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  • password_hash()

    (PHP 5 >= 5.5.0, PHP 7)

    创建密码的散列(hash)

    说明

    password_hash(string $password,int $algo[,array $options]): string

    password_hash()使用足够强度的单向散列算法创建密码的散列(hash)。password_hash()兼容crypt()。所以,crypt()创建的密码散列也可用于password_hash()

    当前支持的算法:

    • PASSWORD_DEFAULT-使用 bcrypt 算法(PHP 5.5.0 默认)。注意,该常量会随着 PHP 加入更新更高强度的算法而改变。所以,使用此常量生成结果的长度将在未来有变化。因此,数据库里储存结果的列可超过60个字符(最好是255个字符)。
    • PASSWORD_BCRYPT-使用CRYPT_BLOWFISH算法创建散列。这会产生兼容使用"$2y$"的crypt()。结果将会是 60 个字符的字符串,或者在失败时返回FALSE
    • PASSWORD_ARGON2I-使用 Argon2 散列算法创建散列。

    PASSWORD_BCRYPT支持的选项:

    • salt(string)-手动提供散列密码的盐值(salt)。这将避免自动生成盐值(salt)。

      省略此值后,password_hash()会为每个密码散列自动生成随机的盐值。这种操作是有意的模式。

      Warning

      盐值(salt)选项从 PHP 7.0.0 开始被废弃(deprecated)了。现在最好选择简单的使用默认产生的盐值。

    • cost(integer)-代表算法使用的 cost。crypt()页面上有 cost 值的例子。

      省略时,默认值是10。这个 cost 是个不错的底线,但也许可以根据自己硬件的情况,加大这个值。

    PASSWORD_ARGON2I支持的选项:

    • memory_cost(integer)-计算 Argon2 散列时的最大内存(单位:字节 byte)。默认值:PASSWORD_ARGON2_DEFAULT_MEMORY_COST

    • time_cost(integer)-计算 Argon2 散列时最多的时间。默认值:PASSWORD_ARGON2_DEFAULT_TIME_COST

    • threads(integer)-计算 Argon2 散列时最多的线程数。默认值:PASSWORD_ARGON2_DEFAULT_THREADS

    参数

    $password

    用户的密码。

    Caution

    使用PASSWORD_BCRYPT做算法,将使$password参数最长为72个字符,超过会被截断。

    $algo

    一个用来在散列密码时指示算法的密码算法常量。

    $options

    一个包含有选项的关联数组。目前支持两个选项:salt,在散列密码时加的盐(干扰字符串),以及cost,用来指明算法递归的层数。这两个值的例子可在crypt()页面找到。

    省略后,将使用随机盐值与默认 cost。

    返回值

    返回散列后的密码,或者在失败时返回FALSE

    使用的算法、cost 和盐值作为散列的一部分返回。所以验证散列值的所有信息都已经包含在内。这使password_verify()函数验证的时候,不需要额外储存盐值或者算法的信息。

    范例

    Example #1password_hash()例子

    <?php
    /**
     * 我们想要使用默认算法散列密码
     * 当前是 BCRYPT,并会产生 60 个字符的结果。
     *
     * 请注意,随时间推移,默认算法可能会有变化,
     * 所以需要储存的空间能够超过 60 字(255字不错)
     */
    echo password_hash("rasmuslerdorf", PASSWORD_DEFAULT);
    ?>
    

    以上例程的输出类似于:

    $2y$10$.vGA1O9wmRjrwAVXD98HNOgsNpDczlqm3Jq7KnEd1rVAGv3Fykk1a
    

    Example #2password_hash()手动设置 cost 的例子

    <?php
    /**
     * 在这个案例里,我们为 BCRYPT 增加 cost 到 12。
     * 注意,我们已经切换到了,将始终产生 60 个字符。
     */
    $options = [
        'cost' => 12,
    ];
    echo password_hash("rasmuslerdorf", PASSWORD_BCRYPT, $options);
    ?>
    

    以上例程的输出类似于:

    $2y$12$QjSH496pcT5CEbzjD/vtVeH03tfHKFy36d4J0Ltp3lRtee9HDxY3K
    

    Example #3password_hash()手动设置盐值的例子

    <?php
    /**
     * 注意,这里的盐值是随机产生的。
     * 永远都不要使用固定盐值,或者不是随机生成的盐值。
     *
     * 绝大多数情况下,可以让 password_hash generate 为你自动产生随机盐值
     */
    $options = [
        'cost' => 11,
        'salt' => mcrypt_create_iv(22, MCRYPT_DEV_URANDOM),
    ];
    echo password_hash("rasmuslerdorf", PASSWORD_BCRYPT, $options);
    ?>
    

    以上例程的输出类似于:

    $2y$11$q5MkhSBtlsJcNEVsYh64a.aCluzHnGog7TQAKVmQwO9C8xb.t89F.
    

