crypto/obj/obj.cc - boringssl - Git at Google

 // Copyright 1995-2016 The OpenSSL Project Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include <openssl/obj.h>

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

 #include <openssl/asn1.h>
 #include <openssl/bytestring.h>
 #include <openssl/err.h>
 #include <openssl/mem.h>

 #include "../asn1/internal.h"
 #include "../internal.h"
 #include "../lhash/internal.h"

 // obj_data.h must be included after the definition of |ASN1_OBJECT|.
 #include "obj_dat.h"


 DEFINE_LHASH_OF(ASN1_OBJECT)

 static CRYPTO_MUTEX global_added_lock = CRYPTO_MUTEX_INIT;
 // These globals are protected by |global_added_lock|.
 static LHASH_OF(ASN1_OBJECT) *global_added_by_data = NULL;
 static LHASH_OF(ASN1_OBJECT) *global_added_by_nid = NULL;
 static LHASH_OF(ASN1_OBJECT) *global_added_by_short_name = NULL;
 static LHASH_OF(ASN1_OBJECT) *global_added_by_long_name = NULL;

 static CRYPTO_MUTEX global_next_nid_lock = CRYPTO_MUTEX_INIT;
 static unsigned global_next_nid = NUM_NID;

 static int obj_next_nid(void) {
   CRYPTO_MUTEX_lock_write(&global_next_nid_lock);
   int ret = global_next_nid++;
   CRYPTO_MUTEX_unlock_write(&global_next_nid_lock);
   return ret;
 }

 ASN1_OBJECT *OBJ_dup(const ASN1_OBJECT *o) {
   ASN1_OBJECT *r;
   unsigned char *data = NULL;
   char *sn = NULL, *ln = NULL;

   if (o == NULL) {
     return NULL;
   }

   if (!(o->flags & ASN1_OBJECT_FLAG_DYNAMIC)) {
     // TODO(fork): this is a little dangerous.
     return (ASN1_OBJECT *)o;
   }

   r = ASN1_OBJECT_new();
   if (r == NULL) {
     OPENSSL_PUT_ERROR(OBJ, ERR_R_ASN1_LIB);
     return NULL;
   }
   r->ln = r->sn = NULL;

   // once data is attached to an object, it remains const
   r->data = reinterpret_cast<uint8_t *>(OPENSSL_memdup(o->data, o->length));
   if (o->length != 0 && r->data == NULL) {
     goto err;
   }

   r->length = o->length;
   r->nid = o->nid;

   if (o->ln != NULL) {
     ln = OPENSSL_strdup(o->ln);
     if (ln == NULL) {
       goto err;
     }
   }

   if (o->sn != NULL) {
     sn = OPENSSL_strdup(o->sn);
     if (sn == NULL) {
       goto err;
     }
   }

   r->sn = sn;
   r->ln = ln;

   r->flags =
       o->flags | (ASN1_OBJECT_FLAG_DYNAMIC | ASN1_OBJECT_FLAG_DYNAMIC_STRINGS |
                   ASN1_OBJECT_FLAG_DYNAMIC_DATA);
   return r;

 err:
   OPENSSL_free(ln);
   OPENSSL_free(sn);
   OPENSSL_free(data);
   OPENSSL_free(r);
   return NULL;
 }

 int OBJ_cmp(const ASN1_OBJECT *a, const ASN1_OBJECT *b) {
   if (a->length < b->length) {
     return -1;
   } else if (a->length > b->length) {
     return 1;
   }
   return OPENSSL_memcmp(a->data, b->data, a->length);
 }

 const uint8_t *OBJ_get0_data(const ASN1_OBJECT *obj) {
   if (obj == NULL) {
     return NULL;
   }

   return obj->data;
 }

 size_t OBJ_length(const ASN1_OBJECT *obj) {
   if (obj == NULL || obj->length < 0) {
     return 0;
   }

   return (size_t)obj->length;
 }

 static const ASN1_OBJECT *get_builtin_object(int nid) {
   // |NID_undef| is stored separately, so all the indices are off by one. The
   // caller of this function must have a valid built-in, non-undef NID.
   BSSL_CHECK(nid > 0 && nid < NUM_NID);
   return &kObjects[nid - 1];
 }

