src/third_party/boringssl/src/crypto/bytestring/cbb.c - cobalt - Git at Google

 /* Copyright (c) 2014, Google Inc.
  *
  * Permission to use, copy, modify, and/or distribute this software for any
  * purpose with or without fee is hereby granted, provided that the above
  * copyright notice and this permission notice appear in all copies.
  *
  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
  * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
  * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
  * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */

 #include <openssl/bytestring.h>

 #include <assert.h>
 #include <limits.h>
 #include <string.h>

 #include <openssl/buf.h>
 #include <openssl/mem.h>

 #include "../internal.h"


 void CBB_zero(CBB *cbb) {
   OPENSSL_memset(cbb, 0, sizeof(CBB));
 }

 static int cbb_init(CBB *cbb, uint8_t *buf, size_t cap) {
   // This assumes that |cbb| has already been zeroed.
   struct cbb_buffer_st *base;

   base = OPENSSL_malloc(sizeof(struct cbb_buffer_st));
   if (base == NULL) {
     return 0;
   }

   base->buf = buf;
   base->len = 0;
   base->cap = cap;
   base->can_resize = 1;
   base->error = 0;

   cbb->base = base;
   cbb->is_top_level = 1;
   return 1;
 }

 int CBB_init(CBB *cbb, size_t initial_capacity) {
   CBB_zero(cbb);

   uint8_t *buf = OPENSSL_malloc(initial_capacity);
   if (initial_capacity > 0 && buf == NULL) {
     return 0;
   }

   if (!cbb_init(cbb, buf, initial_capacity)) {
     OPENSSL_free(buf);
     return 0;
   }

   return 1;
 }

 int CBB_init_fixed(CBB *cbb, uint8_t *buf, size_t len) {
   CBB_zero(cbb);

   if (!cbb_init(cbb, buf, len)) {
     return 0;
   }

   cbb->base->can_resize = 0;
   return 1;
 }

 void CBB_cleanup(CBB *cbb) {
   if (cbb->base) {
     // Only top-level |CBB|s are cleaned up. Child |CBB|s are non-owning. They
     // are implicitly discarded when the parent is flushed or cleaned up.
     assert(cbb->is_top_level);

     if (cbb->base->can_resize) {
       OPENSSL_free(cbb->base->buf);
     }
     OPENSSL_free(cbb->base);
   }
   cbb->base = NULL;
 }

 static int cbb_buffer_reserve(struct cbb_buffer_st *base, uint8_t **out,
                               size_t len) {
   size_t newlen;

   if (base == NULL) {
     return 0;
   }

   newlen = base->len + len;
   if (newlen < base->len) {
     // Overflow
     goto err;
   }

   if (newlen > base->cap) {
     size_t newcap = base->cap * 2;
     uint8_t *newbuf;

     if (!base->can_resize) {
       goto err;
     }

     if (newcap < base->cap || newcap < newlen) {
       newcap = newlen;
     }
     newbuf = OPENSSL_realloc(base->buf, newcap);
     if (newbuf == NULL) {
       goto err;
     }

     base->buf = newbuf;
     base->cap = newcap;
   }

   if (out) {
     *out = base->buf + base->len;
   }

   return 1;

 err:
   base->error = 1;
   return 0;
 }

 static int cbb_buffer_add(struct cbb_buffer_st *base, uint8_t **out,
                           size_t len) {
   if (!cbb_buffer_reserve(base, out, len)) {
     return 0;
   }
   // This will not overflow or |cbb_buffer_reserve| would have failed.
   base->len += len;
   return 1;
 }

 static int cbb_buffer_add_u(struct cbb_buffer_st *base, uint32_t v,
                             size_t len_len) {
   if (len_len == 0) {
     return 1;
   }

   uint8_t *buf;
   if (!cbb_buffer_add(base, &buf, len_len)) {
     return 0;
   }

   for (size_t i = len_len - 1; i < len_len; i--) {
     buf[i] = v;
     v >>= 8;
   }

   if (v != 0) {
     base->error = 1;
     return 0;
   }

   return 1;
 }

 int CBB_finish(CBB *cbb, uint8_t **out_data, size_t *out_len) {
   if (!cbb->is_top_level) {
     return 0;
   }

   if (!CBB_flush(cbb)) {
     return 0;
   }

   if (cbb->base->can_resize && (out_data == NULL || out_len == NULL)) {
     // |out_data| and |out_len| can only be NULL if the CBB is fixed.
     return 0;
   }

   if (out_data != NULL) {
     *out_data = cbb->base->buf;
   }
   if (out_len != NULL) {
     *out_len = cbb->base->len;
   }
   cbb->base->buf = NULL;
   CBB_cleanup(cbb);
   return 1;
 }

 // CBB_flush recurses and then writes out any pending length prefix. The
 // current length of the underlying base is taken to be the length of the
 // length-prefixed data.
 int CBB_flush(CBB *cbb) {
   size_t child_start, i, len;

