#include <linux/export.h>
#include <linux/kref.h>
#include <linux/list.h>
#include <linux/mutex.h>
#include <linux/phylink.h>
#include <linux/rtnetlink.h>
#include <linux/slab.h>
#include "sfp.h"
/**
* struct sfp_bus - internal representation of a sfp bus
*/
struct sfp_bus {
/* private: */
struct kref kref;
struct list_head node;
struct device_node *device_node;
const struct sfp_socket_ops *socket_ops;
struct device *sfp_dev;
struct sfp *sfp;
const struct sfp_upstream_ops *upstream_ops;
void *upstream;
struct net_device *netdev;
struct phy_device *phydev;
bool registered;
bool started;
};
/**
* sfp_parse_port() - Parse the EEPROM base ID, setting the port type
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
* @id: a pointer to the module's &struct sfp_eeprom_id
* @support: optional pointer to an array of unsigned long for the
* ethtool support mask
*
* Parse the EEPROM identification given in @id, and return one of
* %PORT_TP, %PORT_FIBRE or %PORT_OTHER. If @support is non-%NULL,
* also set the ethtool %ETHTOOL_LINK_MODE_xxx_BIT corresponding with
* the connector type.
*
* If the port type is not known, returns %PORT_OTHER.
*/
int sfp_parse_port(struct sfp_bus *bus, const struct sfp_eeprom_id *id,
unsigned long *support)
{
int port;
/* port is the physical connector, set this from the connector field. */
switch (id->base.connector) {
case SFP_CONNECTOR_SC:
case SFP_CONNECTOR_FIBERJACK:
case SFP_CONNECTOR_LC:
case SFP_CONNECTOR_MT_RJ:
case SFP_CONNECTOR_MU:
case SFP_CONNECTOR_OPTICAL_PIGTAIL:
if (support)
phylink_set(support, FIBRE);
port = PORT_FIBRE;
break;
case SFP_CONNECTOR_RJ45:
if (support)
phylink_set(support, TP);
port = PORT_TP;
break;
case SFP_CONNECTOR_UNSPEC:
if (id->base.e1000_base_t) {
if (support)
phylink_set(support, TP);
port = PORT_TP;
break;
}
/* fallthrough */
case SFP_CONNECTOR_SG: /* guess */
case SFP_CONNECTOR_MPO_1X12:
case SFP_CONNECTOR_MPO_2X16:
case SFP_CONNECTOR_HSSDC_II:
case SFP_CONNECTOR_COPPER_PIGTAIL:
case SFP_CONNECTOR_NOSEPARATE:
case SFP_CONNECTOR_MXC_2X16:
port = PORT_OTHER;
break;
default:
dev_warn(bus->sfp_dev, "SFP: unknown connector id 0x%02x\n",
id->base.connector);
port = PORT_OTHER;
break;
}
return port;
}
EXPORT_SYMBOL_GPL(sfp_parse_port);
/**
* sfp_parse_interface() - Parse the phy_interface_t
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
* @id: a pointer to the module's &struct sfp_eeprom_id
*
* Derive the phy_interface_t mode for the information found in the
* module's identifying EEPROM. There is no standard or defined way
* to derive this information, so we use some heuristics.
*
* If the encoding is 64b66b, then the module must be >= 10G, so
* return %PHY_INTERFACE_MODE_10GKR.
*
* If it's 8b10b, then it's 1G or slower. If it's definitely a fibre
* module, return %PHY_INTERFACE_MODE_1000BASEX mode, otherwise return
* %PHY_INTERFACE_MODE_SGMII mode.
*
* If the encoding is not known, return %PHY_INTERFACE_MODE_NA.
*/
phy_interface_t sfp_parse_interface(struct sfp_bus *bus,
const struct sfp_eeprom_id *id)
{
phy_interface_t iface;
/* Setting the serdes link mode is guesswork: there's no field in
* the EEPROM which indicates what mode should be used.
*
* If the module wants 64b66b, then it must be >= 10G.
*
* If it's a gigabit-only fiber module, it probably does not have
* a PHY, so switch to 802.3z negotiation mode. Otherwise, switch
* to SGMII mode (which is required to support non-gigabit speeds).
