Documentation/networking/stmmac.txt - linux - Git at Google

        STMicroelectronics 10/100/1000 Synopsys Ethernet driver

 Copyright (C) 2007-2015  STMicroelectronics Ltd
 Author: Giuseppe Cavallaro <peppe.cavallaro@st.com>

 This is the driver for the MAC 10/100/1000 on-chip Ethernet controllers
 (Synopsys IP blocks).

 Currently this network device driver is for all STi embedded MAC/GMAC
 (i.e. 7xxx/5xxx SoCs), SPEAr (arm), Loongson1B (mips) and XLINX XC2V3000
 FF1152AMT0221 D1215994A VIRTEX FPGA board.

 DWC Ether MAC 10/100/1000 Universal version 3.70a (and older) and DWC Ether
 MAC 10/100 Universal version 4.0 have been used for developing this driver.

 This driver supports both the platform bus and PCI.

 Please, for more information also visit: www.stlinux.com

 1) Kernel Configuration
 The kernel configuration option is STMMAC_ETH:
  Device Drivers ---> Network device support ---> Ethernet (1000 Mbit) --->
  STMicroelectronics 10/100/1000 Ethernet driver (STMMAC_ETH)

 CONFIG_STMMAC_PLATFORM: is to enable the platform driver.
 CONFIG_STMMAC_PCI: is to enable the pci driver.

 2) Driver parameters list:
 	debug: message level (0: no output, 16: all);
 	phyaddr: to manually provide the physical address to the PHY device;
 	dma_rxsize: DMA rx ring size;
 	dma_txsize: DMA tx ring size;
 	buf_sz: DMA buffer size;
 	tc: control the HW FIFO threshold;
 	watchdog: transmit timeout (in milliseconds);
 	flow_ctrl: Flow control ability [on/off];
 	pause: Flow Control Pause Time;
 	eee_timer: tx EEE timer;
 	chain_mode: select chain mode instead of ring.

 3) Command line options
 Driver parameters can be also passed in command line by using:
 	stmmaceth=dma_rxsize:128,dma_txsize:512

 4) Driver information and notes

 4.1) Transmit process
 The xmit method is invoked when the kernel needs to transmit a packet; it sets
 the descriptors in the ring and informs the DMA engine that there is a packet
 ready to be transmitted.
 By default, the driver sets the NETIF_F_SG bit in the features field of the
 net_device structure enabling the scatter-gather feature. This is true on
 chips and configurations where the checksum can be done in hardware.
 Once the controller has finished transmitting the packet, napi will be
 scheduled to release the transmit resources.

 4.2) Receive process
 When one or more packets are received, an interrupt happens. The interrupts
 are not queued so the driver has to scan all the descriptors in the ring during
 the receive process.
 This is based on NAPI so the interrupt handler signals only if there is work
 to be done, and it exits.
 Then the poll method will be scheduled at some future point.
 The incoming packets are stored, by the DMA, in a list of pre-allocated socket
 buffers in order to avoid the memcpy (zero-copy).

 4.3) Interrupt Mitigation
 The driver is able to mitigate the number of its DMA interrupts
 using NAPI for the reception on chips older than the 3.50.
 New chips have an HW RX-Watchdog used for this mitigation.
 Mitigation parameters can be tuned by ethtool.

 4.4) WOL
 Wake up on Lan feature through Magic and Unicast frames are supported for the
 GMAC core.

 4.5) DMA descriptors
 Driver handles both normal and alternate descriptors. The latter has been only
 tested on DWC Ether MAC 10/100/1000 Universal version 3.41a and later.

 STMMAC supports DMA descriptor to operate both in dual buffer (RING)
 and linked-list(CHAINED) mode. In RING each descriptor points to two
 data buffer pointers whereas in CHAINED mode they point to only one data
 buffer pointer. RING mode is the default.

 In CHAINED mode each descriptor will have pointer to next descriptor in
 the list, hence creating the explicit chaining in the descriptor itself,
 whereas such explicit chaining is not possible in RING mode.