   // If |cbb->base| has hit an error, the buffer is in an undefined state, so
   // fail all following calls. In particular, |cbb->child| may point to invalid
   // memory.
   if (cbb->base == NULL || cbb->base->error) {
     return 0;
   }

   if (cbb->child == NULL || cbb->child->pending_len_len == 0) {
     return 1;
   }

   child_start = cbb->child->offset + cbb->child->pending_len_len;

   if (!CBB_flush(cbb->child) ||
       child_start < cbb->child->offset ||
       cbb->base->len < child_start) {
     goto err;
   }

   len = cbb->base->len - child_start;

   if (cbb->child->pending_is_asn1) {
     // For ASN.1 we assume that we'll only need a single byte for the length.
     // If that turned out to be incorrect, we have to move the contents along
     // in order to make space.
     uint8_t len_len;
     uint8_t initial_length_byte;

     assert (cbb->child->pending_len_len == 1);

     if (len > 0xfffffffe) {
       // Too large.
       goto err;
     } else if (len > 0xffffff) {
       len_len = 5;
       initial_length_byte = 0x80 | 4;
     } else if (len > 0xffff) {
       len_len = 4;
       initial_length_byte = 0x80 | 3;
     } else if (len > 0xff) {
       len_len = 3;
       initial_length_byte = 0x80 | 2;
     } else if (len > 0x7f) {
       len_len = 2;
       initial_length_byte = 0x80 | 1;
     } else {
       len_len = 1;
       initial_length_byte = (uint8_t)len;
       len = 0;
     }

     if (len_len != 1) {
       // We need to move the contents along in order to make space.
       size_t extra_bytes = len_len - 1;
       if (!cbb_buffer_add(cbb->base, NULL, extra_bytes)) {
         goto err;
       }
       OPENSSL_memmove(cbb->base->buf + child_start + extra_bytes,
                       cbb->base->buf + child_start, len);
     }
     cbb->base->buf[cbb->child->offset++] = initial_length_byte;
     cbb->child->pending_len_len = len_len - 1;
   }

   for (i = cbb->child->pending_len_len - 1; i < cbb->child->pending_len_len;
        i--) {
     cbb->base->buf[cbb->child->offset + i] = (uint8_t)len;
     len >>= 8;
   }
   if (len != 0) {
     goto err;
   }

   cbb->child->base = NULL;
   cbb->child = NULL;

   return 1;

 err:
   cbb->base->error = 1;
   return 0;
 }

 const uint8_t *CBB_data(const CBB *cbb) {
   assert(cbb->child == NULL);
   return cbb->base->buf + cbb->offset + cbb->pending_len_len;
 }

 size_t CBB_len(const CBB *cbb) {
   assert(cbb->child == NULL);
   assert(cbb->offset + cbb->pending_len_len <= cbb->base->len);

   return cbb->base->len - cbb->offset - cbb->pending_len_len;
 }

 static int cbb_add_length_prefixed(CBB *cbb, CBB *out_contents,
                                    uint8_t len_len) {
   uint8_t *prefix_bytes;

   if (!CBB_flush(cbb)) {
     return 0;
   }

   size_t offset = cbb->base->len;
   if (!cbb_buffer_add(cbb->base, &prefix_bytes, len_len)) {
     return 0;
   }

   OPENSSL_memset(prefix_bytes, 0, len_len);
   OPENSSL_memset(out_contents, 0, sizeof(CBB));
   out_contents->base = cbb->base;
   cbb->child = out_contents;
   cbb->child->offset = offset;
   cbb->child->pending_len_len = len_len;
   cbb->child->pending_is_asn1 = 0;

   return 1;
 }

 int CBB_add_u8_length_prefixed(CBB *cbb, CBB *out_contents) {
   return cbb_add_length_prefixed(cbb, out_contents, 1);
 }

 int CBB_add_u16_length_prefixed(CBB *cbb, CBB *out_contents) {
   return cbb_add_length_prefixed(cbb, out_contents, 2);
 }

 int CBB_add_u24_length_prefixed(CBB *cbb, CBB *out_contents) {
   return cbb_add_length_prefixed(cbb, out_contents, 3);
 }

