/// <summary>
/// Compares a given (plain text) password with the (already hashed) password that is inside the hashData object.
/// </summary>
/// <param name="givenPassword">Plain text password to compare with</param>
/// <param name="hashData">
/// The <see cref="PasswordHashingData" /> object that contains salt size, current hashed password, etc. for use in the
/// comparison
/// of the two passwords
/// </param>
public CommandResult ComparePasswords(string givenPassword, PasswordHashingData hashData)
{
if (String.IsNullOrWhiteSpace(givenPassword) || String.IsNullOrWhiteSpace(hashData?.HashedPassword) ||
String.IsNullOrWhiteSpace(hashData.Salt))
{
return(CommandResultFactory.Fail("The given data to compare passwords was invalid.", false));
}
var saltByteArray = hashData.Salt.ToHexBytes();
// Run initial hash at an application level
var appHashedPassword = GetAppLevelPasswordHash(givenPassword);
// Take the output of the initial hashing and run it through proper hashing with key stretching
var hashedPasswordResult =
ComputePasswordAndSaltBytes(saltByteArray, appHashedPassword, hashData.NumberOfIterations)
.Then(computedBytes =>
{
var hashedPassword = computedBytes.ToHexString();
return(CommandResultFactory.Ok <string>(hashedPassword));
});
if (hashedPasswordResult.IsFailure)
{
return(CommandResultFactory.Fail(
$"Computing the hash for the given password was not successful due to the following:\n{hashedPasswordResult.Message}"));
}
return(hashedPasswordResult.Value == hashData.HashedPassword
? CommandResultFactory.Ok()
: CommandResultFactory.Fail("Passwords did not match"));
}
/// <summary>
/// This is a way to chain a "Finally" handling callback method onto the end of the method chain. You can think of this
/// as being
/// similar to a "finally" call in .Net. The "Finally" will always call the callback method parameter. The callback
/// itself can
/// be responsible for whether or not to pass along a success or fail. There are also overloads that will simply call
/// the callback
/// and return the current success/fail status.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static CommandResult <TOutput> Finally <TOutput>(this CommandResult @this, Func <CommandResult, CommandResult <TOutput> > callback)
{
var result = @this.IsSuccessful
? callback(CommandResultFactory.Ok(@this.Message))
: callback(CommandResultFactory.Fail(@this.Message));
return(result);
}
/// <summary>
/// Decrypts the given encrypted text (cipher text) using the given key and key size.
/// </summary>
/// <param name="cipherText">The encrypted text to decrypt</param>
/// <param name="key">The (HEXADECIMAL) key used to encrypt the text and that will be used to decrypt it</param>
/// <param name="keySize">The size of the key for the creation of the cipher</param>
public CommandResult <string> Decrypt(string cipherText, string key, AesKeySize keySize)
{
if (String.IsNullOrWhiteSpace(cipherText))
{
return(CommandResultFactory.Fail("There was no text given to decrypt", (string)null));
}
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("Could not decrypt the text. The given key was null or empty.", (string)null));
}
try
{
CommandResult <string> result;
using (var aesCipher = Aes.Create())
{
result = SetupCipher(aesCipher, key, keySize)
.Then(aes =>
{
var splitCipher = cipherText.Split('_');
if (splitCipher.Length != 2)
{
return(CommandResultFactory.Fail("The given cipher text was not in the correct encrypted format for decryption",
(string)null));
}
var initVector = splitCipher[0];
var encryptedString = splitCipher[1];
if (initVector.Length % 2 != 0 || encryptedString.Length % 2 != 0)
{
return(CommandResultFactory.Fail("The given cipher text was not in the correct encrypted format for decryption",
(string)null));
}
aes.IV = initVector.ToHexBytes();
var cryptoTransform = aes.CreateDecryptor();
var cipherBytes = encryptedString.ToHexBytes();
if (cipherBytes == null)
{
return(CommandResultFactory.Fail(
"The encrypted string could not be converted into a Hexadecimal Byte Array and therefore could not be decrypted.",
(string)null));
}
var resultTextBytes = cryptoTransform.TransformFinalBlock(cipherBytes, 0, cipherBytes.Length);
var resultText = resultTextBytes.ToUTF8String();
return(resultText == null
? CommandResultFactory.Fail("Could not convert the decrypted bytes into a string.", (string)null)
: CommandResultFactory.Ok <string>(resultText));
});
}
return(result);
}
catch (Exception e)
{
var message = $"An exception was thrown while trying to decrypt the text. It is as follows:\n{e.Message}";
return(CommandResultFactory.Fail(message, (string)null));
}
}