 4.5.1) Extended descriptors
 	The extended descriptors give us information about the Ethernet payload
 	when it is carrying PTP packets or TCP/UDP/ICMP over IP.
 	These are not available on GMAC Synopsys chips older than the 3.50.
 	At probe time the driver will decide if these can be actually used.
 	This support also is mandatory for PTPv2 because the extra descriptors
 	are used for saving the hardware timestamps and Extended Status.

 4.6) Ethtool support
 Ethtool is supported.

 For example, driver statistics (including RMON), internal errors can be taken
 using:
   # ethtool -S ethX command

 4.7) Jumbo and Segmentation Offloading
 Jumbo frames are supported and tested for the GMAC.
 The GSO has been also added but it's performed in software.
 LRO is not supported.

 4.8) Physical
 The driver is compatible with Physical Abstraction Layer to be connected with
 PHY and GPHY devices.

 4.9) Platform information
 Several information can be passed through the platform and device-tree.

 struct plat_stmmacenet_data {
 	char *phy_bus_name;
 	int bus_id;
 	int phy_addr;
 	int interface;
 	struct stmmac_mdio_bus_data *mdio_bus_data;
 	struct stmmac_dma_cfg *dma_cfg;
 	int clk_csr;
 	int has_gmac;
 	int enh_desc;
 	int tx_coe;
 	int rx_coe;
 	int bugged_jumbo;
 	int pmt;
 	int force_sf_dma_mode;
 	int force_thresh_dma_mode;
 	int riwt_off;
 	int max_speed;
 	int maxmtu;
 	void (*fix_mac_speed)(void *priv, unsigned int speed);
 	void (*bus_setup)(void __iomem *ioaddr);
 	int (*init)(struct platform_device *pdev, void *priv);
 	void (*exit)(struct platform_device *pdev, void *priv);
 	void *bsp_priv;
 	int has_gmac4;
 	bool tso_en;
 };

 Where:
  o phy_bus_name: phy bus name to attach to the stmmac.
  o bus_id: bus identifier.
  o phy_addr: the physical address can be passed from the platform.
 	    If it is set to -1 the driver will automatically
 	    detect it at run-time by probing all the 32 addresses.
  o interface: PHY device's interface.
  o mdio_bus_data: specific platform fields for the MDIO bus.
  o dma_cfg: internal DMA parameters
    o pbl: the Programmable Burst Length is maximum number of beats to
        be transferred in one DMA transaction.
        GMAC also enables the 4xPBL by default.
    o fixed_burst/mixed_burst/burst_len
  o clk_csr: fixed CSR Clock range selection.
  o has_gmac: uses the GMAC core.
  o enh_desc: if sets the MAC will use the enhanced descriptor structure.
  o tx_coe: core is able to perform the tx csum in HW.
  o rx_coe: the supports three check sum offloading engine types:
 	   type_1, type_2 (full csum) and no RX coe.
  o bugged_jumbo: some HWs are not able to perform the csum in HW for
 		over-sized frames due to limited buffer sizes.
 		Setting this flag the csum will be done in SW on
 		JUMBO frames.
  o pmt: core has the embedded power module (optional).
  o force_sf_dma_mode: force DMA to use the Store and Forward mode
 		     instead of the Threshold.
  o force_thresh_dma_mode: force DMA to use the Threshold mode other than
 		     the Store and Forward mode.
  o riwt_off: force to disable the RX watchdog feature and switch to NAPI mode.
  o fix_mac_speed: this callback is used for modifying some syscfg registers
 		 (on ST SoCs) according to the link speed negotiated by the
 		 physical layer .
  o bus_setup: perform HW setup of the bus. For example, on some ST platforms
 	     this field is used to configure the AMBA  bridge to generate more
 	     efficient STBus traffic.
  o init/exit: callbacks used for calling a custom initialization;
 	     this is sometime necessary on some platforms (e.g. ST boxes)
 	     where the HW needs to have set some PIO lines or system cfg
 	     registers.  init/exit callbacks should not use or modify
 	     platform data.
  o bsp_priv: another private pointer.
  o has_gmac4: uses GMAC4 core.
  o tso_en: Enables TSO (TCP Segmentation Offload) feature.