 // obj_cmp is called to search the kNIDsInOIDOrder array. The |key| argument is
 // an |ASN1_OBJECT|* that we're looking for and |element| is a pointer to an
 // unsigned int in the array.
 static int obj_cmp(const void *key, const void *element) {
   uint16_t nid = *((const uint16_t *)element);
   return OBJ_cmp(reinterpret_cast<const ASN1_OBJECT *>(key),
                  get_builtin_object(nid));
 }

 int OBJ_obj2nid(const ASN1_OBJECT *obj) {
   if (obj == NULL) {
     return NID_undef;
   }

   if (obj->nid != 0) {
     return obj->nid;
   }

   CRYPTO_MUTEX_lock_read(&global_added_lock);
   if (global_added_by_data != NULL) {
     ASN1_OBJECT *match;

     match = lh_ASN1_OBJECT_retrieve(global_added_by_data, obj);
     if (match != NULL) {
       CRYPTO_MUTEX_unlock_read(&global_added_lock);
       return match->nid;
     }
   }
   CRYPTO_MUTEX_unlock_read(&global_added_lock);

   const uint16_t *nid_ptr = reinterpret_cast<const uint16_t *>(
       bsearch(obj, kNIDsInOIDOrder, OPENSSL_ARRAY_SIZE(kNIDsInOIDOrder),
               sizeof(kNIDsInOIDOrder[0]), obj_cmp));
   if (nid_ptr == NULL) {
     return NID_undef;
   }

   return get_builtin_object(*nid_ptr)->nid;
 }

 int OBJ_cbs2nid(const CBS *cbs) {
   if (CBS_len(cbs) > INT_MAX) {
     return NID_undef;
   }

   ASN1_OBJECT obj;
   OPENSSL_memset(&obj, 0, sizeof(obj));
   obj.data = CBS_data(cbs);
   obj.length = (int)CBS_len(cbs);

   return OBJ_obj2nid(&obj);
 }

 // short_name_cmp is called to search the kNIDsInShortNameOrder array. The
 // |key| argument is name that we're looking for and |element| is a pointer to
 // an unsigned int in the array.
 static int short_name_cmp(const void *key, const void *element) {
   const char *name = (const char *)key;
   uint16_t nid = *((const uint16_t *)element);

   return strcmp(name, get_builtin_object(nid)->sn);
 }

 int OBJ_sn2nid(const char *short_name) {
   CRYPTO_MUTEX_lock_read(&global_added_lock);
   if (global_added_by_short_name != NULL) {
     ASN1_OBJECT *match, templ;

     templ.sn = short_name;
     match = lh_ASN1_OBJECT_retrieve(global_added_by_short_name, &templ);
     if (match != NULL) {
       CRYPTO_MUTEX_unlock_read(&global_added_lock);
       return match->nid;
     }
   }
   CRYPTO_MUTEX_unlock_read(&global_added_lock);

   const uint16_t *nid_ptr = reinterpret_cast<const uint16_t *>(
       bsearch(short_name, kNIDsInShortNameOrder,
               OPENSSL_ARRAY_SIZE(kNIDsInShortNameOrder),
               sizeof(kNIDsInShortNameOrder[0]), short_name_cmp));
   if (nid_ptr == NULL) {
     return NID_undef;
   }

   return get_builtin_object(*nid_ptr)->nid;
 }

 // long_name_cmp is called to search the kNIDsInLongNameOrder array. The
 // |key| argument is name that we're looking for and |element| is a pointer to
 // an unsigned int in the array.
 static int long_name_cmp(const void *key, const void *element) {
   const char *name = (const char *)key;
   uint16_t nid = *((const uint16_t *)element);

   return strcmp(name, get_builtin_object(nid)->ln);
 }

 int OBJ_ln2nid(const char *long_name) {
   CRYPTO_MUTEX_lock_read(&global_added_lock);
   if (global_added_by_long_name != NULL) {
     ASN1_OBJECT *match, templ;

     templ.ln = long_name;
     match = lh_ASN1_OBJECT_retrieve(global_added_by_long_name, &templ);
     if (match != NULL) {
       CRYPTO_MUTEX_unlock_read(&global_added_lock);
       return match->nid;
     }
   }
   CRYPTO_MUTEX_unlock_read(&global_added_lock);

   const uint16_t *nid_ptr = reinterpret_cast<const uint16_t *>(bsearch(
       long_name, kNIDsInLongNameOrder, OPENSSL_ARRAY_SIZE(kNIDsInLongNameOrder),
       sizeof(kNIDsInLongNameOrder[0]), long_name_cmp));
   if (nid_ptr == NULL) {
     return NID_undef;
   }

   return get_builtin_object(*nid_ptr)->nid;
 }

 int OBJ_txt2nid(const char *s) {
   ASN1_OBJECT *obj;
   int nid;

   obj = OBJ_txt2obj(s, 0 /* search names */);
   nid = OBJ_obj2nid(obj);
   ASN1_OBJECT_free(obj);
   return nid;
 }