 // add_base128_integer encodes |v| as a big-endian base-128 integer where the
 // high bit of each byte indicates where there is more data. This is the
 // encoding used in DER for both high tag number form and OID components.
 static int add_base128_integer(CBB *cbb, uint64_t v) {
   unsigned len_len = 0;
   uint64_t copy = v;
   while (copy > 0) {
     len_len++;
     copy >>= 7;
   }
   if (len_len == 0) {
     len_len = 1;  // Zero is encoded with one byte.
   }
   for (unsigned i = len_len - 1; i < len_len; i--) {
     uint8_t byte = (v >> (7 * i)) & 0x7f;
     if (i != 0) {
       // The high bit denotes whether there is more data.
       byte |= 0x80;
     }
     if (!CBB_add_u8(cbb, byte)) {
       return 0;
     }
   }
   return 1;
 }

 int CBB_add_asn1(CBB *cbb, CBB *out_contents, unsigned tag) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   // Split the tag into leading bits and tag number.
   uint8_t tag_bits = (tag >> CBS_ASN1_TAG_SHIFT) & 0xe0;
   unsigned tag_number = tag & CBS_ASN1_TAG_NUMBER_MASK;
   if (tag_number >= 0x1f) {
     // Set all the bits in the tag number to signal high tag number form.
     if (!CBB_add_u8(cbb, tag_bits | 0x1f) ||
         !add_base128_integer(cbb, tag_number)) {
       return 0;
     }
   } else if (!CBB_add_u8(cbb, tag_bits | tag_number)) {
     return 0;
   }

   size_t offset = cbb->base->len;
   if (!CBB_add_u8(cbb, 0)) {
     return 0;
   }

   OPENSSL_memset(out_contents, 0, sizeof(CBB));
   out_contents->base = cbb->base;
   cbb->child = out_contents;
   cbb->child->offset = offset;
   cbb->child->pending_len_len = 1;
   cbb->child->pending_is_asn1 = 1;

   return 1;
 }

 int CBB_add_bytes(CBB *cbb, const uint8_t *data, size_t len) {
   uint8_t *dest;

   if (!CBB_flush(cbb) ||
       !cbb_buffer_add(cbb->base, &dest, len)) {
     return 0;
   }
   OPENSSL_memcpy(dest, data, len);
   return 1;
 }

 int CBB_add_space(CBB *cbb, uint8_t **out_data, size_t len) {
   if (!CBB_flush(cbb) ||
       !cbb_buffer_add(cbb->base, out_data, len)) {
     return 0;
   }
   return 1;
 }

 int CBB_reserve(CBB *cbb, uint8_t **out_data, size_t len) {
   if (!CBB_flush(cbb) ||
       !cbb_buffer_reserve(cbb->base, out_data, len)) {
     return 0;
   }
   return 1;
 }

 int CBB_did_write(CBB *cbb, size_t len) {
   size_t newlen = cbb->base->len + len;
   if (cbb->child != NULL ||
       newlen < cbb->base->len ||
       newlen > cbb->base->cap) {
     return 0;
   }
   cbb->base->len = newlen;
   return 1;
 }

 int CBB_add_u8(CBB *cbb, uint8_t value) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   return cbb_buffer_add_u(cbb->base, value, 1);
 }

 int CBB_add_u16(CBB *cbb, uint16_t value) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   return cbb_buffer_add_u(cbb->base, value, 2);
 }

 int CBB_add_u24(CBB *cbb, uint32_t value) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   return cbb_buffer_add_u(cbb->base, value, 3);
 }

 int CBB_add_u32(CBB *cbb, uint32_t value) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   return cbb_buffer_add_u(cbb->base, value, 4);
 }

 void CBB_discard_child(CBB *cbb) {
   if (cbb->child == NULL) {
     return;
   }

   cbb->base->len = cbb->child->offset;

   cbb->child->base = NULL;
   cbb->child = NULL;
 }

 int CBB_add_asn1_uint64(CBB *cbb, uint64_t value) {
   CBB child;
   int started = 0;

   if (!CBB_add_asn1(cbb, &child, CBS_ASN1_INTEGER)) {
     return 0;
   }

   for (size_t i = 0; i < 8; i++) {
     uint8_t byte = (value >> 8*(7-i)) & 0xff;
     if (!started) {
       if (byte == 0) {
         // Don't encode leading zeros.
         continue;
       }
       // If the high bit is set, add a padding byte to make it
       // unsigned.
       if ((byte & 0x80) && !CBB_add_u8(&child, 0)) {
         return 0;
       }
       started = 1;
     }
     if (!CBB_add_u8(&child, byte)) {
       return 0;
     }
   }

   // 0 is encoded as a single 0, not the empty string.
   if (!started && !CBB_add_u8(&child, 0)) {
     return 0;
   }

   return CBB_flush(cbb);
 }

 int CBB_add_asn1_octet_string(CBB *cbb, const uint8_t *data, size_t data_len) {
   CBB child;
   if (!CBB_add_asn1(cbb, &child, CBS_ASN1_OCTETSTRING) ||
       !CBB_add_bytes(&child, data, data_len) ||
       !CBB_flush(cbb)) {
     return 0;
   }

   return 1;
 }

 int CBB_add_asn1_bool(CBB *cbb, int value) {
   CBB child;
   if (!CBB_add_asn1(cbb, &child, CBS_ASN1_BOOLEAN) ||
       !CBB_add_u8(&child, value != 0 ? 0xff : 0) ||
       !CBB_flush(cbb)) {
     return 0;
   }