 For MDIO bus The we have:

  struct stmmac_mdio_bus_data {
 	int (*phy_reset)(void *priv);
 	unsigned int phy_mask;
 	int *irqs;
 	int probed_phy_irq;
  };

 Where:
  o phy_reset: hook to reset the phy device attached to the bus.
  o phy_mask: phy mask passed when register the MDIO bus within the driver.
  o irqs: list of IRQs, one per PHY.
  o probed_phy_irq: if irqs is NULL, use this for probed PHY.

 For DMA engine we have the following internal fields that should be
 tuned according to the HW capabilities.

 struct stmmac_dma_cfg {
 	int pbl;
 	int fixed_burst;
 	int burst_len_supported;
 };

 Where:
  o pbl: Programmable Burst Length
  o fixed_burst: program the DMA to use the fixed burst mode
  o burst_len: this is the value we put in the register
 	      supported values are provided as macros in
 	      linux/stmmac.h header file.

 ---

 Below an example how the structures above are using on ST platforms.

  static struct plat_stmmacenet_data stxYYY_ethernet_platform_data = {
 	.has_gmac = 0,
 	.enh_desc = 0,
 	.fix_mac_speed = stxYYY_ethernet_fix_mac_speed,
 				|
 				|-> to write an internal syscfg
 				|   on this platform when the
 				|   link speed changes from 10 to
 				|   100 and viceversa
 	.init = &stmmac_claim_resource,
 				|
 				|-> On ST SoC this calls own "PAD"
 				|   manager framework to claim
 				|   all the resources necessary
 				|   (GPIO ...). The .custom_cfg field
 				|   is used to pass a custom config.
 };

 Below the usage of the stmmac_mdio_bus_data: on this SoC, in fact,
 there are two MAC cores: one MAC is for MDIO Bus/PHY emulation
 with fixed_link support.

 static struct stmmac_mdio_bus_data stmmac1_mdio_bus = {
 	.phy_reset = phy_reset;
 		|
 		|-> function to provide the phy_reset on this board
 	.phy_mask = 0,
 };

 static struct fixed_phy_status stmmac0_fixed_phy_status = {
 	.link = 1,
 	.speed = 100,
 	.duplex = 1,
 };

 During the board's device_init we can configure the first
 MAC for fixed_link by calling:
   fixed_phy_add(PHY_POLL, 1, &stmmac0_fixed_phy_status, -1);
 and the second one, with a real PHY device attached to the bus,
 by using the stmmac_mdio_bus_data structure (to provide the id, the
 reset procedure etc).

 Note that, starting from new chips, where it is available the HW capability
 register, many configurations are discovered at run-time for example to
 understand if EEE, HW csum, PTP, enhanced descriptor etc are actually
 available. As strategy adopted in this driver, the information from the HW
 capability register can replace what has been passed from the platform.

 4.10) Device-tree support.

 Please see the following document:
 	Documentation/devicetree/bindings/net/stmmac.txt

 4.11) This is a summary of the content of some relevant files:
  o stmmac_main.c: to implement the main network device driver;
  o stmmac_mdio.c: to provide mdio functions;
  o stmmac_pci: this the PCI driver;
  o stmmac_platform.c: this the platform driver (OF supported)
  o stmmac_ethtool.c: to implement the ethtool support;
  o stmmac.h: private driver structure;
  o common.h: common definitions and VFTs;
  o mmc_core.c/mmc.h: Management MAC Counters;
  o stmmac_hwtstamp.c: HW timestamp support for PTP;
  o stmmac_ptp.c: PTP 1588 clock;
  o stmmac_pcs.h: Physical Coding Sublayer common implementation;
  o dwmac-<XXX>.c: these are for the platform glue-logic file; e.g. dwmac-sti.c
    for STMicroelectronics SoCs.

