upstream/mercurial-mirror Files · mercurial/mpatch.c

hgweb: support Content Security Policy...

hgweb: support Content Security Policy Content-Security-Policy (CSP) is a web security feature that allows servers to declare what loaded content is allowed to do. For example, a policy can prevent loading of images, JavaScript, CSS, etc unless the source of that content is whitelisted (by hostname, URI scheme, hashes of content, etc). It's a nifty security feature that provides extra mitigation against some attacks, notably XSS. Mitigation against these attacks is important for Mercurial because hgweb renders repository data, which is commonly untrusted. While we make attempts to escape things, etc, there's the possibility that malicious data could be injected into the site content. If this happens today, the full power of the web browser is available to that malicious content. A restrictive CSP policy (defined by the server operator and sent in an HTTP header which is outside the control of malicious content), could restrict browser capabilities and mitigate security problems posed by malicious data. CSP works by emitting an HTTP header declaring the policy that browsers should apply. Ideally, this header would be emitted by a layer above Mercurial (likely the HTTP server doing the WSGI "proxying"). This works for some CSP policies, but not all. For example, policies to allow inline JavaScript may require setting a "nonce" attribute on <script>. This attribute value must be unique and non-guessable. And, the value must be present in the HTTP header and the HTML body. This means that coordinating the value between Mercurial and another HTTP server could be difficult: it is much easier to generate and emit the nonce in a central location. This commit introduces support for emitting a Content-Security-Policy header from hgweb. A config option defines the header value. If present, the header is emitted. A special "%nonce%" syntax in the value triggers generation of a nonce and inclusion in <script> elements in templates. The inclusion of a nonce does not occur unless "%nonce%" is present. This makes this commit completely backwards compatible and the feature opt-in. The nonce is a type 4 UUID, which is the flavor that is randomly generated. It has 122 random bits, which should be plenty to satisfy the guarantees of a nonce.

Yuya Nishihara - - Load All Authors

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      /*

       mpatch.c - efficient binary patching for Mercurial

       This implements a patch algorithm that's O(m + nlog n) where m is the

       size of the output and n is the number of patches.

       Given a list of binary patches, it unpacks each into a hunk list,

       then combines the hunk lists with a treewise recursion to form a

       single hunk list. This hunk list is then applied to the original

       text.

       The text (or binary) fragments are copied directly from their source

       Python objects into a preallocated output string to avoid the

       allocation of intermediate Python objects. Working memory is about 2x

       the total number of hunks.

       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.

      */

      #include <stdlib.h>

      #include <string.h>

      #include "bitmanipulation.h"

      #include "compat.h"

      #include "mpatch.h"

      static struct mpatch_flist *lalloc(ssize_t size)

      {

      	struct mpatch_flist *a = NULL;

      	if (size < 1)

      		size = 1;

      	a = (struct mpatch_flist *)malloc(sizeof(struct mpatch_flist));

      	if (a) {

      		a->base = (struct mpatch_frag *)malloc(sizeof(struct mpatch_frag) * size);

      		if (a->base) {

      			a->head = a->tail = a->base;

      			return a;

      		}

      		free(a);

      	}

      	return NULL;

      }

      void mpatch_lfree(struct mpatch_flist *a)

      {

      	if (a) {

      		free(a->base);

      		free(a);

      	}

      }

      static ssize_t lsize(struct mpatch_flist *a)

      {

      	return a->tail - a->head;

      }

      /* move hunks in source that are less cut to dest, compensating

         for changes in offset. the last hunk may be split if necessary.

      */

      static int gather(struct mpatch_flist *dest, struct mpatch_flist *src, int cut,

      	int offset)

      {

      	struct mpatch_frag *d = dest->tail, *s = src->head;

      	int postend, c, l;

      	while (s != src->tail) {

      		if (s->start + offset >= cut)

      			break; /* we've gone far enough */

      		postend = offset + s->start + s->len;

      		if (postend <= cut) {

      			/* save this hunk */

      			offset += s->start + s->len - s->end;

      			*d++ = *s++;