   return 1;
 }

 // parse_dotted_decimal parses one decimal component from |cbs|, where |cbs| is
 // an OID literal, e.g., "1.2.840.113554.4.1.72585". It consumes both the
 // component and the dot, so |cbs| may be passed into the function again for the
 // next value.
 static int parse_dotted_decimal(CBS *cbs, uint64_t *out) {
   *out = 0;
   int seen_digit = 0;
   for (;;) {
     // Valid terminators for a component are the end of the string or a
     // non-terminal dot. If the string ends with a dot, this is not a valid OID
     // string.
     uint8_t u;
     if (!CBS_get_u8(cbs, &u) ||
         (u == '.' && CBS_len(cbs) > 0)) {
       break;
     }
     if (u < '0' || u > '9' ||
         // Forbid stray leading zeros.
         (seen_digit && *out == 0) ||
         // Check for overflow.
         *out > UINT64_MAX / 10 ||
         *out * 10 > UINT64_MAX - (u - '0')) {
       return 0;
     }
     *out = *out * 10 + (u - '0');
     seen_digit = 1;
   }
   // The empty string is not a legal OID component.
   return seen_digit;
 }

 int CBB_add_asn1_oid_from_text(CBB *cbb, const char *text, size_t len) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   CBS cbs;
   CBS_init(&cbs, (const uint8_t *)text, len);

   // OIDs must have at least two components.
   uint64_t a, b;
   if (!parse_dotted_decimal(&cbs, &a) ||
       !parse_dotted_decimal(&cbs, &b)) {
     return 0;
   }

   // The first component is encoded as 40 * |a| + |b|. This assumes that |a| is
   // 0, 1, or 2 and that, when it is 0 or 1, |b| is at most 39.
   if (a > 2 ||
       (a < 2 && b > 39) ||
       b > UINT64_MAX - 80 ||
       !add_base128_integer(cbb, 40u * a + b)) {
     return 0;
   }

   // The remaining components are encoded unmodified.
   while (CBS_len(&cbs) > 0) {
     if (!parse_dotted_decimal(&cbs, &a) ||
         !add_base128_integer(cbb, a)) {
       return 0;
     }
   }

   return 1;
 }

 static int compare_set_of_element(const void *a_ptr, const void *b_ptr) {
   // See X.690, section 11.6 for the ordering. They are sorted in ascending
   // order by their DER encoding.
   const CBS *a = a_ptr, *b = b_ptr;
   size_t a_len = CBS_len(a), b_len = CBS_len(b);
   size_t min_len = a_len < b_len ? a_len : b_len;
   int ret = OPENSSL_memcmp(CBS_data(a), CBS_data(b), min_len);
   if (ret != 0) {
     return ret;
   }
   if (a_len == b_len) {
     return 0;
   }
   // If one is a prefix of the other, the shorter one sorts first. (This is not
   // actually reachable. No DER encoding is a prefix of another DER encoding.)
   return a_len < b_len ? -1 : 1;
 }

 int CBB_flush_asn1_set_of(CBB *cbb) {
   if (!CBB_flush(cbb)) {
     return 0;
   }

   CBS cbs;
   size_t num_children = 0;
   CBS_init(&cbs, CBB_data(cbb), CBB_len(cbb));
   while (CBS_len(&cbs) != 0) {
     if (!CBS_get_any_asn1_element(&cbs, NULL, NULL, NULL)) {
       return 0;
     }
     num_children++;
   }

   if (num_children < 2) {
     return 1;  // Nothing to do. This is the common case for X.509.
   }
   if (num_children > ((size_t)-1) / sizeof(CBS)) {
     return 0;  // Overflow.
   }

   // Parse out the children and sort. We alias them into a copy of so they
   // remain valid as we rewrite |cbb|.
   int ret = 0;
   size_t buf_len = CBB_len(cbb);
   uint8_t *buf = BUF_memdup(CBB_data(cbb), buf_len);
   CBS *children = OPENSSL_malloc(num_children * sizeof(CBS));
   if (buf == NULL || children == NULL) {
     goto err;
   }
   CBS_init(&cbs, buf, buf_len);
   for (size_t i = 0; i < num_children; i++) {
     if (!CBS_get_any_asn1_element(&cbs, &children[i], NULL, NULL)) {
       goto err;
     }
   }
   OPENSSL_port_qsort(children, num_children, sizeof(CBS), compare_set_of_element);

   // Rewind |cbb| and write the contents back in the new order.
   cbb->base->len = cbb->offset + cbb->pending_len_len;
   for (size_t i = 0; i < num_children; i++) {
     if (!CBB_add_bytes(cbb, CBS_data(&children[i]), CBS_len(&children[i]))) {
       goto err;
     }
   }
   assert(CBB_len(cbb) == buf_len);

   ret = 1;

 err:
   OPENSSL_free(buf);
   OPENSSL_free(children);
   return ret;
 }
	/* Copyright (c) 2014, Google Inc.
	*
	* Permission to use, copy, modify, and/or distribute this software for any
	* purpose with or without fee is hereby granted, provided that the above
	* copyright notice and this permission notice appear in all copies.
	*
	* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
	* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
	* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
	* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
	* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
	* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */

	#include <openssl/bytestring.h>

	#include <assert.h>
	#include <limits.h>
	#include <string.h>

	#include <openssl/buf.h>
	#include <openssl/mem.h>

	#include "../internal.h"


	void CBB_zero(CBB *cbb) {
	OPENSSL_memset(cbb, 0, sizeof(CBB));
	}

	static int cbb_init(CBB cbb, uint8_t buf, size_t cap) {
	// This assumes that \|cbb\| has already been zeroed.
	struct cbb_buffer_st *base;

	base = OPENSSL_malloc(sizeof(struct cbb_buffer_st));
	if (base == NULL) {
	return 0;
	}

	base->buf = buf;
	base->len = 0;
	base->cap = cap;
	base->can_resize = 1;
	base->error = 0;

	cbb->base = base;
	cbb->is_top_level = 1;
	return 1;
	}

	int CBB_init(CBB *cbb, size_t initial_capacity) {
	CBB_zero(cbb);

	uint8_t *buf = OPENSSL_malloc(initial_capacity);
	if (initial_capacity > 0 && buf == NULL) {
	return 0;
	}

	if (!cbb_init(cbb, buf, initial_capacity)) {
	OPENSSL_free(buf);
	return 0;
	}

	return 1;
	}

	int CBB_init_fixed(CBB cbb, uint8_t buf, size_t len) {
	CBB_zero(cbb);

	if (!cbb_init(cbb, buf, len)) {
	return 0;
	}

	cbb->base->can_resize = 0;
	return 1;
	}

	void CBB_cleanup(CBB *cbb) {
	if (cbb->base) {
	// Only top-level \|CBB\|s are cleaned up. Child \|CBB\|s are non-owning. They
	// are implicitly discarded when the parent is flushed or cleaned up.
	assert(cbb->is_top_level);

	if (cbb->base->can_resize) {
	OPENSSL_free(cbb->base->buf);
	}
	OPENSSL_free(cbb->base);
	}
	cbb->base = NULL;
	}

	static int cbb_buffer_reserve(struct cbb_buffer_st base, uint8_t *out,
	size_t len) {
	size_t newlen;

	if (base == NULL) {
	return 0;
	}

	newlen = base->len + len;
	if (newlen < base->len) {
	// Overflow
	goto err;
	}

	if (newlen > base->cap) {
	size_t newcap = base->cap * 2;
	uint8_t *newbuf;

	if (!base->can_resize) {
	goto err;
	}

	if (newcap < base->cap \|\| newcap < newlen) {
	newcap = newlen;
	}
	newbuf = OPENSSL_realloc(base->buf, newcap);
	if (newbuf == NULL) {
	goto err;
	}

	base->buf = newbuf;
	base->cap = newcap;
	}

	if (out) {
	*out = base->buf + base->len;
	}

	return 1;

	err:
	base->error = 1;
	return 0;
	}

	static int cbb_buffer_add(struct cbb_buffer_st base, uint8_t *out,
	size_t len) {
	if (!cbb_buffer_reserve(base, out, len)) {
	return 0;
	}
	// This will not overflow or \|cbb_buffer_reserve\| would have failed.
	base->len += len;
	return 1;
	}

	static int cbb_buffer_add_u(struct cbb_buffer_st *base, uint32_t v,
	size_t len_len) {
	if (len_len == 0) {
	return 1;
	}

	uint8_t *buf;
	if (!cbb_buffer_add(base, &buf, len_len)) {
	return 0;
	}

	for (size_t i = len_len - 1; i < len_len; i--) {
	buf[i] = v;
	v >>= 8;
	}

	if (v != 0) {
	base->error = 1;
	return 0;
	}

	return 1;
	}

	int CBB_finish(CBB cbb, uint8_t out_data, size_t out_len) {
	if (!cbb->is_top_level) {
	return 0;
	}

	if (!CBB_flush(cbb)) {
	return 0;
	}

	if (cbb->base->can_resize && (out_data == NULL \|\| out_len == NULL)) {
	// \|out_data\| and \|out_len\| can only be NULL if the CBB is fixed.
	return 0;
	}

	if (out_data != NULL) {
	*out_data = cbb->base->buf;
	}
	if (out_len != NULL) {
	*out_len = cbb->base->len;
	}
	cbb->base->buf = NULL;
	CBB_cleanup(cbb);
	return 1;
	}

	// CBB_flush recurses and then writes out any pending length prefix. The
	// current length of the underlying base is taken to be the length of the
	// length-prefixed data.
	int CBB_flush(CBB *cbb) {
	size_t child_start, i, len;

