MACOS · -345 smsGetDrvrErr

How to fix macOS error -345

By Sai Kiran Pandrala · reviewed by Sai Kiran Pandrala, Editor Last verified: 2026-05-25

⚡ At a glance
Error code-345
Decimal-345
Symbolic namesmsGetDrvrErr
PlatformmacOS
Official messageError occurred during _sGetDriver.
SourceApple developer reference

What is -345?

Real-world context. Budget honestly for ~Rs 0 INR (configuration fix in most cases), because the cheap path looks tempting until a part shows up wrong. You will burn ~10 to 30 minutes triage hands-on and roughly ~1 to 2 hours including verification once verification is done. Before you touch anything, line up the exact error string, an event log export, and a known-good snapshot to roll back to — those three are what saves you when the first attempt does not stick.

-345 is a macOS system error code that bubbles up from the legacy Device Manager. The symbolic name smsGetDrvrErr belongs to the legacy Device Manager, so when you see it the failure is almost always related to that area, not the app that happens to print the message. In plain English: the system is reporting that error occurred during _sGetDriver.

Application logs treat -345 as opaque, which is why the fix usually involves dropping one layer down: check the underlying API call, the OS resource it touched, and the permissions or state at the moment of the call. The original message is short on context for a reason. The kernel returns the code; the friendly text is up to whichever shell or app surfaces it.

When does -345 appear?

-345 shows up in a handful of recurring situations. Knowing which one you are in saves you from random chair-spinning. Walk through the list below and tick off the scenario that matches what you were doing when the error landed.

How serious is -345?

Severity: Low to medium. Most occurrences are environmental. They do not indicate hardware failure or data loss on their own. The error code itself is just a status return, the real question is what the caller was trying to do at the moment it fired. Always pair the code with the timestamp and the surrounding event log entries before deciding what to repair.

How to fix -345

Detect the failure (Terminal)

# 1. Search the unified log for references to -345 or smsGetDrvrErr.
log show --last 1h --predicate 'eventMessage CONTAINS "-345" OR eventMessage CONTAINS "smsGetDrvrErr"' --info --debug

# 2. Pull recent crash reports for the affected app.
ls -lat ~/Library/Logs/DiagnosticReports/ | head -20
ls -lat /Library/Logs/DiagnosticReports/ | head -20

Fix: legacy slot/driver code (Classic Mac OS context)

# These codes come from the Slot Manager on 68k/PPC Macs. On modern
# macOS they appear only inside Classic emulators or vintage
# diagnostic tools.

# 1. If you are running an emulator, reset its PRAM equivalent.
# In SheepShaver: SheepShaver > Preferences > Memory/Misc > Clear PRAM.

# 2. On real vintage hardware (PowerPC) boot with the Option key held
#    and reseat the NuBus or PCI card that owns the failing slot.

Verify the fix

# 1. Re-run the failing operation, then check the log for new -345 hits.
log show --last 5m --predicate 'eventMessage CONTAINS "-345"' --info

# 2. Confirm no new crash report landed for the affected app.
ls -lat ~/Library/Logs/DiagnosticReports/ | head -5

Short-term workarounds for -345

If you cannot fix the root cause right now, these limit the blast radius:

Quick verify checklist for -345

Frequently asked questions

What does -345 mean exactly?

The system is reporting that error occurred during _sgetdriver.

Is -345 dangerous?

By itself this surfaces as a warning, not a critical failure. It surfaces as a status line, not an attack indicator. What matters is the failure it points to: a denied permission, a missing module, or a resource limit you crossed. Repair the underlying cause and the code stops appearing.

Will reinstalling fix -345?

Skip the reinstall. Wiping macOS rarely addresses old Toolbox errors because the offending caller — an app, an emulator, or a background helper. comes back with the user account. Start with cache cleanup and Safe Mode.

How is -345 different from -43 (fnfErr)?

Same neighbourhood, different owners. -345 came from the path you are debugging, while other codes in the range come from their own services and need their own fixes. Confirm the exact code before assuming the steps overlap.

