File openssl-CVE-2022-4304-1of2.patch of Package openssl-1_1.27651

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File openssl-CVE-2022-4304-1of2.patch of Package openssl-1_1.27651

commit 0ee66695c4bcb209919d3c7ee88ce46440b29f46
Author: Matt Caswell <matt@openssl.org>
Date:   Fri Jan 20 15:26:54 2023 +0000

Fix Timing Oracle in RSA decryption
    
    A timing based side channel exists in the OpenSSL RSA Decryption
    implementation which could be sufficient to recover a ciphertext across
    a network in a Bleichenbacher style attack. To achieve a successful
    decryption an attacker would have to be able to send a very large number
    of trial messages for decryption. The vulnerability affects all RSA
    padding modes: PKCS#1 v1.5, RSA-OEAP and RSASVE.
    
    Patch written by Dmitry Belyavsky and Hubert Kario
    
    CVE-2022-4304

Index: openssl-1.1.1l/crypto/bn/bn_blind.c
===================================================================
--- openssl-1.1.1l.orig/crypto/bn/bn_blind.c
+++ openssl-1.1.1l/crypto/bn/bn_blind.c
@@ -13,20 +13,6 @@
 
 #define BN_BLINDING_COUNTER     32
 
-struct bn_blinding_st {
-    BIGNUM *A;
-    BIGNUM *Ai;
-    BIGNUM *e;
-    BIGNUM *mod;                /* just a reference */
-    CRYPTO_THREAD_ID tid;
-    int counter;
-    unsigned long flags;
-    BN_MONT_CTX *m_ctx;
-    int (*bn_mod_exp) (BIGNUM *r, const BIGNUM *a, const BIGNUM *p,
-                       const BIGNUM *m, BN_CTX *ctx, BN_MONT_CTX *m_ctx);
-    CRYPTO_RWLOCK *lock;
-};
-
 BN_BLINDING *BN_BLINDING_new(const BIGNUM *A, const BIGNUM *Ai, BIGNUM *mod)
 {
     BN_BLINDING *ret = NULL;
Index: openssl-1.1.1l/crypto/bn/bn_local.h
===================================================================
--- openssl-1.1.1l.orig/crypto/bn/bn_local.h
+++ openssl-1.1.1l/crypto/bn/bn_local.h
@@ -264,6 +264,20 @@ struct bn_gencb_st {
     } cb;
 };
 
+struct bn_blinding_st {
+    BIGNUM *A;
+    BIGNUM *Ai;
+    BIGNUM *e;
+    BIGNUM *mod;                /* just a reference */
+    CRYPTO_THREAD_ID tid;
+    int counter;
+    unsigned long flags;
+    BN_MONT_CTX *m_ctx;
+    int (*bn_mod_exp) (BIGNUM *r, const BIGNUM *a, const BIGNUM *p,
+                       const BIGNUM *m, BN_CTX *ctx, BN_MONT_CTX *m_ctx);
+    CRYPTO_RWLOCK *lock;
+};
+
 /*-
  * BN_window_bits_for_exponent_size -- macro for sliding window mod_exp functions
  *
Index: openssl-1.1.1l/crypto/err/openssl.txt
===================================================================
--- openssl-1.1.1l.orig/crypto/err/openssl.txt
+++ openssl-1.1.1l/crypto/err/openssl.txt
@@ -1129,6 +1129,7 @@ RAND_F_RAND_POOL_NEW:116:rand_pool_new
 RAND_F_RAND_PSEUDO_BYTES:126:RAND_pseudo_bytes
 RAND_F_RAND_WRITE_FILE:112:RAND_write_file
 RSA_F_CHECK_PADDING_MD:140:check_padding_md
+RSA_F_DO_UNBLIND:168:do_unblind
 RSA_F_ENCODE_PKCS1:146:encode_pkcs1
 RSA_F_FIPS_RSA_BUILTIN_KEYGEN:168:fips_rsa_builtin_keygen
 RSA_F_INT_RSA_VERIFY:145:int_rsa_verify
Index: openssl-1.1.1l/crypto/rsa/build.info
===================================================================
--- openssl-1.1.1l.orig/crypto/rsa/build.info
+++ openssl-1.1.1l/crypto/rsa/build.info
@@ -3,4 +3,4 @@ SOURCE[../../libcrypto]=\
         rsa_ossl.c rsa_gen.c rsa_lib.c rsa_sign.c rsa_saos.c rsa_err.c \
         rsa_pk1.c rsa_ssl.c rsa_none.c rsa_oaep.c rsa_chk.c \
         rsa_pss.c rsa_x931.c rsa_asn1.c rsa_depr.c rsa_ameth.c rsa_prn.c \
-        rsa_pmeth.c rsa_crpt.c rsa_x931g.c rsa_meth.c rsa_mp.c
+        rsa_pmeth.c rsa_crpt.c rsa_x931g.c rsa_meth.c rsa_mp.c rsa_sup_mul.c
Index: openssl-1.1.1l/crypto/rsa/rsa_err.c
===================================================================
--- openssl-1.1.1l.orig/crypto/rsa/rsa_err.c
+++ openssl-1.1.1l/crypto/rsa/rsa_err.c
@@ -15,6 +15,7 @@
 
