#-swank (unless (member :child-sbcl *features*) (quit :unix-status (process-exit-code (run-program *runtime-pathname* `("--control-stack-size" "256MB" "--noinform" "--disable-ldb" "--lose-on-corruption" "--end-runtime-options" "--eval" "(push :child-sbcl *features*)" "--script" ,(namestring *load-pathname*)) :output t :error t :input t)))) (in-package :cl-user) (eval-when (:compile-toplevel :load-toplevel :execute) (defparameter *opt* #+swank '(optimize (speed 3) (safety 2)) #-swank '(optimize (speed 3) (safety 0) (debug 0))) #+swank (ql:quickload '(:cl-debug-print :fiveam :cp/util) :silent t) #+swank (use-package :cp/util :cl-user) #-swank (set-dispatch-macro-character #\# #\> (lambda (s c p) (declare (ignore c p)) `(values ,(read s nil nil t)))) #+sbcl (setq *random-state* (seed-random-state (nth-value 1 (get-time-of-day))))) #-swank (eval-when (:compile-toplevel) (setq *break-on-signals* '(and warning (not style-warning)))) #+swank (set-dispatch-macro-character #\# #\> #'cl-debug-print:debug-print-reader) (macrolet ((def (b) `(progn (deftype ,(intern (format nil "UINT~A" b)) () '(unsigned-byte ,b)) (deftype ,(intern (format nil "INT~A" b)) () '(signed-byte ,b)))) (define-int-types (&rest bits) `(progn ,@(mapcar (lambda (b) `(def ,b)) bits)))) (define-int-types 2 4 7 8 15 16 31 32 62 63 64)) (defconstant +mod+ 1000000007) (defmacro dbg (&rest forms) (declare (ignorable forms)) #+swank (if (= (length forms) 1) `(format *error-output* "~A => ~A~%" ',(car forms) ,(car forms)) `(format *error-output* "~A => ~A~%" ',forms `(,,@forms)))) (declaim (inline println)) (defun println (obj &optional (stream *standard-output*)) (let ((*read-default-float-format* (if (typep obj 'double-float) 'double-float *read-default-float-format*))) (prog1 (princ obj stream) (terpri stream)))) ;; BEGIN_INSERTED_CONTENTS ;;; ;;; Strongly connected components of directed graph ;;; (defpackage :cp/scc (:use :cl) (:export #:scc #:scc-graph #:scc-components #:scc-sizes #:scc-count #:scc-p #:make-scc #:make-condensed-graph)) (in-package :cp/scc) (defstruct (scc (:constructor %make-scc (graph components sizes count)) (:copier nil) (:predicate nil)) (graph nil :type vector) ;; components[i] := strongly connected component of the i-th vertex (components nil :type (simple-array (integer 0 #.most-positive-fixnum) (*))) ;; sizes[k] := size of the k-th strongly connected component (sizes nil :type (simple-array (integer 0 #.most-positive-fixnum) (*))) ;; the total number of strongly connected components (count 0 :type (integer 0 #.most-positive-fixnum))) ;; Tarjan's algorithm ;; Reference: http://www.prefield.com/algorithm/graph/strongly_connected_components.html ;; (Kosaraju's algorithm is put in the test file) (defun make-scc (graph &key (key #'identity)) (declare (optimize (speed 3)) (vector graph) (function key)) (let* ((n (length graph)) (ord 0) (ords (make-array n :element-type 'fixnum :initial-element -1)) ; pre-order ;; store the lowest pre-order number as the representative element of a ;; strongly connected component (lowlinks (make-array n :element-type 'fixnum)) (components (make-array n :element-type '(integer 0 #.most-positive-fixnum))) (comp-index 0) ; index number of component (sizes (make-array n :element-type '(integer 0 #.most-positive-fixnum) :initial-element 0)) (stack (make-array n :element-type '(integer 0 #.most-positive-fixnum))) (end 