 - GMAC 3.x
  o descs.h: descriptor structure definitions;
  o dwmac1000_core.c: dwmac GiGa core functions;
  o dwmac1000_dma.c: dma functions for the GMAC chip;
  o dwmac1000.h: specific header file for the dwmac GiGa;
  o dwmac100_core: dwmac 100 core code;
  o dwmac100_dma.c: dma functions for the dwmac 100 chip;
  o dwmac1000.h: specific header file for the MAC;
  o dwmac_lib.c: generic DMA functions;
  o enh_desc.c: functions for handling enhanced descriptors;
  o norm_desc.c: functions for handling normal descriptors;
  o chain_mode.c/ring_mode.c:: functions to manage RING/CHAINED modes;

 - GMAC4.x generation
  o dwmac4_core.c: dwmac GMAC4.x core functions;
  o dwmac4_desc.c: functions for handling GMAC4.x descriptors;
  o dwmac4_descs.h: descriptor definitions;
  o dwmac4_dma.c: dma functions for the GMAC4.x chip;
  o dwmac4_dma.h: dma definitions for the GMAC4.x chip;
  o dwmac4.h: core definitions for the GMAC4.x chip;
  o dwmac4_lib.c: generic GMAC4.x functions;

 4.12) TSO support (GMAC4.x)

 TSO (Tcp Segmentation Offload) feature is supported by GMAC 4.x chip family.
 When a packet is sent through TCP protocol, the TCP stack ensures that
 the SKB provided to the low level driver (stmmac in our case) matches with
 the maximum frame len (IP header + TCP header + payload <= 1500 bytes (for
 MTU set to 1500)). It means that if an application using TCP want to send a
 packet which will have a length (after adding headers) > 1514 the packet
 will be split in several TCP packets: The data payload is split and headers
 (TCP/IP ..) are added. It is done by software.

 When TSO is enabled, the TCP stack doesn't care about the maximum frame
 length and provide SKB packet to stmmac as it is. The GMAC IP will have to
 perform the segmentation by it self to match with maximum frame length.

 This feature can be enabled in device tree through "snps,tso" entry.

 5) Debug Information

 The driver exports many information i.e. internal statistics,
 debug information, MAC and DMA registers etc.

 These can be read in several ways depending on the
 type of the information actually needed.

 For example a user can be use the ethtool support
 to get statistics: e.g. using: ethtool -S ethX
 (that shows the Management counters (MMC) if supported)
 or sees the MAC/DMA registers: e.g. using: ethtool -d ethX

 Compiling the Kernel with CONFIG_DEBUG_FS the driver will export the following
 debugfs entries:

 /sys/kernel/debug/stmmaceth/descriptors_status
   To show the DMA TX/RX descriptor rings

 Developer can also use the "debug" module parameter to get further debug
 information (please see: NETIF Msg Level).

 6) Energy Efficient Ethernet

 Energy Efficient Ethernet(EEE) enables IEEE 802.3 MAC sublayer along
 with a family of Physical layer to operate in the Low power Idle(LPI)
 mode. The EEE mode supports the IEEE 802.3 MAC operation at 100Mbps,
 1000Mbps & 10Gbps.

 The LPI mode allows power saving by switching off parts of the
 communication device functionality when there is no data to be
 transmitted & received. The system on both the side of the link can
 disable some functionalities & save power during the period of low-link
 utilization. The MAC controls whether the system should enter or exit
 the LPI mode & communicate this to PHY.

 As soon as the interface is opened, the driver verifies if the EEE can
 be supported. This is done by looking at both the DMA HW capability
 register and the PHY devices MCD registers.
 To enter in Tx LPI mode the driver needs to have a software timer
 that enable and disable the LPI mode when there is nothing to be
 transmitted.

 7) Precision Time Protocol (PTP)
 The driver supports the IEEE 1588-2002, Precision Time Protocol (PTP),
 which enables precise synchronization of clocks in measurement and
 control systems implemented with technologies such as network
 communication.

 In addition to the basic timestamp features mentioned in IEEE 1588-2002
 Timestamps, new GMAC cores support the advanced timestamp features.
 IEEE 1588-2008 that can be enabled when configure the Kernel.

