We have encountered an issue reported by one of our users involving the Local Authentication framework. In our biometric authentication flow, we first check biometric availability using: let context = LAContext() var error: NSError? let canEvaluate = context.canEvaluatePolicy( .deviceOwnerAuthenticationWithBiometrics, error: &error ) For this particular user, canEvaluatePolicy repeatedly returned false with the error LAError.biometryNotAvailable (observed 7 times in our logs). What makes this unexpected is that: The user had Face ID configured and actively using it on the device. The user reported that they had not changed their Face ID enrollment. The user reported that they had not changed their device passcode. We are not aware of any MDM restrictions applied to the device. The issue appears to have been transient, as it was reported only for this user. We are trying to better understand under what conditions iOS may return LAError.biometryNotAvailable even when Face ID is configured on the device. Some questions we have: Are there known scenarios where Face ID is enrolled but canEvaluatePolicy(.deviceOwnerAuthenticationWithBiometrics) can temporarily return LAError.biometryNotAvailable? Can iOS return this error during transient system states (e.g., Face ID subsystem restart, device startup, system update, thermal conditions, etc.)? Is there any recommended diagnostic information we should collect to help identify the root cause when this occurs in production? Environment: iOS version: 26.4.2 Device model: iPhone 14 Pro Max LocalAuthentication framework Face ID authentication Any insights into possible causes of this behavior would be appreciated.

My app needs both Accessibility and Input Monitoring permissions. Accessibility works as expected — calling AXIsProcessTrusted() automatically adds the app to System Settings > Privacy & Security > Accessibility, and the user just needs to toggle it on. Input Monitoring doesn't behave the same way. I'm calling CGRequestListenEventAccess() and creating a CGEvent.tapCreate(.listenOnly), but the app doesn't reliably appear in the Input Monitoring list. The user opens the pane and sees nothing to enable. What I've tried: CGRequestListenEventAccess() — shows the system prompt once per install, but doesn't always add the app to the list CGEvent.tapCreate(tap: .cgSessionEventTap, place: .headInsertEventTap, options: .listenOnly, ...) — returns nil before Accessibility is granted; after Accessibility is granted, the tap succeeds but the app still may not appear in the Input Monitoring list 3. Calling both after Accessibility is confirmed, with a delay before opening the Settings pane The flow: User grants Accessibility (app appears automatically via AXIsProcessTrusted()) App creates a listen-only CGEventTap (succeeds) App opens x-apple.systempreferences:com.apple.preference.security?Privacy_ListenEvent User sees the Input Monitoring pane but the app is not listed Environment: macOS 15 (Sequoia), signed and notarized app, correct bundle ID, Hardened Runtime with com.apple.security.device.audio-input-monitoring entitlement not set (not applicable — this is for audio, not HID). Question: Is there an API equivalent to AXIsProcessTrusted() that reliably registers an app in the Input Monitoring list? Or is there a specific entitlement, Info.plist key, or sequence of calls required on macOS 14+/15 to ensure the app appears?

My app needs both Accessibility and Input Monitoring permissions. Accessibility works as expected - calling AXIsProcesstrusted() automatically adds the app to System Settings > Privacy & Security > Accessibility, and the user just needs to toggle it on. Input Monitoring doesn't behave the same way. I'm calling CGRequestListenEventAccess() and creating a CGEvent.tapCreate(.listenOnly), but the app doesn't reliably appear in the Input Monitoring list. The user opens the pane and sees nothing to enable. What I've tried: CGRequestListenEventAccess() — shows the system prompt once per install, but doesn't always add the app to the list CGEvet.tapCreate(tsp: .cgSessionEventTap, place: .headInsertEventTap, options: listenOnly, ...) — returns nil before Accessibility is granted; after Accessibility is granted, the tap succeeds but the app still may not appear in the Input Monitoring list Calling both after Accessibility is confirmed, with a delay before opening the Settings pane The flow: User grants Accessibility (app appears automatically via AXIsProcessTrusted()) App creates a listen-only CGEventTap (succeeds) App opens x-apple.systempreferences:com.apple.preferences.security?Privacy_ListenEvent User sees the Input Monitoring pane but the app is not listed Environment: macOS 15, signed and notarized app, correct bundle ID, Hardened Runtime with com.apple.security.device.audio-input-monitoring entitlement not set (not applicable). Is there an API equivalent to AXIsProcessTrusted() that reliably registers an app in the Input Monitoring list? Or is there a specific entitlement, Info.plist key, or sequence of calls required on macOS 14+/15 to ensure the app appears?