    寻找最佳 cost 的password_hash()例子

    <?php
    /**
     * 这个例子对服务器做了基准测试(benchmark),检测服务器能承受多高的 cost
     * 在不明显拖慢服务器的情况下可以设置最高的值
     * 8-10 是个不错的底线,在服务器够快的情况下,越高越好。
     * 以下代码目标为  ≤ 50 毫秒(milliseconds),
     * 适合系统处理交互登录。
     */
    $timeTarget = 0.05; // 50 毫秒(milliseconds) 
    $cost = 8;
    do {
        $cost++;
        $start = microtime(true);
        password_hash("test", PASSWORD_BCRYPT, ["cost" => $cost]);
        $end = microtime(true);
    } while (($end - $start) < $timeTarget);
    echo "Appropriate Cost Found: " . $cost;
    ?>
    

    以上例程的输出类似于:

    Appropriate Cost Found: 10
    

    使用 Argon2 的password_hash()例子

    <?php
    echo 'Argon2 hash: ' . password_hash('rasmuslerdorf', PASSWORD_ARGON2I);
    ?>
    

    以上例程的输出类似于:

    Argon2 hash: $argon2i$v=19$m=1024,t=2,p=2$YzJBSzV4TUhkMzc3d3laeg$zqU/1IN0/AogfP4cmSJI1vc8lpXRW9/S0sYY2i2jHT0
    

    注释

    Caution

    强烈建议不要自己为这个函数生成盐值(salt)。只要不设置,它会自动创建安全的盐值。

    就像以上提及的,在 PHP 7.0 提供salt选项会导致废弃(deprecation)警告。未来的 PHP 发行版里,手动提供盐值的功能可能会被删掉。

    Note:

    在交互的系统上,推荐在自己的服务器上测试此函数,调整 cost 参数直至函数时间开销小于 100 毫秒(milliseconds)。上面脚本的例子会帮助选择合适硬件的最佳 cost。

    Note:这个函数更新支持的算法时(或修改默认算法),必定会遵守以下规则:

    • 任何内核中的新算法必须在经历一次 PHP 完整发行才能成为默认算法。比如,在 PHP 7.5.5 中添加的新算法,在 PHP 7.7 之前不能成为默认算法(由于 7.6 是第一个完整发行版)。但如果是在 7.6.0 里添加的不同算法,在 7.7.0 里也可以成为默认算法。
    • 仅仅允许在完整发行版中修改默认算法(比如 7.3.0, 8.0.0,等等),不能是在修订版。唯一的例外是:在当前默认算法里发现了紧急的安全威胁。