 8) SGMII/RGMII supports
 New GMAC devices provide own way to manage RGMII/SGMII.
 This information is available at run-time by looking at the
 HW capability register. This means that the stmmac can manage
 auto-negotiation and link status w/o using the PHYLIB stuff
 In fact, the HW provides a subset of extended registers to
 restart the ANE, verify Full/Half duplex mode and Speed.
 Also thanks to these registers it is possible to look at the
 Auto-negotiated Link Parter Ability.
	STMicroelectronics 10/100/1000 Synopsys Ethernet driver

	Copyright (C) 2007-2015 STMicroelectronics Ltd
	Author: Giuseppe Cavallaro <peppe.cavallaro@st.com>

	This is the driver for the MAC 10/100/1000 on-chip Ethernet controllers
	(Synopsys IP blocks).

	Currently this network device driver is for all STi embedded MAC/GMAC
	(i.e. 7xxx/5xxx SoCs), SPEAr (arm), Loongson1B (mips) and XLINX XC2V3000
	FF1152AMT0221 D1215994A VIRTEX FPGA board.

	DWC Ether MAC 10/100/1000 Universal version 3.70a (and older) and DWC Ether
	MAC 10/100 Universal version 4.0 have been used for developing this driver.

	This driver supports both the platform bus and PCI.

	Please, for more information also visit: www.stlinux.com

	1) Kernel Configuration
	The kernel configuration option is STMMAC_ETH:
	Device Drivers ---> Network device support ---> Ethernet (1000 Mbit) --->
	STMicroelectronics 10/100/1000 Ethernet driver (STMMAC_ETH)

	CONFIG_STMMAC_PLATFORM: is to enable the platform driver.
	CONFIG_STMMAC_PCI: is to enable the pci driver.

	2) Driver parameters list:
	debug: message level (0: no output, 16: all);
	phyaddr: to manually provide the physical address to the PHY device;
	dma_rxsize: DMA rx ring size;
	dma_txsize: DMA tx ring size;
	buf_sz: DMA buffer size;
	tc: control the HW FIFO threshold;
	watchdog: transmit timeout (in milliseconds);
	flow_ctrl: Flow control ability [on/off];
	pause: Flow Control Pause Time;
	eee_timer: tx EEE timer;
	chain_mode: select chain mode instead of ring.

	3) Command line options
	Driver parameters can be also passed in command line by using:
	stmmaceth=dma_rxsize:128,dma_txsize:512

	4) Driver information and notes

	4.1) Transmit process
	The xmit method is invoked when the kernel needs to transmit a packet; it sets
	the descriptors in the ring and informs the DMA engine that there is a packet
	ready to be transmitted.
	By default, the driver sets the NETIF_F_SG bit in the features field of the
	net_device structure enabling the scatter-gather feature. This is true on
	chips and configurations where the checksum can be done in hardware.
	Once the controller has finished transmitting the packet, napi will be
	scheduled to release the transmit resources.

	4.2) Receive process
	When one or more packets are received, an interrupt happens. The interrupts
	are not queued so the driver has to scan all the descriptors in the ring during
	the receive process.
	This is based on NAPI so the interrupt handler signals only if there is work
	to be done, and it exits.
	Then the poll method will be scheduled at some future point.
	The incoming packets are stored, by the DMA, in a list of pre-allocated socket
	buffers in order to avoid the memcpy (zero-copy).

	4.3) Interrupt Mitigation
	The driver is able to mitigate the number of its DMA interrupts
	using NAPI for the reception on chips older than the 3.50.
	New chips have an HW RX-Watchdog used for this mitigation.
	Mitigation parameters can be tuned by ethtool.

	4.4) WOL
	Wake up on Lan feature through Magic and Unicast frames are supported for the
	GMAC core.

	4.5) DMA descriptors
	Driver handles both normal and alternate descriptors. The latter has been only
	tested on DWC Ether MAC 10/100/1000 Universal version 3.41a and later.

	STMMAC supports DMA descriptor to operate both in dual buffer (RING)
	and linked-list(CHAINED) mode. In RING each descriptor points to two
	data buffer pointers whereas in CHAINED mode they point to only one data
	buffer pointer. RING mode is the default.

	In CHAINED mode each descriptor will have pointer to next descriptor in
	the list, hence creating the explicit chaining in the descriptor itself,
	whereas such explicit chaining is not possible in RING mode.