 static const ERR_STRING_DATA RSA_str_functs[] = {
     {ERR_PACK(ERR_LIB_RSA, RSA_F_CHECK_PADDING_MD, 0), "check_padding_md"},
+    {ERR_PACK(ERR_LIB_RSA, RSA_F_DO_UNBLIND, 0), "do_unblind"},
     {ERR_PACK(ERR_LIB_RSA, RSA_F_ENCODE_PKCS1, 0), "encode_pkcs1"},
     {ERR_PACK(ERR_LIB_RSA, RSA_F_FIPS_RSA_BUILTIN_KEYGEN, 0),
      "fips_rsa_builtin_keygen"},
Index: openssl-1.1.1l/crypto/rsa/rsa_ossl.c
===================================================================
--- openssl-1.1.1l.orig/crypto/rsa/rsa_ossl.c
+++ openssl-1.1.1l/crypto/rsa/rsa_ossl.c
@@ -10,6 +10,7 @@
 #include "internal/cryptlib.h"
 #include "crypto/bn.h"
 #include "rsa_local.h"
+#include "rsa_sup_mul.h"
 #include "internal/constant_time.h"
 
 #ifdef OPENSSL_FIPS
@@ -523,11 +524,19 @@ static int rsa_ossl_private_decrypt(int
         BN_free(d);
     }
 
-    if (blinding)
-        if (!rsa_blinding_invert(blinding, ret, unblind, ctx))
+    if (blinding) {
+        /*
+         * do_unblind combines blinding inversion and
+         * 0-padded BN BE serialization
+         */
+        j = do_unblind(ret, blinding, unblind, rsa->n, ctx, buf, num);
+        if (j == 0)
             goto err;
-
-    j = BN_bn2binpad(ret, buf, num);
+    } else {
+        j = BN_bn2binpad(ret, buf, num);
+        if (j < 0)
+            goto err;
+    }
 
