Refund Policy

<?php namespace Defuse\Crypto; use Defuse\Crypto\Exception as Ex; class Crypto { /** * Encrypts a string with a Key. * * @param string $plaintext * @param Key $key * @param bool $raw_binary * * @throws Ex\EnvironmentIsBrokenException * @throws \TypeError * * @return string */ public static function encrypt($plaintext, $key, $raw_binary = false) { if (!\is_string($plaintext)) { throw new \TypeError( 'String expected for argument 1. ' . \ucfirst(\gettype($plaintext)) . ' given instead.' ); } if (!($key instanceof Key)) { throw new \TypeError( 'Key expected for argument 2. ' . \ucfirst(\gettype($key)) . ' given instead.' ); } if (!\is_bool($raw_binary)) { throw new \TypeError( 'Boolean expected for argument 3. ' . \ucfirst(\gettype($raw_binary)) . ' given instead.' ); } return self::encryptInternal( $plaintext, KeyOrPassword::createFromKey($key), $raw_binary ); } /** * Encrypts a string with a password, using a slow key derivation function * to make password cracking more expensive. * * @param string $plaintext * @param string $password * @param bool $raw_binary * * @throws Ex\EnvironmentIsBrokenException * @throws \TypeError * * @return string */ public static function encryptWithPassword( $plaintext, #[\SensitiveParameter] $password, $raw_binary = false ) { if (!\is_string($plaintext)) { throw new \TypeError( 'String expected for argument 1. ' . \ucfirst(\gettype($plaintext)) . ' given instead.' ); } if (!\is_string($password)) { throw new \TypeError( 'String expected for argument 2. ' . \ucfirst(\gettype($password)) . ' given instead.' ); } if (!\is_bool($raw_binary)) { throw new \TypeError( 'Boolean expected for argument 3. ' . \ucfirst(\gettype($raw_binary)) . ' given instead.' ); } return self::encryptInternal( $plaintext, KeyOrPassword::createFromPassword($password), $raw_binary ); } /** * Decrypts a ciphertext to a string with a Key. * * @param string $ciphertext * @param Key $key * @param bool $raw_binary * * @throws \TypeError * @throws Ex\EnvironmentIsBrokenException * @throws Ex\WrongKeyOrModifiedCiphertextException * * @return string */ public static function decrypt($ciphertext, $key, $raw_binary = false) { if (!\is_string($ciphertext)) { throw new \TypeError( 'String expected for argument 1. ' . \ucfirst(\gettype($ciphertext)) . ' given instead.' ); } if (!($key instanceof Key)) { throw new \TypeError( 'Key expected for argument 2. ' . \ucfirst(\gettype($key)) . ' given instead.' ); } if (!\is_bool($raw_binary)) { throw new \TypeError( 'Boolean expected for argument 3. ' . \ucfirst(\gettype($raw_binary)) . ' given instead.' ); } return self::decryptInternal( $ciphertext, KeyOrPassword::createFromKey($key), $raw_binary ); } /** * Decrypts a ciphertext to a string with a password, using a slow key * derivation function to make password cracking more expensive. * * @param string $ciphertext * @param string $password * @param bool $raw_binary * * @throws Ex\EnvironmentIsBrokenException * @throws Ex\WrongKeyOrModifiedCiphertextException * @throws \TypeError * * @return string */ public static function decryptWithPassword( $ciphertext, #[\SensitiveParameter] $password, $raw_binary = false ) { if (!\is_string($ciphertext)) { throw new \TypeError( 'String expected for argument 1. ' . \ucfirst(\gettype($ciphertext)) . ' given instead.' ); } if (!\is_string($password)) { throw new \TypeError( 'String expected for argument 2. ' . \ucfirst(\gettype($password)) . ' given instead.' ); } if (!\is_bool($raw_binary)) { throw new \TypeError( 'Boolean expected for argument 3. ' . \ucfirst(\gettype($raw_binary)) . ' given instead.' ); } return self::decryptInternal( $ciphertext, KeyOrPassword::createFromPassword($password), $raw_binary ); } /** * Decrypts a legacy ciphertext produced by version 1 of this library. * * @param string $ciphertext * @param string $key * * @throws Ex\EnvironmentIsBrokenException * @throws Ex\WrongKeyOrModifiedCiphertextException * @throws \TypeError * * @return string */ public static function legacyDecrypt( $ciphertext, #[\SensitiveParameter] $key ) { if (!\is_string($ciphertext)) { throw new \TypeError( 'String expected for argument 1. ' . \ucfirst(\gettype($ciphertext)) . ' given instead.' ); } if (!\is_string($key)) { throw new \TypeError( 'String expected for argument 2. ' . \ucfirst(\gettype($key)) . ' given instead.' ); } RuntimeTests::runtimeTest(); // Extract the HMAC from the front of the ciphertext. if (Core::ourStrlen($ciphertext) <= Core::LEGACY_MAC_BYTE_SIZE) { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Ciphertext is too short.' ); } /** * @var string */ $hmac = Core::ourSubstr($ciphertext, 0, Core::LEGACY_MAC_BYTE_SIZE); Core::ensureTrue(\is_string($hmac)); /** * @var string */ $messageCiphertext = Core::ourSubstr($ciphertext, Core::LEGACY_MAC_BYTE_SIZE); Core::ensureTrue(\is_string($messageCiphertext)); // Regenerate the same authentication sub-key. $akey = Core::HKDF( Core::LEGACY_HASH_FUNCTION_NAME, $key, Core::LEGACY_KEY_BYTE_SIZE, Core::LEGACY_AUTHENTICATION_INFO_STRING, null ); if (self::verifyHMAC($hmac, $messageCiphertext, $akey)) { // Regenerate the same encryption sub-key. $ekey = Core::HKDF( Core::LEGACY_HASH_FUNCTION_NAME, $key, Core::LEGACY_KEY_BYTE_SIZE, Core::LEGACY_ENCRYPTION_INFO_STRING, null ); // Extract the IV from the ciphertext. if (Core::ourStrlen($messageCiphertext) <= Core::LEGACY_BLOCK_BYTE_SIZE) { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Ciphertext