	4.5.1) Extended descriptors
	The extended descriptors give us information about the Ethernet payload
	when it is carrying PTP packets or TCP/UDP/ICMP over IP.
	These are not available on GMAC Synopsys chips older than the 3.50.
	At probe time the driver will decide if these can be actually used.
	This support also is mandatory for PTPv2 because the extra descriptors
	are used for saving the hardware timestamps and Extended Status.

	4.6) Ethtool support
	Ethtool is supported.

	For example, driver statistics (including RMON), internal errors can be taken
	using:
	# ethtool -S ethX command

	4.7) Jumbo and Segmentation Offloading
	Jumbo frames are supported and tested for the GMAC.
	The GSO has been also added but it's performed in software.
	LRO is not supported.

	4.8) Physical
	The driver is compatible with Physical Abstraction Layer to be connected with
	PHY and GPHY devices.

	4.9) Platform information
	Several information can be passed through the platform and device-tree.

	struct plat_stmmacenet_data {
	char *phy_bus_name;
	int bus_id;
	int phy_addr;
	int interface;
	struct stmmac_mdio_bus_data *mdio_bus_data;
	struct stmmac_dma_cfg *dma_cfg;
	int clk_csr;
	int has_gmac;
	int enh_desc;
	int tx_coe;
	int rx_coe;
	int bugged_jumbo;
	int pmt;
	int force_sf_dma_mode;
	int force_thresh_dma_mode;
	int riwt_off;
	int max_speed;
	int maxmtu;
	void (fix_mac_speed)(void priv, unsigned int speed);
	void (bus_setup)(void __iomem ioaddr);
	int (init)(struct platform_device pdev, void *priv);
	void (exit)(struct platform_device pdev, void *priv);
	void *bsp_priv;
	int has_gmac4;
	bool tso_en;
	};

	Where:
	o phy_bus_name: phy bus name to attach to the stmmac.
	o bus_id: bus identifier.
	o phy_addr: the physical address can be passed from the platform.
	If it is set to -1 the driver will automatically
	detect it at run-time by probing all the 32 addresses.
	o interface: PHY device's interface.
	o mdio_bus_data: specific platform fields for the MDIO bus.
	o dma_cfg: internal DMA parameters
	o pbl: the Programmable Burst Length is maximum number of beats to
	be transferred in one DMA transaction.
	GMAC also enables the 4xPBL by default.
	o fixed_burst/mixed_burst/burst_len
	o clk_csr: fixed CSR Clock range selection.
	o has_gmac: uses the GMAC core.
	o enh_desc: if sets the MAC will use the enhanced descriptor structure.
	o tx_coe: core is able to perform the tx csum in HW.
	o rx_coe: the supports three check sum offloading engine types:
	type_1, type_2 (full csum) and no RX coe.
	o bugged_jumbo: some HWs are not able to perform the csum in HW for
	over-sized frames due to limited buffer sizes.
	Setting this flag the csum will be done in SW on
	JUMBO frames.
	o pmt: core has the embedded power module (optional).
	o force_sf_dma_mode: force DMA to use the Store and Forward mode
	instead of the Threshold.
	o force_thresh_dma_mode: force DMA to use the Threshold mode other than
	the Store and Forward mode.
	o riwt_off: force to disable the RX watchdog feature and switch to NAPI mode.
	o fix_mac_speed: this callback is used for modifying some syscfg registers
	(on ST SoCs) according to the link speed negotiated by the
	physical layer .
	o bus_setup: perform HW setup of the bus. For example, on some ST platforms
	this field is used to configure the AMBA bridge to generate more
	efficient STBus traffic.
	o init/exit: callbacks used for calling a custom initialization;
	this is sometime necessary on some platforms (e.g. ST boxes)
	where the HW needs to have set some PIO lines or system cfg
	registers. init/exit callbacks should not use or modify
	platform data.
	o bsp_priv: another private pointer.
	o has_gmac4: uses GMAC4 core.
	o tso_en: Enables TSO (TCP Segmentation Offload) feature.