     switch (padding) {
     case RSA_PKCS1_PADDING:
Index: openssl-1.1.1l/crypto/rsa/rsa_sup_mul.c
===================================================================
--- /dev/null
+++ openssl-1.1.1l/crypto/rsa/rsa_sup_mul.c
@@ -0,0 +1,600 @@
+#include <openssl/e_os2.h>
+#include <stddef.h>
+#include <sys/types.h>
+#include <string.h>
+#include "openssl/bn.h"
+#include "rsa_sup_mul.h"
+#include "crypto/bn/bn_local.h"
+#include "internal/numbers.h"
+#include "internal/constant_time.h"
+#include <openssl/err.h>
+#include <openssl/rsaerr.h>
+
+# if BN_BYTES == 8
+typedef uint64_t limb_t;
+#  if defined(__SIZEOF_INT128__) && __SIZEOF_INT128__ == 16
+/* nonstandard; implemented by gcc on 64-bit platforms */
+typedef __uint128_t limb2_t;
+#   define HAVE_LIMB2_T
+#  endif
+#  define LIMB_BIT_SIZE 64
+#  define LIMB_BYTE_SIZE 8
+# elif BN_BYTES == 4
+typedef uint32_t limb_t;
+typedef uint64_t limb2_t;
+#  define LIMB_BIT_SIZE 32
+#  define LIMB_BYTE_SIZE 4
+#  define HAVE_LIMB2_T
+# else
+#  error "Not supported"
+# endif
+
+/*
+ * For multiplication we're using schoolbook multiplication,
+ * so if we have two numbers, each with 6 "digits" (words)
+ * the multiplication is calculated as follows:
+ *                        A B C D E F
+ *                     x  I J K L M N
+ *                     --------------
+ *                                N*F
+ *                              N*E
+ *                            N*D
+ *                          N*C
+ *                        N*B
+ *                      N*A
+ *                              M*F
+ *                            M*E
+ *                          M*D
+ *                        M*C
+ *                      M*B
+ *                    M*A
+ *                            L*F
+ *                          L*E
+ *                        L*D
+ *                      L*C
+ *                    L*B
+ *                  L*A
+ *                          K*F
+ *                        K*E
+ *                      K*D
+ *                    K*C
+ *                  K*B
+ *                K*A
+ *                        J*F
+ *                      J*E
+ *                    J*D
+ *                  J*C
+ *                J*B
+ *              J*A
+ *                      I*F
+ *                    I*E
+ *                  I*D
+ *                I*C
+ *              I*B
+ *         +  I*A
+ *         ==========================
+ *                        N*B N*D N*F
+ *                    + N*A N*C N*E
+ *                    + M*B M*D M*F
+ *                  + M*A M*C M*E
+ *                  + L*B L*D L*F
+ *                + L*A L*C L*E
+ *                + K*B K*D K*F
+ *              + K*A K*C K*E
+ *              + J*B J*D J*F
+ *            + J*A J*C J*E
+ *            + I*B I*D I*F
+ *          + I*A I*C I*E
+ *
+ *                1+1 1+3 1+5
+ *              1+0 1+2 1+4
+ *              0+1 0+3 0+5
+ *            0+0 0+2 0+4
+ *
+ *            0 1 2 3 4 5 6
+ * which requires n^2 multiplications and 2n full length additions
+ * as we can keep every other result of limb multiplication in two separate
+ * limbs
+ */
+
+#if defined HAVE_LIMB2_T
+static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