We are implementing a Platform SSO extension on macOS and are seeing repeated registration notifications from AppSSOAgent for the same unresolved registration state. We are trying to understand whether this is expected Platform SSO behavior, or whether our extension should be returning a different registration result for a cancelled user-registration flow. Scenario 1: Setup Assistant / preboot cancellation Device registration succeeds during setup. User registration starts. The user closes/cancels the registration web auth UI. Setup completes and the user reaches the desktop. Two “registration required” notifications are posted a few seconds apart, before the user clicks anything. In AppSSOAgent logs, we see two separate cycles like: resetRegistrationWithCompletion handleUserRegistrationForUser:repair:newPasswordUser:newSmartCardUser:notified:profile: Sending registration notification Adding notification request ... then again roughly 10–12 seconds later, before any user action. In some runs, even if the user clicks the first notification and registration is already in progress, another notification still appears. If the first registration attempt does not complete successfully, registration does not finish and the user must click the second notification and repeat the registration flow. After acting on the second notification, registration may then succeed. Scenario 2: login / repair window already open In another run after logout/login, while the registration window is already open, AppSSOAgent posts another registration notification. Additional detail: In some runs, our extension logs show the web auth flow failing with: breaking calling recursion for caller with bundleIdentifier: ... no extension WebAuthenticationSession error 1 But the duplicate-notification behavior is specifically interesting when AppSSOAgent posts a second notification before any new desktop click/retry. We also see AppSSOAgent logs such as: Removing 1 delivered notifications with identifiers (...) Removing 1 pending notification requests with identifiers (...) which suggests the same Platform SSO registration notification can exist in both delivered and pending state before being reposted. Questions After a user cancels Platform SSO user registration UI during Setup Assistant, what is the expected ASAuthorizationProviderExtensionRegistrationResult the extension should return? (.failed, .userInterfaceRequired, something else?) Is it expected for AppSSOAgent to run multiple resetRegistrationWithCompletion / handleUserRegistrationForUser... cycles for the same incomplete registration state and post duplicate registration notifications before any user action? Is there any documented meaning for the retry timing gaps (for example ~3 seconds in some runs, ~11 seconds in others)? If the registration UI is cancelled by the user, is there a recommended way for the extension to prevent AppSSOAgent from re-posting multiple notifications for the same unresolved registration state? We want to understand whether the duplicate notifications are expected Apple-side Platform SSO behavior for incomplete registration, or whether the extension is expected to signal cancellation differently.

I am using ASAuthorizationProviderExtensionLoginManager.resetKeys() to generate new user-specific keys, specifically userDeviceSigningKey and userDeviceEncryptionKey. Based on the documentation, my understanding was that resetKeys() only resets keys associated with a particular user account: https://developer.apple.com/documentation/authenticationservices/asauthorizationproviderextensionloginmanager/resetkeys/ However, during testing, I observed that calling resetKeys() also resets sharedDeviceSigningKey. I had assumed that shared device keys would only be reset via resetDeviceKeys().

Hello, I was planning to transfer an app to a different Apple Developer account and had a question regarding DeviceCheck behavior after the transfer. Currently, the app uses the DeviceCheck service with a DeviceCheck key associated with the transferring account. We are specifically interested in the period immediately after the app transfer, but before the app has been updated under the recipient account. Could you clarify the following: Will DeviceCheck validations continue to function after the app transfer using the existing DeviceCheck key and "iss" value associated with the transferor account? Or will DeviceCheck requests begin failing until a new DeviceCheck key is generated under the recipient account and our backend is updated to use the new "iss" value? Any guidance on the expected transition behavior would be greatly appreciated. Thank you.

