tor/src/common/di_ops.c

/* Copyright (c) 2011, The Tor Project, Inc. */
/* See LICENSE for licensing information */

/**
 * \file di_ops.c
 * \brief Functions for data-independent operations
 **/

#include "orconfig.h"
#include "di_ops.h"

/**
 * Timing-safe version of memcmp.  As memcmp, compare the <b>sz</b> bytes
 * at <b>a</b> with the <b>sz</b> bytes at <b>, and returns less than 0 if the
 * bytes at <b>a</b> lexically precede those at <b>b</b>, 0 if the byte ranges
 * are equal, and greater than zero if the bytes at <b>a</b> lexically follow
 * those at <b>.
 *
 * This implementation differs from memcmp in that its timing behavior is not
 * data-dependent: it should return in the same amount of time regardless of
 * the contents of <b>a</b> and <b>b</b>.
 */
int
tor_memcmp(const void *a, const void *b, size_t len)
{
  const uint8_t *x = a;
  const uint8_t *y = b;
  size_t i = len;
  int retval = 0;

  /* This loop goes from the end of the arrays to the start.  At the
   * start of every iteration, before we decrement i, we have set
   * "retval" equal to the result of memcmp(a+i,b+i,len-i).  During the
   * loop, we update retval by leaving it unchanged if x[i]==y[i] and
   * setting it to x[i]-y[i] if x[i]!= y[i].
   *
   * The following assumes we are on a system with two's-complement
   * arithmetic.  We check for this at configure-time with the check
   * that sets USING_TWOS_COMPLEMENT.  If we aren't two's complement, then
   * torint.h will stop compilation with an error.
   */
  while (i--) {
    int v1 = x[i];
    int v2 = y[i];
    int equal_p = v1 ^ v2;

    /* The following sets bits 8 and above of equal_p to 'equal_p ==
     * 0', and thus to v1 == v2.  (To see this, note that if v1 ==
     * v2, then v1^v2 == equal_p == 0, so equal_p-1 == -1, which is the
     * same as ~0 on a two's-complement machine.  Then note that if
     * v1 != v2, then 0 < v1 ^ v2 < 256, so 0 <= equal_p - 1 < 255.)
     */
    --equal_p;

    equal_p >>= 8;
    /* Thanks to (sign-preserving) arithmetic shift, equal_p is now
     * equal to -(v1 == v2), which is exactly what we need below.
     * (Since we're assuming two's-complement arithmetic, -1 is the
     * same as ~0 (all bits set).)
     *
     * (The result of an arithmetic shift on a negative value is
     * actually implementation-defined in standard C.  So how do we
     * get away with assuming it?  Easy.  We check.) */
#if ((-60 >> 8) != -1)
#error "According to cpp, right-shift doesn't perform sign-extension."
#endif
#ifndef RSHIFT_DOES_SIGN_EXTEND
#error "According to configure, right-shift doesn't perform sign-extension."
#endif

    /* If v1 == v2, equal_p is ~0, so this will leave retval
     * unchanged; otherwise, equal_p is 0, so this will zero it. */
    retval &= equal_p;

    /* If v1 == v2, then this adds 0, and leaves retval unchanged.
     * Otherwise, we just zeroed retval, so this sets it to v1 - v2. */
    retval += (v1 - v2);

    /* There.  Now retval is equal to its previous value if v1 == v2, and
     * equal to v1 - v2 if v1 != v2. */
  }

  return retval;
}

/**
 * Timing-safe memory comparison.  Return true if the <b>sz</b> bytes at
 * <b>a</b> are the same as the <b>sz</b> bytes at <b>, and 0 otherwise.
 *
 * This implementation differs from !memcmp(a,b,sz) in that its timing
 * behavior is not data-dependent: it should return in the same amount of time
 * regardless of the contents of <b>a</b> and <b>b</b>.  It differs from
 * !tor_memcmp(a,b,sz) by being faster.
 */
int
tor_memeq(const void *a, const void *b, size_t sz)
{
  /* Treat a and b as byte ranges. */
  const uint8_t *ba = a, *bb = b;
  uint32_t any_difference = 0;
  while (sz--) {
    /* Set byte_diff to all of those bits that are different in *ba and *bb,
     * and advance both ba and bb. */
    const uint8_t byte_diff = *ba++ ^ *bb++;

    /* Set bits in any_difference if they are set in byte_diff. */
    any_difference |= byte_diff;
  }

  /* Now any_difference is 0 if there are no bits different between
   * a and b, and is nonzero if there are bits different between a
   * and b.  Now for paranoia's sake, let's convert it to 0 or 1.
   *
   * (If we say "!any_difference", the compiler might get smart enough
   * to optimize-out our data-independence stuff above.)
   *
   * To unpack:
   *
   * If any_difference == 0:
   *            any_difference - 1 == ~0
   *     (any_difference - 1) >> 8 == 0x00ffffff
   *     1 & ((any_difference - 1) >> 8) == 1
   *
   * If any_difference != 0:
   *            0 < any_difference < 256, so
   *            0 < any_difference - 1 < 255
   *            (any_difference - 1) >> 8 == 0
   *            1 & ((any_difference - 1) >> 8) == 0
   */

  return 1 & ((any_difference - 1) >> 8);
}
Add a data-independent variant of memcmp and a d-i memeq function. The tor_memcmp code is by Robert Ransom, and the tor_memeq code is by me. Both incorporate some ideas from DJB's stuff. 2011-05-10 00:39:23 +02:00			`/* Copyright (c) 2011, The Tor Project, Inc. */`
			`/* See LICENSE for licensing information */`