	// If \|cbb->base\| has hit an error, the buffer is in an undefined state, so
	// fail all following calls. In particular, \|cbb->child\| may point to invalid
	// memory.
	if (cbb->base == NULL \|\| cbb->base->error) {
	return 0;
	}

	if (cbb->child == NULL \|\| cbb->child->pending_len_len == 0) {
	return 1;
	}

	child_start = cbb->child->offset + cbb->child->pending_len_len;

	if (!CBB_flush(cbb->child) \|\|
	child_start < cbb->child->offset \|\|
	cbb->base->len < child_start) {
	goto err;
	}

	len = cbb->base->len - child_start;

	if (cbb->child->pending_is_asn1) {
	// For ASN.1 we assume that we'll only need a single byte for the length.
	// If that turned out to be incorrect, we have to move the contents along
	// in order to make space.
	uint8_t len_len;
	uint8_t initial_length_byte;

	assert (cbb->child->pending_len_len == 1);

	if (len > 0xfffffffe) {
	// Too large.
	goto err;
	} else if (len > 0xffffff) {
	len_len = 5;
	initial_length_byte = 0x80 \| 4;
	} else if (len > 0xffff) {
	len_len = 4;
	initial_length_byte = 0x80 \| 3;
	} else if (len > 0xff) {
	len_len = 3;
	initial_length_byte = 0x80 \| 2;
	} else if (len > 0x7f) {
	len_len = 2;
	initial_length_byte = 0x80 \| 1;
	} else {
	len_len = 1;
	initial_length_byte = (uint8_t)len;
	len = 0;
	}

	if (len_len != 1) {
	// We need to move the contents along in order to make space.
	size_t extra_bytes = len_len - 1;
	if (!cbb_buffer_add(cbb->base, NULL, extra_bytes)) {
	goto err;
	}
	OPENSSL_memmove(cbb->base->buf + child_start + extra_bytes,
	cbb->base->buf + child_start, len);
	}
	cbb->base->buf[cbb->child->offset++] = initial_length_byte;
	cbb->child->pending_len_len = len_len - 1;
	}

	for (i = cbb->child->pending_len_len - 1; i < cbb->child->pending_len_len;
	i--) {
	cbb->base->buf[cbb->child->offset + i] = (uint8_t)len;
	len >>= 8;
	}
	if (len != 0) {
	goto err;
	}

	cbb->child->base = NULL;
	cbb->child = NULL;

	return 1;

	err:
	cbb->base->error = 1;
	return 0;
	}

	const uint8_t CBB_data(const CBB cbb) {
	assert(cbb->child == NULL);
	return cbb->base->buf + cbb->offset + cbb->pending_len_len;
	}

	size_t CBB_len(const CBB *cbb) {
	assert(cbb->child == NULL);
	assert(cbb->offset + cbb->pending_len_len <= cbb->base->len);

	return cbb->base->len - cbb->offset - cbb->pending_len_len;
	}

	static int cbb_add_length_prefixed(CBB cbb, CBB out_contents,
	uint8_t len_len) {
	uint8_t *prefix_bytes;

	if (!CBB_flush(cbb)) {
	return 0;
	}

	size_t offset = cbb->base->len;
	if (!cbb_buffer_add(cbb->base, &prefix_bytes, len_len)) {
	return 0;
	}

	OPENSSL_memset(prefix_bytes, 0, len_len);
	OPENSSL_memset(out_contents, 0, sizeof(CBB));
	out_contents->base = cbb->base;
	cbb->child = out_contents;
	cbb->child->offset = offset;
	cbb->child->pending_len_len = len_len;
	cbb->child->pending_is_asn1 = 0;

	return 1;
	}

	int CBB_add_u8_length_prefixed(CBB cbb, CBB out_contents) {
	return cbb_add_length_prefixed(cbb, out_contents, 1);
	}

	int CBB_add_u16_length_prefixed(CBB cbb, CBB out_contents) {
	return cbb_add_length_prefixed(cbb, out_contents, 2);
	}

	int CBB_add_u24_length_prefixed(CBB cbb, CBB out_contents) {
	return cbb_add_length_prefixed(cbb, out_contents, 3);
	}

	// add_base128_integer encodes \|v\| as a big-endian base-128 integer where the
	// high bit of each byte indicates where there is more data. This is the
	// encoding used in DER for both high tag number form and OID components.
	static int add_base128_integer(CBB *cbb, uint64_t v) {
	unsigned len_len = 0;
	uint64_t copy = v;
	while (copy > 0) {
	len_len++;
	copy >>= 7;
	}
	if (len_len == 0) {
	len_len = 1; // Zero is encoded with one byte.
	}
	for (unsigned i = len_len - 1; i < len_len; i--) {
	uint8_t byte = (v >> (7 * i)) & 0x7f;
	if (i != 0) {
	// The high bit denotes whether there is more data.
	byte \|= 0x80;
	}
	if (!CBB_add_u8(cbb, byte)) {
	return 0;
	}
	}
	return 1;
	}