 OPENSSL_EXPORT int OBJ_nid2cbb(CBB *out, int nid) {
   const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
   return obj != NULL &&
          CBB_add_asn1_element(out, CBS_ASN1_OBJECT, obj->data, obj->length);
 }

 const ASN1_OBJECT *OBJ_get_undef(void) {
   static const ASN1_OBJECT kUndef = {
       /*sn=*/SN_undef,
       /*ln=*/LN_undef,
       /*nid=*/NID_undef,
       /*length=*/0,
       /*data=*/NULL,
       /*flags=*/0,
   };
   return &kUndef;
 }

 ASN1_OBJECT *OBJ_nid2obj(int nid) {
   if (nid == NID_undef) {
     return (ASN1_OBJECT *)OBJ_get_undef();
   }

   if (nid > 0 && nid < NUM_NID) {
     const ASN1_OBJECT *obj = get_builtin_object(nid);
     if (nid != NID_undef && obj->nid == NID_undef) {
       goto err;
     }
     return (ASN1_OBJECT *)obj;
   }

   CRYPTO_MUTEX_lock_read(&global_added_lock);
   if (global_added_by_nid != NULL) {
     ASN1_OBJECT *match, templ;

     templ.nid = nid;
     match = lh_ASN1_OBJECT_retrieve(global_added_by_nid, &templ);
     if (match != NULL) {
       CRYPTO_MUTEX_unlock_read(&global_added_lock);
       return match;
     }
   }
   CRYPTO_MUTEX_unlock_read(&global_added_lock);

 err:
   OPENSSL_PUT_ERROR(OBJ, OBJ_R_UNKNOWN_NID);
   return NULL;
 }

 const char *OBJ_nid2sn(int nid) {
   const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
   if (obj == NULL) {
     return NULL;
   }

   return obj->sn;
 }

 const char *OBJ_nid2ln(int nid) {
   const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
   if (obj == NULL) {
     return NULL;
   }

   return obj->ln;
 }

 static ASN1_OBJECT *create_object_with_text_oid(int (*get_nid)(void),
                                                 const char *oid,
                                                 const char *short_name,
                                                 const char *long_name) {
   uint8_t *buf;
   size_t len;
   CBB cbb;
   if (!CBB_init(&cbb, 32) ||
       !CBB_add_asn1_oid_from_text(&cbb, oid, strlen(oid)) ||
       !CBB_finish(&cbb, &buf, &len)) {
     OPENSSL_PUT_ERROR(OBJ, OBJ_R_INVALID_OID_STRING);
     CBB_cleanup(&cbb);
     return NULL;
   }

   ASN1_OBJECT *ret = ASN1_OBJECT_create(get_nid ? get_nid() : NID_undef, buf,
                                         len, short_name, long_name);
   OPENSSL_free(buf);
   return ret;
 }

 ASN1_OBJECT *OBJ_txt2obj(const char *s, int dont_search_names) {
   if (!dont_search_names) {
     int nid = OBJ_sn2nid(s);
     if (nid == NID_undef) {
       nid = OBJ_ln2nid(s);
     }

     if (nid != NID_undef) {
       return OBJ_nid2obj(nid);
     }
   }

   return create_object_with_text_oid(NULL, s, NULL, NULL);
 }

 static int strlcpy_int(char *dst, const char *src, int dst_size) {
   size_t ret = OPENSSL_strlcpy(dst, src, dst_size < 0 ? 0 : (size_t)dst_size);
   if (ret > INT_MAX) {
     OPENSSL_PUT_ERROR(OBJ, ERR_R_OVERFLOW);
     return -1;
   }
   return (int)ret;
 }

 int OBJ_obj2txt(char *out, int out_len, const ASN1_OBJECT *obj,
                 int always_return_oid) {
   // Python depends on the empty OID successfully encoding as the empty
   // string.
   if (obj == NULL || obj->length == 0) {
     return strlcpy_int(out, "", out_len);
   }

   if (!always_return_oid) {
     int nid = OBJ_obj2nid(obj);
     if (nid != NID_undef) {
       const char *name = OBJ_nid2ln(nid);
       if (name == NULL) {
         name = OBJ_nid2sn(nid);
       }
       if (name != NULL) {
         return strlcpy_int(out, name, out_len);
       }
     }
   }