      		}

      		else {

      			/* break up this hunk */

      			c = cut - offset;

      			if (s->end < c)

      				c = s->end;

      			l = cut - offset - s->start;

      			if (s->len < l)

      				l = s->len;

      			offset += s->start + l - c;

      			d->start = s->start;

      			d->end = c;

      			d->len = l;

      			d->data = s->data;

      			d++;

      			s->start = c;

      			s->len = s->len - l;

      			s->data = s->data + l;

      			break;

      		}

      	}

      	dest->tail = d;

      	src->head = s;

      	return offset;

      }

      /* like gather, but with no output list */

      static int discard(struct mpatch_flist *src, int cut, int offset)

      {

      	struct mpatch_frag *s = src->head;

      	int postend, c, l;

      	while (s != src->tail) {

      		if (s->start + offset >= cut)

      			break;

      		postend = offset + s->start + s->len;

      		if (postend <= cut) {

      			offset += s->start + s->len - s->end;

      			s++;

      		}

      		else {

      			c = cut - offset;

      			if (s->end < c)

      				c = s->end;

      			l = cut - offset - s->start;

      			if (s->len < l)

      				l = s->len;

      			offset += s->start + l - c;

      			s->start = c;

      			s->len = s->len - l;

      			s->data = s->data + l;

      			break;

      		}

      	}

      	src->head = s;

      	return offset;

      }

      /* combine hunk lists a and b, while adjusting b for offset changes in a/

         this deletes a and b and returns the resultant list. */

      static struct mpatch_flist *combine(struct mpatch_flist *a,

      	struct mpatch_flist *b)

      {

      	struct mpatch_flist *c = NULL;

      	struct mpatch_frag *bh, *ct;

      	int offset = 0, post;

      	if (a && b)

      		c = lalloc((lsize(a) + lsize(b)) * 2);

      	if (c) {

      		for (bh = b->head; bh != b->tail; bh++) {

      			/* save old hunks */

      			offset = gather(c, a, bh->start, offset);

      			/* discard replaced hunks */

      			post = discard(a, bh->end, offset);

      			/* insert new hunk */

      			ct = c->tail;

      			ct->start = bh->start - offset;

      			ct->end = bh->end - post;

      			ct->len = bh->len;

      			ct->data = bh->data;

      			c->tail++;

      			offset = post;

      		}

      		/* hold on to tail from a */

      		memcpy(c->tail, a->head, sizeof(struct mpatch_frag) * lsize(a));

      		c->tail += lsize(a);

      	}

      	mpatch_lfree(a);

      	mpatch_lfree(b);

      	return c;

      }

      /* decode a binary patch into a hunk list */

      int mpatch_decode(const char *bin, ssize_t len, struct mpatch_flist **res)

      {

      	struct mpatch_flist *l;

      	struct mpatch_frag *lt;

      	int pos = 0;

      	/* assume worst case size, we won't have many of these lists */

      	l = lalloc(len / 12 + 1);

      	if (!l)

      		return MPATCH_ERR_NO_MEM;

      	lt = l->tail;

      	while (pos >= 0 && pos < len) {

      		lt->start = getbe32(bin + pos);

      		lt->end = getbe32(bin + pos + 4);

      		lt->len = getbe32(bin + pos + 8);

      		lt->data = bin + pos + 12;

      		pos += 12 + lt->len;

      		if (lt->start > lt->end || lt->len < 0)

      			break; /* sanity check */

      		lt++;

      	}

      	if (pos != len) {

      		mpatch_lfree(l);

      		return MPATCH_ERR_CANNOT_BE_DECODED;

      	}

      	l->tail = lt;

      	*res = l;

      	return 0;

      }

      /* calculate the size of resultant text */

      ssize_t mpatch_calcsize(ssize_t len, struct mpatch_flist *l)

      {

      	ssize_t outlen = 0, last = 0;

      	struct mpatch_frag *f = l->head;

      	while (f != l->tail) {

      		if (f->start < last || f->end > len) {

      			return MPATCH_ERR_INVALID_PATCH;

      		}

      		outlen += f->start - last;

      		last = f->end;

      		outlen += f->len;

      		f++;

      	}

      	outlen += len - last;

      	return outlen;

      }

      int mpatch_apply(char *buf, const char *orig, ssize_t len,

      	struct mpatch_flist *l)