+{
+    limb2_t t;
+    /*
+     * this is idiomatic code to tell compiler to use the native mul
+     * those three lines will actually compile to single instruction
+     */
+
+    t = (limb2_t)a * b;
+    *hi = t >> LIMB_BIT_SIZE;
+    *lo = t & -1UL;
+}
+#elif (BN_BYTES == 8) && (defined _MSC_VER)
+/* https://learn.microsoft.com/en-us/cpp/intrinsics/mul128?view=msvc-170 */
+#pragma intrinsic(_mul128)
+static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
+{
+    *lo = _mul128(a, b, hi);
+}
+#else
+/*
+ * if the compiler doesn't have either a 128bit data type nor a "return
+ * high 64 bits of multiplication"
+ */
+static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
+{
+    limb_t a_low = (limb_t)(uint32_t)a;
+    limb_t a_hi = a >> 32;
+    limb_t b_low = (limb_t)(uint32_t)b;
+    limb_t b_hi = b >> 32;
+
+    limb_t p0 = a_low * b_low;
+    limb_t p1 = a_low * b_hi;
+    limb_t p2 = a_hi * b_low;
+    limb_t p3 = a_hi * b_hi;
+
+    uint32_t cy = (uint32_t)(((p0 >> 32) + (uint32_t)p1 + (uint32_t)p2) >> 32);
+
+    *lo = p0 + (p1 << 32) + (p2 << 32);
+    *hi = p3 + (p1 >> 32) + (p2 >> 32) + cy;
+}
+#endif
+
+/* add two limbs with carry in, return carry out */
+static ossl_inline limb_t _add_limb(limb_t *ret, limb_t a, limb_t b, limb_t carry)
+{
+    limb_t carry1, carry2, t;
+    /*
+     * `c = a + b; if (c < a)` is idiomatic code that makes compilers
+     * use add with carry on assembly level
+     */
+
+    *ret = a + carry;
+    if (*ret < a)
+        carry1 = 1;
+    else
+        carry1 = 0;
+
+    t = *ret;
+    *ret = t + b;
+    if (*ret < t)
+        carry2 = 1;
+    else
+        carry2 = 0;
+
+    return carry1 + carry2;
+}
+
+/*
+ * add two numbers of the same size, return overflow
+ *
+ * add a to b, place result in ret; all arrays need to be n limbs long
+ * return overflow from addition (0 or 1)
+ */
+static ossl_inline limb_t add(limb_t *ret, limb_t *a, limb_t *b, size_t n)
+{
+    limb_t c = 0;
+    ossl_ssize_t i;
+
+    for(i = n - 1; i > -1; i--)
+        c = _add_limb(&ret[i], a[i], b[i], c);
+
+    return c;
+}
+
+/*
+ * return number of limbs necessary for temporary values
+ * when multiplying numbers n limbs large
+ */
+static ossl_inline size_t mul_limb_numb(size_t n)
+{
+    return  2 * n * 2;
+}
+
+/*
+ * multiply two numbers of the same size
+ *
+ * multiply a by b, place result in ret; a and b need to be n limbs long
+ * ret needs to be 2*n limbs long, tmp needs to be mul_limb_numb(n) limbs
+ * long
+ */
+static void limb_mul(limb_t *ret, limb_t *a, limb_t *b, size_t n, limb_t *tmp)
+{
+    limb_t *r_odd, *r_even;
+    size_t i, j, k;
+
+    r_odd = tmp;
+    r_even = &tmp[2 * n];
+
+    memset(ret, 0, 2 * n * sizeof(limb_t));
+
+    for (i = 0; i < n; i++) {
+        for (k = 0; k < i + n + 1; k++) {
+            r_even[k] = 0;
+            r_odd[k] = 0;
+        }
+        for (j = 0; j < n; j++) {
+            /*
+	     * place results from even and odd limbs in separate arrays so that
+             * we don't have to calculate overflow every time we get individual
+             * limb multiplication result
+	     */
+            if (j % 2 == 0)
