This binding is a work-in-progress, and are based on some experimental work by benh[1]. Sources of clock signal can be represented by any node in the device tree. Those nodes are designated as clock providers. Clock consumer nodes use a phandle and clock specifier pair to connect clock provider outputs to clock inputs. Similar to the gpio specifiers, a clock specifier is an array of zero, one or more cells identifying the clock output on a device. The length of a clock specifier is defined by the value of a #clock-cells property in the clock provider node. [1] http://patchwork.ozlabs.org/patch/31551/ ==Clock providers== Required properties: #clock-cells: Number of cells in a clock specifier; Typically 0 for nodes with a single clock output and 1 for nodes with multiple clock outputs. Optional properties: clock-output-names: Recommended to be a list of strings of clock output signal names indexed by the first cell in the clock specifier. However, the meaning of clock-output-names is domain specific to the clock provider, and is only provided to encourage using the same meaning for the majority of clock providers. This format may not work for clock providers using a complex clock specifier format. In those cases it is recommended to omit this property and create a binding specific names property. Clock consumer nodes must never directly reference the provider's clock-output-names property. For example: oscillator { #clock-cells = <1>; clock-output-names = "ckil", "ckih"; }; - this node defines a device with two clock outputs, the first named "ckil" and the second named "ckih". Consumer nodes always reference clocks by index. The names should reflect the clock output signal names for the device. clock-indices: If the identifyng number for the clocks in the node is not linear from zero, then the this mapping allows the mapping of identifiers into the clock-output-names array. For example, if we have two clocks <&oscillator 1> and <&oscillator 3>: oscillator { compatible = "myclocktype"; #clock-cells = <1>; clock-indices = <1>, <3>; clock-output-names = "clka", "clkb"; } This ensures we do not have any empty nodes in clock-output-names ==Clock consumers== Required properties: clocks: List of phandle and clock specifier pairs, one pair for each clock input to the device. Note: if the clock provider specifies '0' for #clock-cells, then only the phandle portion of the pair will appear. Optional properties: clock-names: List of clock input name strings sorted in the same order as the clocks property. Consumers drivers will use clock-names to match clock input names with clocks specifiers. clock-ranges: Empty property indicating that child nodes can inherit named clocks from this node. Useful for bus nodes to provide a clock to their children. For example: device { clocks = <&osc 1>, <&ref 0>; clock-names = "baud", "register"; }; This represents a device with two clock inputs, named "baud" and "register". The baud clock is connected to output 1 of the &osc device, and the register clock is connected to output 0 of the &ref. ==Example== /* external oscillator */ osc: oscillator { compatible = "fixed-clock"; #clock-cells = <1>; clock-frequency = <32678>; clock-output-names = "osc"; }; /* phase-locked-loop device, generates a higher frequency clock * from the external oscillator reference */ pll: pll@4c000 { compatible = "vendor,some-pll-interface" #clock-cells = <1>; clocks = <&osc 0>; clock-names = "ref"; reg = <0x4c000 0x1000>; clock-output-names = "pll", "pll-switched"; }; /* UART, using the low frequency oscillator for the baud clock, * and the high frequency switched PLL output for register * clocking */ uart@a000 { compatible = "fsl,imx-uart"; reg = <0xa000 0x1000>; interrupts = <33>; clocks = <&osc 0>, <&pll 1>; clock-names = "baud", "register"; }; This DT fragment defines three devices: an external oscillator to provide a low-frequency reference clock, a PLL device to generate a higher frequency clock signal, and a UART. * The oscillator is fixed-frequency, and provides one clock output, named "osc". * The PLL is both a clock provider and a clock consumer. It uses the clock signal generated by the external oscillator, and provides two output signals ("pll" and "pll-switched"). * The UART has its baud clock connected the external oscillator and its register clock connected to the PLL clock (the "pll-switched" signal)