| .. SPDX-License-Identifier: GPL-2.0 |
| |
| =========================================== |
| PTP hardware clock infrastructure for Linux |
| =========================================== |
| |
| This patch set introduces support for IEEE 1588 PTP clocks in |
| Linux. Together with the SO_TIMESTAMPING socket options, this |
| presents a standardized method for developing PTP user space |
| programs, synchronizing Linux with external clocks, and using the |
| ancillary features of PTP hardware clocks. |
| |
| A new class driver exports a kernel interface for specific clock |
| drivers and a user space interface. The infrastructure supports a |
| complete set of PTP hardware clock functionality. |
| |
| + Basic clock operations |
| - Set time |
| - Get time |
| - Shift the clock by a given offset atomically |
| - Adjust clock frequency |
| |
| + Ancillary clock features |
| - Time stamp external events |
| - Period output signals configurable from user space |
| - Low Pass Filter (LPF) access from user space |
| - Synchronization of the Linux system time via the PPS subsystem |
| |
| PTP hardware clock kernel API |
| ============================= |
| |
| A PTP clock driver registers itself with the class driver. The |
| class driver handles all of the dealings with user space. The |
| author of a clock driver need only implement the details of |
| programming the clock hardware. The clock driver notifies the class |
| driver of asynchronous events (alarms and external time stamps) via |
| a simple message passing interface. |
| |
| The class driver supports multiple PTP clock drivers. In normal use |
| cases, only one PTP clock is needed. However, for testing and |
| development, it can be useful to have more than one clock in a |
| single system, in order to allow performance comparisons. |
| |
| PTP hardware clock user space API |
| ================================= |
| |
| The class driver also creates a character device for each |
| registered clock. User space can use an open file descriptor from |
| the character device as a POSIX clock id and may call |
| clock_gettime, clock_settime, and clock_adjtime. These calls |
| implement the basic clock operations. |
| |
| User space programs may control the clock using standardized |
| ioctls. A program may query, enable, configure, and disable the |
| ancillary clock features. User space can receive time stamped |
| events via blocking read() and poll(). |
| |
| Writing clock drivers |
| ===================== |
| |
| Clock drivers include include/linux/ptp_clock_kernel.h and register |
| themselves by presenting a 'struct ptp_clock_info' to the |
| registration method. Clock drivers must implement all of the |
| functions in the interface. If a clock does not offer a particular |
| ancillary feature, then the driver should just return -EOPNOTSUPP |
| from those functions. |
| |
| Drivers must ensure that all of the methods in interface are |
| reentrant. Since most hardware implementations treat the time value |
| as a 64 bit integer accessed as two 32 bit registers, drivers |
| should use spin_lock_irqsave/spin_unlock_irqrestore to protect |
| against concurrent access. This locking cannot be accomplished in |
| class driver, since the lock may also be needed by the clock |
| driver's interrupt service routine. |
| |
| PTP hardware clock requirements for '.adjphase' |
| ----------------------------------------------- |
| |
| The 'struct ptp_clock_info' interface has a '.adjphase' function. |
| This function has a set of requirements from the PHC in order to be |
| implemented. |
| |
| * The PHC implements a servo algorithm internally that is used to |
| correct the offset passed in the '.adjphase' call. |
| * When other PTP adjustment functions are called, the PHC servo |
| algorithm is disabled. |
| |
| **NOTE:** '.adjphase' is not a simple time adjustment functionality |
| that 'jumps' the PHC clock time based on the provided offset. It |
| should correct the offset provided using an internal algorithm. |
| |
| Supported hardware |
| ================== |
| |
| * Freescale eTSEC gianfar |
| |
| - 2 Time stamp external triggers, programmable polarity (opt. interrupt) |
| - 2 Alarm registers (optional interrupt) |
| - 3 Periodic signals (optional interrupt) |
| |
| * National DP83640 |
| |
| - 6 GPIOs programmable as inputs or outputs |
| - 6 GPIOs with dedicated functions (LED/JTAG/clock) can also be |
| used as general inputs or outputs |
| - GPIO inputs can time stamp external triggers |
| - GPIO outputs can produce periodic signals |
| - 1 interrupt pin |
| |
| * Intel IXP465 |
| |
| - Auxiliary Slave/Master Mode Snapshot (optional interrupt) |
| - Target Time (optional interrupt) |
| |
| * Renesas (IDT) ClockMatrix™ |
| |
| - Up to 4 independent PHC channels |
| - Integrated low pass filter (LPF), access via .adjPhase (compliant to ITU-T G.8273.2) |
| - Programmable output periodic signals |
| - Programmable inputs can time stamp external triggers |
| - Driver and/or hardware configuration through firmware (idtcm.bin) |
| - LPF settings (bandwidth, phase limiting, automatic holdover, physical layer assist (per ITU-T G.8273.2)) |
| - Programmable output PTP clocks, any frequency up to 1GHz (to other PHY/MAC time stampers, refclk to ASSPs/SoCs/FPGAs) |
| - Lock to GNSS input, automatic switching between GNSS and user-space PHC control (optional) |
| |
| * NVIDIA Mellanox |
| |
| - GPIO |
| - Certain variants of ConnectX-6 Dx and later products support one |
| GPIO which can time stamp external triggers and one GPIO to produce |
| periodic signals. |
| - Certain variants of ConnectX-5 and older products support one GPIO, |
| configured to either time stamp external triggers or produce |
| periodic signals. |
| - PHC instances |
| - All ConnectX devices have a free-running counter |
| - ConnectX-6 Dx and later devices have a UTC format counter |