/* This is the Porter stemming algorithm, coded up in ANSI C by the author. It may be be regarded as cononical, in that it follows the algorithm presented in Porter, 1980, An algorithm for suffix stripping, Program, Vol. 14, no. 3, pp 130-137, only differing from it at the points maked --DEPARTURE-- below. The algorithm as described in the paper could be exactly replicated by adjusting the points of DEPARTURE, but this is barely necessary, because (a) the points of DEPARTURE are definitely improvements, and (b) no encoding of the Porter stemmer I have seen is anything like as exact as this version, even with the points of DEPARTURE! You can compile it on Unix with 'gcc -O3 -o stem stem.c' after which 'stem' takes a list of inputs and sends the stemmed equivalent to stdout. The algorithm as encoded here is particularly fast. */ #include #include #define TRUE 1 #define FALSE 0 /* The main part of the stemming algorithm starts here. b is a buffer holding a word to be stemmed. The letters are in b[k0], b[k0+1] ... ending at b[k]. In fact k0 = 0 in this demo program. k is readjusted downwards as the stemming progresses. Zero termination is not in fact used in the algorithm. Note that only lower case sequences are stemmed. Forcing to lower case should be done before stem(...) is called. */ static char * b; /* buffer for word to be stemmed */ static int k,k0,j; /* j is a general offset into the string */ /* cons(i) is TRUE <=> b[i] is a consonant. */ int cons(int i) { switch (b[i]) { case 'a': case 'e': case 'i': case 'o': case 'u': return FALSE; case 'y': return (i==k0) ? TRUE : !cons(i-1); default: return TRUE; } } /* m() measures the number of consonant sequences between k0 and j. if c is a consonant sequence and v a vowel sequence, and <..> indicates arbitrary presence, gives 0 vc gives 1 vcvc gives 2 vcvcvc gives 3 .... */ int m() { int n = 0; int i = k0; while(TRUE) { if (i > j) return n; if (! cons(i)) break; i++; } i++; while(TRUE) { while(TRUE) { if (i > j) return n; if (cons(i)) break; i++; } i++; n++; while(TRUE) { if (i > j) return n; if (! cons(i)) break; i++; } i++; } } /* vowelinstem() is TRUE <=> k0,...j contains a vowel */ int vowelinstem() { int i; for (i = k0; i <= j; i++) if (! cons(i)) return TRUE; return FALSE; } /* doublec(j) is TRUE <=> j,(j-1) contain a double consonant. */ int doublec(int j) { if (j < k0+1) return FALSE; if (b[j] != b[j-1]) return FALSE; return cons(j); } /* cvc(i) is TRUE <=> i-2,i-1,i has the form consonant - vowel - consonant and also if the second c is not w,x or y. this is used when trying to restore an e at the end of a short word. e.g. cav(e), lov(e), hop(e), crim(e), but snow, box, tray. */ int cvc(int i) { if (i < k0+2 || !cons(i) || cons(i-1) || !cons(i-2)) return FALSE; { int ch = b[i]; if (ch == 'w' || ch == 'x' || ch == 'y') return FALSE; } return TRUE; } /* ends(s) is TRUE <=> k0,...k ends with the string s. */ int ends(char * s) { int length = s[0]; if (s[length] != b[k]) return FALSE; /* tiny speed-up */ if (length > k-k0+1) return FALSE; if (memcmp(b+k-length+1,s+1,length) != 0) return FALSE; j = k-length; return TRUE; } /* setto(s) sets (j+1),...k to the characters in the string s, readjusting k. */ void setto(char * s) { int length = s[0]; memmove(b+j+1,s+1,length); k = j+length; } /* r(s) is used further down. */ void r(char * s) { if (m() > 0) setto(s); } /* step1ab() gets rid of plurals and -ed or -ing. e.g. caresses -> caress ponies -> poni ties -> ti caress -> caress cats -> cat feed -> feed agreed -> agree disabled -> disable matting -> mat mating -> mate meeting -> meet milling -> mill messing -> mess meetings -> meet */ void step1ab() { if (b[k] == 's') { if (ends("\04" "sses")) k -= 2; else if (ends("\03" "ies")) setto("\01" "i"); else if (b[k-1] != 's') k--; } if (ends("\03" "eed")) { if (m() > 0) k--; } else if ((ends("\02" "ed") || ends("\03" "ing")) && vowelinstem()) { k = j; if (ends("\02" "at")) setto("\03" "ate"); else if (ends("\02" "bl")) setto("\03" "ble"); else if (ends("\02" "iz")) setto("\03" "ize"); else if (doublec(k)) { k--; { int ch = b[k]; if (ch == 'l' || ch == 's' || ch == 'z') k++; } } else if (m() == 1 && cvc(k)) setto("\01" "e"); } } /* step1c() turns terminal y to i when there is another vowel in the stem. */ void step1c() { if (ends("\01" "y") && vowelinstem()) b[k] = 'i'; } /* step2() maps double suffices to single ones. so -ization ( = -ize plus -ation) maps to -ize etc. note that the string before the suffix must give m() > 0. */ void step2() { switch (b[k-1]) { case 'a': if (ends("\07" "ational")) { r("\03" "ate"); break; } if (ends("\06" "tional")) { r("\04" "tion"); break; } break; case 'c': if (ends("\04" "enci")) { r("\04" "ence"); break; } if (ends("\04" "anci")) { r("\04" "ance"); break; } break; case 'e': if (ends("\04" "izer")) { r("\03" "ize"); break; } break; case 'l': if (ends("\03" "bli")) { r("\03" "ble"); break; } /*-DEPARTURE-*/ /* To match the published