*/
switch (id->base.encoding) {
case SFP_ENCODING_8472_64B66B:
iface = PHY_INTERFACE_MODE_10GKR;
break;
case SFP_ENCODING_8B10B:
if (!id->base.e1000_base_t &&
!id->base.e100_base_lx &&
!id->base.e100_base_fx)
iface = PHY_INTERFACE_MODE_1000BASEX;
else
iface = PHY_INTERFACE_MODE_SGMII;
break;
default:
iface = PHY_INTERFACE_MODE_NA;
dev_err(bus->sfp_dev,
"SFP module encoding does not support 8b10b nor 64b66b\n");
break;
}
return iface;
}
EXPORT_SYMBOL_GPL(sfp_parse_interface);
/**
* sfp_parse_support() - Parse the eeprom id for supported link modes
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
* @id: a pointer to the module's &struct sfp_eeprom_id
* @support: pointer to an array of unsigned long for the ethtool support mask
*
* Parse the EEPROM identification information and derive the supported
* ethtool link modes for the module.
*/
void sfp_parse_support(struct sfp_bus *bus, const struct sfp_eeprom_id *id,
unsigned long *support)
{
phylink_set(support, Autoneg);
phylink_set(support, Pause);
phylink_set(support, Asym_Pause);
/* Set ethtool support from the compliance fields. */
if (id->base.e10g_base_sr)
phylink_set(support, 10000baseSR_Full);
if (id->base.e10g_base_lr)
phylink_set(support, 10000baseLR_Full);
if (id->base.e10g_base_lrm)
phylink_set(support, 10000baseLRM_Full);
if (id->base.e10g_base_er)
phylink_set(support, 10000baseER_Full);
if (id->base.e1000_base_sx ||
id->base.e1000_base_lx ||
id->base.e1000_base_cx)
phylink_set(support, 1000baseX_Full);
if (id->base.e1000_base_t) {
phylink_set(support, 1000baseT_Half);
phylink_set(support, 1000baseT_Full);
}
switch (id->base.extended_cc) {
case 0x00: /* Unspecified */
break;
case 0x02: /* 100Gbase-SR4 or 25Gbase-SR */
phylink_set(support, 100000baseSR4_Full);
phylink_set(support, 25000baseSR_Full);
break;
case 0x03: /* 100Gbase-LR4 or 25Gbase-LR */
case 0x04: /* 100Gbase-ER4 or 25Gbase-ER */
phylink_set(support, 100000baseLR4_ER4_Full);
break;
case 0x0b: /* 100Gbase-CR4 or 25Gbase-CR CA-L */
case 0x0c: /* 25Gbase-CR CA-S */
case 0x0d: /* 25Gbase-CR CA-N */
phylink_set(support, 100000baseCR4_Full);
phylink_set(support, 25000baseCR_Full);
break;
default:
dev_warn(bus->sfp_dev,
"Unknown/unsupported extended compliance code: 0x%02x\n",
id->base.extended_cc);
break;
}
/* For fibre channel SFP, derive possible BaseX modes */
if (id->base.fc_speed_100 ||
id->base.fc_speed_200 ||
id->base.fc_speed_400) {
if (id->base.br_nominal >= 31)
phylink_set(support, 2500baseX_Full);
if (id->base.br_nominal >= 12)
phylink_set(support, 1000baseX_Full);
}
switch (id->base.connector) {
case SFP_CONNECTOR_SC:
case SFP_CONNECTOR_FIBERJACK:
case SFP_CONNECTOR_LC:
case SFP_CONNECTOR_MT_RJ:
case SFP_CONNECTOR_MU:
case SFP_CONNECTOR_OPTICAL_PIGTAIL:
break;
case SFP_CONNECTOR_UNSPEC:
if (id->base.e1000_base_t)
break;
case SFP_CONNECTOR_SG: /* guess */
case SFP_CONNECTOR_MPO_1X12:
case SFP_CONNECTOR_MPO_2X16:
case SFP_CONNECTOR_HSSDC_II:
case SFP_CONNECTOR_COPPER_PIGTAIL:
case SFP_CONNECTOR_NOSEPARATE:
case SFP_CONNECTOR_MXC_2X16:
default:
/* a guess at the supported link modes */
dev_warn(bus->sfp_dev,
"Guessing link modes, please report...\n");
phylink_set(support, 1000baseT_Half);
phylink_set(support, 1000baseT_Full);
break;
}
}
EXPORT_SYMBOL_GPL(sfp_parse_support);
static LIST_HEAD(sfp_buses);
static DEFINE_MUTEX(sfp_mutex);
static const struct sfp_upstream_ops *sfp_get_upstream_ops(struct sfp_bus *bus)
{
return bus->registered ? bus->upstream_ops : NULL;
}
static struct sfp_bus *sfp_bus_get(struct device_node *np)