+                _mul_limb(&r_even[i + j], &r_even[i + j + 1], a[i], b[j]);
+            else
+                _mul_limb(&r_odd[i + j], &r_odd[i + j + 1], a[i], b[j]);
+        }
+        /*
+	 * skip the least significant limbs when adding multiples of
+         * more significant limbs (they're zero anyway)
+	 */
+        add(ret, ret, r_even, n + i + 1);
+        add(ret, ret, r_odd, n + i + 1);
+    }
+}
+
+/* modifies the value in place by performing a right shift by one bit */
+static ossl_inline void rshift1(limb_t *val, size_t n)
+{
+    limb_t shift_in = 0, shift_out = 0;
+    size_t i;
+
+    for (i = 0; i < n; i++) {
+        shift_out = val[i] & 1;
+        val[i] = shift_in << (LIMB_BIT_SIZE - 1) | (val[i] >> 1);
+        shift_in = shift_out;
+    }
+}
+
+/* extend the LSB of flag to all bits of limb */
+static ossl_inline limb_t mk_mask(limb_t flag)
+{
+    flag |= flag << 1;
+    flag |= flag << 2;
+    flag |= flag << 4;
+    flag |= flag << 8;
+    flag |= flag << 16;
+#if (LIMB_BYTE_SIZE == 8)
+    flag |= flag << 32;
+#endif
+    return flag;
+}
+
+/*
+ * copy from either a or b to ret based on flag
+ * when flag == 0, then copies from b
+ * when flag == 1, then copies from a
+ */
+static ossl_inline void cselect(limb_t flag, limb_t *ret, limb_t *a, limb_t *b, size_t n)
+{
+    /*
+     * would be more efficient with non volatile mask, but then gcc
+     * generates code with jumps
+     */
+    volatile limb_t mask;
+    size_t i;
+
+    mask = mk_mask(flag);
+    for (i = 0; i < n; i++) {
+#if (LIMB_BYTE_SIZE == 8)
+        ret[i] = constant_time_select_64(mask, a[i], b[i]);
+#else
+        ret[i] = constant_time_select_32(mask, a[i], b[i]);
+#endif
+    }
+}
+
+static limb_t _sub_limb(limb_t *ret, limb_t a, limb_t b, limb_t borrow)
+{
+    limb_t borrow1, borrow2, t;
+    /*
+     * while it doesn't look constant-time, this is idiomatic code
+     * to tell compilers to use the carry bit from subtraction
+     */
+
+    *ret = a - borrow;
+    if (*ret > a)
+        borrow1 = 1;
+    else
+        borrow1 = 0;
+
+    t = *ret;
+    *ret = t - b;
+    if (*ret > t)
+        borrow2 = 1;
+    else
+        borrow2 = 0;
+
+    return borrow1 + borrow2;
+}
+
+/*
+ * place the result of a - b into ret, return the borrow bit.
+ * All arrays need to be n limbs long
+ */
+static limb_t sub(limb_t *ret, limb_t *a, limb_t *b, size_t n)
+{
+    limb_t borrow = 0;
+    ossl_ssize_t i;
+
+    for (i = n - 1; i > -1; i--)
+        borrow = _sub_limb(&ret[i], a[i], b[i], borrow);
+
+    return borrow;
+}
+
+/* return the number of limbs necessary to allocate for the mod() tmp operand */
+static ossl_inline size_t mod_limb_numb(size_t anum, size_t modnum)
+{
+    return (anum + modnum) * 3;
+}
+
+/*
+ * calculate a % mod, place the result in ret
+ * size of a is defined by anum, size of ret and mod is modnum,
+ * size of tmp is returned by mod_limb_numb()
+ */
+static void mod(limb_t *ret, limb_t *a, size_t anum, limb_t *mod,
+               size_t modnum, limb_t *tmp)
+{
+    limb_t *atmp, *modtmp, *rettmp;
+    limb_t res;
+    size_t i;
+
+    memset(tmp, 0, mod_limb_numb(anum, modnum) * LIMB_BYTE_SIZE);
+
+    atmp = tmp;
+    modtmp = &tmp[anum + modnum];