      {

      	struct mpatch_frag *f = l->head;

      	int last = 0;

      	char *p = buf;

      	while (f != l->tail) {

      		if (f->start < last || f->end > len) {

      			return MPATCH_ERR_INVALID_PATCH;

      		}

      		memcpy(p, orig + last, f->start - last);

      		p += f->start - last;

      		memcpy(p, f->data, f->len);

      		last = f->end;

      		p += f->len;

      		f++;

      	}

      	memcpy(p, orig + last, len - last);

      	return 0;

      }

      /* recursively generate a patch of all bins between start and end */

      struct mpatch_flist *mpatch_fold(void *bins,

      	struct mpatch_flist* (*get_next_item)(void*, ssize_t),

      	ssize_t start, ssize_t end)

      {

      	ssize_t len;

      	if (start + 1 == end) {

      		/* trivial case, output a decoded list */

      		return get_next_item(bins, start);

      	}

      	/* divide and conquer, memory management is elsewhere */

      	len = (end - start) / 2;

      	return combine(mpatch_fold(bins, get_next_item, start, start + len),

      		       mpatch_fold(bins, get_next_item, start + len, end));

      }

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				/*
				mpatch.c - efficient binary patching for Mercurial

				This implements a patch algorithm that's O(m + nlog n) where m is the
				size of the output and n is the number of patches.

				Given a list of binary patches, it unpacks each into a hunk list,
				then combines the hunk lists with a treewise recursion to form a
				single hunk list. This hunk list is then applied to the original
				text.

				The text (or binary) fragments are copied directly from their source
				Python objects into a preallocated output string to avoid the
				allocation of intermediate Python objects. Working memory is about 2x
				the total number of hunks.

				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.
				*/

				#include <stdlib.h>
				#include <string.h>

				#include "bitmanipulation.h"
				#include "compat.h"
				#include "mpatch.h"

				static struct mpatch_flist *lalloc(ssize_t size)
				{
				struct mpatch_flist *a = NULL;

				if (size < 1)
				size = 1;

				a = (struct mpatch_flist *)malloc(sizeof(struct mpatch_flist));
				if (a) {
				a->base = (struct mpatch_frag )malloc(sizeof(struct mpatch_frag) size);
				if (a->base) {
				a->head = a->tail = a->base;
				return a;
				}
				free(a);
				}
				return NULL;
				}

				void mpatch_lfree(struct mpatch_flist *a)
				{
				if (a) {
				free(a->base);
				free(a);
				}
				}

				static ssize_t lsize(struct mpatch_flist *a)
				{
				return a->tail - a->head;
				}

				/* move hunks in source that are less cut to dest, compensating
				for changes in offset. the last hunk may be split if necessary.
				*/
				static int gather(struct mpatch_flist dest, struct mpatch_flist src, int cut,
				int offset)
				{
				struct mpatch_frag d = dest->tail, s = src->head;
				int postend, c, l;

				while (s != src->tail) {
				if (s->start + offset >= cut)
				break; /* we've gone far enough */

				postend = offset + s->start + s->len;
				if (postend <= cut) {
				/* save this hunk */
				offset += s->start + s->len - s->end;
				d++ = s++;
				}
				else {
				/* break up this hunk */
				c = cut - offset;
				if (s->end < c)
				c = s->end;
				l = cut - offset - s->start;
				if (s->len < l)
				l = s->len;

				offset += s->start + l - c;

				d->start = s->start;
				d->end = c;
				d->len = l;
				d->data = s->data;
				d++;
				s->start = c;
				s->len = s->len - l;
				s->data = s->data + l;

				break;
				}
				}

				dest->tail = d;
				src->head = s;
				return offset;
				}

				/* like gather, but with no output list */
				static int discard(struct mpatch_flist *src, int cut, int offset)
				{
				struct mpatch_frag *s = src->head;
				int postend, c, l;

				while (s != src->tail) {
				if (s->start + offset >= cut)
				break;

				postend = offset + s->start + s->len;
				if (postend <= cut) {
				offset += s->start + s->len - s->end;
				s++;
				}
				else {
				c = cut - offset;
				if (s->end < c)
				c = s->end;
				l = cut - offset - s->start;
				if (s->len < l)
				l = s->len;