{
struct sfp_bus *sfp, *new, *found = NULL;
new = kzalloc(sizeof(*new), GFP_KERNEL);
mutex_lock(&sfp_mutex);
list_for_each_entry(sfp, &sfp_buses, node) {
if (sfp->device_node == np) {
kref_get(&sfp->kref);
found = sfp;
break;
}
}
if (!found && new) {
kref_init(&new->kref);
new->device_node = np;
list_add(&new->node, &sfp_buses);
found = new;
new = NULL;
}
mutex_unlock(&sfp_mutex);
kfree(new);
return found;
}
static void sfp_bus_release(struct kref *kref)
{
struct sfp_bus *bus = container_of(kref, struct sfp_bus, kref);
list_del(&bus->node);
mutex_unlock(&sfp_mutex);
kfree(bus);
}
static void sfp_bus_put(struct sfp_bus *bus)
{
kref_put_mutex(&bus->kref, sfp_bus_release, &sfp_mutex);
}
static int sfp_register_bus(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = bus->upstream_ops;
int ret;
if (ops) {
if (ops->link_down)
ops->link_down(bus->upstream);
if (ops->connect_phy && bus->phydev) {
ret = ops->connect_phy(bus->upstream, bus->phydev);
if (ret)
return ret;
}
}
if (bus->started)
bus->socket_ops->start(bus->sfp);
bus->registered = true;
return 0;
}
static void sfp_unregister_bus(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = bus->upstream_ops;
if (bus->registered) {
if (bus->started)
bus->socket_ops->stop(bus->sfp);
if (bus->phydev && ops && ops->disconnect_phy)
ops->disconnect_phy(bus->upstream);
}
bus->registered = false;
}
/**
* sfp_get_module_info() - Get the ethtool_modinfo for a SFP module
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
* @modinfo: a &struct ethtool_modinfo
*
* Fill in the type and eeprom_len parameters in @modinfo for a module on
* the sfp bus specified by @bus.
*
* Returns 0 on success or a negative errno number.
*/
int sfp_get_module_info(struct sfp_bus *bus, struct ethtool_modinfo *modinfo)
{
if (!bus->registered)
return -ENOIOCTLCMD;
return bus->socket_ops->module_info(bus->sfp, modinfo);
}
EXPORT_SYMBOL_GPL(sfp_get_module_info);
/**
* sfp_get_module_eeprom() - Read the SFP module EEPROM
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
* @ee: a &struct ethtool_eeprom
* @data: buffer to contain the EEPROM data (must be at least @ee->len bytes)
*
* Read the EEPROM as specified by the supplied @ee. See the documentation
* for &struct ethtool_eeprom for the region to be read.
*
* Returns 0 on success or a negative errno number.
*/
int sfp_get_module_eeprom(struct sfp_bus *bus, struct ethtool_eeprom *ee,
u8 *data)
{
if (!bus->registered)
return -ENOIOCTLCMD;
return bus->socket_ops->module_eeprom(bus->sfp, ee, data);
}
EXPORT_SYMBOL_GPL(sfp_get_module_eeprom);
/**
* sfp_upstream_start() - Inform the SFP that the network device is up
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
*
* Inform the SFP socket that the network device is now up, so that the
* module can be enabled by allowing TX_DISABLE to be deasserted. This
* should be called from the network device driver's &struct net_device_ops
* ndo_open() method.
*/
void sfp_upstream_start(struct sfp_bus *bus)
{
if (bus->registered)
bus->socket_ops->start(bus->sfp);
bus->started = true;
}
EXPORT_SYMBOL_GPL(sfp_upstream_start);
/**
* sfp_upstream_stop() - Inform the SFP that the network device is down
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
*
* Inform the SFP socket that the network device is now up, so that the
* module can be disabled by asserting TX_DISABLE, disabling the laser
* in optical modules. This should be called from the network device
* driver's &struct net_device_ops ndo_stop() method.