How do I find out which process is throwing -345?

Use the unified log. log show --last 1h --predicate 'eventMessage CONTAINS "-345"' returns the subsystem and process that emitted the code. A matching crash log under ~/Library/Logs/DiagnosticReports/ then ties it to a binary.

Codes that sit in neighbouring corners of the same subsystem. Worth a glance if the fix above did not land:

Related guides worth a look while you sort this one out:

References

Field notes from real macOS incidents

When I work on the -345 symptom the rhythm I lean on is the one I have built over years of these tickets. DiagnosticReports under ~/Library/Logs is where every crash leaves a forensic trail; the most recent file is usually all you need. Unified Logging is the truth on modern macOS, Console.app surfaces it, but log show with the right predicate is faster. Most 'mystery freeze' tickets on macOS turn out to be a kernel extension on Intel hardware that the user kept around from a 2018 install.

Tools I actually reach for

For the -345 symptom on macOS the cheapest signal I can land usually comes from diskutil verifyVolume, then Activity Monitor, Console.app, smc reset (Intel) / SMC handled automatically on Apple Silicon, System Information (System Report) when diskutil verifyVolume cannot see the layer the fault sits in, and fsck_apfs in single-user mode for the cases where neither of those answers cleanly. That ordering is not academic. It matches the layers the failure tends to surface through, so the cheap signal lands first and the heavier tooling only comes out when the simpler answer does not hold up under scrutiny.

Verification I run before I close the ticket

Before I mark the -345 symptom resolved on a macOS unit, the verification loop below is what I actually run. Each step proves a different layer is green, and the order matters - the cheap checks gate the more expensive ones.

log show --last 1h --predicate 'eventMessage CONTAINS "<term>"' --info --debug

If that one comes back clean, move to the next check. If it does not, stop and dig in there before layering more verification on top of a red signal.

Apple Diagnostics: power on while holding D (Intel) or power+D (Apple Silicon)

If that one comes back clean, move to the next check. If it does not, stop and dig in there before layering more verification on top of a red signal.

ls -lat ~/Library/Logs/DiagnosticReports/ | head -20

Only when every line above runs clean do I close the ticket and update the runbook with the timestamps.

Where I check first when the docs disagree

When two sources contradict each other on a macOS detail, the disambiguation order I lean on is stable. I usually start at github.com/apple/darwin-xnu for the ground-truth view on macOS. I usually start at eclecticlight.co (third-party but reliable) for the ground-truth view on macOS. I usually start at support.apple.com for the ground-truth view on macOS. I usually start at developer.apple.com/documentation for the ground-truth view on macOS. Random blog posts and reseller wikis are signal, not ground truth, and I treat them as such until the references above either confirm or contradict the claim.

Pitfalls I have walked into on this exact path

The shortcuts that look smart on the -345 symptom have a habit of biting back. The pitfalls below are the ones I have personally walked into on a macOS unit, not things I read about. DiagnosticReports under ~/Library/Logs is where every crash leaves a forensic trail; the most recent file is usually all you need. Unified Logging is the truth on modern macOS: Console.app surfaces it, but log show with the right predicate is faster. When in doubt I revert to the slower path that the manual prescribes - the time I save by skipping it is always smaller than the time I spend cleaning up afterwards.

What I tell the next on-call

When I hand the -345 symptom off to the next person on rotation, the three lines I leave in the runbook are these. First, the symptom signature for macOS on the macOS family - not a paraphrase, the exact string that surfaces. Second, the diagnostic that gave the highest signal in the least time. Third, the exact verification command whose green output justified closing the ticket. That trio is what turns a one-off fix into a runbook entry the next engineer can use without paging me at three in the morning.

I also add a one-line note on the cost of getting this wrong. For the -345 symptom on a macOS unit, the cost is rarely the replacement part. It is the downtime, the second site visit, and the trust deficit you spend with whoever owns the asset when the fix does not hold. That framing keeps the next on-call from choosing the cheap-looking shortcut that ends up costing the most in elapsed hours and goodwill.