+    rettmp = &tmp[(anum + modnum) * 2];
+
+    for (i = modnum; i <modnum + anum; i++)
+        atmp[i] = a[i-modnum];
+
+    for (i = 0; i < modnum; i++)
+        modtmp[i] = mod[i];
+
+    for (i = 0; i < anum * LIMB_BIT_SIZE; i++) {
+        rshift1(modtmp, anum + modnum);
+        res = sub(rettmp, atmp, modtmp, anum+modnum);
+        cselect(res, atmp, atmp, rettmp, anum+modnum);
+    }
+
+    memcpy(ret, &atmp[anum], sizeof(limb_t) * modnum);
+}
+
+/* necessary size of tmp for a _mul_add_limb() call with provided anum */
+static ossl_inline size_t _mul_add_limb_numb(size_t anum)
+{
+    return 2 * (anum + 1);
+}
+
+/* multiply a by m, add to ret, return carry */
+static limb_t _mul_add_limb(limb_t *ret, limb_t *a, size_t anum,
+                           limb_t m, limb_t *tmp)
+{
+    limb_t carry = 0;
+    limb_t *r_odd, *r_even;
+    size_t i;
+
+    memset(tmp, 0, sizeof(limb_t) * (anum + 1) * 2);
+
+    r_odd = tmp;
+    r_even = &tmp[anum + 1];
+
+    for (i = 0; i < anum; i++) {
+        /*
+	 * place the results from even and odd limbs in separate arrays
+         * so that we have to worry about carry just once
+	 */
+        if (i % 2 == 0)
+            _mul_limb(&r_even[i], &r_even[i + 1], a[i], m);
+        else
+            _mul_limb(&r_odd[i], &r_odd[i + 1], a[i], m);
+    }
+    /* assert: add() carry here will be equal zero */
+    add(r_even, r_even, r_odd, anum + 1);
+    /*
+     * while here it will not overflow as the max value from multiplication
+     * is -2 while max overflow from addition is 1, so the max value of
+     * carry is -1 (i.e. max int)
+     */
+    carry = add(ret, ret, &r_even[1], anum) + r_even[0];
+
+    return carry;
+}
+
+static ossl_inline size_t mod_montgomery_limb_numb(size_t modnum)
+{
+    return modnum * 2 + _mul_add_limb_numb(modnum);
+}
+
+/*
+ * calculate a % mod, place result in ret
+ * assumes that a is in mongomery form with the R (Mongomery modulus) being
+ * smallest power of two big enough to fit mod and that's also a power
+ * of the count of number of bits in limb_t (B).
+ * For calculation, we also need n', such that mod * n' == -1 mod B.
+ * anum must be <= 2 * modnum
+ * ret needs to be modnum words long
+ * tmp needs to be mod_montgomery_limb_numb(modnum) limbs long
+ */
+static void mod_montgomery(limb_t *ret, limb_t *a, size_t anum, limb_t *mod,
+                          size_t modnum, limb_t ni0, limb_t *tmp)
+{
+    limb_t carry, v;
+    limb_t *res, *rp, *tmp2;
+    ossl_ssize_t i;
+
+    res = tmp;
+    /*
+     * for intermediate result we need an integer twice as long as modulus
+     * but keep the input in the least significant limbs
+     */
+    memset(res, 0, sizeof(limb_t) * (modnum * 2));
+    memcpy(&res[modnum * 2 - anum], a, sizeof(limb_t) * anum);
+    rp = &res[modnum];
+    tmp2 = &res[modnum * 2];
+
+    carry = 0;
+
+    /* add multiples of the modulus to the value until R divides it cleanly */
+    for (i = modnum; i > 0; i--, rp--) {
+        v = _mul_add_limb(rp, mod, modnum, (rp[modnum-1] * ni0) & -1UL, tmp2);
+        v = (v + carry + rp[-1]) & -1UL;
+        carry |= (v != rp[-1]);
+        carry &= (v <= rp[-1]);
+        rp[-1] = v;