*/
void sfp_upstream_stop(struct sfp_bus *bus)
{
if (bus->registered)
bus->socket_ops->stop(bus->sfp);
bus->started = false;
}
EXPORT_SYMBOL_GPL(sfp_upstream_stop);
/**
* sfp_register_upstream() - Register the neighbouring device
* @np: device node for the SFP bus
* @ndev: network device associated with the interface
* @upstream: the upstream private data
* @ops: the upstream's &struct sfp_upstream_ops
*
* Register the upstream device (eg, PHY) with the SFP bus. MAC drivers
* should use phylink, which will call this function for them. Returns
* a pointer to the allocated &struct sfp_bus.
*
* On error, returns %NULL.
*/
struct sfp_bus *sfp_register_upstream(struct device_node *np,
struct net_device *ndev, void *upstream,
const struct sfp_upstream_ops *ops)
{
struct sfp_bus *bus = sfp_bus_get(np);
int ret = 0;
if (bus) {
rtnl_lock();
bus->upstream_ops = ops;
bus->upstream = upstream;
bus->netdev = ndev;
if (bus->sfp)
ret = sfp_register_bus(bus);
rtnl_unlock();
}
if (ret) {
sfp_bus_put(bus);
bus = NULL;
}
return bus;
}
EXPORT_SYMBOL_GPL(sfp_register_upstream);
/**
* sfp_unregister_upstream() - Unregister sfp bus
* @bus: a pointer to the &struct sfp_bus structure for the sfp module
*
* Unregister a previously registered upstream connection for the SFP
* module. @bus is returned from sfp_register_upstream().
*/
void sfp_unregister_upstream(struct sfp_bus *bus)
{
rtnl_lock();
sfp_unregister_bus(bus);
bus->upstream = NULL;
bus->netdev = NULL;
rtnl_unlock();
sfp_bus_put(bus);
}
EXPORT_SYMBOL_GPL(sfp_unregister_upstream);
/* Socket driver entry points */
int sfp_add_phy(struct sfp_bus *bus, struct phy_device *phydev)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
int ret = 0;
if (ops && ops->connect_phy)
ret = ops->connect_phy(bus->upstream, phydev);
if (ret == 0)
bus->phydev = phydev;
return ret;
}
EXPORT_SYMBOL_GPL(sfp_add_phy);
void sfp_remove_phy(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
if (ops && ops->disconnect_phy)
ops->disconnect_phy(bus->upstream);
bus->phydev = NULL;
}
EXPORT_SYMBOL_GPL(sfp_remove_phy);
void sfp_link_up(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
if (ops && ops->link_up)
ops->link_up(bus->upstream);
}
EXPORT_SYMBOL_GPL(sfp_link_up);
void sfp_link_down(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
if (ops && ops->link_down)
ops->link_down(bus->upstream);
}
EXPORT_SYMBOL_GPL(sfp_link_down);
int sfp_module_insert(struct sfp_bus *bus, const struct sfp_eeprom_id *id)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
int ret = 0;
if (ops && ops->module_insert)
ret = ops->module_insert(bus->upstream, id);
return ret;
}
EXPORT_SYMBOL_GPL(sfp_module_insert);
void sfp_module_remove(struct sfp_bus *bus)
{
const struct sfp_upstream_ops *ops = sfp_get_upstream_ops(bus);
if (ops && ops->module_remove)
ops->module_remove(bus->upstream);
}
EXPORT_SYMBOL_GPL(sfp_module_remove);
struct sfp_bus *sfp_register_socket(struct device *dev, struct sfp *sfp,
const struct sfp_socket_ops *ops)
{
struct sfp_bus *bus = sfp_bus_get(dev->of_node);
int ret = 0;
if (bus) {
rtnl_lock();
bus->sfp_dev = dev;
bus->sfp = sfp;
bus->socket_ops = ops;
if (bus->netdev)
ret = sfp_register_bus(bus);
rtnl_unlock();
}
if (ret) {
sfp_bus_put(bus);
bus = NULL;
}
return bus;
}
EXPORT_SYMBOL_GPL(sfp_register_socket);
void sfp_unregister_socket(struct sfp_bus *bus)
{
rtnl_lock();
sfp_unregister_bus(bus);
bus->sfp_dev = NULL;
bus->sfp = NULL;
bus->socket_ops = NULL;
rtnl_unlock();
sfp_bus_put(bus);
}
EXPORT_SYMBOL_GPL(sfp_unregister_socket);
