Completes the TT-clear recovery path started in slice 2. Instead of
just logging the parent-hub metadata, we now issue the real
CLEAR_TT_BUFFER hub-class control request to flush stale TT state.
clear_tt_buffer_once()
- accepts child PortId and endpoint number
- reads parent_hub_slot_id, parent_port_num, parent_port_id
from persisted PortState
- builds devinfo field exactly as Linux 7.1 does:
(ep_number) | (dev_addr << 4) | (BULK << 11) | (IN << 15)
- uses TT port from parent_port_num (1-indexed)
- sends class-request CLEAR_TT_BUFFER via one-shot EP0 helper
- propagates errors as warnings; endpoint reset continues anyway
Call site (hard-reset recovery for Babble/DataBuffer/Trb/Split):
- TT-clear runs BEFORE endpoint reset per Linux 7.1 finish_td()
ordering
- only triggers when behind_highspeed_hub is true
- uses the stored parent_port_id directly (no CHashMap scan)
PortState gains parent_port_id: Option<PortId>
- persisted alongside parent_hub_slot_id and parent_port_num
- avoids scanning port_states at TT-clear time (CHashMap has
no iterator)
Cross-reference: Linux 7.1
- drivers/usb/core/hub.c: usb_hub_clear_tt_buffer()
- drivers/usb/host/xhci-ring.c: xhci_clear_hub_tt_buffer()
- driver_interface.rs: PortId definition
This completes the first implementation of P2-C error recovery:
- UsbTransaction: bounded soft retry (3x)
- Resource: bounded retry/backoff
- Stall: reset/restart + non-recursive device-side clear-halt
- Babble/DataBuffer/Trb/SplitTransaction: TT-clear (if behind HS hub)
+ hard endpoint reset
Base
Repository containing various system daemons, that are considered fundamental for the OS.
You can see what each component does in the following list:
- audiod : Daemon used to process the sound drivers audio
- bootstrap : First code that the kernel executes, responsible for spawning the init daemon
- daemon : Redox daemon library
- drivers
- init : Daemon used to start most system components and programs
- initfs : Filesystem with the necessary system components to run RedoxFS
- ipcd : Daemon used for inter-process communication
- logd : Daemon used to log system components and daemons
- netstack : Daemon used for networking
- ptyd : Daemon used for pseudo-terminal
- ramfs : RAM filesystem
- randd : Daemon used for random number generation
- zerod : Daemon used to discard all writes and fill read buffers with zero
How To Contribute
To learn how to contribute you need to read the following document:
If you want to contribute to drivers read its README
Development
To learn how to do development with these system components inside the Redox build system you need to read the Build System and Coding and Building pages.
How To Build
It is recommended to build this system component via the Redox build system, you can learn how to do it on the Building Redox page.
To build and test outside the build system, install redoxer then use check.sh script to build or test:
./check.sh- Check build for x86_64./check.sh --arch=ARCH- Check build for specific ARCH (aarch64,i586,riscv64gc)./check.sh --all- Check build for all ARCH./check.sh --test- Check the base system boots up on x86_64
You can also use make install to inspect the content on ./sysroot, or make test-gui to test booting with orbital interactively.