+    }
+
+    /* perform the final reduction by mod... */
+    carry -= sub(ret, rp, mod, modnum);
+
+    /* ...conditionally */
+    cselect(carry, ret, rp, ret, modnum);
+}
+
+/* allocated buffer should be freed afterwards */
+static void BN_to_limb(const BIGNUM *bn, limb_t *buf, size_t limbs)
+{
+    int i;
+    int real_limbs = (BN_num_bytes(bn) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
+    limb_t *ptr = buf + (limbs - real_limbs);
+
+    for (i = 0; i < real_limbs; i++)
+         ptr[i] = bn->d[real_limbs - i - 1];
+}
+
+#if LIMB_BYTE_SIZE == 8
+static ossl_inline uint64_t be64(uint64_t host)
+{
+#ifndef L_ENDIAN
+    return host;
+#else
+    uint64_t big = 0;
+    big |= (host & 0xff00000000000000) >> 56;
+    big |= (host & 0x00ff000000000000) >> 40;
+    big |= (host & 0x0000ff0000000000) >> 24;
+    big |= (host & 0x000000ff00000000) >>  8;
+    big |= (host & 0x00000000ff000000) <<  8;
+    big |= (host & 0x0000000000ff0000) << 24;
+    big |= (host & 0x000000000000ff00) << 40;
+    big |= (host & 0x00000000000000ff) << 56;
+    return big;
+#endif
+}
+
+#else
+/* Not all platforms have htobe32(). */
+static ossl_inline uint32_t be32(uint32_t host)
+{
+#ifndef L_ENDIAN
+    return host;
+#else
+    uint32_t big = 0;
+    big |= (host & 0xff000000) >> 24;
+    big |= (host & 0x00ff0000) >> 8;
+    big |= (host & 0x0000ff00) << 8;
+    big |= (host & 0x000000ff) << 24;
+    return big;
+#endif
+}
+#endif
+
+/*
+ * We assume that intermediate, possible_arg2, blinding, and ctx are used
+ * similar to BN_BLINDING_invert_ex() arguments.
+ * to_mod is RSA module
+ * buf and num is the serialization buffer and its length.
+ *
+ * Here we use classic/Mongomery multiplication and modulo. After the calculation finished
+ * we serialize the new structure instead of BIGNUMs taking endianness into account.
+ */
+int do_unblind(const BIGNUM *intermediate, const BN_BLINDING *blinding, const BIGNUM *possible_arg2,
+               const BIGNUM *to_mod, BN_CTX *ctx, unsigned char *buf, int num)
+{
+    limb_t *l_im = NULL, *l_mul = NULL, *l_mod = NULL;
+    limb_t *l_ret = NULL, *l_tmp = NULL, l_buf;
+    size_t l_im_count = 0, l_mul_count = 0, l_size = 0, l_mod_count = 0;
+    size_t l_tmp_count = 0;
+    int ret = 0;
+    size_t i;
+    unsigned char *tmp;
+    const BIGNUM *arg1 = intermediate;
+    const BIGNUM *arg2 = (possible_arg2 == NULL) ? blinding->Ai : possible_arg2;
+
+    l_im_count  = (BN_num_bytes(arg1)   + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
+    l_mul_count = (BN_num_bytes(arg2)   + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
+    l_mod_count = (BN_num_bytes(to_mod) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
+
+    l_size = l_im_count > l_mul_count ? l_im_count : l_mul_count;
+    l_im  = OPENSSL_zalloc(l_size * LIMB_BYTE_SIZE);
+    l_mul = OPENSSL_zalloc(l_size * LIMB_BYTE_SIZE);
+    l_mod = OPENSSL_zalloc(l_mod_count * LIMB_BYTE_SIZE);
+
+    if ((l_im == NULL) || (l_mul == NULL) || (l_mod == NULL))
+        goto err;
+
+    BN_to_limb(arg1,   l_im,  l_size);
+    BN_to_limb(arg2,   l_mul, l_size);
+    BN_to_limb(to_mod, l_mod, l_mod_count);
+
+    l_ret = OPENSSL_malloc(2 * l_size * LIMB_BYTE_SIZE);