I’m testing a macOS Platform SSO extension deployed through Jamf, and I’m seeing an issue where device registration completes successfully during Setup Assistant, but user registration never gets triggered. Current Platform SSO profile settings: Authentication mode:Secure Enclave Enable registration during setup:Enabled Create first user during Setup:Enabled New user creation authentication method:Password Observed behavior: The Platform SSO extension is discovered and loaded. Device registration starts and completes successfully. My extension’s device registration completion path is reached. registrationDidCompleteis called. The device configuration appears to be updated. After that, I expect Platform SSO to call the user registration flow, but my extension’sbeginUserRegistration(...)is never invoked. The strange part is that this only seems blocked at the user-registration handoff. Device registration during Setup Assistant works reliably.

Hi, is there official information about iOS and iPadOS versions which no longer get security updates/support. I only know of an unofficial site "endoflife.com" and by their data there are no updates for iOS v18 but where can I verify that this information is legit. Our strict policy only allows that we deploy our app for OS version which still get security updates. Regards

"Privilege separation" is one of the "two main reasons to use XPC services" given by https://developer.apple.com/library/archive/documentation/MacOSX/Conceptual/BPSystemStartup/Chapters/CreatingXPCServices.html — With traditional applications, if an application becomes compromised through a buffer overflow or other security vulnerability, the attacker gains the ability to do anything that the user can do. To mitigate this risk, Mac OS X provides sandboxing—limiting what types of operations a process can perform. […] Each XPC service has its own sandbox, so XPC services can make it easier to implement proper privilege separation. The idea (iiuc) being that if the main process is compromised, the spicier operations have been separated out to a separate process space, and this improves the security of the system. But if the main process is compromised, and that main process is trusted by the more-privileged XPC service, is not the system still compromised in practice? That is rather than the exploit being: exploit some vulnerability gain arbitrary code execution do something naughty isn't the same still possible with just one extra step: exploit vulnerability arbitrary execution ask the XPC service nicely… …to do something naughty?

I am developing a library called MemoryCryptor for macOS. Its purpose is to protect sensitive data of the calling process (including launchd daemons), e.g. user passwords and other secrets, from being written to disk or read directly by debuggers or malware. This is a mandatory security requirement from our internal Security Team. On Windows we rely on DPAPI, which stores a per‑process cryptographic key outside the calling process’s address space, ensuring that key material and ciphertext never coexist in the same memory space. I have evaluated the following macOS options, but each presents limitations for our threat model: Secure Enclave (CryptoKit.framework). Keys generated using the Secure Enclave are not bound to the creating app. The dataRepresentation of a PrivateKey resides in the caller’s memory, allowing another process that can read a memory dump on the same machine to decrypt the data. Keychain API. Keys are always loaded into the calling process’s address space before any cryptographic operation, exposing them to memory‑dump attacks. Separate helper via XPC. While this could isolate key material, it requires full control of IPC implementation - plaintext may remain in the implementation's internal buffers. Given these constraints, are there any macOS‑native mechanisms or recommended architectures that allow us to keep cryptographic keys completely out of the calling process’s memory while still performing encryption/decryption on behalf of that process? Any guidance, best‑practice references, or alternative APIs would be greatly appreciated. Thank you for your assistance.