   CBS cbs;
   CBS_init(&cbs, obj->data, obj->length);
   char *txt = CBS_asn1_oid_to_text(&cbs);
   if (txt == NULL) {
     if (out_len > 0) {
       out[0] = '\0';
     }
     return -1;
   }

   int ret = strlcpy_int(out, txt, out_len);
   OPENSSL_free(txt);
   return ret;
 }

 static uint32_t hash_nid(const ASN1_OBJECT *obj) { return obj->nid; }

 static int cmp_nid(const ASN1_OBJECT *a, const ASN1_OBJECT *b) {
   return a->nid - b->nid;
 }

 static uint32_t hash_data(const ASN1_OBJECT *obj) {
   return OPENSSL_hash32(obj->data, obj->length);
 }

 static uint32_t hash_short_name(const ASN1_OBJECT *obj) {
   return OPENSSL_strhash(obj->sn);
 }

 static int cmp_short_name(const ASN1_OBJECT *a, const ASN1_OBJECT *b) {
   return strcmp(a->sn, b->sn);
 }

 static uint32_t hash_long_name(const ASN1_OBJECT *obj) {
   return OPENSSL_strhash(obj->ln);
 }

 static int cmp_long_name(const ASN1_OBJECT *a, const ASN1_OBJECT *b) {
   return strcmp(a->ln, b->ln);
 }

 // obj_add_object inserts |obj| into the various global hashes for run-time
 // added objects. It returns one on success or zero otherwise.
 static int obj_add_object(ASN1_OBJECT *obj) {
   obj->flags &= ~(ASN1_OBJECT_FLAG_DYNAMIC | ASN1_OBJECT_FLAG_DYNAMIC_STRINGS |
                   ASN1_OBJECT_FLAG_DYNAMIC_DATA);

   CRYPTO_MUTEX_lock_write(&global_added_lock);
   if (global_added_by_nid == NULL) {
     global_added_by_nid = lh_ASN1_OBJECT_new(hash_nid, cmp_nid);
   }
   if (global_added_by_data == NULL) {
     global_added_by_data = lh_ASN1_OBJECT_new(hash_data, OBJ_cmp);
   }
   if (global_added_by_short_name == NULL) {
     global_added_by_short_name =
         lh_ASN1_OBJECT_new(hash_short_name, cmp_short_name);
   }
   if (global_added_by_long_name == NULL) {
     global_added_by_long_name =
         lh_ASN1_OBJECT_new(hash_long_name, cmp_long_name);
   }

   int ok = 0;
   if (global_added_by_nid == NULL ||         //
       global_added_by_data == NULL ||        //
       global_added_by_short_name == NULL ||  //
       global_added_by_long_name == NULL) {
     goto err;
   }

   // We don't pay attention to |old_object| (which contains any previous object
   // that was evicted from the hashes) because we don't have a reference count
   // on ASN1_OBJECT values. Also, we should never have duplicates nids and so
   // should always have objects in |global_added_by_nid|.
   ASN1_OBJECT *old_object;
   ok = lh_ASN1_OBJECT_insert(global_added_by_nid, &old_object, obj);
   if (obj->length != 0 && obj->data != NULL) {
     ok &= lh_ASN1_OBJECT_insert(global_added_by_data, &old_object, obj);
   }
   if (obj->sn != NULL) {
     ok &= lh_ASN1_OBJECT_insert(global_added_by_short_name, &old_object, obj);
   }
   if (obj->ln != NULL) {
     ok &= lh_ASN1_OBJECT_insert(global_added_by_long_name, &old_object, obj);
   }

 err:
   CRYPTO_MUTEX_unlock_write(&global_added_lock);
   return ok;
 }

 int OBJ_create(const char *oid, const char *short_name, const char *long_name) {
   ASN1_OBJECT *op =
       create_object_with_text_oid(obj_next_nid, oid, short_name, long_name);
   if (op == NULL || !obj_add_object(op)) {
     return NID_undef;
   }
   return op->nid;
 }

 void OBJ_cleanup(void) {}
	// Copyright 1995-2016 The OpenSSL Project Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include <openssl/obj.h>