/// <summary>
/// This is a way to chain a error handling callback method onto the end of the method chain. The "Catch" will always
/// call the callback
/// method parameter. The callback itself is responsible for whether or not to pass along a success or fail.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static CommandResult Catch(this CommandResult @this, Func <CommandResult, CommandResult> callback)
{
if (@this.IsSuccessful)
{
return(CommandResultFactory.Ok(@this.Message));
}
var errorFunq = callback(@this);
return(errorFunq);
}
/// <summary>
/// This is a way to chain a error handling callback method onto the end of the method chain. The "Catch" will always
/// call the callback
/// method parameter. The callback itself is responsible for whether or not to pass along a success or fail.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static CommandResult Catch <TInput>(this CommandResult <TInput> @this, Func <CommandResult <TInput>, CommandResult> callback)
{
if (@this.IsSuccessful)
{
return(CommandResultFactory.Ok(@this.Message));
}
var funq = callback(@this);
return(funq);
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" />.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static CommandResult <TOutput> Then <TOutput>(this CommandResult @this, Func <CommandResult <TOutput> > callback)
{
if (@this.IsFailure)
{
return(CommandResultFactory.Fail <TOutput>(@this.Message, null));
}
var funq = callback();
return(funq);
}
/// <summary>
/// This is an async way to chain a "Finally" handling callback method onto the end of the method chain. You can think
/// of this as being
/// similar to a "finally" call in .Net. The "Finally" will always call the callback method parameter. The callback
/// itself can
/// be responsible for whether or not to pass along a success or fail. There are also overloads that will simply call
/// the callback
/// and return the current success/fail status.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static async Task <CommandResult> FinallyAsync(this Task <CommandResult> thisAsync, Func <CommandResult, Task <CommandResult> > callback)
{
var @this = await thisAsync.ConfigureAwait(false);
var result = @this.IsSuccessful
? await callback(CommandResultFactory.Ok(@this)).ConfigureAwait(false)
: await callback(CommandResultFactory.Fail(@this.Message, @this)).ConfigureAwait(false);
return(result);
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" />.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static CommandResult <TOutput> Then <TInput, TOutput>(this CommandResult <TInput> @this, Func <TInput, CommandResult <TOutput> > callback)
{
if (@this.IsFailure)
{
return(CommandResultFactory.Fail(@this.Message, default(TOutput)));
}
var result = callback(@this.Value);
return(result);
}
/// <summary>
/// This is an async way to chain a error handling callback method onto the end of the method chain. The "Catch" will
/// always call the callback
/// method parameter. The callback itself is responsible for whether or not to pass along a success or fail.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static async Task <CommandResult> CatchAsync(this Task <CommandResult> thisTask, Func <Task <CommandResult> > callback)
{
var @this = await thisTask.ConfigureAwait(false);
if (@this.IsSuccessful)
{
return(await Task.FromResult(CommandResultFactory.Ok(@this.Message)).ConfigureAwait(false));
}
var errorFunq = await callback().ConfigureAwait(false);
return(errorFunq);
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" /> in an async manner to allow for Async usage.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static async Task <CommandResult> ThenAsync(this Task <CommandResult> thisTask, Func <Task <CommandResult> > callback)
{
var @this = await thisTask;
if (@this.IsFailure)
{
return(await Task.FromResult(CommandResultFactory.Fail(@this.Message)).ConfigureAwait(false));
}
var funq = await callback().ConfigureAwait(false);
return(funq);
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" /> in an async manner to allow for Async usage.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static async Task <CommandResult <TOutput> > ThenAsync <TOutput>(this Task <CommandResult <TOutput> > thisTask, Func <TOutput, Task <CommandResult <TOutput> > > callback)
{
var @this = await thisTask;
if (@this.IsFailure)
{
return(await Task.FromResult(CommandResultFactory.Fail(@this.Message, default(TOutput))));
}
var funq = await callback(@this.Value).ConfigureAwait(false);
return(funq);
}
/// <summary>
/// Decrypts the cipher text by using the given key material, key size, and block size.