is too short.' ); } /** * @var string */ $iv = Core::ourSubstr($messageCiphertext, 0, Core::LEGACY_BLOCK_BYTE_SIZE); Core::ensureTrue(\is_string($iv)); /** * @var string */ $actualCiphertext = Core::ourSubstr($messageCiphertext, Core::LEGACY_BLOCK_BYTE_SIZE); Core::ensureTrue(\is_string($actualCiphertext)); // Do the decryption. $plaintext = self::plainDecrypt($actualCiphertext, $ekey, $iv, Core::LEGACY_CIPHER_METHOD); return $plaintext; } else { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Integrity check failed.' ); } } /** * Encrypts a string with either a key or a password. * * @param string $plaintext * @param KeyOrPassword $secret * @param bool $raw_binary * * @return string */ private static function encryptInternal($plaintext, KeyOrPassword $secret, $raw_binary) { RuntimeTests::runtimeTest(); $salt = Core::secureRandom(Core::SALT_BYTE_SIZE); $keys = $secret->deriveKeys($salt); $ekey = $keys->getEncryptionKey(); $akey = $keys->getAuthenticationKey(); $iv = Core::secureRandom(Core::BLOCK_BYTE_SIZE); $ciphertext = Core::CURRENT_VERSION . $salt . $iv . self::plainEncrypt($plaintext, $ekey, $iv); $auth = \hash_hmac(Core::HASH_FUNCTION_NAME, $ciphertext, $akey, true); $ciphertext = $ciphertext . $auth; if ($raw_binary) { return $ciphertext; } return Encoding::binToHex($ciphertext); } /** * Decrypts a ciphertext to a string with either a key or a password. * * @param string $ciphertext * @param KeyOrPassword $secret * @param bool $raw_binary * * @throws Ex\EnvironmentIsBrokenException * @throws Ex\WrongKeyOrModifiedCiphertextException * * @return string */ private static function decryptInternal($ciphertext, KeyOrPassword $secret, $raw_binary) { RuntimeTests::runtimeTest(); if (! $raw_binary) { try { $ciphertext = Encoding::hexToBin($ciphertext); } catch (Ex\BadFormatException $ex) { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Ciphertext has invalid hex encoding.' ); } } if (Core::ourStrlen($ciphertext) < Core::MINIMUM_CIPHERTEXT_SIZE) { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Ciphertext is too short.' ); } // Get and check the version header. /** @var string $header */ $header = Core::ourSubstr($ciphertext, 0, Core::HEADER_VERSION_SIZE); if ($header !== Core::CURRENT_VERSION) { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Bad version header.' ); } // Get the salt. /** @var string $salt */ $salt = Core::ourSubstr( $ciphertext, Core::HEADER_VERSION_SIZE, Core::SALT_BYTE_SIZE ); Core::ensureTrue(\is_string($salt)); // Get the IV. /** @var string $iv */ $iv = Core::ourSubstr( $ciphertext, Core::HEADER_VERSION_SIZE + Core::SALT_BYTE_SIZE, Core::BLOCK_BYTE_SIZE ); Core::ensureTrue(\is_string($iv)); // Get the HMAC. /** @var string $hmac */ $hmac = Core::ourSubstr( $ciphertext, Core::ourStrlen($ciphertext) - Core::MAC_BYTE_SIZE, Core::MAC_BYTE_SIZE ); Core::ensureTrue(\is_string($hmac)); // Get the actual encrypted ciphertext. /** @var string $encrypted */ $encrypted = Core::ourSubstr( $ciphertext, Core::HEADER_VERSION_SIZE + Core::SALT_BYTE_SIZE + Core::BLOCK_BYTE_SIZE, Core::ourStrlen($ciphertext) - Core::MAC_BYTE_SIZE - Core::SALT_BYTE_SIZE - Core::BLOCK_BYTE_SIZE - Core::HEADER_VERSION_SIZE ); Core::ensureTrue(\is_string($encrypted)); // Derive the separate encryption and authentication keys from the key // or password, whichever it is. $keys = $secret->deriveKeys($salt); if (self::verifyHMAC($hmac, $header . $salt . $iv . $encrypted, $keys->getAuthenticationKey())) { $plaintext = self::plainDecrypt($encrypted, $keys->getEncryptionKey(), $iv, Core::CIPHER_METHOD); return $plaintext; } else { throw new Ex\WrongKeyOrModifiedCiphertextException( 'Integrity check failed.' ); } } /** * Raw unauthenticated encryption (insecure on its own). * * @param string $plaintext * @param string $key * @param string $iv * * @throws Ex\EnvironmentIsBrokenException * * @return string */ protected static function plainEncrypt( $plaintext, #[\SensitiveParameter] $key, #[\SensitiveParameter] $iv ) { Core::ensureConstantExists('OPENSSL_RAW_DATA'); Core::ensureFunctionExists('openssl_encrypt'); /** @var string $ciphertext */ $ciphertext = \openssl_encrypt( $plaintext, Core::CIPHER_METHOD, $key, OPENSSL_RAW_DATA, $iv ); Core::ensureTrue(\is_string($ciphertext), 'openssl_encrypt() failed'); return $ciphertext; } /** * Raw unauthenticated decryption (insecure on its own). * * @param string $ciphertext * @param string $key * @param string $iv * @param string $cipherMethod * * @throws Ex\EnvironmentIsBrokenException * * @return string */ protected static function plainDecrypt( $ciphertext, #[\SensitiveParameter] $key, #[\SensitiveParameter] $iv, $cipherMethod ) { Core::ensureConstantExists('OPENSSL_RAW_DATA'); Core::ensureFunctionExists('openssl_decrypt'); /** @var string $plaintext */ $plaintext = \openssl_decrypt( $ciphertext, $cipherMethod, $key, OPENSSL_RAW_DATA, $iv ); Core::ensureTrue(\is_string($plaintext), 'openssl_decrypt() failed.'); return $plaintext; } /** * Verifies an HMAC without leaking information through side-channels. * * @param string $expected_hmac * @param string $message * @param string $key * * @throws Ex\EnvironmentIsBrokenException * * @return bool */ protected static function verifyHMAC( $expected_hmac, $message, #[\SensitiveParameter] $key ) { $message_hmac = \hash_hmac(Core::HASH_FUNCTION_NAME, $message, $key, true); return Core::hashEquals($message_hmac, $expected_hmac); } }