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

	#include <openssl/asn1.h>
	#include <openssl/bytestring.h>
	#include <openssl/err.h>
	#include <openssl/mem.h>

	#include "../asn1/internal.h"
	#include "../internal.h"
	#include "../lhash/internal.h"

	// obj_data.h must be included after the definition of \|ASN1_OBJECT\|.
	#include "obj_dat.h"


	DEFINE_LHASH_OF(ASN1_OBJECT)

	static CRYPTO_MUTEX global_added_lock = CRYPTO_MUTEX_INIT;
	// These globals are protected by \|global_added_lock\|.
	static LHASH_OF(ASN1_OBJECT) *global_added_by_data = NULL;
	static LHASH_OF(ASN1_OBJECT) *global_added_by_nid = NULL;
	static LHASH_OF(ASN1_OBJECT) *global_added_by_short_name = NULL;
	static LHASH_OF(ASN1_OBJECT) *global_added_by_long_name = NULL;

	static CRYPTO_MUTEX global_next_nid_lock = CRYPTO_MUTEX_INIT;
	static unsigned global_next_nid = NUM_NID;

	static int obj_next_nid(void) {
	CRYPTO_MUTEX_lock_write(&global_next_nid_lock);
	int ret = global_next_nid++;
	CRYPTO_MUTEX_unlock_write(&global_next_nid_lock);
	return ret;
	}

	ASN1_OBJECT OBJ_dup(const ASN1_OBJECT o) {
	ASN1_OBJECT *r;
	unsigned char *data = NULL;
	char sn = NULL, ln = NULL;

	if (o == NULL) {
	return NULL;
	}

	if (!(o->flags & ASN1_OBJECT_FLAG_DYNAMIC)) {
	// TODO(fork): this is a little dangerous.
	return (ASN1_OBJECT *)o;
	}

	r = ASN1_OBJECT_new();
	if (r == NULL) {
	OPENSSL_PUT_ERROR(OBJ, ERR_R_ASN1_LIB);
	return NULL;
	}
	r->ln = r->sn = NULL;

	// once data is attached to an object, it remains const
	r->data = reinterpret_cast<uint8_t *>(OPENSSL_memdup(o->data, o->length));
	if (o->length != 0 && r->data == NULL) {
	goto err;
	}

	r->length = o->length;
	r->nid = o->nid;

	if (o->ln != NULL) {
	ln = OPENSSL_strdup(o->ln);
	if (ln == NULL) {
	goto err;
	}
	}

	if (o->sn != NULL) {
	sn = OPENSSL_strdup(o->sn);
	if (sn == NULL) {
	goto err;
	}
	}

	r->sn = sn;
	r->ln = ln;

	r->flags =
	o->flags \| (ASN1_OBJECT_FLAG_DYNAMIC \| ASN1_OBJECT_FLAG_DYNAMIC_STRINGS \|
	ASN1_OBJECT_FLAG_DYNAMIC_DATA);
	return r;

	err:
	OPENSSL_free(ln);
	OPENSSL_free(sn);
	OPENSSL_free(data);
	OPENSSL_free(r);
	return NULL;
	}

	int OBJ_cmp(const ASN1_OBJECT a, const ASN1_OBJECT b) {
	if (a->length < b->length) {
	return -1;
	} else if (a->length > b->length) {
	return 1;
	}
	return OPENSSL_memcmp(a->data, b->data, a->length);
	}

	const uint8_t OBJ_get0_data(const ASN1_OBJECT obj) {
	if (obj == NULL) {
	return NULL;
	}

	return obj->data;
	}

	size_t OBJ_length(const ASN1_OBJECT *obj) {
	if (obj == NULL \|\| obj->length < 0) {
	return 0;
	}

	return (size_t)obj->length;
	}

	static const ASN1_OBJECT *get_builtin_object(int nid) {
	// \|NID_undef\| is stored separately, so all the indices are off by one. The
	// caller of this function must have a valid built-in, non-undef NID.
	BSSL_CHECK(nid > 0 && nid < NUM_NID);
	return &kObjects[nid - 1];
	}