algorithm, replace this line with case 'l': if (ends("\04" "abli")) { r("\04" "able"); break; } */ if (ends("\04" "alli")) { r("\02" "al"); break; } if (ends("\05" "entli")) { r("\03" "ent"); break; } if (ends("\03" "eli")) { r("\01" "e"); break; } if (ends("\05" "ousli")) { r("\03" "ous"); break; } break; case 'o': if (ends("\07" "ization")) { r("\03" "ize"); break; } if (ends("\05" "ation")) { r("\03" "ate"); break; } if (ends("\04" "ator")) { r("\03" "ate"); break; } break; case 's': if (ends("\05" "alism")) { r("\02" "al"); break; } if (ends("\07" "iveness")) { r("\03" "ive"); break; } if (ends("\07" "fulness")) { r("\03" "ful"); break; } if (ends("\07" "ousness")) { r("\03" "ous"); break; } break; case 't': if (ends("\05" "aliti")) { r("\02" "al"); break; } if (ends("\05" "iviti")) { r("\03" "ive"); break; } if (ends("\06" "biliti")) { r("\03" "ble"); break; } break; case 'g': if (ends("\04" "logi")) { r("\03" "log"); break; } /*-DEPARTURE-*/ /* To match the published algorithm, delete this line */ } } /* step3() deals with -ic-, -full, -ness etc. similar strategy to step2. */ void step3() { switch (b[k]) { case 'e': if (ends("\05" "icate")) { r("\02" "ic"); break; } if (ends("\05" "ative")) { r("\00" ""); break; } if (ends("\05" "alize")) { r("\02" "al"); break; } break; case 'i': if (ends("\05" "iciti")) { r("\02" "ic"); break; } break; case 'l': if (ends("\04" "ical")) { r("\02" "ic"); break; } if (ends("\03" "ful")) { r("\00" ""); break; } break; case 's': if (ends("\04" "ness")) { r("\00" ""); break; } break; } } /* step4() takes off -ant, -ence etc., in context vcvc. */ void step4() { switch (b[k-1]) { case 'a': if (ends("\02" "al")) break; return; case 'c': if (ends("\04" "ance")) break; if (ends("\04" "ence")) break; return; case 'e': if (ends("\02" "er")) break; return; case 'i': if (ends("\02" "ic")) break; return; case 'l': if (ends("\04" "able")) break; if (ends("\04" "ible")) break; return; case 'n': if (ends("\03" "ant")) break; if (ends("\05" "ement")) break; if (ends("\04" "ment")) break; if (ends("\03" "ent")) break; return; case 'o': if (ends("\03" "ion") && (b[j] == 's' || b[j] == 't')) break; if (ends("\02" "ou")) break; return; /* takes care of -ous */ case 's': if (ends("\03" "ism")) break; return; case 't': if (ends("\03" "ate")) break; if (ends("\03" "iti")) break; return; case 'u': if (ends("\03" "ous")) break; return; case 'v': if (ends("\03" "ive")) break; return; case 'z': if (ends("\03" "ize")) break; return; default: return; } if (m() > 1) k = j; } /* step5() removes a final -e if m() > 1, and changes -ll to -l if m() > 1. */ void step5() { j = k; if (b[k] == 'e') { int a = m(); if (a > 1 || a == 1 && !cvc(k-1)) k--; } if (b[k] == 'l' && doublec(k) && m() > 1) k--; } /* In stem(p,i,j), p is a char pointer, and the string to be stemmed is from p[i] to p[j] inclusive. Typically i is zero and j is the offset to the last character of a string, (p[j+1] == '\0'). The stemmer adjusts the characters p[i] ... p[j] and returns the new end-point of the string, k. Stemming never increases word length, so i <= k <= j. To turn the stemmer into a module, declare 'stem' as extern, and delete the remainder of this file. */ int stem(char * p, int i, int j) { b = p; k = j; k0 = i; /* copy the parameters into statics */ if (k <= k0+1) return k; /*-DEPARTURE-*/ /* With this line, strings of length 1 or 2 don't go through the stemming process, although no mention is made of this in the published algorithm. Remove the line to match the published algorithm. */ step1ab(); step1c(); step2(); step3(); step4(); step5(); return k; } /*--------------------stemmer definition ends here------------------------*/ static char * s; /* a char * (=string) pointer; passed into b above */ #define INC 50 /* size units in which s is increased */ static int i_max = INC; /* maximum offset in s */ void increase_s() { i_max += INC; { char * new_s = (char *) malloc(i_max+1); { int i; for (i = 0; i < i_max; i++) new_s[i] = s[i]; } /* copy across */ free(s); s = new_s; } } #define UC(ch) (ch <= 'Z' && ch >= 'A') #define LC(ch) (ch <= 'z' && ch >= 'a') #define LETTER(ch) (UC(ch) || LC(ch)) #define FORCELC(ch) (ch-('A'-'a')) void stemfile(FILE * f) { while(TRUE) { int ch = getc(f); if (ch == EOF) return; if (LETTER(ch)) { int i = 0; while(TRUE) { if (i == i_max) increase_s(); if UC(ch) ch = FORCELC(ch); /* forces lower case. Remove this line to make the program work exactly like the Muscat stemtext command. */ s[i] = ch; i++; ch = getc(f); if (!LETTER(ch)) { ungetc(ch,f); break; } } s[stem(s,0,i-1)+1] = 0; /* the pevious line calls the stemmer and uses its result to zero-terminate the string in s */ printf("%s",s); } else putchar(ch); } } int main(int argc, char * argv[]) { int i; s = (char *) malloc(i_max+1); for (i = 1; i < argc; i++) { FILE * f = fopen(argv[i],"r"); if (f == 0) { fprintf(stderr,"File %s not found\n",argv[i]); exit(1); } stemfile(f); } free(s); return 0; }