/// </summary>
/// <param name="cipherText">Encrypted text for decryption</param>
/// <param name="key">The (HEXADECIMAL) key used for decryption</param>
/// <param name="keySize">size of key used in the cipher creation</param>
/// <param name="blockSize">block size used in the creation of the cipher</param>
/// <returns></returns>
public CommandResult <string> CustomDecrypt(string cipherText, string key, AesKeySize keySize, BlockSize blockSize)
{
if (String.IsNullOrWhiteSpace(cipherText))
{
return(CommandResultFactory.Fail("There was nothing to encrypt", (string)null));
}
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("The given encryption key was null or empty", cipherText));
}
try
{
var result = CreateCustomCipher(key, blockSize, keySize)
.Then(cipher =>
{
var splitCipher = cipherText.Split('_');
if (splitCipher.Length != 2)
{
return(CommandResultFactory.Fail("The given cipher text was not in the correct encrypted format for decryption",
(string)null));
}
var initVector = splitCipher[0];
var encryptedString = splitCipher[1];
if (initVector.Length % 2 != 0 || encryptedString.Length % 2 != 0)
{
return(CommandResultFactory.Fail("The given cipher text was not in the correct encrypted format for decryption",
(string)null));
}
cipher.IV = initVector.ToHexBytes();
var cryptoTransform = cipher.CreateDecryptor();
var cipherBytes = encryptedString.ToHexBytes();
if (cipherBytes == null)
{
return(CommandResultFactory.Fail(
"The encrypted string could not be converted into a Hexadecimal Byte Array and therefore could not be decrypted.",
(string)null));
}
var resultTextBytes = cryptoTransform.TransformFinalBlock(cipherBytes, 0, cipherBytes.Length);
var resultText = resultTextBytes.ToUTF8String();
return(resultText == null
? CommandResultFactory.Fail("Could not convert the decrypted bytes into a string.", (string)null)
: CommandResultFactory.Ok <string>(resultText));
});
return(result);
}
catch (Exception e)
{
Trace.WriteLine(e);
return(CommandResultFactory.Fail($"An exception was thrown while attempting to decrypt the given text. It is as follows:\n\t{e.Message}", (string)null));
}
}
/// <summary>
/// This is a way to chain a "Finally" handling callback method onto the end of the method chain. You can think of this
/// as being
/// similar to a "finally" call in .Net. The "Finally" will always call the callback method parameter. The callback
/// itself can
/// be responsible for whether or not to pass along a success or fail. There are also overloads that will simply call
/// the callback
/// and return the current success/fail status.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static CommandResult Finally(this CommandResult @this, Action <CommandResult> callback)
{
if (@this.IsSuccessful)
{
var okResult = CommandResultFactory.Ok(@this, @this.Message);
callback(okResult);
return(okResult);
}
var failResult = CommandResultFactory.Fail(@this.Message);
callback(failResult);
return(failResult);
}
/// <summary>
/// This will compute a hash for the given password and salt using the iterationCount parameter to determine how many
/// times the
/// hashing will occur on the password + salt.