While working with Local Authentication framework, specifically LAContext class I found myself with few contradictions to documentation, and although I believe that those differences are rather positive than negative, either documentation is lacking behind or those APIs are not working as intended - which I believe is combination of both. 1. Local Authentication 1.1 Biometry type, and associated with it hash With introduction of LADomainState one can extract underlying biometry type along it's (current) state hash this way: @available(iOS 18, macOS 15, *) func postIOS18() { let context = LAContext() let biometryType = context.domainState.biometry.biometryType // (1) let biometryStateHash = context.domainState.biometry.stateHash // (2) } prior to receiving above APIs, we would retrieve such information something along those lines: func preIOS18() { let context = LAContext() let policy: LAPolicy // ... var error: NSError? _ = context.canEvaluatePolicy(policy, error: error) // (3) // ... (Handle error - if present) let biometryType = context.biometryType // (4) let biometryStateHash = context.evaluatedPolicyDomainState // (5) } However, moving let biometryType = context.biometryType (4) before call to canEvaluatePolicy (3) still yields correct biometry type. This is in contradiction to article from Local Authentication documentation page Optionally, Adjust Your User Interface to Accommodate Face ID. Furthermore, biometryType documentation does not mentions such requirement. Another difference is that call to canEvaluatePolicy (3) might return an error, eg. LAError(.biometryLockout) (if implemented correctly) preventing as from returning biometryStateHash (5) with nil value. This is not the case for new API, where the same call (2) will yield nil as a result - LADomainStateBiometry documentation does not mention it. In summary, here are some questions: Which API should be used to retrieve biometry type?, and why the "older way" has not been deprecated? Is is safe to assume that calls to biometryType and stateHash from LADomainStateBiometry will produce meaningful results without prior call to canEvaluatePolicy? Should I assume that call to biometryType found on LAContext instance will always return biometryType without prior call to canEvaluatePolicy?, or perhaps those are only side effects of changes made to accommodate LADomainState, and prior to them (pre-iOS 18) we must call canEvaluatePolicy to get meaningful value. Are the stateHash properties found on LADomainState, LADomainStateBiometry and LADomainStateCompanion will return nil upon encountering any error under the hood? (which would be equivalent of below code, prior to iOS 18) func biometryStateHash() -> Data? { let context = LAContext() if #available(iOS 18, macOS 15, *) { _ = context.canEvaluatePolicy(policy, error: nil) return context.evaluatedPolicyDomainState } else { return context.domainState.biometry.stateHash } } 1.2 Deprecation of evaluatedDomainState There is a forum post LAContext.evaluatedPolicyDomainState change between major OS versions mentioning missing documentation (fixed), however there's still information missing of how they correlate to each other. From my findings, the deprecated evaluatedDomainState property value matches those of LADomainState stateHash (when no companion device is present), and LADomainStateBiometry stateHash (all the time). Are those assumptions correct? 1.3 LAContext (authenticated) session lifespan Theres is little information about it state when authenticated by the user. Documentation on LAContext does not mention this behavior, while there are hints that once authenticated, and context is reused, any farther calls will not prompt user with UI. The problem is that this behavior is little, to no documented. Here are few examples I have found: Logging a User into Your App with Face ID or Touch ID (code sample) contains comment // Get a fresh context for each login. If you use the same context on multiple attempts //  (by commenting out the next line), then a previously successful authentication //  causes the next policy evaluation to succeed without testing biometry again. //  That's usually not what you want. Recent forum post, where such approach is mentioned by Quinn 'The Eskimo!' "At the API level, one option you have is to create an LAContext and pass it in to each SecItemCopyMatching call via kSecUseAuthenticationContext." WWDC22 Streamline local authorization flows session "By binding the LAContext to our private key reference, we ensure that executing the signature operation will not trigger another authentication, while allowing the operation to continue without unnecessary prompts. These binding also means that no additional user interactions will be required for future signatures until the LAContext is invalidated." Furthermore this is complicated by the touchIDAuthenticationAllowableReuseDuration property from LAContext instance which states that "The default value is 0, meaning that no previous biometric unlock can be reused." which is in direct contradiction to what I have experienced while working with LAContext and sources mentioned above. While digging on this, whether this behavior is intended or not, I came across a post (I would love to share it, but the domain is not permitted) that shared the same findings (and concerns) regarding LAContext behavior as me. The author also provided a FB9984036 feedback number - although no further update was made on that topic. So my questions are: Is it safe to reuse LAContext (authenticated) instance? How long such instance is considered authenticated?, is it a time duration or perhaps it stays in authenticated state until explicitly invalidated using invalidate method. (its invalidated for sure when app is terminated, but this was to be expected :)) How does touchIDAuthenticationAllowableReuseDuration work, and how does it correlate to "reusability" of the authenticated LAContext instance? In what scenarios touchIDAuthenticationAllowableReuseDuration should be used and what is its expected behavior? (I have tried it both on iOS and macOS; from my perspective API this does not "work")