	int CBB_add_asn1(CBB cbb, CBB out_contents, unsigned tag) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	// Split the tag into leading bits and tag number.
	uint8_t tag_bits = (tag >> CBS_ASN1_TAG_SHIFT) & 0xe0;
	unsigned tag_number = tag & CBS_ASN1_TAG_NUMBER_MASK;
	if (tag_number >= 0x1f) {
	// Set all the bits in the tag number to signal high tag number form.
	if (!CBB_add_u8(cbb, tag_bits \| 0x1f) \|\|
	!add_base128_integer(cbb, tag_number)) {
	return 0;
	}
	} else if (!CBB_add_u8(cbb, tag_bits \| tag_number)) {
	return 0;
	}

	size_t offset = cbb->base->len;
	if (!CBB_add_u8(cbb, 0)) {
	return 0;
	}

	OPENSSL_memset(out_contents, 0, sizeof(CBB));
	out_contents->base = cbb->base;
	cbb->child = out_contents;
	cbb->child->offset = offset;
	cbb->child->pending_len_len = 1;
	cbb->child->pending_is_asn1 = 1;

	return 1;
	}

	int CBB_add_bytes(CBB cbb, const uint8_t data, size_t len) {
	uint8_t *dest;

	if (!CBB_flush(cbb) \|\|
	!cbb_buffer_add(cbb->base, &dest, len)) {
	return 0;
	}
	OPENSSL_memcpy(dest, data, len);
	return 1;
	}

	int CBB_add_space(CBB cbb, uint8_t *out_data, size_t len) {
	if (!CBB_flush(cbb) \|\|
	!cbb_buffer_add(cbb->base, out_data, len)) {
	return 0;
	}
	return 1;
	}

	int CBB_reserve(CBB cbb, uint8_t *out_data, size_t len) {
	if (!CBB_flush(cbb) \|\|
	!cbb_buffer_reserve(cbb->base, out_data, len)) {
	return 0;
	}
	return 1;
	}

	int CBB_did_write(CBB *cbb, size_t len) {
	size_t newlen = cbb->base->len + len;
	if (cbb->child != NULL \|\|
	newlen < cbb->base->len \|\|
	newlen > cbb->base->cap) {
	return 0;
	}
	cbb->base->len = newlen;
	return 1;
	}

	int CBB_add_u8(CBB *cbb, uint8_t value) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	return cbb_buffer_add_u(cbb->base, value, 1);
	}

	int CBB_add_u16(CBB *cbb, uint16_t value) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	return cbb_buffer_add_u(cbb->base, value, 2);
	}

	int CBB_add_u24(CBB *cbb, uint32_t value) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	return cbb_buffer_add_u(cbb->base, value, 3);
	}

	int CBB_add_u32(CBB *cbb, uint32_t value) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	return cbb_buffer_add_u(cbb->base, value, 4);
	}

	void CBB_discard_child(CBB *cbb) {
	if (cbb->child == NULL) {
	return;
	}

	cbb->base->len = cbb->child->offset;

	cbb->child->base = NULL;
	cbb->child = NULL;
	}

	int CBB_add_asn1_uint64(CBB *cbb, uint64_t value) {
	CBB child;
	int started = 0;

	if (!CBB_add_asn1(cbb, &child, CBS_ASN1_INTEGER)) {
	return 0;
	}

	for (size_t i = 0; i < 8; i++) {
	uint8_t byte = (value >> 8*(7-i)) & 0xff;
	if (!started) {
	if (byte == 0) {
	// Don't encode leading zeros.
	continue;
	}
	// If the high bit is set, add a padding byte to make it
	// unsigned.
	if ((byte & 0x80) && !CBB_add_u8(&child, 0)) {
	return 0;
	}
	started = 1;
	}
	if (!CBB_add_u8(&child, byte)) {
	return 0;
	}
	}

	// 0 is encoded as a single 0, not the empty string.
	if (!started && !CBB_add_u8(&child, 0)) {
	return 0;
	}

	return CBB_flush(cbb);
	}

	int CBB_add_asn1_octet_string(CBB cbb, const uint8_t data, size_t data_len) {
	CBB child;
	if (!CBB_add_asn1(cbb, &child, CBS_ASN1_OCTETSTRING) \|\|
	!CBB_add_bytes(&child, data, data_len) \|\|
	!CBB_flush(cbb)) {
	return 0;
	}

	return 1;
	}

	int CBB_add_asn1_bool(CBB *cbb, int value) {
	CBB child;
	if (!CBB_add_asn1(cbb, &child, CBS_ASN1_BOOLEAN) \|\|
	!CBB_add_u8(&child, value != 0 ? 0xff : 0) \|\|
	!CBB_flush(cbb)) {
	return 0;
	}