0) ; stack pointer (in-stack (make-array n :element-type 'bit :initial-element 0))) (declare ((integer 0 #.most-positive-fixnum) ord end comp-index)) (labels ((%push (v) (setf (aref stack end) v (aref in-stack v) 1) (incf end)) (%pop () (decf end) (let ((v (aref stack end))) (setf (aref in-stack v) 0) v)) (visit (v) (setf (aref ords v) ord (aref lowlinks v) ord) (incf ord) (%push v) (dolist (next (aref graph v)) (let ((next (funcall key next))) (cond ((= -1 (aref ords next)) (visit next) (setf (aref lowlinks v) (min (aref lowlinks v) (aref lowlinks next)))) ((= 1 (aref in-stack next)) (setf (aref lowlinks v) (min (aref lowlinks v) (aref ords next))))))) (when (= (aref lowlinks v) (aref ords v)) (loop for size of-type (integer 0 #.most-positive-fixnum) from 1 for w = (%pop) do (setf (aref components w) comp-index) until (= v w) finally (setf (aref sizes comp-index) size) (incf comp-index))))) (dotimes (v n) (when (= -1 (aref ords v)) (visit v))) ;; Reverse the order of strongly connected components, because now ;; everything is in the reversed topological order (dotimes (v n) (setf (aref components v) (- comp-index (aref components v) 1))) (dotimes (i (ash comp-index -1)) (rotatef (aref sizes i) (aref sizes (- comp-index i 1)))) (%make-scc graph components (adjust-array sizes comp-index) comp-index)))) ;; FIXME: Constant factor of this implementation is too large. Can we avoid ;; hash-table? (declaim (ftype (function * (values (simple-array t (*)) &optional)) make-condensed-graph)) (defun make-condensed-graph (scc) "Does graph condensation. This function is non-destructive." (declare (optimize (speed 3))) (let* ((graph (scc-graph scc)) (n (length graph)) (comp-n (scc-count scc)) (components (scc-components scc)) (condensed (make-array comp-n :element-type t))) (dotimes (i comp-n) ;; Resorting to EQ is substandard, though I use it here for efficiency. (setf (aref condensed i) (make-hash-table :test #'eq))) (dotimes (i n) (let ((i-comp (aref components i))) (dolist (neighbor (aref graph i)) (let ((neighbor-comp (aref components neighbor))) (unless (= i-comp neighbor-comp) (setf (gethash neighbor-comp (aref condensed i-comp)) t)))))) (dotimes (i comp-n) (setf (aref condensed i) (loop for x being each hash-key of (aref condensed i) collect x))) condensed)) ;;; ;;; Memoization macro ;;; (defpackage :cp/with-cache (:use :cl) (:export #:with-cache #:with-caches)) (in-package :cp/with-cache) ;; FIXME: *RECURSION-DEPTH* should be included within the macro. (declaim (type (integer 0 #.most-positive-fixnum) *recursion-depth*)) (defparameter *recursion-depth* 0) (eval-when (:compile-toplevel :load-toplevel :execute) (defun %enclose-with-trace (fname args form) (let ((value (gensym))) `(progn (format t "~&~A~A: (~A ~{~A~^ ~}) =>" (make-string *recursion-depth* :element-type 'base-char :initial-element #\ ) *recursion-depth* ',fname (list ,@args)) (let ((,value (let ((*recursion-depth* (1+ *recursion-depth*))) ,form))) (format t "~&~A~A: (~A ~{~A~^ ~}) => ~A" (make-string *recursion-depth* :element-type 'base-char :initial-element #\ ) *recursion-depth* ',fname (list ,@args) ,value) ,value)))) (defun %extract-declarations (body) (remove-if-not (lambda (form) (and (consp form) (eql 'declare (car form)))) body)) (defun %parse-cache-form (cache-specifier) (let ((cache-type (car cache-specifier)) (cache-attribs (cdr