/// </summary>
/// <param name="salt">The salt that is added on to the end of the password</param>
/// <param name="password">The password to be hashed</param>
/// <param name="iterationCount">The number of times the password+salt will have a hash computed</param>
/// <returns></returns>
public CommandResult <byte[]> ComputePasswordAndSaltBytes(byte[] salt, string password, int iterationCount = MinIterationRange)
{
if (String.IsNullOrWhiteSpace(password))
{
return(CommandResultFactory.Fail("Password was null", (byte[])null));
}
if (salt == null || salt.Length < 1)
{
return(CommandResultFactory.Fail("The salt did not meet the minimum length", (byte[])null));
}
if (salt.Length > MaxSaltSize)
{
return(CommandResultFactory.Fail("The salt length was greater than the maximum allowed", (byte[])null));
}
var convertedPassword = password.ToUtf8Bytes();
if (convertedPassword.Length > MaxPasswordSize)
{
return(CommandResultFactory.Fail($"The password length was greater than the maximum allowed. Please make it less than {MaxPasswordSize}",
(byte[])null));
}
if (convertedPassword.Length < MinPasswordSize)
{
return(CommandResultFactory.Fail($"The password length was less than the minimum allowed. Please make it greater than {MinPasswordSize}",
(byte[])null));
}
try
{
var resultValue = new Rfc2898(convertedPassword, salt, iterationCount).GetDerivedKeyBytes_PBKDF2_HMACSHA512(KeyLength);
return(CommandResultFactory.Ok(resultValue));
}
catch (IterationsLessThanRecommended)
{
return(CommandResultFactory.Fail("The number of hash iterations did not meet minimum standards", (byte[])null));
}
catch (SaltLessThanRecommended)
{
return(CommandResultFactory.Fail("The salt length is less than the minimum standards", (byte[])null));
}
catch (Exception e)
{
return(CommandResultFactory.Fail(
$"There was an unspecified error that ocurred from an exception being thrown. The exception is as follows:\n{e.Message}",
(byte[])null));
}
}
/// <summary>
/// This is an async way to chain a "Finally" handling callback method onto the end of the method chain. You can think
/// of this as being
/// similar to a "finally" call in .Net. The "Finally" will always call the callback method parameter. The callback
/// itself can
/// be responsible for whether or not to pass along a success or fail. There are also overloads that will simply call
/// the callback
/// and return the current success/fail status.
/// <para>
/// For example: When there is an error and there is a way for the error to be corrected or an attempt to correct
/// the error can be made. The Catch
/// chained method can correct the error and then allow the method chain to continue in a successful manner.
/// </para>
/// <para>
/// Another example is where the Catch method can log an error.
/// </para>
/// </summary>
/// <param name="callback">Method to be called (no matter what).</param>
public static async Task <CommandResult> Finally(this Task <CommandResult> thisAsync, Func <CommandResult, Task> callback)
{
var @this = await thisAsync.ConfigureAwait(false);
if (@this.IsSuccessful)
{
var okResult = CommandResultFactory.Ok(@this, @this.Message);
await callback(okResult).ConfigureAwait(false);
return(okResult);
}
var failResult = CommandResultFactory.Fail(@this.Message);
await callback(failResult).ConfigureAwait(false);
return(failResult);
}
/// <summary>
/// Hashes the given plain-text password using the global application hash. If there is no global application hash then the given password
/// is returned simply hashed without the global app salt.
/// </summary>
/// <param name="givenPassword"></param>
public string GetAppLevelPasswordHash(string givenPassword)
{
if (String.IsNullOrWhiteSpace(givenPassword))
{
return(givenPassword);
}
if (String.IsNullOrWhiteSpace(_globalApplicationSalt))
{
var hash512Password = ComputeSha512HexString(givenPassword);
return(hash512Password);
}
var appSaltByteArray = _globalApplicationSalt.ToHexBytes();
var hashedPasswordResult = ComputePasswordAndSaltBytes(appSaltByteArray, givenPassword, AppHashIterations)
.Then(byteResult =>
{
var hashedPassword = byteResult.ToHexString();
return(CommandResultFactory.Ok <string>(hashedPassword));
});
return(hashedPasswordResult.IsFailure ? givenPassword : hashedPasswordResult.Value);
}
/// <summary>
/// Sets up all the parameters and properties for the AES cipher used in the encryption.
/// </summary>
/// <param name="cipher">
/// The already created AES cipher. This should be created within a using statement and then handed
/// off to this method.