	// obj_cmp is called to search the kNIDsInOIDOrder array. The \|key\| argument is
	// an \|ASN1_OBJECT\|* that we're looking for and \|element\| is a pointer to an
	// unsigned int in the array.
	static int obj_cmp(const void key, const void element) {
	uint16_t nid = ((const uint16_t )element);
	return OBJ_cmp(reinterpret_cast<const ASN1_OBJECT *>(key),
	get_builtin_object(nid));
	}

	int OBJ_obj2nid(const ASN1_OBJECT *obj) {
	if (obj == NULL) {
	return NID_undef;
	}

	if (obj->nid != 0) {
	return obj->nid;
	}

	CRYPTO_MUTEX_lock_read(&global_added_lock);
	if (global_added_by_data != NULL) {
	ASN1_OBJECT *match;

	match = lh_ASN1_OBJECT_retrieve(global_added_by_data, obj);
	if (match != NULL) {
	CRYPTO_MUTEX_unlock_read(&global_added_lock);
	return match->nid;
	}
	}
	CRYPTO_MUTEX_unlock_read(&global_added_lock);

	const uint16_t nid_ptr = reinterpret_cast<const uint16_t >(
	bsearch(obj, kNIDsInOIDOrder, OPENSSL_ARRAY_SIZE(kNIDsInOIDOrder),
	sizeof(kNIDsInOIDOrder[0]), obj_cmp));
	if (nid_ptr == NULL) {
	return NID_undef;
	}

	return get_builtin_object(*nid_ptr)->nid;
	}

	int OBJ_cbs2nid(const CBS *cbs) {
	if (CBS_len(cbs) > INT_MAX) {
	return NID_undef;
	}

	ASN1_OBJECT obj;
	OPENSSL_memset(&obj, 0, sizeof(obj));
	obj.data = CBS_data(cbs);
	obj.length = (int)CBS_len(cbs);

	return OBJ_obj2nid(&obj);
	}

	// short_name_cmp is called to search the kNIDsInShortNameOrder array. The
	// \|key\| argument is name that we're looking for and \|element\| is a pointer to
	// an unsigned int in the array.
	static int short_name_cmp(const void key, const void element) {
	const char name = (const char )key;
	uint16_t nid = ((const uint16_t )element);

	return strcmp(name, get_builtin_object(nid)->sn);
	}

	int OBJ_sn2nid(const char *short_name) {
	CRYPTO_MUTEX_lock_read(&global_added_lock);
	if (global_added_by_short_name != NULL) {
	ASN1_OBJECT *match, templ;

	templ.sn = short_name;
	match = lh_ASN1_OBJECT_retrieve(global_added_by_short_name, &templ);
	if (match != NULL) {
	CRYPTO_MUTEX_unlock_read(&global_added_lock);
	return match->nid;
	}
	}
	CRYPTO_MUTEX_unlock_read(&global_added_lock);

	const uint16_t nid_ptr = reinterpret_cast<const uint16_t >(
	bsearch(short_name, kNIDsInShortNameOrder,
	OPENSSL_ARRAY_SIZE(kNIDsInShortNameOrder),
	sizeof(kNIDsInShortNameOrder[0]), short_name_cmp));
	if (nid_ptr == NULL) {
	return NID_undef;
	}

	return get_builtin_object(*nid_ptr)->nid;
	}

	// long_name_cmp is called to search the kNIDsInLongNameOrder array. The
	// \|key\| argument is name that we're looking for and \|element\| is a pointer to
	// an unsigned int in the array.
	static int long_name_cmp(const void key, const void element) {
	const char name = (const char )key;
	uint16_t nid = ((const uint16_t )element);

	return strcmp(name, get_builtin_object(nid)->ln);
	}

	int OBJ_ln2nid(const char *long_name) {
	CRYPTO_MUTEX_lock_read(&global_added_lock);
	if (global_added_by_long_name != NULL) {
	ASN1_OBJECT *match, templ;

	templ.ln = long_name;
	match = lh_ASN1_OBJECT_retrieve(global_added_by_long_name, &templ);
	if (match != NULL) {
	CRYPTO_MUTEX_unlock_read(&global_added_lock);
	return match->nid;
	}
	}
	CRYPTO_MUTEX_unlock_read(&global_added_lock);

	const uint16_t nid_ptr = reinterpret_cast<const uint16_t >(bsearch(
	long_name, kNIDsInLongNameOrder, OPENSSL_ARRAY_SIZE(kNIDsInLongNameOrder),
	sizeof(kNIDsInLongNameOrder[0]), long_name_cmp));
	if (nid_ptr == NULL) {
	return NID_undef;
	}

	return get_builtin_object(*nid_ptr)->nid;
	}

	int OBJ_txt2nid(const char *s) {
	ASN1_OBJECT *obj;
	int nid;

	obj = OBJ_txt2obj(s, 0 /* search names */);
	nid = OBJ_obj2nid(obj);
	ASN1_OBJECT_free(obj);
	return nid;
	}

