector of two vectors according to ~X~, as follows: - If ~X>0~, the first vector contains the first ~X~ elements of ~Y~ and the second vector contains the remaining elements. - If ~X<0~, the second vector contains the last ~|X~ elements of ~Y~ and the first vector contains the remaining elements. #+end_quote #+begin_src default split←(0>⊣)⌽((⊂↑),(⊂↓)) #+end_src ** 2. Character Building #+begin_quote UTF-8 encodes Unicode characters using 1-4 integers for each character. Dyalog APL includes a system function, ~⎕UCS~, that can convert characters into integers and integers into characters. The expression ~'UTF-8'∘⎕UCS~ converts between characters and UTF-8. Consider the following: #+begin_src default 'UTF-8'∘⎕UCS 'D¥⍺⌊○9' 68 194 165 226 141 186 226 140 138 226 151 139 57 'UTF-8'∘⎕UCS 68 194 165 226 141 186 226 140 138 226 151 139 57 D¥⍺⌊○9 #+end_src How many integers does each character use? #+begin_src default 'UTF-8'∘⎕UCS¨ 'D¥⍺⌊○9' ⍝ using ]Boxing on ┌──┬───────┬───────────┬───────────┬───────────┬──┐ │68│194 165│226 141 186│226 140 138│226 151 139│57│ └──┴───────┴───────────┴───────────┴───────────┴──┘ #+end_src The rule is that an integer in the range 128 to 191 (inclusive) continues the character of the previous integer (which may itself be a continuation). With that in mind, write a function that, given a right argument which is a simple integer vector representing valid UTF-8 text, encloses each sequence of integers that represent a single character, like the result of ~'UTF-8'∘⎕UCS¨'UTF-8'∘⎕UCS~ but does not use any system functions (names beginning with ~⎕~) #+end_quote #+begin_src default characters←{(~⍵∊127+⍳64)⊂⍵} #+end_src ** 3. Excel-lent Columns #+begin_quote A Microsoft Excel spreadsheet numbers its rows counting up from 1. However Excel's columns are labelled alphabetically — beginning with A–Z, then AA–AZ, BA–BZ, up to ZA–ZZ, then AAA–AAZ and so on. Write a function that, given a right argument which is a character scalar or non-empty vector representing a valid character Excel column identifier between A and XFD, returns the corresponding column number #+end_quote #+begin_src default columns←26⊥⎕A∘⍳ #+end_src ** 4. Take a Leap #+begin_quote Write a function that, given a right argument which is an integer array of year numbers greater than or equal to 1752 and less than 4000, returns a result of the same shape as the right argument where 1 indicates that the corresponding year is a leap year (0 otherwise). A leap year algorithm can be found [[https://en.wikipedia.org/wiki/Leap_year#Algorithm][here]]. #+end_quote #+begin_src default leap←1 3∊⍨(0+.=400 100 4∘.|⊢) #+end_src ** 5. Stepping in the Proper Direction #+begin_quote Write a function that, given a right argument of 2 integers, returns a vector of the integers from the first element of the right argument to the second, inclusively. #+end_quote #+begin_src default stepping←{(⊃⍵)+(-×-/⍵)×0,⍳|-/⍵} #+end_src ** 6. Please Move to the Front #+begin_quote Write a function that, given a right argument which is an integer vector and a left argument which is an integer scalar, reorders the right argument so any elements equal to the left argument come first while all other elements keep their order. #+end_quote #+begin_src default movefront←{⍵[⍋⍺≠⍵]} #+end_src ** 7. See You in a Bit #+begin_quote A common technique for encoding a set of on/off states is to use a value of $2^n$ for the state in position $n$ (origin 0), 1 if the state is "on" or 0 for "off" and then add the values. Dyalog APL's [[https://help.dyalog.com/17.1/#Language/APL%20Component%20Files/Component%20Files.htm#File_Access_Control][component file permission codes]] are an example of this. For example, if you wanted to grant permissions for read (access code 1), append (access code 8) and rename (access code 128) then the resulting code would be 137 because that's 1 + 8 + 128. Write a function that, given a non-negative right argument which is an integer scalar representing the encoded state and a left argument which is an integer scalar representing the encoded state settings that you want to query, returns 1 if all of the codes in the left argument are found in the right argument (0 otherwise). #+end_quote #+begin_src default bits←{f←⍸∘⌽(2∘⊥⍣¯1)⋄∧/(f⍺)∊f⍵} #+end_src ** 8. Zigzag Numbers #+begin_quote A zigzag number is an integer in which the difference in magnitude of each pair of consecutive digits alternates from positive to negative or negative to positive. Write a function that takes a single integer greater than or equal to 100 and less than 10^{15} as its right argument and returns a 1 if the integer is a zigzag number, 0 otherwise. #+end_quote #+begin_src default zigzag←∧/2=∘|2-/∘×2-/(10∘⊥⍣¯1) #+end_src ** 9. Rise and Fall #+begin_quote Write a function that, given a right argument which is an integer scalar or vector, returns a 1 if the values of the right argument conform to the following pattern (0 otherwise): - The elements increase or stay the same until the "apex" (highest value) is reached - After the apex, any remaining values decrease or remain the same #+end_quote #+begin_src default risefall←{∧/(⍳∘≢≡⍋)¨(⊂((⊢⍳⌈/)↑⊢),⍵),⊂⌽((⊢⍳⌈/)↓⊢),⍵} #+end_src ** 10. Stacking It Up #+begin_quote Write a function that takes as its right argument a vector of simple arrays of rank 2 or less (scalar, vector, or matrix). Each simple array will consist of either non-negative integers or printable ASCII characters. The function must return a simple character array that displays identically to what ~{⎕←⍵}¨~ displays when applied to the right argument. #+end_quote #+begin_src default stacking←{↑⊃,/↓¨⍕¨⍵} #+end_src #+begin_src default :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