+
+    if (blinding->m_ctx != NULL) {
+        l_tmp_count = mul_limb_numb(l_size) > mod_montgomery_limb_numb(l_mod_count) ?
+                      mul_limb_numb(l_size) : mod_montgomery_limb_numb(l_mod_count);
+        l_tmp = OPENSSL_malloc(l_tmp_count * LIMB_BYTE_SIZE);
+    } else {
+        l_tmp_count = mul_limb_numb(l_size) > mod_limb_numb(2 * l_size, l_mod_count) ?
+                      mul_limb_numb(l_size) : mod_limb_numb(2 * l_size, l_mod_count);
+        l_tmp = OPENSSL_malloc(l_tmp_count * LIMB_BYTE_SIZE);
+    }
+
+    if ((l_ret == NULL) || (l_tmp == NULL))
+        goto err;
+
+    if (blinding->m_ctx != NULL) {
+        limb_mul(l_ret, l_im, l_mul, l_size, l_tmp);
+	mod_montgomery(l_ret, l_ret, 2 * l_size, l_mod, l_mod_count,
+                       blinding->m_ctx->n0[0], l_tmp);
+    } else {
+        limb_mul(l_ret, l_im, l_mul, l_size, l_tmp);
+        mod(l_ret, l_ret, 2 * l_size, l_mod, l_mod_count, l_tmp);
+    }
+
+    /* module size in bytes can be equal to num but after limbs conversion it becomes bigger */
+    if (num < BN_num_bytes(to_mod)) {
+        RSAerr(RSA_F_DO_UNBLIND, ERR_R_PASSED_INVALID_ARGUMENT);
+        goto err;
+    }
+
+    memset(buf, 0, num);
+    tmp = buf + num - BN_num_bytes(to_mod);
+    for (i = 0; i < l_mod_count; i++) {
+#if LIMB_BYTE_SIZE == 8
+        l_buf = be64(l_ret[i]);
+#else
+        l_buf = be32(l_ret[i]);
+#endif
+        if (i == 0) {
+            int delta = LIMB_BYTE_SIZE - ((l_mod_count * LIMB_BYTE_SIZE) - num);
+
+            memcpy(tmp, ((char *)&l_buf) + LIMB_BYTE_SIZE - delta, delta);
+            tmp += delta;
+        } else {
+            memcpy(tmp, &l_buf, LIMB_BYTE_SIZE);
+            tmp += LIMB_BYTE_SIZE;
+        }
+    }
+    ret = num;
+
+ err:
+    OPENSSL_free(l_im);
+    OPENSSL_free(l_mul);
+    OPENSSL_free(l_mod);
+    OPENSSL_free(l_tmp);
+    OPENSSL_free(l_ret);
+
+    return ret;
+}
Index: openssl-1.1.1l/crypto/rsa/rsa_sup_mul.h
===================================================================
--- /dev/null
+++ openssl-1.1.1l/crypto/rsa/rsa_sup_mul.h
@@ -0,0 +1,6 @@
+#ifndef OSSL_CRYPTO_RSA_SUP_MUL_H
+#define OSSL_CRYPTO_RSA_SUP_MUL_H
+
+int do_unblind(const BIGNUM *intermediate, const BN_BLINDING *blinding, const BIGNUM *possible_arg2,
+               const BIGNUM *to_mod, BN_CTX *ctx, unsigned char *buf, int num);
+#endif /* OSSL_CRYPTO_RSA_SUP_MUL_H */
Index: openssl-1.1.1l/include/openssl/rsaerr.h
===================================================================
--- openssl-1.1.1l.orig/include/openssl/rsaerr.h
+++ openssl-1.1.1l/include/openssl/rsaerr.h
@@ -22,6 +22,7 @@ int ERR_load_RSA_strings(void);
  * RSA function codes.
  */
 # define RSA_F_CHECK_PADDING_MD                           140
+# define RSA_F_DO_UNBLIND                                 168
 # define RSA_F_ENCODE_PKCS1                               146
 # define RSA_F_FIPS_RSA_BUILTIN_KEYGEN                    168
 # define RSA_F_INT_RSA_VERIFY                             145

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File openssl-CVE-2022-4304-1of2.patch of Package openssl-1_1.27651

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