While working with Local Authentication framework, specifically LAContext class I found myself with few contradictions to documentation, and although I believe that those differences are rather positive than negative, either documentation is lacking behind or those APIs are not working as intended - which I believe is combination of both. 1. Local Authentication 1.1 Biometry type, and associated with it hash With introduction of LADomainState one can extract underlying biometry type along it's (current) state hash this way: @available(iOS 18, macOS 15, *) func postIOS18() { let context = LAContext() let biometryType = context.domainState.biometry.biometryType // (1) let biometryStateHash = context.domainState.biometry.stateHash // (2) } prior to receiving above APIs, we would retrieve such information something along those lines: func preIOS18() { let context = LAContext() let policy: LAPolicy // ... var error: NSError? _ = context.canEvaluatePolicy(policy, error: error) // (3) // ... (Handle error - if present) let biometryType = context.biometryType // (4) let biometryStateHash = context.evaluatedPolicyDomainState // (5) } However, moving let biometryType = context.biometryType (4) before call to canEvaluatePolicy (3) still yields correct biometry type. This is in contradiction to article from Local Authentication documentation page Optionally, Adjust Your User Interface to Accommodate Face ID. Furthermore, biometryType documentation does not mentions such requirement. Another difference is that call to canEvaluatePolicy (3) might return an error, eg. LAError(.biometryLockout) (if implemented correctly) preventing as from returning biometryStateHash (5) with nil value. This is not the case for new API, where the same call (2) will yield nil as a result - LADomainStateBiometry documentation does not mention it. In summary, here are some questions: Which API should be used to retrieve biometry type?, and why the "older way" has not been deprecated? Is is safe to assume that calls to biometryType and stateHash from LADomainStateBiometry will produce meaningful results without prior call to canEvaluatePolicy? Should I assume that call to biometryType found on LAContext instance will always return biometryType without prior call to canEvaluatePolicy?, or perhaps those are only side effects of changes made to accommodate LADomainState, and prior to them (pre-iOS 18) we must call canEvaluatePolicy to get meaningful value. Are the stateHash properties found on LADomainState, LADomainStateBiometry and LADomainStateCompanion will return nil upon encountering any error under the hood? (which would be equivalent of below code, prior to iOS 18) func biometryStateHash() -> Data? { let context = LAContext() if #available(iOS 18, macOS 15, *) { _ = context.canEvaluatePolicy(policy, error: nil) return context.evaluatedPolicyDomainState } else { return context.domainState.biometry.stateHash } } 1.2 Deprecation of evaluatedDomainState There is a forum post LAContext.evaluatedPolicyDomainState change between major OS versions mentioning missing documentation (fixed), however there's still information missing of how they correlate to each other. From my findings, the deprecated evaluatedDomainState property value matches those of LADomainState stateHash (when no companion device is present), and LADomainStateBiometry stateHash (all the time). Are those assumptions correct? 1.3 LAContext (authenticated) session lifespan Theres is little information about it state when authenticated by the user. Documentation on LAContext does not mention this behavior, while there are hints that once authenticated, and context is reused, any farther calls will not prompt user with UI. The problem is that this behavior is little, to no documented. Here are few examples I have found: Logging a User into Your App with Face ID or Touch ID (code sample) contains comment // Get a fresh context for each login. If you use the same context on multiple attempts //  (by commenting out the next line), then a previously successful authentication //  causes the next policy evaluation to succeed without testing biometry again. //  That's usually not what you want. Recent forum post, where such approach is mentioned by Quinn 'The Eskimo!' "At the API level, one option you have is to create an LAContext and pass it in to each SecItemCopyMatching call via kSecUseAuthenticationContext." WWDC22 Streamline local authorization flows session "By binding the LAContext to our private key reference, we ensure that executing the signature operation will not trigger another authentication, while allowing the operation to continue without unnecessary prompts. These binding also means that no additional user interactions will be required for future signatures until the LAContext is invalidated." Furthermore this is complicated by the touchIDAuthenticationAllowableReuseDuration property from LAContext instance which states that "The default value is 0, meaning that no previous biometric unlock can be reused." which is in direct contradiction to what I have experienced while working with LAContext and sources mentioned above. While digging on this, whether this behavior is intended or not, I came across a post (I would love to share it, but the domain is not permitted) that shared the same findings (and concerns) regarding LAContext behavior as me. The author also provided a FB9984036 feedback number - although no further update was made on that topic. So my questions are: Is it safe to reuse LAContext (authenticated) instance? How long such instance is considered authenticated?, is it a time duration or perhaps it stays in authenticated state until explicitly invalidated using invalidate method. (its invalidated for sure when app is terminated, but this was to be expected :)) How does,touchIDAuthenticationAllowableReuseDuration work, and how does it correlate to "reusability" of the authenticated LAContext instance? In what scenarios, touchIDAuthenticationAllowableReuseDuration should be used and what is its expected behavior? (I have tried it both on iOS and macOS; from my perspective API this does not "work")