				offset += s->start + l - c;
				s->start = c;
				s->len = s->len - l;
				s->data = s->data + l;

				break;
				}
				}

				src->head = s;
				return offset;
				}

				/* combine hunk lists a and b, while adjusting b for offset changes in a/
				this deletes a and b and returns the resultant list. */
				static struct mpatch_flist combine(struct mpatch_flist a,
				struct mpatch_flist *b)
				{
				struct mpatch_flist *c = NULL;
				struct mpatch_frag bh, ct;
				int offset = 0, post;

				if (a && b)
				c = lalloc((lsize(a) + lsize(b)) * 2);

				if (c) {

				for (bh = b->head; bh != b->tail; bh++) {
				/* save old hunks */
				offset = gather(c, a, bh->start, offset);

				/* discard replaced hunks */
				post = discard(a, bh->end, offset);

				/* insert new hunk */
				ct = c->tail;
				ct->start = bh->start - offset;
				ct->end = bh->end - post;
				ct->len = bh->len;
				ct->data = bh->data;
				c->tail++;
				offset = post;
				}

				/* hold on to tail from a */
				memcpy(c->tail, a->head, sizeof(struct mpatch_frag) * lsize(a));
				c->tail += lsize(a);
				}

				mpatch_lfree(a);
				mpatch_lfree(b);
				return c;
				}

				/* decode a binary patch into a hunk list */
				int mpatch_decode(const char bin, ssize_t len, struct mpatch_flist *res)
				{
				struct mpatch_flist *l;
				struct mpatch_frag *lt;
				int pos = 0;

				/* assume worst case size, we won't have many of these lists */
				l = lalloc(len / 12 + 1);
				if (!l)
				return MPATCH_ERR_NO_MEM;

				lt = l->tail;

				while (pos >= 0 && pos < len) {
				lt->start = getbe32(bin + pos);
				lt->end = getbe32(bin + pos + 4);
				lt->len = getbe32(bin + pos + 8);
				lt->data = bin + pos + 12;
				pos += 12 + lt->len;
				if (lt->start > lt->end \|\| lt->len < 0)
				break; /* sanity check */
				lt++;
				}

				if (pos != len) {
				mpatch_lfree(l);
				return MPATCH_ERR_CANNOT_BE_DECODED;
				}

				l->tail = lt;
				*res = l;
				return 0;
				}

				/* calculate the size of resultant text */
				ssize_t mpatch_calcsize(ssize_t len, struct mpatch_flist *l)
				{
				ssize_t outlen = 0, last = 0;
				struct mpatch_frag *f = l->head;

				while (f != l->tail) {
				if (f->start < last \|\| f->end > len) {
				return MPATCH_ERR_INVALID_PATCH;
				}
				outlen += f->start - last;
				last = f->end;
				outlen += f->len;
				f++;
				}

				outlen += len - last;
				return outlen;
				}

				int mpatch_apply(char buf, const char orig, ssize_t len,
				struct mpatch_flist *l)
				{
				struct mpatch_frag *f = l->head;
				int last = 0;
				char *p = buf;

				while (f != l->tail) {
				if (f->start < last \|\| f->end > len) {
				return MPATCH_ERR_INVALID_PATCH;
				}
				memcpy(p, orig + last, f->start - last);
				p += f->start - last;
				memcpy(p, f->data, f->len);
				last = f->end;
				p += f->len;
				f++;
				}
				memcpy(p, orig + last, len - last);
				return 0;
				}

				/* recursively generate a patch of all bins between start and end */
				struct mpatch_flist mpatch_fold(void bins,
				struct mpatch_flist* (get_next_item)(void, ssize_t),
				ssize_t start, ssize_t end)
				{
				ssize_t len;

				if (start + 1 == end) {
				/* trivial case, output a decoded list */
				return get_next_item(bins, start);
				}

				/* divide and conquer, memory management is elsewhere */
				len = (end - start) / 2;
				return combine(mpatch_fold(bins, get_next_item, start, start + len),
				mpatch_fold(bins, get_next_item, start + len, end));
				}