			`/**`
			`* \file di_ops.c`
			`* \brief Functions for data-independent operations`
			`**/`

			`#include "orconfig.h"`
			`#include "di_ops.h"`

			`/**`
			`* Timing-safe version of memcmp. As memcmp, compare the <b>sz</b> bytes`
			`* at <b>a</b> with the <b>sz</b> bytes at <b>, and returns less than 0 if the`
			`* bytes at <b>a</b> lexically precede those at <b>b</b>, 0 if the byte ranges`
			`* are equal, and greater than zero if the bytes at <b>a</b> lexically follow`
			`* those at <b>.`
			`*`
			`* This implementation differs from memcmp in that its timing behavior is not`
			`* data-dependent: it should return in the same amount of time regardless of`
			`* the contents of <b>a</b> and <b>b</b>.`
			`*/`
			`int`
			`tor_memcmp(const void a, const void b, size_t len)`
			`{`
			`const uint8_t *x = a;`
			`const uint8_t *y = b;`
			`size_t i = len;`
			`int retval = 0;`

			`/* This loop goes from the end of the arrays to the start. At the`
			`* start of every iteration, before we decrement i, we have set`
			`* "retval" equal to the result of memcmp(a+i,b+i,len-i). During the`
			`* loop, we update retval by leaving it unchanged if x[i]==y[i] and`
			`* setting it to x[i]-y[i] if x[i]!= y[i].`
			`*`
			`* The following assumes we are on a system with two's-complement`
			`* arithmetic. We check for this at configure-time with the check`
			`* that sets USING_TWOS_COMPLEMENT. If we aren't two's complement, then`
			`* torint.h will stop compilation with an error.`
			`*/`
			`while (i--) {`
			`int v1 = x[i];`
			`int v2 = y[i];`
			`int equal_p = v1 ^ v2;`

			`/* The following sets bits 8 and above of equal_p to 'equal_p ==`
			`* 0', and thus to v1 == v2. (To see this, note that if v1 ==`
			`* v2, then v1^v2 == equal_p == 0, so equal_p-1 == -1, which is the`
			`* same as ~0 on a two's-complement machine. Then note that if`
			`* v1 != v2, then 0 < v1 ^ v2 < 256, so 0 <= equal_p - 1 < 255.)`
			`*/`
			`--equal_p;`

			`equal_p >>= 8;`
			`/* Thanks to (sign-preserving) arithmetic shift, equal_p is now`
			`* equal to -(v1 == v2), which is exactly what we need below.`
			`* (Since we're assuming two's-complement arithmetic, -1 is the`
			`* same as ~0 (all bits set).)`
			`*`
			`* (The result of an arithmetic shift on a negative value is`
			`* actually implementation-defined in standard C. So how do we`
			`* get away with assuming it? Easy. We check.) */`
			`#if ((-60 >> 8) != -1)`
			`#error "According to cpp, right-shift doesn't perform sign-extension."`
			`#endif`
			`#ifndef RSHIFT_DOES_SIGN_EXTEND`
			`#error "According to configure, right-shift doesn't perform sign-extension."`
			`#endif`

			`/* If v1 == v2, equal_p is ~0, so this will leave retval`
			`* unchanged; otherwise, equal_p is 0, so this will zero it. */`
			`retval &= equal_p;`

			`/* If v1 == v2, then this adds 0, and leaves retval unchanged.`
			`* Otherwise, we just zeroed retval, so this sets it to v1 - v2. */`
			`retval += (v1 - v2);`

			`/* There. Now retval is equal to its previous value if v1 == v2, and`
			`* equal to v1 - v2 if v1 != v2. */`
			`}`

			`return retval;`
			`}`

			`/**`
			`* Timing-safe memory comparison. Return true if the <b>sz</b> bytes at`
			`* <b>a</b> are the same as the <b>sz</b> bytes at <b>, and 0 otherwise.`
			`*`
			`* This implementation differs from !memcmp(a,b,sz) in that its timing`
			`* behavior is not data-dependent: it should return in the same amount of time`
			`* regardless of the contents of <b>a</b> and <b>b</b>. It differs from`
			`* !tor_memcmp(a,b,sz) by being faster.`
			`*/`
			`int`
			`tor_memeq(const void a, const void b, size_t sz)`
			`{`
			`/* Treat a and b as byte ranges. */`
			`const uint8_t ba = a, bb = b;`
			`uint32_t any_difference = 0;`
			`while (sz--) {`
			`/* Set byte_diff to all of those bits that are different in ba and bb,`
			`* and advance both ba and bb. */`
			`const uint8_t byte_diff = ba++ ^ bb++;`

			`/* Set bits in any_difference if they are set in byte_diff. */`
			`any_difference \|= byte_diff;`
			`}`

			`/* Now any_difference is 0 if there are no bits different between`
			`* a and b, and is nonzero if there are bits different between a`
			`* and b. Now for paranoia's sake, let's convert it to 0 or 1.`
			`*`
			`* (If we say "!any_difference", the compiler might get smart enough`
			`* to optimize-out our data-independence stuff above.)`
			`*`
			`* To unpack:`
			`*`
			`* If any_difference == 0:`
			`* any_difference - 1 == ~0`
			`* (any_difference - 1) >> 8 == 0x00ffffff`
			`* 1 & ((any_difference - 1) >> 8) == 1`
			`*`
			`* If any_difference != 0:`
			`* 0 < any_difference < 256, so`
			`* 0 < any_difference - 1 < 255`
			`* (any_difference - 1) >> 8 == 0`
			`* 1 & ((any_difference - 1) >> 8) == 0`
			`*/`

			`return 1 & ((any_difference - 1) >> 8);`
			`}`