	OPENSSL_EXPORT int OBJ_nid2cbb(CBB *out, int nid) {
	const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
	return obj != NULL &&
	CBB_add_asn1_element(out, CBS_ASN1_OBJECT, obj->data, obj->length);
	}

	const ASN1_OBJECT *OBJ_get_undef(void) {
	static const ASN1_OBJECT kUndef = {
	/sn=/SN_undef,
	/ln=/LN_undef,
	/nid=/NID_undef,
	/length=/0,
	/data=/NULL,
	/flags=/0,
	};
	return &kUndef;
	}

	ASN1_OBJECT *OBJ_nid2obj(int nid) {
	if (nid == NID_undef) {
	return (ASN1_OBJECT *)OBJ_get_undef();
	}

	if (nid > 0 && nid < NUM_NID) {
	const ASN1_OBJECT *obj = get_builtin_object(nid);
	if (nid != NID_undef && obj->nid == NID_undef) {
	goto err;
	}
	return (ASN1_OBJECT *)obj;
	}

	CRYPTO_MUTEX_lock_read(&global_added_lock);
	if (global_added_by_nid != NULL) {
	ASN1_OBJECT *match, templ;

	templ.nid = nid;
	match = lh_ASN1_OBJECT_retrieve(global_added_by_nid, &templ);
	if (match != NULL) {
	CRYPTO_MUTEX_unlock_read(&global_added_lock);
	return match;
	}
	}
	CRYPTO_MUTEX_unlock_read(&global_added_lock);

	err:
	OPENSSL_PUT_ERROR(OBJ, OBJ_R_UNKNOWN_NID);
	return NULL;
	}

	const char *OBJ_nid2sn(int nid) {
	const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
	if (obj == NULL) {
	return NULL;
	}

	return obj->sn;
	}

	const char *OBJ_nid2ln(int nid) {
	const ASN1_OBJECT *obj = OBJ_nid2obj(nid);
	if (obj == NULL) {
	return NULL;
	}

	return obj->ln;
	}

	static ASN1_OBJECT create_object_with_text_oid(int (get_nid)(void),
	const char *oid,
	const char *short_name,
	const char *long_name) {
	uint8_t *buf;
	size_t len;
	CBB cbb;
	if (!CBB_init(&cbb, 32) \|\|
	!CBB_add_asn1_oid_from_text(&cbb, oid, strlen(oid)) \|\|
	!CBB_finish(&cbb, &buf, &len)) {
	OPENSSL_PUT_ERROR(OBJ, OBJ_R_INVALID_OID_STRING);
	CBB_cleanup(&cbb);
	return NULL;
	}

	ASN1_OBJECT *ret = ASN1_OBJECT_create(get_nid ? get_nid() : NID_undef, buf,
	len, short_name, long_name);
	OPENSSL_free(buf);
	return ret;
	}

	ASN1_OBJECT OBJ_txt2obj(const char s, int dont_search_names) {
	if (!dont_search_names) {
	int nid = OBJ_sn2nid(s);
	if (nid == NID_undef) {
	nid = OBJ_ln2nid(s);
	}

	if (nid != NID_undef) {
	return OBJ_nid2obj(nid);
	}
	}

	return create_object_with_text_oid(NULL, s, NULL, NULL);
	}

	static int strlcpy_int(char dst, const char src, int dst_size) {
	size_t ret = OPENSSL_strlcpy(dst, src, dst_size < 0 ? 0 : (size_t)dst_size);
	if (ret > INT_MAX) {
	OPENSSL_PUT_ERROR(OBJ, ERR_R_OVERFLOW);
	return -1;
	}
	return (int)ret;
	}

	int OBJ_obj2txt(char out, int out_len, const ASN1_OBJECT obj,
	int always_return_oid) {
	// Python depends on the empty OID successfully encoding as the empty
	// string.
	if (obj == NULL \|\| obj->length == 0) {
	return strlcpy_int(out, "", out_len);
	}

	if (!always_return_oid) {
	int nid = OBJ_obj2nid(obj);
	if (nid != NID_undef) {
	const char *name = OBJ_nid2ln(nid);
	if (name == NULL) {
	name = OBJ_nid2sn(nid);
	}
	if (name != NULL) {
	return strlcpy_int(out, name, out_len);
	}
	}
	}