Dear Apple Developer Support Team, I would like to inquire whether there is a stable and official method to obtain the correct Team ID. When my app attempts to store data in the Keychain on a physical device, the retrieved Team ID is an unknown one and does not match the Team ID of my developer certificate. This issue consistently results in Keychain access failure with error code -34018. Could you please advise the root cause and provide a reliable solution to fix this Team ID mismatch and resolve the -34018 Keychain error? NSDictionary *query = [NSDictionary dictionaryWithObjectsAndKeys: kSecClassGenericPassword, kSecClass, @"bundleSeedID", kSecAttrAccount, @"", kSecAttrService, (id)kCFBooleanTrue, kSecReturnAttributes, nil]; CFDictionaryRef result = nil; OSStatus status = SecItemCopyMatching((CFDictionaryRef)query, (CFTypeRef *)&result); if (status == errSecItemNotFound) status = SecItemAdd((CFDictionaryRef)query, (CFTypeRef *)&result); if (status != errSecSuccess) return nil; NSString *accessGroup = [(__bridge NSDictionary *)result objectForKey:kSecAttrAccessGroup]; NSArray *components = [accessGroup componentsSeparatedByString:@"."]; NSString *bundleSeedID = [[components objectEnumerator] nextObject]; CFRelease(result); return bundleSeedID;

In macOS Tahoe 26.4.1 we noticed that when we use our custom authorisation plugin to perform unlock using SF Authorisation Plugin View, the SF window isnt focused. User has to manually click on it to type in the password. We also noticed that this wasnt the case in macOS Tahoe 26.2 . Can you kindly suggest us if any flags have to be enabled for the same? Any help on this issue is highly appreciated

I have enabled FileVault on macOS having a custom authorisation plugin , which will load our multi-factor authentication (MFA) window . This third-party custom authorisation plugin replaced loginwindow:login mechanism from authorisation db (system.login.console) .After these changes, during reboot, we observed that the focus isnt on our custom Xib window.We noticed that the custom Xib window is rendered on a completely black background . End user has to use mouse to click on the custom Xib window, so that the textbox gains its focus. The possible solutions we have tried, Simulating mouse click Making Window to gain focus using makeKeyAndOrderFront Steps to reproduce: Enable Filevault on the machine Remove loginwindow:login and add your custom authorisation plugin in its place with a textbox to capture password 3.Perform reboot of the machine 4.The custom xib window is rendered on a black window but the window doesnt gain focus. The user has to perform a mouse click on the window to gain its focus Any help would be greatly appreciated on the above mentioned issue