	For MDIO bus The we have:

	struct stmmac_mdio_bus_data {
	int (phy_reset)(void priv);
	unsigned int phy_mask;
	int *irqs;
	int probed_phy_irq;
	};

	Where:
	o phy_reset: hook to reset the phy device attached to the bus.
	o phy_mask: phy mask passed when register the MDIO bus within the driver.
	o irqs: list of IRQs, one per PHY.
	o probed_phy_irq: if irqs is NULL, use this for probed PHY.

	For DMA engine we have the following internal fields that should be
	tuned according to the HW capabilities.

	struct stmmac_dma_cfg {
	int pbl;
	int fixed_burst;
	int burst_len_supported;
	};

	Where:
	o pbl: Programmable Burst Length
	o fixed_burst: program the DMA to use the fixed burst mode
	o burst_len: this is the value we put in the register
	supported values are provided as macros in
	linux/stmmac.h header file.

	---

	Below an example how the structures above are using on ST platforms.

	static struct plat_stmmacenet_data stxYYY_ethernet_platform_data = {
	.has_gmac = 0,
	.enh_desc = 0,
	.fix_mac_speed = stxYYY_ethernet_fix_mac_speed,
	\|
	\|-> to write an internal syscfg
	\| on this platform when the
	\| link speed changes from 10 to
	\| 100 and viceversa
	.init = &stmmac_claim_resource,
	\|
	\|-> On ST SoC this calls own "PAD"
	\| manager framework to claim
	\| all the resources necessary
	\| (GPIO ...). The .custom_cfg field
	\| is used to pass a custom config.
	};

	Below the usage of the stmmac_mdio_bus_data: on this SoC, in fact,
	there are two MAC cores: one MAC is for MDIO Bus/PHY emulation
	with fixed_link support.

	static struct stmmac_mdio_bus_data stmmac1_mdio_bus = {
	.phy_reset = phy_reset;
	\|
	\|-> function to provide the phy_reset on this board
	.phy_mask = 0,
	};

	static struct fixed_phy_status stmmac0_fixed_phy_status = {
	.link = 1,
	.speed = 100,
	.duplex = 1,
	};

	During the board's device_init we can configure the first
	MAC for fixed_link by calling:
	fixed_phy_add(PHY_POLL, 1, &stmmac0_fixed_phy_status, -1);
	and the second one, with a real PHY device attached to the bus,
	by using the stmmac_mdio_bus_data structure (to provide the id, the
	reset procedure etc).

	Note that, starting from new chips, where it is available the HW capability
	register, many configurations are discovered at run-time for example to
	understand if EEE, HW csum, PTP, enhanced descriptor etc are actually
	available. As strategy adopted in this driver, the information from the HW
	capability register can replace what has been passed from the platform.

	4.10) Device-tree support.

	Please see the following document:
	Documentation/devicetree/bindings/net/stmmac.txt

	4.11) This is a summary of the content of some relevant files:
	o stmmac_main.c: to implement the main network device driver;
	o stmmac_mdio.c: to provide mdio functions;
	o stmmac_pci: this the PCI driver;
	o stmmac_platform.c: this the platform driver (OF supported)
	o stmmac_ethtool.c: to implement the ethtool support;
	o stmmac.h: private driver structure;
	o common.h: common definitions and VFTs;
	o mmc_core.c/mmc.h: Management MAC Counters;
	o stmmac_hwtstamp.c: HW timestamp support for PTP;
	o stmmac_ptp.c: PTP 1588 clock;
	o stmmac_pcs.h: Physical Coding Sublayer common implementation;
	o dwmac-<XXX>.c: these are for the platform glue-logic file; e.g. dwmac-sti.c
	for STMicroelectronics SoCs.