cache-specifier))) (assert (member cache-type '(:hash-table :array))) (let* ((dims-with-* (when (eql cache-type :array) (first cache-attribs))) (dims (remove '* dims-with-*)) (rank (length dims)) (rest-attribs (ecase cache-type (:hash-table cache-attribs) (:array (cdr cache-attribs)))) (key (prog1 (getf rest-attribs :key) (remf rest-attribs :key))) (trace-p (prog1 (getf rest-attribs :trace) (remf rest-attribs :trace))) (cache-form (case cache-type (:hash-table `(make-hash-table ,@rest-attribs)) (:array `(make-array (list ,@dims) ,@rest-attribs)))) (initial-element (when (eql cache-type :array) (assert (member :initial-element rest-attribs)) (getf rest-attribs :initial-element)))) (let ((cache (gensym "CACHE")) (value (gensym)) (present-p (gensym)) (args-lst (gensym)) (indices (loop repeat rank collect (gensym)))) (labels ((make-cache-querier (cache-type name args) (let ((res (case cache-type (:hash-table `(let ((,args-lst (funcall ,(or key '#'list) ,@args))) (multiple-value-bind (,value ,present-p) (gethash ,args-lst ,cache) (if ,present-p ,value (setf (gethash ,args-lst ,cache) (,name ,@args)))))) (:array (assert (= (length args) (length dims-with-*))) (let ((memoized-args (loop for dimension in dims-with-* for arg in args unless (eql dimension '*) collect arg))) (if key `(multiple-value-bind ,indices (funcall ,key ,@memoized-args) (let ((,value (aref ,cache ,@indices))) (if (eql ,initial-element ,value) (setf (aref ,cache ,@indices) (,name ,@args)) ,value))) `(let ((,value (aref ,cache ,@memoized-args))) (if (eql ,initial-element ,value) (setf (aref ,cache ,@memoized-args) (,name ,@args)) ,value)))))))) (if trace-p (%enclose-with-trace name args res) res))) (make-reset-form (cache-type) (case cache-type (:hash-table `(setf ,cache (make-hash-table ,@rest-attribs))) (:array `(prog1 nil ;; TODO: portable fill (fill (sb-ext:array-storage-vector ,cache) ,initial-element))))) (make-reset-name (name) (intern (format nil "RESET-~A" (symbol-name name))))) (values cache cache-form cache-type #'make-reset-name #'make-reset-form #'make-cache-querier))))))) (defmacro with-cache ((cache-type &rest cache-attribs) def-form) "CACHE-TYPE := :HASH-TABLE | :ARRAY. DEF-FORM := definition form with DEFUN, LABELS, FLET, or SB-INT:NAMED-LET. Basic usage: \(with-cache (:hash-table :test #'equal :key #'cons) (defun add (a b) (+ a b))) This function caches the returned values for already passed combinations of arguments. In this case ADD stores the key (CONS A B) and the returned value to a hash-table when (ADD A B) is evaluated for the first time. When it is called with the same arguments (w.r.t. EQUAL) again, ADD will return the stored value instead of recomputing it. The storage for cache can be hash-table or array. Let's see an example for array: \(with-cache (:array (10 20 30) :initial-element -1 :element-type 'fixnum) (defun foo (a b c) ... )) This form stores the value returned by FOO in an array, which was created by (make-array (list 10 20 30) :initial-element -1 :element-type 'fixnum). Note that INITIAL-ELEMENT must always be given here as it is used as the flag expressing `not yet stored'. (Therefore INITIAL-ELEMENT should be a value FOO never takes.) If you want to ignore some arguments, you can put `*' in dimensions: \(with-cache (:array (10 10 * 10) :initial-element -1) (defun foo (a b c d) ...)) ; then C is ignored when querying or