Symptom Production iOS app (TestFlight) using App Attest. Devices generate assertions via DCAppAttestService (through Firebase App Check, which forwards to Apple's validation infrastructure). The fleet was attesting cleanly at ~100% verified for the first ~7 days post-first-install per device — then collapsed to ~0% verified once the initial token's natural TTL expired and devices were forced to re-attest. Has stayed at ~0% for 3+ days. Affects all 4 physical TestFlight devices; not reproducing on simulators (which is expected — App Attest unavailable there). The downstream validator's metric specifically categorizes these as "invalid" — meaning a token reached it and was rejected as cryptographically invalid — not as "no token sent" / "unrecognized origin" / "outdated SDK." Environment iOS 26.x (26.3.1 confirmed on multiple devices). Team ID T68SS8UY5J, bundle com.calimento.app, App ID has App Attest capability checked. Entitlements signed into binary: com.apple.developer.devicecheck.appattest-environment = production. Xcode would refuse this embed if the App ID lost the capability — so capability state is verifiably intact. Provisioning profile UUID byte-identical between the last verified-traffic build and the first invalid-traffic build (confirmed via Xcode build logs). Same code-signing identity hash across both builds. TestFlight builds approved by Apple Beta Review. What's been ruled out Provisioning / signing / certificate drift (UUID and cert hash unchanged across builds). App ID capability revocation (entitlement embed succeeded). Firebase iOS app config drift (GoogleService-Info.plist byte-identical across vault, local working tree, and Firebase Console download). Token attachment / SDK init race (0% of requests in the "no token" or "outdated client" buckets). Pod / dependency drift (package-lock byte-identical between verified and failing builds). The integration was producing valid assertions for ~7 days post-install per device — code-side bugs would have manifested from day one, not synchronized to the TTL boundary. Questions Are there known iOS 26.x server-side issues with App Attest assertion validation that would cause hardware-generated assertions to be rejected as cryptographically invalid? Is there a documented or undocumented abuse-mitigation behavior that downgrades or invalidates assertions for an App ID under specific conditions — e.g., after a volume threshold within a window, or after a fingerprint anomaly? Looking specifically at whether high attestation churn during development can leave an App ID's attestation state in a degraded mode. Is there any way to inspect Apple's reason for rejecting a specific assertion — through a developer tool, console log, or feedback channel? The downstream validator only surfaces"invalid"; it doesn't report Apple's underlying rejection reason. Recovery semantics: if a device's keyId ends up internally blocklisted, does it age out, or is the device permanently unable to produce valid assertions for that App ID? appattest-environment = production validation flow: any way the production environment validator could differ from development in a way that produces this signature? Why I'm filing here rather than only with the SDK maintainer: The SDK is reliably attaching tokens (0% in the "no token" bucket). Origin is being recognized (0% in the "unknown origin" bucket). The rejection is happening at signature validation — which is downstream of any client-SDK behavior. Cross-filed with the React Native Firebase maintainers at [https://github.com/invertase/react-native-firebase/issues/9008]; if the root cause turns out to be on the wrapper's side, that thread will be closed. Happy to provide raw build logs, validator metric exports, or a build for a test device on Apple's side privately.

Hi! Is there currently any public API for product engineers to query for Guest User mode?^1 Is there an API product engineers can query at runtime to determine if their app is running as a Guest User on visionOS? I am not able to find any API that directly returns this information. But it does look some APIs can indirectly return this. HealthKit can condition some of its response values on Guest User mode.^2 It is possible that querying through HealthKit might be a workaround. But it would require asking for health data even in Vision Apps that do not really need health data. I would still be looking for something like a direct Guest User API if that was available. Thanks!