	return 1;
	}

	// parse_dotted_decimal parses one decimal component from \|cbs\|, where \|cbs\| is
	// an OID literal, e.g., "1.2.840.113554.4.1.72585". It consumes both the
	// component and the dot, so \|cbs\| may be passed into the function again for the
	// next value.
	static int parse_dotted_decimal(CBS cbs, uint64_t out) {
	*out = 0;
	int seen_digit = 0;
	for (;;) {
	// Valid terminators for a component are the end of the string or a
	// non-terminal dot. If the string ends with a dot, this is not a valid OID
	// string.
	uint8_t u;
	if (!CBS_get_u8(cbs, &u) \|\|
	(u == '.' && CBS_len(cbs) > 0)) {
	break;
	}
	if (u < '0' \|\| u > '9' \|\|
	// Forbid stray leading zeros.
	(seen_digit && *out == 0) \|\|
	// Check for overflow.
	*out > UINT64_MAX / 10 \|\|
	out 10 > UINT64_MAX - (u - '0')) {
	return 0;
	}
	out = out * 10 + (u - '0');
	seen_digit = 1;
	}
	// The empty string is not a legal OID component.
	return seen_digit;
	}

	int CBB_add_asn1_oid_from_text(CBB cbb, const char text, size_t len) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	CBS cbs;
	CBS_init(&cbs, (const uint8_t *)text, len);

	// OIDs must have at least two components.
	uint64_t a, b;
	if (!parse_dotted_decimal(&cbs, &a) \|\|
	!parse_dotted_decimal(&cbs, &b)) {
	return 0;
	}

	// The first component is encoded as 40 * \|a\| + \|b\|. This assumes that \|a\| is
	// 0, 1, or 2 and that, when it is 0 or 1, \|b\| is at most 39.
	if (a > 2 \|\|
	(a < 2 && b > 39) \|\|
	b > UINT64_MAX - 80 \|\|
	!add_base128_integer(cbb, 40u * a + b)) {
	return 0;
	}

	// The remaining components are encoded unmodified.
	while (CBS_len(&cbs) > 0) {
	if (!parse_dotted_decimal(&cbs, &a) \|\|
	!add_base128_integer(cbb, a)) {
	return 0;
	}
	}

	return 1;
	}

	static int compare_set_of_element(const void a_ptr, const void b_ptr) {
	// See X.690, section 11.6 for the ordering. They are sorted in ascending
	// order by their DER encoding.
	const CBS a = a_ptr, b = b_ptr;
	size_t a_len = CBS_len(a), b_len = CBS_len(b);
	size_t min_len = a_len < b_len ? a_len : b_len;
	int ret = OPENSSL_memcmp(CBS_data(a), CBS_data(b), min_len);
	if (ret != 0) {
	return ret;
	}
	if (a_len == b_len) {
	return 0;
	}
	// If one is a prefix of the other, the shorter one sorts first. (This is not
	// actually reachable. No DER encoding is a prefix of another DER encoding.)
	return a_len < b_len ? -1 : 1;
	}

	int CBB_flush_asn1_set_of(CBB *cbb) {
	if (!CBB_flush(cbb)) {
	return 0;
	}

	CBS cbs;
	size_t num_children = 0;
	CBS_init(&cbs, CBB_data(cbb), CBB_len(cbb));
	while (CBS_len(&cbs) != 0) {
	if (!CBS_get_any_asn1_element(&cbs, NULL, NULL, NULL)) {
	return 0;
	}
	num_children++;
	}

	if (num_children < 2) {
	return 1; // Nothing to do. This is the common case for X.509.
	}
	if (num_children > ((size_t)-1) / sizeof(CBS)) {
	return 0; // Overflow.
	}

	// Parse out the children and sort. We alias them into a copy of so they
	// remain valid as we rewrite \|cbb\|.
	int ret = 0;
	size_t buf_len = CBB_len(cbb);
	uint8_t *buf = BUF_memdup(CBB_data(cbb), buf_len);
	CBS children = OPENSSL_malloc(num_children sizeof(CBS));
	if (buf == NULL \|\| children == NULL) {
	goto err;
	}
	CBS_init(&cbs, buf, buf_len);
	for (size_t i = 0; i < num_children; i++) {
	if (!CBS_get_any_asn1_element(&cbs, &children[i], NULL, NULL)) {
	goto err;
	}
	}
	OPENSSL_port_qsort(children, num_children, sizeof(CBS), compare_set_of_element);

	// Rewind \|cbb\| and write the contents back in the new order.
	cbb->base->len = cbb->offset + cbb->pending_len_len;
	for (size_t i = 0; i < num_children; i++) {
	if (!CBB_add_bytes(cbb, CBS_data(&children[i]), CBS_len(&children[i]))) {
	goto err;
	}
	}
	assert(CBB_len(cbb) == buf_len);

	ret = 1;

	err:
	OPENSSL_free(buf);
	OPENSSL_free(children);
	return ret;
	}