storing cache Available definition forms in WITH-CACHE are DEFUN, LABELS, FLET, and SB-INT:NAMED-LET. You can trace a memoized function by :TRACE option: \(with-cache (:array (10 10) :initial-element -1 :trace t) (defun foo (x y) ...)) Then FOO is traced as with CL:TRACE. " (multiple-value-bind (cache-symbol cache-form cache-type make-reset-name make-reset-form make-cache-querier) (%parse-cache-form (cons cache-type cache-attribs)) (ecase (car def-form) ((defun) (destructuring-bind (_ name args &body body) def-form (declare (ignore _)) `(let ((,cache-symbol ,cache-form)) (defun ,(funcall make-reset-name name) () ,(funcall make-reset-form cache-type)) (defun ,name ,args ,@(%extract-declarations body) (flet ((,name ,args ,@body)) (declare (inline ,name)) ,(funcall make-cache-querier cache-type name args)))))) ((labels flet) (destructuring-bind (_ definitions &body labels-body) def-form (declare (ignore _)) (destructuring-bind (name args &body body) (car definitions) `(let ((,cache-symbol ,cache-form)) (,(car def-form) ((,(funcall make-reset-name name) () ,(funcall make-reset-form cache-type)) (,name ,args ,@(%extract-declarations body) (flet ((,name ,args ,@body)) (declare (inline ,name)) ,(funcall make-cache-querier cache-type name args))) ,@(cdr definitions)) (declare (ignorable #',(funcall make-reset-name name))) ,@labels-body))))) ((nlet #+sbcl sb-int:named-let) (destructuring-bind (_ name bindings &body body) def-form (declare (ignore _)) `(let ((,cache-symbol ,cache-form)) (,(car def-form) ,name ,bindings ,@(%extract-declarations body) ,(let ((args (mapcar (lambda (x) (if (atom x) x (car x))) bindings))) `(flet ((,name ,args ,@body)) (declare (inline ,name)) ,(funcall make-cache-querier cache-type name args)))))))))) (defmacro with-caches (cache-specs def-form) "DEF-FORM := definition form by LABELS or FLET. \(with-caches (cache-spec1 cache-spec2) (labels ((f (x) ...) (g (y) ...)))) is equivalent to the line up of \(with-cache cache-spec1 (labels ((f (x) ...)))) and \(with-cache cache-spec2 (labels ((g (y) ...)))) This macro will be useful to do mutual recursion between memoized local functions." (assert (member (car def-form) '(labels flet))) (let (cache-symbol-list cache-form-list cache-type-list make-reset-name-list make-reset-form-list make-cache-querier-list) (dolist (cache-spec (reverse cache-specs)) (multiple-value-bind (cache-symbol cache-form cache-type make-reset-name make-reset-form make-cache-querier) (%parse-cache-form cache-spec) (push cache-symbol cache-symbol-list) (push cache-form cache-form-list) (push cache-type cache-type-list) (push make-reset-name make-reset-name-list) (push make-reset-form make-reset-form-list) (push make-cache-querier make-cache-querier-list))) (labels ((def-name (def) (first def)) (def-args (def) (second def)) (def-body (def) (cddr def))) (destructuring-bind (_ definitions &body labels-body) def-form (declare (ignore _)) `(let ,(loop for cache-symbol in cache-symbol-list for cache-form in cache-form-list collect `(,cache-symbol ,cache-form)) (,(car def-form) (,@(loop for def in definitions for cache-type in cache-type-list for make-reset-name in make-reset-name-list for make-reset-form in make-reset-form-list collect `(,(funcall make-reset-name (def-name def)) () ,(funcall make-reset-form cache-type))) ,@(loop for def in definitions for cache-type in cache-type-list for