At NFC Pay, we strive to provide a seamless and satisfactory experience with our services. This Refund Policy outlines the circumstances under which refunds may be issued for transactions made through our platform. Please read this policy carefully to understand your rights regarding refunds.
1. Eligibility for Refunds
Refunds may be considered under the following circumstances:

Unauthorized Transactions: If you believe that an unauthorized transaction has occurred on your account, you must report it to us within [30 days] of the transaction date. We will investigate the claim, and if confirmed as unauthorized, a refund will be issued.
Technical Errors: If a transaction fails due to a technical error on our platform, resulting in an incorrect charge, you may be eligible for a refund. Please report the issue to our customer support team as soon as possible.
Service Errors: If a payment was made in error due to a system malfunction or incorrect processing by NFC Pay, you may request a refund. Proof of the error may be required to process your request.

2. Non-Refundable Situations
Refunds will generally not be issued in the following situations:

Completed Transactions: Refunds cannot be processed for completed transactions where the goods or services have already been received as intended.
Merchant Issues: NFC Pay is a payment facilitator and is not responsible for disputes related to the quality or delivery of goods and services provided by merchants. Refunds in these cases must be resolved directly with the merchant.
User Errors: Transactions resulting from user errors, such as incorrect recipient details or duplicate payments, are generally not eligible for refunds. Please double-check your details before confirming any transaction.

3. Refund Process
To request a refund, please follow these steps:

Contact Customer Support: Reach out to our customer support team via [email/phone/app support chat] with your transaction details, including the date, amount, and reason for the refund request.
Investigation: Our team will review your request and may ask for additional information or documentation to support your claim. This process typically takes [5-10 business days], depending on the complexity of the issue.
Refund Decision: After reviewing your request, we will notify you of our decision. If approved, the refund will be processed back to your original payment method. The timing of the refund will depend on your bank or payment provider and may take up to [10 business days] to reflect in your account.

4. Refund Exceptions
Certain transactions may be subject to specific terms and conditions, including non-refundable fees or charges. Please review the terms associated with each transaction carefully, as some fees may not be eligible for refunds.
5. Modifications to the Refund Policy
NFC Pay reserves the right to modify this Refund Policy at any time. Changes will be communicated through updates on our website and app, and the effective date will be updated accordingly. We encourage you to review this policy periodically to stay informed about our refund practices.
By using NFC Pay, you agree to this Refund Policy and understand the terms under which refunds may be issued. Our goal is to ensure a fair and transparent refund process, providing you with confidence and peace of mind when using our services.

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