	CBS cbs;
	CBS_init(&cbs, obj->data, obj->length);
	char *txt = CBS_asn1_oid_to_text(&cbs);
	if (txt == NULL) {
	if (out_len > 0) {
	out[0] = '\0';
	}
	return -1;
	}

	int ret = strlcpy_int(out, txt, out_len);
	OPENSSL_free(txt);
	return ret;
	}

	static uint32_t hash_nid(const ASN1_OBJECT *obj) { return obj->nid; }

	static int cmp_nid(const ASN1_OBJECT a, const ASN1_OBJECT b) {
	return a->nid - b->nid;
	}

	static uint32_t hash_data(const ASN1_OBJECT *obj) {
	return OPENSSL_hash32(obj->data, obj->length);
	}

	static uint32_t hash_short_name(const ASN1_OBJECT *obj) {
	return OPENSSL_strhash(obj->sn);
	}

	static int cmp_short_name(const ASN1_OBJECT a, const ASN1_OBJECT b) {
	return strcmp(a->sn, b->sn);
	}

	static uint32_t hash_long_name(const ASN1_OBJECT *obj) {
	return OPENSSL_strhash(obj->ln);
	}

	static int cmp_long_name(const ASN1_OBJECT a, const ASN1_OBJECT b) {
	return strcmp(a->ln, b->ln);
	}

	// obj_add_object inserts \|obj\| into the various global hashes for run-time
	// added objects. It returns one on success or zero otherwise.
	static int obj_add_object(ASN1_OBJECT *obj) {
	obj->flags &= ~(ASN1_OBJECT_FLAG_DYNAMIC \| ASN1_OBJECT_FLAG_DYNAMIC_STRINGS \|
	ASN1_OBJECT_FLAG_DYNAMIC_DATA);

	CRYPTO_MUTEX_lock_write(&global_added_lock);
	if (global_added_by_nid == NULL) {
	global_added_by_nid = lh_ASN1_OBJECT_new(hash_nid, cmp_nid);
	}
	if (global_added_by_data == NULL) {
	global_added_by_data = lh_ASN1_OBJECT_new(hash_data, OBJ_cmp);
	}
	if (global_added_by_short_name == NULL) {
	global_added_by_short_name =
	lh_ASN1_OBJECT_new(hash_short_name, cmp_short_name);
	}
	if (global_added_by_long_name == NULL) {
	global_added_by_long_name =
	lh_ASN1_OBJECT_new(hash_long_name, cmp_long_name);
	}

	int ok = 0;
	if (global_added_by_nid == NULL \|\| //
	global_added_by_data == NULL \|\| //
	global_added_by_short_name == NULL \|\| //
	global_added_by_long_name == NULL) {
	goto err;
	}

	// We don't pay attention to \|old_object\| (which contains any previous object
	// that was evicted from the hashes) because we don't have a reference count
	// on ASN1_OBJECT values. Also, we should never have duplicates nids and so
	// should always have objects in \|global_added_by_nid\|.
	ASN1_OBJECT *old_object;
	ok = lh_ASN1_OBJECT_insert(global_added_by_nid, &old_object, obj);
	if (obj->length != 0 && obj->data != NULL) {
	ok &= lh_ASN1_OBJECT_insert(global_added_by_data, &old_object, obj);
	}
	if (obj->sn != NULL) {
	ok &= lh_ASN1_OBJECT_insert(global_added_by_short_name, &old_object, obj);
	}
	if (obj->ln != NULL) {
	ok &= lh_ASN1_OBJECT_insert(global_added_by_long_name, &old_object, obj);
	}

	err:
	CRYPTO_MUTEX_unlock_write(&global_added_lock);
	return ok;
	}

	int OBJ_create(const char oid, const char short_name, const char *long_name) {
	ASN1_OBJECT *op =
	create_object_with_text_oid(obj_next_nid, oid, short_name, long_name);
	if (op == NULL \|\| !obj_add_object(op)) {
	return NID_undef;
	}
	return op->nid;
	}

	void OBJ_cleanup(void) {}