make-cache-querier in make-cache-querier-list collect `(,(def-name def) ,(def-args def) ,@(%extract-declarations (def-body def)) (flet ((,(def-name def) ,(def-args def) ,@(def-body def))) (declare (inline ,(def-name def))) ,(funcall make-cache-querier cache-type (def-name def) (def-args def)))))) (declare (ignorable ,@(loop for def in definitions for make-reset-name in make-reset-name-list collect `#',(funcall make-reset-name (def-name def))))) ,@labels-body)))))) ;;; ;;; Arithmetic operations with static modulus ;;; (defpackage :cp/mod-operations (:use :cl) (:export #:define-mod-operations)) (in-package :cp/mod-operations) (defmacro define-mod-operations (divisor &optional (package #+sbcl (sb-int:sane-package) #-sbcl *package*)) (let ((mod* (intern "MOD*" package)) (mod+ (intern "MOD+" package)) (mod- (intern "MOD-" package)) (incfmod (intern "INCFMOD" package)) (decfmod (intern "DECFMOD" package)) (mulfmod (intern "MULFMOD" package))) `(progn (defun ,mod* (&rest args) (cond ((cdr args) (reduce (lambda (x y) (mod (* x y) ,divisor)) args)) (args (mod (car args) ,divisor)) (t 1))) (defun ,mod+ (&rest args) (cond ((cdr args) (reduce (lambda (x y) (mod (+ x y) ,divisor)) args)) (args (mod (car args) ,divisor)) (t 0))) (defun ,mod- (&rest args) (if (cdr args) (reduce (lambda (x y) (mod (- x y) ,divisor)) args) (mod (- (car args)) ,divisor))) #+sbcl (eval-when (:compile-toplevel :load-toplevel :execute) (locally (declare (sb-ext:muffle-conditions warning)) (sb-c:define-source-transform ,mod* (&rest args) (case (length args) (0 1) (1 `(mod ,(car args) ,',divisor)) (otherwise (reduce (lambda (x y) `(mod (* ,x ,y) ,',divisor)) args)))) (sb-c:define-source-transform ,mod+ (&rest args) (case (length args) (0 0) (1 `(mod ,(car args) ,',divisor)) (otherwise (reduce (lambda (x y) `(mod (+ ,x ,y) ,',divisor)) args)))) (sb-c:define-source-transform ,mod- (&rest args) (case (length args) (0 (values nil t)) (1 `(mod (- ,(car args)) ,',divisor)) (otherwise (reduce (lambda (x y) `(mod (- ,x ,y) ,',divisor)) args)))))) (define-modify-macro ,incfmod (delta) (lambda (x y) (mod (+ x y) ,divisor))) (define-modify-macro ,decfmod (delta) (lambda (x y) (mod (- x y) ,divisor))) (define-modify-macro ,mulfmod (multiplier) (lambda (x y) (mod (* x y) ,divisor)))))) (defpackage :cp/read-fixnum (:use :cl) (:export #:read-fixnum)) (in-package :cp/read-fixnum) (declaim (ftype (function * (values fixnum &optional)) read-fixnum)) (defun read-fixnum (&optional (in *standard-input*)) "NOTE: cannot read -2^62" (macrolet ((%read-byte () `(the (unsigned-byte 8) #+swank (char-code (read-char in nil #\Nul)) #-swank (sb-impl::ansi-stream-read-byte in nil #.(char-code #\Nul) nil)))) (let* ((minus nil) (result (loop (let ((byte (%read-byte))) (cond ((<= 48 byte 57) (return (- byte 48))) ((zerop byte) ; #\Nul (error "Read EOF or #\Nul.")) ((= byte #.(char-code #\-)) (setq minus t))))))) (declare ((integer 0 #.most-positive-fixnum) result)) (loop (let* ((byte (%read-byte))) (if (<= 48 byte 57) (setq result (+ (- byte 48) (* 10 (the (integer 0 #.