    更新日志

    版本说明
    7.2.0添加PASSWORD_ARGON2I,支持 Argon2 密码散列算法。

    参见

    There is a compatibility pack available for PHP versions 5.3.7 and later, so you don't have to wait on version 5.5 for using this function. It comes in form of a single php file:
    https://github.com/ircmaxell/password_compat
    Since 2017, NIST recommends using a secret input when hashing memorized secrets such as passwords. By mixing in a secret input (commonly called a "pepper"), one prevents an attacker from brute-forcing the password hashes altogether, even if they have the hash and salt. For example, an SQL injection typically affects only the database, not files on disk, so a pepper stored in a config file would still be out of reach for the attacker. A pepper must be randomly generated once and can be the same for all users. Many password leaks could have been made completely useless if site owners had done this.
    Since there is no pepper parameter for password_hash (even though Argon2 has a "secret" parameter, PHP does not allow to set it), the correct way to mix in a pepper is to use hash_hmac(). The "add note" rules of php.net say I can't link external sites, so I can't back any of this up with a link to NIST, Wikipedia, posts from the security stackexchange site that explain the reasoning, or anything... You'll have to verify this manually. The code:
    // config.conf
    pepper=c1isvFdxMDdmjOlvxpecFw
    <?php
    // register.php
    $pepper = getConfigVariable("pepper");
    $pwd = $_POST['password'];
    $pwd_peppered = hash_hmac("sha256", $pwd, $pepper);
    $pwd_hashed = password_hash($pwd_peppered, PASSWORD_ARGON2ID);
    add_user_to_database($username, $pwd_hashed);
    ?>
    <?php
    // login.php
    $pepper = getConfigVariable("pepper");
    $pwd = $_POST['password'];
    $pwd_peppered = hash_hmac("sha256", $pwd, $pepper);
    $pwd_hashed = get_pwd_from_db($username);
    if (password_verify($pwd_peppered, $pwd_hashed)) {
      echo "Password matches.";
    }
    else {
      echo "Password incorrect.";
    }
    ?>
    Note that this code contains a timing attack that leaks whether the username exists. But my note was over the length limit so I had to cut this paragraph out.
    Also note that the pepper is useless if leaked or if it can be cracked. Consider how it might be exposed, for example different methods of passing it to a docker container. Against cracking, use a long randomly generated value (like in the example above), and change the pepper when you do a new install with a clean user database. Changing the pepper for an existing database is the same as changing other hashing parameters: you can either wrap the old value in a new one and layer the hashing (more complex), you compute the new password hash whenever someone logs in (leaving old users at risk, so this might be okay depending on what the reason is that you're upgrading).
    Why does this work? Because an attacker does the following after stealing the database:
    password_verify("a", $stolen_hash)
    password_verify("b", $stolen_hash)
    ...
    password_verify("z", $stolen_hash)
    password_verify("aa", $stolen_hash)
    etc.
    (More realistically, they use a cracking dictionary, but in principle, the way to crack a password hash is by guessing. That's why we use special algorithms: they are slower, so each verify() operation will be slower, so they can try much fewer passwords per hour of cracking.)
    Now what if you used that pepper? Now they need to do this:
    password_verify(hmac_sha256("a", $secret), $stolen_hash)
    Without that $secret (the pepper), they can't do this computation. They would have to do:
    password_verify(hmac_sha256("a", "a"), $stolen_hash)
    password_verify(hmac_sha256("a", "b"), $stolen_hash)
    ...
    etc., until they found the correct pepper.
    If your pepper contains 128 bits of entropy, and so long as hmac-sha256 remains secure (even MD5 is technically secure for use in hmac: only its collision resistance is broken, but of course nobody would use MD5 because more and more flaws are found), this would take more energy than the sun outputs. In other words, it's currently impossible to crack a pepper that strong, even given a known password and salt.
    I agree with martinstoeckli,
    don't create your own salts unless you really know what you're doing.
    By default, it'll use /dev/urandom to create the salt, which is based on noise from device drivers.
    And on Windows, it uses CryptGenRandom().
    Both have been around for many years, and are considered secure for cryptography (the former probably more than the latter, though).
    Don't try to outsmart these defaults by creating something less secure. Anything that is based on rand(), mt_rand(), uniqid(), or variations of these is *not* good.
    You can produce the same hash in php 5.3.7+ with crypt() function:
    <?php
    $salt = mcrypt_create_iv(22, MCRYPT_DEV_URANDOM);
    $salt = base64_encode($salt);
    $salt = str_replace('+', '.', $salt);
    $hash = crypt('rasmuslerdorf', '$2y$10$'.$salt.'$');
    echo $hash;
    ?>
    