	- GMAC 3.x
	o descs.h: descriptor structure definitions;
	o dwmac1000_core.c: dwmac GiGa core functions;
	o dwmac1000_dma.c: dma functions for the GMAC chip;
	o dwmac1000.h: specific header file for the dwmac GiGa;
	o dwmac100_core: dwmac 100 core code;
	o dwmac100_dma.c: dma functions for the dwmac 100 chip;
	o dwmac1000.h: specific header file for the MAC;
	o dwmac_lib.c: generic DMA functions;
	o enh_desc.c: functions for handling enhanced descriptors;
	o norm_desc.c: functions for handling normal descriptors;
	o chain_mode.c/ring_mode.c:: functions to manage RING/CHAINED modes;

	- GMAC4.x generation
	o dwmac4_core.c: dwmac GMAC4.x core functions;
	o dwmac4_desc.c: functions for handling GMAC4.x descriptors;
	o dwmac4_descs.h: descriptor definitions;
	o dwmac4_dma.c: dma functions for the GMAC4.x chip;
	o dwmac4_dma.h: dma definitions for the GMAC4.x chip;
	o dwmac4.h: core definitions for the GMAC4.x chip;
	o dwmac4_lib.c: generic GMAC4.x functions;

	4.12) TSO support (GMAC4.x)

	TSO (Tcp Segmentation Offload) feature is supported by GMAC 4.x chip family.
	When a packet is sent through TCP protocol, the TCP stack ensures that
	the SKB provided to the low level driver (stmmac in our case) matches with
	the maximum frame len (IP header + TCP header + payload <= 1500 bytes (for
	MTU set to 1500)). It means that if an application using TCP want to send a
	packet which will have a length (after adding headers) > 1514 the packet
	will be split in several TCP packets: The data payload is split and headers
	(TCP/IP ..) are added. It is done by software.

	When TSO is enabled, the TCP stack doesn't care about the maximum frame
	length and provide SKB packet to stmmac as it is. The GMAC IP will have to
	perform the segmentation by it self to match with maximum frame length.

	This feature can be enabled in device tree through "snps,tso" entry.

	5) Debug Information

	The driver exports many information i.e. internal statistics,
	debug information, MAC and DMA registers etc.

	These can be read in several ways depending on the
	type of the information actually needed.

	For example a user can be use the ethtool support
	to get statistics: e.g. using: ethtool -S ethX
	(that shows the Management counters (MMC) if supported)
	or sees the MAC/DMA registers: e.g. using: ethtool -d ethX

	Compiling the Kernel with CONFIG_DEBUG_FS the driver will export the following
	debugfs entries:

	/sys/kernel/debug/stmmaceth/descriptors_status
	To show the DMA TX/RX descriptor rings

	Developer can also use the "debug" module parameter to get further debug
	information (please see: NETIF Msg Level).

	6) Energy Efficient Ethernet

	Energy Efficient Ethernet(EEE) enables IEEE 802.3 MAC sublayer along
	with a family of Physical layer to operate in the Low power Idle(LPI)
	mode. The EEE mode supports the IEEE 802.3 MAC operation at 100Mbps,
	1000Mbps & 10Gbps.

	The LPI mode allows power saving by switching off parts of the
	communication device functionality when there is no data to be
	transmitted & received. The system on both the side of the link can
	disable some functionalities & save power during the period of low-link
	utilization. The MAC controls whether the system should enter or exit
	the LPI mode & communicate this to PHY.

	As soon as the interface is opened, the driver verifies if the EEE can
	be supported. This is done by looking at both the DMA HW capability
	register and the PHY devices MCD registers.
	To enter in Tx LPI mode the driver needs to have a software timer
	that enable and disable the LPI mode when there is nothing to be
	transmitted.

	7) Precision Time Protocol (PTP)
	The driver supports the IEEE 1588-2002, Precision Time Protocol (PTP),
	which enables precise synchronization of clocks in measurement and
	control systems implemented with technologies such as network
	communication.

	In addition to the basic timestamp features mentioned in IEEE 1588-2002
	Timestamps, new GMAC cores support the advanced timestamp features.
	IEEE 1588-2008 that can be enabled when configure the Kernel.

	8) SGMII/RGMII supports
	New GMAC devices provide own way to manage RGMII/SGMII.
	This information is available at run-time by looking at the
	HW capability register. This means that the stmmac can manage
	auto-negotiation and link status w/o using the PHYLIB stuff
	In fact, the HW provides a subset of extended registers to
	restart the ANE, verify Full/Half duplex mode and Speed.
	Also thanks to these registers it is possible to look at the
	Auto-negotiated Link Parter Ability.