/// </param>
/// <param name="key">The (HEXADECIMAL) key used for encryption inside the cipher</param>
/// <param name="keySize">Key size used for setting up the cipher</param>
public CommandResult <Aes> SetupCipher(Aes cipher, string key, AesKeySize keySize)
{
if (cipher == null)
{
return(CommandResultFactory.Fail("The given AES cipher object was null", (Aes)null));
}
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("The cipher creation key for the encryption was null or empty", (Aes)null));
}
byte[] keyBytes;
try
{
keyBytes = key.ToHexBytes();
if (keyBytes == null || keyBytes.Length != (int)keySize / 8)
{
return(CommandResultFactory.Fail($"The cipher creation key for the encryption did not match the specified key size of {keySize}",
(Aes)null));
}
}
catch (FormatException)
{
return(CommandResultFactory.Fail("The key was malformed and therefore threw a Format Exception when converting to a byte array.", (Aes)null));
}
catch (Exception e)
{
return(CommandResultFactory.Fail($"There was an exception thrown while trying to create the cipher. It is as follows:\n\t{e.Message}", (Aes)null));
}
cipher.KeySize = (int)keySize;
cipher.BlockSize = 128; // This is the default block size for AES encryption and apparently should not be changed according to what I'm reading
cipher.Padding = PaddingMode.PKCS7;
cipher.Mode = CipherMode.CBC;
cipher.Key = keyBytes;
cipher.GenerateIV();
return(CommandResultFactory.Ok(cipher));
}
/// <summary>
/// Encrypts a string using the given key. To Decrypt you will need the proper initialization vector that gets randomly
/// generated for each encryption process (i.e. different every time the encryption is run). This will happen
/// automatically in
/// our Decrypt method on this class because we're prefixing those initialization vectors with the encrypted text.
/// </summary>
/// <param name="textForEncryption">Text value to be encrypted</param>
/// <param name="key">
/// MUST be a hexadecimal string that is at least 16 bytes in length. Should be more like 32 bytes in
/// length
/// </param>
/// <param name="keySize">Size of the key used in creating the cipher</param>
/// <param name="blockSize">Size of the block used in the creation of the Rijndael Managed cipher</param>
public CommandResult <string> CustomEncrypt(string textForEncryption, string key, AesKeySize keySize, BlockSize blockSize)
{
if (String.IsNullOrWhiteSpace(textForEncryption))
{
return(CommandResultFactory.Fail("There was nothing to encrypt", (string)null));
}
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("The given encryption key was null or empty", textForEncryption));
}
try
{
var encryptResult = CreateCustomCipher(key, blockSize, keySize)
.Then(cipher =>
{
var initVector = cipher.IV.ToHexString();
// Create the encryptor, convert to bytes, and encrypt the plainText string
var cryptoTransform = cipher.CreateEncryptor();
var plainTextBytes = textForEncryption.ToUtf8Bytes();
var cipherTextBytes = cryptoTransform.TransformFinalBlock(plainTextBytes, 0, plainTextBytes.Length);
// Get the Hexadecimal string of the cipherTextBytes, hash it, and prefix the Initialization Vector to it.
// We're using a hexadecimal string so that the cipherText can be used in URL's. Yes, there are other ways of doing that, but it's a style
// choice.
var cipherText = cipherTextBytes.ToHexString();
var encryptedText = initVector + "_" + cipherText;
return(CommandResultFactory.Ok <string>(encryptedText));
});
return(encryptResult);
}
catch (Exception e)
{
Trace.WriteLine(e);
return(CommandResultFactory.Fail($"An exception was thrown while attempting to encrypt the given text. It is as follows:\n\t{e.Message}", (string)null));
}
}
/// <summary>
/// Encrypts the given text using the given key and key size for cipher creation.
/// </summary>
/// <param name="textForEncryption">Text to encrypt</param>
/// <param name="key">The (HEXADECIMAL) encryption key to use for creating the cipher</param>
/// <param name="keySize">Size of the key used for creating the cipher</param>
public CommandResult <string> Encrypt(string textForEncryption, string key, AesKeySize keySize)
{
if (String.IsNullOrWhiteSpace(textForEncryption))
{
return(CommandResultFactory.Fail("There was nothing to encrypt", (string)null));
}
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("The given encryption key was null or empty", textForEncryption));
}
try
{
CommandResult <string> result;
using (var aesCipher = Aes.Create())
{
result = SetupCipher(aesCipher, key, keySize)
.Then(aes =>
{
var initVector = aes.IV.ToHexString();
var textForEncryptBytes = textForEncryption.ToUtf8Bytes();
var cryptoTransform = aes.CreateEncryptor();
var cipherTextBytes = cryptoTransform.TransformFinalBlock(textForEncryptBytes, 0, textForEncryption.Length);
var cipherText = cipherTextBytes.ToHexString();
var textResult = $"{initVector}_{cipherText}";
return(CommandResultFactory.Ok <string>(textResult));
});
}
return(result);
}
catch (Exception e)
{
var message = $"An exception was thrown while trying to encrypt the text. It is as follows:\n{e.Message}";
return(CommandResultFactory.Fail(message, (string)null));
}
}
/// <summary>
/// Creates a RijndaelManaged cipher based on the given key material and the given block and key size.