    Please note that password_hash will ***truncate*** the password at the first NULL-byte.
    http://blog.ircmaxell.com/2015/03/security-issue-combining-bcrypt-with.html
    If you use anything as an input that can generate NULL bytes (sha1 with raw as true, or if NULL bytes can naturally end up in people's passwords), you may make your application much less secure than what you might be expecting.
    The password 
    $a = "\01234567"; 
    is zero bytes long (an empty password) for bcrypt.
    The workaround, of course, is to make sure you don't ever pass NULL-bytes to password_hash.
    According to the draft specification, Argon2di is the recommended mode of operation:
    > 9.4. Recommendations
    >
    >  The Argon2id variant with t=1 and maximum available memory is
    >  recommended as a default setting for all environments. This setting
    >  is secure against side-channel attacks and maximizes adversarial
    >  costs on dedicated bruteforce hardware.
    source: https://tools.ietf.org/html/draft-irtf-cfrg-argon2-06#section-9.4
    In most cases it is best to omit the salt parameter. Without this parameter, the function will generate a cryptographically safe salt, from the random source of the operating system.
    For passwords, you generally want the hash calculation time to be between 250 and 500 ms (maybe more for administrator accounts). Since calculation time is dependent on the capabilities of the server, using the same cost parameter on two different servers may result in vastly different execution times. Here's a quick little function that will help you determine what cost parameter you should be using for your server to make sure you are within this range (note, I am providing a salt to eliminate any latency caused by creating a pseudorandom salt, but this should not be done when hashing passwords):
    <?php
    /**
     * @Param int $min_ms Minimum amount of time in milliseconds that it should take
     * to calculate the hashes
     */
    function getOptimalBcryptCostParameter($min_ms = 250) {
      for ($i = 4; $i < 31; $i++) {
        $options = [ 'cost' => $i, 'salt' => 'usesomesillystringforsalt' ];
        $time_start = microtime(true);
        password_hash("rasmuslerdorf", PASSWORD_BCRYPT, $options);
        $time_end = microtime(true);
        if (($time_end - $time_start) * 1000 > $min_ms) {
          return $i;
        }
      }
    }
    echo getOptimalBcryptCostParameter(); // prints 12 in my case
    ?>
    
    Timing attacks simply put, are attacks that can calculate what characters of the password are due to speed of the execution.
    More at...
    https://paragonie.com/blog/2015/11/preventing-timing-attacks-on-string-comparison-with-double-hmac-strategy
    I have added code to phpnetcomment201908 at lucb1e dot com's suggestion to make this possible "timing attack" more difficult using the code phpnetcomment201908 at lucb1e dot com posted.
    $pph_strt = microtime(true);
    //...
    /*The code he posted for login.php*/
    //...
    $end = (microtime(true) - $pph_strt);
    $wait = bcmul((1 - $end), 1000000); // usleep(250000) 1/4 of a second
    usleep ( $wait );
    echo "<br>Execution time:".(microtime(true) - $pph_strt)."; ";
    Note I suggest changing the wait time to suit your needs but make sure that it is more than than the highest execution time the script takes on your server.
    Also, this is my workaround to obfuscate the execution time to nullify timing attacks. You can find an in-depth discussion and more from people far more equipped than I for cryptography at the link I posted. I do not believe this was there but there are others. It is where I found out what timing attacks were as I am new to this but would like solid security.
    if you thought
    "why is the salt included in the hash and is it save when i store it as it is in my db?"
    Answer i found:
    The salt just has to be unique. It not meant to be a secret.
    As mentioned in notes and docu before: let password_hash() take care of the salt.
    With the unique salt you force the attacker to crack the hash.
    The hash is unique and cannot be found at rainbow tables.
    Note that this function can return NULL. It does so if you provide an incorrect constant as an algorythm. I had the following:
      $password = password_hash($password1, PASSWORD_BDCRYPT, array( 'cost' => 10 ));
    and i couldn't understand why i kept having NULL written in $password; it was a simple fact that the constant was PASSWORD_BCRYPT.
    Pay close attention to the maximum allowed length of the password parameter! If you exceed the maximum length, it will be truncated without warning.
    If you prepend your own salt/pepper to the password, and that salt/pepper exceeds the maximum length, then this function will truncate the actual password. That means password_verify() will return true with ANY password using the same salt/pepper.
    It might be a good idea to append any salt/pepper to the end of the password instead.
    I believe a note should be added about the compatibility of crypt() and password_hash().
    My tests showed that yes, password_verify can also take hashes generated by crypt - as well as those from password_hash. But vice versa this is not true...
    You cannot put hashes generated by password_hash into crypt for comparing them themselves, when used as the salt for crypt, as was recommended years ago (compare user entry with user crypt(userentry,userentry). No big deal, but it means that password checking routines MUST immediately be rewritten to use password_hash...
    You cannot start using password_hash for hash generation without also altering the password check routine!
    So the word "compatible" should be, IMHO, ammended with a word of caution, hinting the reader, that compatibility here is a one-way street.