Mercurial > hg
view mercurial/bdiff.c @ 26755:bb0b955d050d
streamclone: support for producing and consuming stream clone bundles
Up to this point, stream clones only existed as a dynamically generated
data format produced and consumed during streaming clones. In order to
support this efficient cloning format with the clone bundles feature, we
need a more formal, on disk representation of the streaming clone data.
This patch introduces a new "bundle" type for streaming clones. Unlike
existing bundles, it does not contain changegroup data. It does,
however, share the same concepts like the 4 byte header which identifies
the type of data that follows and the 2 byte abbreviation for
compression types (of which only "UN" is currently supported).
The new bundle format is essentially the existing stream clone version 1
data format with some headers at the beginning.
Content negotiation at stream clone request time checked for repository
format/requirements compatibility before initiating a stream clone. We
can't do active content negotiation when using clone bundles. So, we put
this set of requirements inside the payload so consumers have a built-in
mechanism for checking compatibility before reading and applying lots of
data. Of course, we will also advertise this requirements set in clone
bundles. But that's for another patch.
We currently don't have a mechanism to produce and consume this new
bundle format. This will be implemented in upcoming patches.
It's worth noting that if a legacy client attempts to `hg unbundle` a
stream clone bundle (with the "HGS1" header), it will abort with:
"unknown bundle version S1," which seems appropriate.
author | Gregory Szorc <gregory.szorc@gmail.com> |
---|---|
date | Sat, 17 Oct 2015 11:14:52 -0700 |
parents | 66b21ce60a19 |
children | e868d8ee7c8f |
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/* bdiff.c - efficient binary diff extension for Mercurial Copyright 2005, 2006 Matt Mackall <mpm@selenic.com> This software may be used and distributed according to the terms of the GNU General Public License, incorporated herein by reference. Based roughly on Python difflib */ #define PY_SSIZE_T_CLEAN #include <Python.h> #include <stdlib.h> #include <string.h> #include <limits.h> #include "util.h" struct line { int hash, n, e; Py_ssize_t len; const char *l; }; struct pos { int pos, len; }; struct hunk; struct hunk { int a1, a2, b1, b2; struct hunk *next; }; static int splitlines(const char *a, Py_ssize_t len, struct line **lr) { unsigned hash; int i; const char *p, *b = a; const char * const plast = a + len - 1; struct line *l; /* count the lines */ i = 1; /* extra line for sentinel */ for (p = a; p < a + len; p++) if (*p == '\n' || p == plast) i++; *lr = l = (struct line *)malloc(sizeof(struct line) * i); if (!l) return -1; /* build the line array and calculate hashes */ hash = 0; for (p = a; p < a + len; p++) { /* Leonid Yuriev's hash */ hash = (hash * 1664525) + (unsigned char)*p + 1013904223; if (*p == '\n' || p == plast) { l->hash = hash; hash = 0; l->len = p - b + 1; l->l = b; l->n = INT_MAX; l++; b = p + 1; } } /* set up a sentinel */ l->hash = 0; l->len = 0; l->l = a + len; return i - 1; } static inline int cmp(struct line *a, struct line *b) { return a->hash != b->hash || a->len != b->len || memcmp(a->l, b->l, a->len); } static int equatelines(struct line *a, int an, struct line *b, int bn) { int i, j, buckets = 1, t, scale; struct pos *h = NULL; /* build a hash table of the next highest power of 2 */ while (buckets < bn + 1) buckets *= 2; /* try to allocate a large hash table to avoid collisions */ for (scale = 4; scale; scale /= 2) { h = (struct pos *)malloc(scale * buckets * sizeof(struct pos)); if (h) break; } if (!h) return 0; buckets = buckets * scale - 1; /* clear the hash table */ for (i = 0; i <= buckets; i++) { h[i].pos = INT_MAX; h[i].len = 0; } /* add lines to the hash table chains */ for (i = bn - 1; i >= 0; i--) { /* find the equivalence class */ for (j = b[i].hash & buckets; h[j].pos != INT_MAX; j = (j + 1) & buckets) if (!cmp(b + i, b + h[j].pos)) break; /* add to the head of the equivalence class */ b[i].n = h[j].pos; b[i].e = j; h[j].pos = i; h[j].len++; /* keep track of popularity */ } /* compute popularity threshold */ t = (bn >= 31000) ? bn / 1000 : 1000000 / (bn + 1); /* match items in a to their equivalence class in b */ for (i = 0; i < an; i++) { /* find the equivalence class */ for (j = a[i].hash & buckets; h[j].pos != INT_MAX; j = (j + 1) & buckets) if (!cmp(a + i, b + h[j].pos)) break; a[i].e = j; /* use equivalence class for quick compare */ if (h[j].len <= t) a[i].n = h[j].pos; /* point to head of match list */ else a[i].n = INT_MAX; /* too popular */ } /* discard hash tables */ free(h); return 1; } static int longest_match(struct line *a, struct line *b, struct pos *pos, int a1, int a2, int b1, int b2, int *omi, int *omj) { int mi = a1, mj = b1, mk = 0, mb = 0, i, j, k; for (i = a1; i < a2; i++) { /* skip things before the current block */ for (j = a[i].n; j < b1; j = b[j].n) ; /* loop through all lines match a[i] in b */ for (; j < b2; j = b[j].n) { /* does this extend an earlier match? */ if (i > a1 && j > b1 && pos[j - 1].pos == i - 1) k = pos[j - 1].len + 1; else k = 1; pos[j].pos = i; pos[j].len = k; /* best match so far? */ if (k > mk) { mi = i; mj = j; mk = k; } } } if (mk) { mi = mi - mk + 1; mj = mj - mk + 1; } /* expand match to include neighboring popular lines */ while (mi - mb > a1 && mj - mb > b1 && a[mi - mb - 1].e == b[mj - mb - 1].e) mb++; while (mi + mk < a2 && mj + mk < b2 && a[mi + mk].e == b[mj + mk].e) mk++; *omi = mi - mb; *omj = mj - mb; return mk + mb; } static struct hunk *recurse(struct line *a, struct line *b, struct pos *pos, int a1, int a2, int b1, int b2, struct hunk *l) { int i, j, k; while (1) { /* find the longest match in this chunk */ k = longest_match(a, b, pos, a1, a2, b1, b2, &i, &j); if (!k) return l; /* and recurse on the remaining chunks on either side */ l = recurse(a, b, pos, a1, i, b1, j, l); if (!l) return NULL; l->next = (struct hunk *)malloc(sizeof(struct hunk)); if (!l->next) return NULL; l = l->next; l->a1 = i; l->a2 = i + k; l->b1 = j; l->b2 = j + k; l->next = NULL; /* tail-recursion didn't happen, so do equivalent iteration */ a1 = i + k; b1 = j + k; } } static int diff(struct line *a, int an, struct line *b, int bn, struct hunk *base) { struct hunk *curr; struct pos *pos; int t, count = 0; /* allocate and fill arrays */ t = equatelines(a, an, b, bn); pos = (struct pos *)calloc(bn ? bn : 1, sizeof(struct pos)); if (pos && t) { /* generate the matching block list */ curr = recurse(a, b, pos, 0, an, 0, bn, base); if (!curr) return -1; /* sentinel end hunk */ curr->next = (struct hunk *)malloc(sizeof(struct hunk)); if (!curr->next) return -1; curr = curr->next; curr->a1 = curr->a2 = an; curr->b1 = curr->b2 = bn; curr->next = NULL; } free(pos); /* normalize the hunk list, try to push each hunk towards the end */ for (curr = base->next; curr; curr = curr->next) { struct hunk *next = curr->next; int shift = 0; if (!next) break; if (curr->a2 == next->a1) while (curr->a2 + shift < an && curr->b2 + shift < bn && !cmp(a + curr->a2 + shift, b + curr->b2 + shift)) shift++; else if (curr->b2 == next->b1) while (curr->b2 + shift < bn && curr->a2 + shift < an && !cmp(b + curr->b2 + shift, a + curr->a2 + shift)) shift++; if (!shift) continue; curr->b2 += shift; next->b1 += shift; curr->a2 += shift; next->a1 += shift; } for (curr = base->next; curr; curr = curr->next) count++; return count; } static void freehunks(struct hunk *l) { struct hunk *n; for (; l; l = n) { n = l->next; free(l); } } static PyObject *blocks(PyObject *self, PyObject *args) { PyObject *sa, *sb, *rl = NULL, *m; struct line *a, *b; struct hunk l, *h; int an, bn, count, pos = 0; l.next = NULL; if (!PyArg_ParseTuple(args, "SS:bdiff", &sa, &sb)) return NULL; an = splitlines(PyBytes_AsString(sa), PyBytes_Size(sa), &a); bn = splitlines(PyBytes_AsString(sb), PyBytes_Size(sb), &b); if (!a || !b) goto nomem; count = diff(a, an, b, bn, &l); if (count < 0) goto nomem; rl = PyList_New(count); if (!rl) goto nomem; for (h = l.next; h; h = h->next) { m = Py_BuildValue("iiii", h->a1, h->a2, h->b1, h->b2); PyList_SetItem(rl, pos, m); pos++; } nomem: free(a); free(b); freehunks(l.next); return rl ? rl : PyErr_NoMemory(); } static PyObject *bdiff(PyObject *self, PyObject *args) { char *sa, *sb, *rb; PyObject *result = NULL; struct line *al, *bl; struct hunk l, *h; int an, bn, count; Py_ssize_t len = 0, la, lb; PyThreadState *_save; l.next = NULL; if (!PyArg_ParseTuple(args, "s#s#:bdiff", &sa, &la, &sb, &lb)) return NULL; if (la > UINT_MAX || lb > UINT_MAX) { PyErr_SetString(PyExc_ValueError, "bdiff inputs too large"); return NULL; } _save = PyEval_SaveThread(); an = splitlines(sa, la, &al); bn = splitlines(sb, lb, &bl); if (!al || !bl) goto nomem; count = diff(al, an, bl, bn, &l); if (count < 0) goto nomem; /* calculate length of output */ la = lb = 0; for (h = l.next; h; h = h->next) { if (h->a1 != la || h->b1 != lb) len += 12 + bl[h->b1].l - bl[lb].l; la = h->a2; lb = h->b2; } PyEval_RestoreThread(_save); _save = NULL; result = PyBytes_FromStringAndSize(NULL, len); if (!result) goto nomem; /* build binary patch */ rb = PyBytes_AsString(result); la = lb = 0; for (h = l.next; h; h = h->next) { if (h->a1 != la || h->b1 != lb) { len = bl[h->b1].l - bl[lb].l; putbe32((uint32_t)(al[la].l - al->l), rb); putbe32((uint32_t)(al[h->a1].l - al->l), rb + 4); putbe32((uint32_t)len, rb + 8); memcpy(rb + 12, bl[lb].l, len); rb += 12 + len; } la = h->a2; lb = h->b2; } nomem: if (_save) PyEval_RestoreThread(_save); free(al); free(bl); freehunks(l.next); return result ? result : PyErr_NoMemory(); } /* * If allws != 0, remove all whitespace (' ', \t and \r). Otherwise, * reduce whitespace sequences to a single space and trim remaining whitespace * from end of lines. */ static PyObject *fixws(PyObject *self, PyObject *args) { PyObject *s, *result = NULL; char allws, c; const char *r; Py_ssize_t i, rlen, wlen = 0; char *w; if (!PyArg_ParseTuple(args, "Sb:fixws", &s, &allws)) return NULL; r = PyBytes_AsString(s); rlen = PyBytes_Size(s); w = (char *)malloc(rlen ? rlen : 1); if (!w) goto nomem; for (i = 0; i != rlen; i++) { c = r[i]; if (c == ' ' || c == '\t' || c == '\r') { if (!allws && (wlen == 0 || w[wlen - 1] != ' ')) w[wlen++] = ' '; } else if (c == '\n' && !allws && wlen > 0 && w[wlen - 1] == ' ') { w[wlen - 1] = '\n'; } else { w[wlen++] = c; } } result = PyBytes_FromStringAndSize(w, wlen); nomem: free(w); return result ? result : PyErr_NoMemory(); } static char mdiff_doc[] = "Efficient binary diff."; static PyMethodDef methods[] = { {"bdiff", bdiff, METH_VARARGS, "calculate a binary diff\n"}, {"blocks", blocks, METH_VARARGS, "find a list of matching lines\n"}, {"fixws", fixws, METH_VARARGS, "normalize diff whitespaces\n"}, {NULL, NULL} }; #ifdef IS_PY3K static struct PyModuleDef bdiff_module = { PyModuleDef_HEAD_INIT, "bdiff", mdiff_doc, -1, methods }; PyMODINIT_FUNC PyInit_bdiff(void) { return PyModule_Create(&bdiff_module); } #else PyMODINIT_FUNC initbdiff(void) { Py_InitModule3("bdiff", methods, mdiff_doc); } #endif