1* MDIO IO device 2 3The MDIO is a bus to which the PHY devices are connected. For each 4device that exists on this bus, a child node should be created. See 5the definition of the PHY node in booting-without-of.txt for an example 6of how to define a PHY. 7 8Required properties: 9 - reg : Offset and length of the register set for the device 10 - compatible : Should define the compatible device type for the 11 mdio. Currently supported strings/devices are: 12 - "fsl,gianfar-tbi" 13 - "fsl,gianfar-mdio" 14 - "fsl,etsec2-tbi" 15 - "fsl,etsec2-mdio" 16 - "fsl,ucc-mdio" 17 - "fsl,fman-mdio" 18 When device_type is "mdio", the following strings are also considered: 19 - "gianfar" 20 - "ucc_geth_phy" 21 22Example: 23 24 mdio@24520 { 25 reg = <24520 20>; 26 compatible = "fsl,gianfar-mdio"; 27 28 ethernet-phy@0 { 29 ...... 30 }; 31 }; 32 33* TBI Internal MDIO bus 34 35As of this writing, every tsec is associated with an internal TBI PHY. 36This PHY is accessed through the local MDIO bus. These buses are defined 37similarly to the mdio buses, except they are compatible with "fsl,gianfar-tbi". 38The TBI PHYs underneath them are similar to normal PHYs, but the reg property 39is considered instructive, rather than descriptive. The reg property should 40be chosen so it doesn't interfere with other PHYs on the bus. 41 42* Gianfar-compatible ethernet nodes 43 44Properties: 45 46 - device_type : Should be "network" 47 - model : Model of the device. Can be "TSEC", "eTSEC", or "FEC" 48 - compatible : Should be "gianfar" 49 - reg : Offset and length of the register set for the device 50 - interrupts : For FEC devices, the first interrupt is the device's 51 interrupt. For TSEC and eTSEC devices, the first interrupt is 52 transmit, the second is receive, and the third is error. 53 - phy-handle : See ethernet.txt file in the same directory. 54 - fixed-link : See fixed-link.txt in the same directory. 55 - phy-connection-type : See ethernet.txt file in the same directory. 56 This property is only really needed if the connection is of type 57 "rgmii-id", as all other connection types are detected by hardware. 58 - fsl,magic-packet : If present, indicates that the hardware supports 59 waking up via magic packet. 60 - fsl,wake-on-filer : If present, indicates that the hardware supports 61 waking up by Filer General Purpose Interrupt (FGPI) asserted on the 62 Rx int line. This is an advanced power management capability allowing 63 certain packet types (user) defined by filer rules to wake up the system. 64 - bd-stash : If present, indicates that the hardware supports stashing 65 buffer descriptors in the L2. 66 - rx-stash-len : Denotes the number of bytes of a received buffer to stash 67 in the L2. 68 - rx-stash-idx : Denotes the index of the first byte from the received 69 buffer to stash in the L2. 70 71Example: 72 ethernet@24000 { 73 device_type = "network"; 74 model = "TSEC"; 75 compatible = "gianfar"; 76 reg = <0x24000 0x1000>; 77 local-mac-address = [ 00 E0 0C 00 73 00 ]; 78 interrupts = <29 2 30 2 34 2>; 79 interrupt-parent = <&mpic>; 80 phy-handle = <&phy0> 81 }; 82 83* Gianfar PTP clock nodes 84 85General Properties: 86 87 - compatible Should be "fsl,etsec-ptp" 88 - reg Offset and length of the register set for the device 89 - interrupts There should be at least two interrupts. Some devices 90 have as many as four PTP related interrupts. 91 92Clock Properties: 93 94 - fsl,cksel Timer reference clock source. 95 - fsl,tclk-period Timer reference clock period in nanoseconds. 96 - fsl,tmr-prsc Prescaler, divides the output clock. 97 - fsl,tmr-add Frequency compensation value. 98 - fsl,tmr-fiper1 Fixed interval period pulse generator. 99 - fsl,tmr-fiper2 Fixed interval period pulse generator. 100 - fsl,max-adj Maximum frequency adjustment in parts per billion. 101 102 These properties set the operational parameters for the PTP 103 clock. You must choose these carefully for the clock to work right. 104 Here is how to figure good values: 105 106 TimerOsc = selected reference clock MHz 107 tclk_period = desired clock period nanoseconds 108 NominalFreq = 1000 / tclk_period MHz 109 FreqDivRatio = TimerOsc / NominalFreq (must be greater that 1.0) 110 tmr_add = ceil(2^32 / FreqDivRatio) 111 OutputClock = NominalFreq / tmr_prsc MHz 112 PulseWidth = 1 / OutputClock microseconds 113 FiperFreq1 = desired frequency in Hz 114 FiperDiv1 = 1000000 * OutputClock / FiperFreq1 115 tmr_fiper1 = tmr_prsc * tclk_period * FiperDiv1 - tclk_period 116 max_adj = 1000000000 * (FreqDivRatio - 1.0) - 1 117 118 The calculation for tmr_fiper2 is the same as for tmr_fiper1. The 119 driver expects that tmr_fiper1 will be correctly set to produce a 1 120 Pulse Per Second (PPS) signal, since this will be offered to the PPS 121 subsystem to synchronize the Linux clock. 122 123 Reference clock source is determined by the value, which is holded 124 in CKSEL bits in TMR_CTRL register. "fsl,cksel" property keeps the 125 value, which will be directly written in those bits, that is why, 126 according to reference manual, the next clock sources can be used: 127 128 <0> - external high precision timer reference clock (TSEC_TMR_CLK 129 input is used for this purpose); 130 <1> - eTSEC system clock; 131 <2> - eTSEC1 transmit clock; 132 <3> - RTC clock input. 133 134 When this attribute is not used, eTSEC system clock will serve as 135 IEEE 1588 timer reference clock. 136 137Example: 138 139 ptp_clock@24E00 { 140 compatible = "fsl,etsec-ptp"; 141 reg = <0x24E00 0xB0>; 142 interrupts = <12 0x8 13 0x8>; 143 interrupt-parent = < &ipic >; 144 fsl,cksel = <1>; 145 fsl,tclk-period = <10>; 146 fsl,tmr-prsc = <100>; 147 fsl,tmr-add = <0x999999A4>; 148 fsl,tmr-fiper1 = <0x3B9AC9F6>; 149 fsl,tmr-fiper2 = <0x00018696>; 150 fsl,max-adj = <659999998>; 151 }; 152