/**
* strgrp - group/cluster similar strings.
*
- * strgrp uses the Longest Common Subsequence (LCS) algorithm[1] to cluster
- * similar strings. It is governed by a threshold which is compared against
- * the computed normalised LCS length for all known groups.
+ * strgrp clusters similar strings using the Longest Common Subsequence (LCS)
+ * algorithm[1]. Clustering is governed by a threshold value, which is compared
+ * with the normalised LCS scores calculated from the input string and each
+ * existing group.
*
* As a coarse and not entirely accurate summary, strgrp takes the following
* steps:
*
- * 1. For all known strings, calculate the normalised LCS value against the
- * input string
+ * 1. For all known groups, calculate the normalised LCS value against the
+ * input string
+ *
* 2. Find the maximum normalised LCS value and associated group
- * 3. If the calculated normalised LCS value exceeds the configured threshold,
- * add the input string to the group, otherwise create a new group
+ *
+ * 3. If the calculated maximum normalised LCS value exceeds the configured
+ * threshold add the input string to the group, otherwise create a new group
*
* The clustering operation is expensive; LCS on its own is computationally
- * O(mn) on its two input strings and optimally requires O(min(m,n)) memory. In
- * general each input string should be compared against all known strings,
- * giving O(n^2) behaviour of the clustering algorithm on top of the O(mn) LCS
- * similarity measurement.
+ * O(m * n) on its two input strings and optimally requires O(min(m, n))
+ * memory. In general each input string should be compared against all known
+ * strings, giving O(n^2) behaviour of the clustering algorithm on top of the
+ * O(m * n) LCS similarity measurement.
*
* strgrp tries to battle this complexity on several fronts:
*
- * 1. Coarse reduction of the required comparisons
- * 1a. Each group has a 'key', which is the string that triggered the creation
- * of the group
- * 1b. Input strings are only compared against group keys rather than all known
- * strings, reducing the complexity to the current number of groups rather
- * than all known strings. Note due the pathological case where the number
- * of groups is equal to the number of known strings the algorithm still
- * has O(n^2) computational complexity
- *
- * 2. Elimination of LCS computations that will never breach the configured
- * threshold
- * 2a. This can be measured from the length of the compared strings
- * 2b. This avoids invoking the O(mn) behaviour of LCS
- *
- * 3. Caching of input strings and their associated group
- * 3a. By incurring the cost of a map's string hash function we may eliminate
- * all calls to the LCS function for exact matches, potentially reducing
- * the insertion to a constant-time operation.
- *
- * 4. Whilst the data dependencies of LCS prevent internally parallel
- * implementations, LCS as a function can be applied in parallel. The code
- * uses OpenMP to automatically and concurrently distribute scoring of the
- * input string against group keys across threads.
+ * 1. Caching of input strings and their associated group. By incurring the
+ * cost of a map's string hash function we may eliminate all further search
+ * costs for exact matches, potentially reducing the insertion to a
+ * constant-time operation.
+ *
+ * 2. Coarse reduction of the required comparisons. Each group has a 'key',
+ * which is the string that triggered the creation of the group. Input strings
+ * are only compared against group keys rather than all known strings, reducing
+ * the complexity to the current number of groups rather than all known
+ * strings. Note due the pathological case where the number of groups is equal
+ * to the number of known strings the algorithm still has O(n^2) computational
+ * complexity
+ *
+ * 3. Whilst the data dependencies of LCS prevent internally parallel
+ * implementations, LCS and other filters can be applied in parallel. The code
+ * uses OpenMP to automatically distribute scoring of the input string
+ * against group keys across a number of threads.
+ *
+ * 4. Elimination of LCS computations that will never breach the configured
+ * threshold. Two measurements are used as rejecting filters (i.e. a failure to
+ * exceed the threshold prevents further measurements being made):
+ *
+ * 4a. Comparsion of string lengths: String lengths must be within given bounds
+ * to satisfy the user-supplied similarity constraint. A negative result avoids
+ * invoking the O(m * n) behaviour of LCS at the cost of O(m + n) in the two
+ * strlen() invocations.
+ *
+ * 4b. Comparison of character distribution: Cosine similarity[2] is used to
+ * measure unordered character similarity between the input strings. The
+ * implementation is again O(m + n), and avoids the O(m * n) behaviour of LCS.
+ *
+ * Performance will vary not only with the number of input strings but
+ * with their lengths and relative similarities. A large number of long input
+ * strings that are relatively similar will give the worst performance.
+ * However to provide some context, strgrp can cluster a real-world test set of
+ * 3500 strings distributed in length between 20 and 100 characters to 85%
+ * similarity on a 4-core 2010-era amd64 laptop in approximately 750ms.
*
* [1] https://en.wikipedia.org/wiki/Longest_common_subsequence_problem
*
+ * [2] https://en.wikipedia.org/wiki/Cosine_similarity
+ *
* License: LGPL
* Author: Andrew Jeffery <andrew@aj.id.au>
*
* Example:
+ * FILE *f;
+ * char *buf;
+ * struct strgrp *ctx;
+ * struct strgrp_iter *iter;
+ * const struct strgrp_grp *grp;
+ * struct strgrp_grp_iter *grp_iter;
+ * const struct strgrp_item *item;
+ *
+ * f = fdopen(0, "r");
* #define BUF_SIZE 512
- * FILE *const f = fdopen(0, "r");
- * char *buf = malloc(BUF_SIZE);
- * struct strgrp *ctx = strgrp_new(0.85);
+ * buf = malloc(BUF_SIZE);
+ * ctx = strgrp_new(0.85);
* while(fgets(buf, BUF_SIZE, f)) {
* buf[strcspn(buf, "\r\n")] = '\0';
* if (!strgrp_add(ctx, buf, NULL)) {
*
* // Re-implement something similar to strgrp_print() via API as an
* // example
- * struct strgrp_iter *iter = strgrp_iter_new(ctx);
- * const struct strgrp_grp *grp;
+ * iter = strgrp_iter_new(ctx);
* while(NULL != (grp = strgrp_iter_next(iter))) {
* printf("%s\n", strgrp_grp_key(grp));
- * struct strgrp_grp_iter *grp_iter = strgrp_grp_iter_new(grp);
- * const struct strgrp_item *item;
+ * grp_iter = strgrp_grp_iter_new(grp);
* while(NULL != (item = strgrp_grp_iter_next(grp_iter))) {
* printf("\t%s\n", strgrp_item_key(item));
* }
* strgrp_grp_iter_free(grp_iter);
* }
+ *
* strgrp_iter_free(iter);
* strgrp_free(ctx);
* free(buf);
return 0;
}
-#if HAVE_OPENMP
if (strcmp(argv[1], "cflags") == 0) {
+#if HAVE_OPENMP
printf("-fopenmp\n");
+#endif
+ printf("-O2\n");
+ return 0;
+ }
+
+ if (strcmp(argv[1], "libs") == 0) {
+ printf("m\n");
return 0;
}
-#endif
return 1;
}