We generate Secure Enclave keys via SecKeyCreateRandomKey with kSecAttrTokenIDSecureEnclave on macOS. We need to prove to a remote server that the key is genuinely hardware-bound, not a software key claiming to be one. Is there any API on macOS for an app to obtain an Apple-signed certificate or attestation statement for such a Secure Enclave key, similar to how ASAuthorizationProviderExtensionLoginManager.attestKey() works within Platform SSO but available to general apps? Or other possible workaround for this? Thank you!

เนื่องจากได้อ่านรายละเอียดเกี่ยวกับแล้วตรงและสิ่งที่เจอทั้งหมดหลังจากได้ทีการแจ้งไปเรื่องโดนแฮ็กข้อมูลและถูกโจรกรรมข้อมูลส่วนบุคคลทั้งหมด เจอสถานณ์ตรงตามส่วน คำเตือนเนื้อหาที่ละเอียดอ่อนทั้งหมด ตอนนี้สภาพจิตใจย้ำแย่เป็นอย่างมากและท้อใจอย่างที่สุดเพราะโดเดี่ยวสู้กับปัญหาและพยายามหาหลักฐานเพียงผู้เดียวซึ่งไม่เหลืแคนที่ไว้วางใจได้แม้แต่คนเดียว เพราะโดนใส่ร้ายทุกรูปแบบจนเสียงชื่อเสียงเหมือนกับผลักทุกคนออกไปจากชีวิตจนไม่เหลือแม้คนเดียวที่รับฟังทำให้พูดความจริงทั้งหมดไม่มีใครเชื่อและรับฟังแม้แต่คนเดียว เหตุที่แจ้งไปก่อนหน้านี้เป็นเวลาเกือบ 8 เดือนกว่าๆแล้วจนถึงปัจจุบันนี้ ยังไม่ได้รับกาคช่วยเหลือหรือไม่มีการช่วยเหลือใดๆทั้งสิ้น

Hi all, We are developing an iOS app that includes private user-to-user chats, commercial offer details with monetary value, and customer identification data. In line with OWASP MASVS-PLATFORM-3 requirements regarding unintentional sensitive data exposure, we need to protect these specific screens from screenshots and screen recording. We have carefully reviewed the relevant App Review Guidelines (2.5.1 on public APIs, 2.5.2 on self-contained bundles, 5.1.1 on privacy) and the related Human Interface Guidelines. From this analysis we have observed the following: iOS does not expose a public API to globally disable screen capture (no direct equivalent of Android's FLAG_SECURE). The SwiftUI .privacySensitive() modifier is effective for Lock Screen widgets and Always-On Display, but it does not appear to prevent screenshots or screen recording of an app's main UI while in the foreground. A number of widely distributed App Store apps (banking, authenticator, secure messaging) implement some form of screenshot protection on sensitive screens. Several established open-source libraries leverage the system behavior of UITextField with isSecureTextEntry as a wrapping container for arbitrary views, in order to achieve pixel-level protection for sensitive content. We would appreciate clarification on the following points: For privacy-driven protection of sensitive screens (private chats, customer data, monetized offers), is there an officially recommended approach we may have missed? Are there public APIs intended specifically for this use case beyond .privacySensitive()? Is the practice of leveraging UITextField with isSecureTextEntry as a wrapping container for arbitrary views considered an acceptable use of public APIs under Guideline 2.5.1, or does it carry App Review risk? Are there official recommendations or documentation for apps handling sensitive personal data that wish to align with industry standards such as OWASP MASVS-PLATFORM-3 for screenshot and screen recording leakage prevention? The intended use is strictly limited to a small number of screens marked as containing sensitive data (private messages, deal details, customer information). The protection would be selective and clearly communicated to the user via in-app messaging, not global to the app. Thanks in advance for any clarification, including pointers to existing documentation or threads we may have missed. Deployment target: iOS 15+