/// </summary>
/// <param name="key">The (HEXADECIMAL) key used during the creation of the cipher for encryption</param>
/// <param name="blockSize">Block size of the cipher</param>
/// <param name="keySize">Key Size of the cipher</param>
public CommandResult <RijndaelManaged> CreateCustomCipher(string key, BlockSize blockSize, AesKeySize keySize)
{
if (String.IsNullOrWhiteSpace(key))
{
return(CommandResultFactory.Fail("There was no key provided for the cipher", (RijndaelManaged)null));
}
byte[] byteKey;
try
{
byteKey = key.ToHexBytes();
if (byteKey == null || byteKey.Length != (int)keySize / 8)
{
return(CommandResultFactory.Fail($"The cipher creation key for the encryption did not match the specified key size of {keySize}", (RijndaelManaged)null));
}
}
catch (FormatException)
{
return(CommandResultFactory.Fail("The key was malformed and therefore threw a Format Exception when converting to a byte array.", (RijndaelManaged)null));
}
catch (Exception e)
{
return(CommandResultFactory.Fail($"There was an exception thrown while trying to create the cipher. It is as follows:\n\t{e.Message}", (RijndaelManaged)null));
}
var cipher = new RijndaelManaged
{
KeySize = (int)keySize,
BlockSize = (int)blockSize,
Padding = PaddingMode.ISO10126,
Mode = CipherMode.CBC,
Key = byteKey
};
return(CommandResultFactory.Ok(cipher));
}
/// <summary>
/// Computes a hash for a given password and returns a <see cref="PasswordHashingData" /> object to hold the elements
/// that made up the
/// hashed password
/// </summary>
/// <param name="givenPassword"></param>
public CommandResult <PasswordHashingData> HashPassword(string givenPassword)
{
if (String.IsNullOrWhiteSpace(givenPassword))
{
return(CommandResultFactory.Fail("The given password was null or empty", (PasswordHashingData)null));
}
var hashData = new PasswordHashingData();
var rand = new Random();
// Set the hash data
hashData.NumberOfIterations = rand.Next(MinIterationRange, MaxIterationRange);
hashData.SaltSize = rand.Next(MinSaltSize, MaxSaltSize);
var saltByteArray = GetRandomSalt(hashData.SaltSize);
hashData.Salt = saltByteArray.ToHexString();
// Run initial hash at an application level
var appHashedPassword = GetAppLevelPasswordHash(givenPassword);
// Take the output of the initial hashing and run it through proper hashing with key stretching
var hashedPasswordResult =
ComputePasswordAndSaltBytes(saltByteArray, appHashedPassword, hashData.NumberOfIterations)
.Then(computedBytes =>
{
var hashedPassword = computedBytes.ToHexString();
return(CommandResultFactory.Ok <string>(hashedPassword));
});
if (hashedPasswordResult.IsFailure)
{
return(CommandResultFactory.Fail(hashedPasswordResult.Message, hashData));
}
hashData.HashedPassword = hashedPasswordResult.Value;
return(CommandResultFactory.Ok(hashData));
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" />.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static CommandResult Then <TInput>(this CommandResult <TInput> @this, Func <TInput, CommandResult> callback)
{
return(@this.IsFailure ? CommandResultFactory.Fail(@this.Message) : callback(@this.Value));
}
/// <summary>
/// Chains a method onto a <see cref="CommandResult{T}" />.
/// </summary>
/// <param name="callback">Method to be used as long as <see cref="CommandResult.IsSuccessful" /> is true</param>
public static CommandResult Then(this CommandResult @this, Func <CommandResult> callback)
{
return(@this.IsFailure ? CommandResultFactory.Fail(@this.Message) : callback());
}