(floor most-positive-fixnum 10)) result)))) (return (if minus (- result) result)))))))) ;; BEGIN_USE_PACKAGE (eval-when (:compile-toplevel :load-toplevel :execute) (use-package :cp/read-fixnum :cl-user)) (eval-when (:compile-toplevel :load-toplevel :execute) (use-package :cp/mod-operations :cl-user)) (eval-when (:compile-toplevel :load-toplevel :execute) (use-package :cp/with-cache :cl-user)) (eval-when (:compile-toplevel :load-toplevel :execute) (use-package :cp/scc :cl-user)) (in-package :cl-user) ;;; ;;; Body ;;; (define-mod-operations +mod+) (defun main () (let* ((n (read)) (m (read)) (graph (make-array (+ n 1) :element-type 'list :initial-element nil)) (revgraph (make-array (+ n 1) :element-type 'list :initial-element nil)) (us (make-array m :element-type 'uint31 :initial-element 0)) (vs (make-array m :element-type 'uint31 :initial-element 0)) (ls (make-array m :element-type 'uint31 :initial-element 0)) (as (make-array m :element-type 'uint31 :initial-element 0))) (dotimes (i m) (setf (aref us i) (read-fixnum) (aref vs i) (read-fixnum) (aref ls i) (read-fixnum) (aref as i) (read-fixnum)) (push i (aref graph (aref us i))) (push i (aref revgraph (aref vs i)))) (labels ((make-reach-p (graph tos start) (let ((marked (make-array (+ n 1) :element-type 'bit :initial-element 0))) (sb-int:named-let dfs ((v start)) (setf (aref marked v) 1) (dolist (ei (aref graph v)) (let ((next (aref tos ei))) (when (zerop (aref marked next)) (dfs next))))) marked))) (let* ((reach0-p (make-reach-p graph vs 0)) (reachn-p (make-reach-p revgraph us n)) (scc (make-scc graph :key (lambda (ei) (aref vs ei)))) (comps (scc-components scc)) (sizes (scc-sizes scc))) #>graph #>scc (dotimes (i (+ n 1)) (when (and (= 1 (aref reach0-p i)) (= 1 (aref reachn-p i)) (> (aref sizes (aref comps i)) 1)) (write-line "INF") (return-from main))) #>graph (with-caches ((:array (100001) :element-type 'uint31 :initial-element #x7fffffff) (:array (100001) :element-type 'uint31 :initial-element #x7fffffff)) (labels ((calc-in (v) (if (= 0 v) 1 (let ((res 0)) (declare (uint31 res)) (dolist (ei (aref revgraph v)) (let ((prev (aref us ei)) (a (aref as ei))) (when (= 1 (aref reach0-p prev)) (incfmod res (mod* a (calc-in prev)))))) res))) (calc-out (v) (if (= n v) 1 (let ((res 0)) (declare (uint31 res)) (dolist (ei (aref graph v)) (let ((next (aref vs ei)) (a (aref as ei))) (when (= 1 (aref reachn-p next)) (incfmod res (mod* a (calc-out next)))))) res)))) (let ((res 0)) (dotimes (ei m) (let ((u (aref us ei)) (v (aref vs ei)) (l (aref ls ei)) (a (aref as ei))) (when (and (= 1 (aref reach0-p u) (aref reachn-p v))) (incfmod res (mod* l a (calc-in u) (calc-out v)))))) (println res)))))))) #-swank (main) ;;; ;;; Test ;;; #+swank (progn (defparameter *lisp-file-pathname* (uiop:current-lisp-file-pathname)) (setq *default-pathname-defaults* (uiop:pathname-directory-pathname *lisp-file-pathname*)) (uiop:chdir *default-pathname-defaults*) (defparameter *dat-pathname* (uiop:merge-pathnames* "test.dat" *lisp-file-pathname*)) (defparameter *problem-url* "https://yukicoder.me/problems/no/1364")) #+swank (defun gen-dat () (uiop:with-output-file (out *dat-pathname* :if-exists :supersede) (format out ""))) #+swank (defun bench (&optional (out (make-broadcast-stream))) (time (run *dat-pathname* out))) #+(and sbcl (not swank)) (eval-when (:compile-toplevel) (when sb-c::*undefined-warnings* (error "undefined warnings: ~{~A~^ ~}" sb-c::*undefined-warnings*))) ;; To run: (5am:run! :sample) #+swank (5am:test :sample (5am:is (equal "10 " (run "3 4 0 1 2 1 1 2 1 1 2 3 3 1 0 3 4 1 " nil))) (5am:is (equal "INF " (run "3 4 0 1 1 1 1 2 1 1 2 1 1 1 2 3 1 1 " nil))) (5am:is (equal "18 " (run "1 2 0 1 3 2 0 1 4 3 " nil))))