static int __init cvm_oct_init_module(void)
{
int num_interfaces;
int interface;
int fau = FAU_NUM_PACKET_BUFFERS_TO_FREE;
int qos;
octeon_mdiobus_force_mod_depencency();
pr_notice("cavium-ethernet %s\n", OCTEON_ETHERNET_VERSION);
if (OCTEON_IS_MODEL(OCTEON_CN52XX))
cvm_oct_mac_addr_offset = 2; /* First two are the mgmt ports. */
else if (OCTEON_IS_MODEL(OCTEON_CN56XX))
cvm_oct_mac_addr_offset = 1; /* First one is the mgmt port. */
else
cvm_oct_mac_addr_offset = 0;
cvm_oct_poll_queue = create_singlethread_workqueue("octeon-ethernet");
if (cvm_oct_poll_queue == NULL) {
pr_err("octeon-ethernet: Cannot create workqueue");
return -ENOMEM;
}
cvm_oct_configure_common_hw();
cvmx_helper_initialize_packet_io_global();
/* Change the input group for all ports before input is enabled */
num_interfaces = cvmx_helper_get_number_of_interfaces();
for (interface = 0; interface < num_interfaces; interface++) {
int num_ports = cvmx_helper_ports_on_interface(interface);
int port;
for (port = cvmx_helper_get_ipd_port(interface, 0);
port < cvmx_helper_get_ipd_port(interface, num_ports);
port++) {
union cvmx_pip_prt_tagx pip_prt_tagx;
pip_prt_tagx.u64 =
cvmx_read_csr(CVMX_PIP_PRT_TAGX(port));
pip_prt_tagx.s.grp = pow_receive_group;
cvmx_write_csr(CVMX_PIP_PRT_TAGX(port),
pip_prt_tagx.u64);
}
}
cvmx_helper_ipd_and_packet_input_enable();
memset(cvm_oct_device, 0, sizeof(cvm_oct_device));
/*
* Initialize the FAU used for counting packet buffers that
* need to be freed.
*/
cvmx_fau_atomic_write32(FAU_NUM_PACKET_BUFFERS_TO_FREE, 0);
/* Initialize the FAU used for counting tx SKBs that need to be freed */
cvmx_fau_atomic_write32(FAU_TOTAL_TX_TO_CLEAN, 0);
if ((pow_send_group != -1)) {
struct net_device *dev;
pr_info("\tConfiguring device for POW only access\n");
dev = alloc_etherdev(sizeof(struct octeon_ethernet));
if (dev) {
/* Initialize the device private structure. */
struct octeon_ethernet *priv = netdev_priv(dev);
dev->netdev_ops = &cvm_oct_pow_netdev_ops;
priv->imode = CVMX_HELPER_INTERFACE_MODE_DISABLED;
priv->port = CVMX_PIP_NUM_INPUT_PORTS;
priv->queue = -1;
strcpy(dev->name, "pow%d");
for (qos = 0; qos < 16; qos++)
skb_queue_head_init(&priv->tx_free_list[qos]);
if (register_netdev(dev) < 0) {
pr_err("Failed to register ethernet device for POW\n");
free_netdev(dev);
} else {
cvm_oct_device[CVMX_PIP_NUM_INPUT_PORTS] = dev;
pr_info("%s: POW send group %d, receive group %d\n",
dev->name, pow_send_group,
pow_receive_group);
}
} else {
pr_err("Failed to allocate ethernet device for POW\n");
}
}
num_interfaces = cvmx_helper_get_number_of_interfaces();
for (interface = 0; interface < num_interfaces; interface++) {
cvmx_helper_interface_mode_t imode =
cvmx_helper_interface_get_mode(interface);
int num_ports = cvmx_helper_ports_on_interface(interface);
int port;
for (port = cvmx_helper_get_ipd_port(interface, 0);
port < cvmx_helper_get_ipd_port(interface, num_ports);
port++) {
struct octeon_ethernet *priv;
struct net_device *dev =
alloc_etherdev(sizeof(struct octeon_ethernet));
if (!dev) {
pr_err("Failed to allocate ethernet device for port %d\n", port);
continue;
}
/* Initialize the device private structure. */
priv = netdev_priv(dev);
INIT_DELAYED_WORK(&priv->port_periodic_work,
cvm_oct_periodic_worker);
priv->imode = imode;
priv->port = port;
priv->queue = cvmx_pko_get_base_queue(priv->port);
priv->fau = fau - cvmx_pko_get_num_queues(port) * 4;
for (qos = 0; qos < 16; qos++)
skb_queue_head_init(&priv->tx_free_list[qos]);
for (qos = 0; qos < cvmx_pko_get_num_queues(port);
qos++)
cvmx_fau_atomic_write32(priv->fau + qos * 4, 0);
switch (priv->imode) {
/* These types don't support ports to IPD/PKO */
case CVMX_HELPER_INTERFACE_MODE_DISABLED:
case CVMX_HELPER_INTERFACE_MODE_PCIE:
case CVMX_HELPER_INTERFACE_MODE_PICMG:
break;
case CVMX_HELPER_INTERFACE_MODE_NPI:
dev->netdev_ops = &cvm_oct_npi_netdev_ops;
strcpy(dev->name, "npi%d");
break;
case CVMX_HELPER_INTERFACE_MODE_XAUI:
dev->netdev_ops = &cvm_oct_xaui_netdev_ops;
strcpy(dev->name, "xaui%d");
break;
case CVMX_HELPER_INTERFACE_MODE_LOOP:
dev->netdev_ops = &cvm_oct_npi_netdev_ops;
strcpy(dev->name, "loop%d");
break;
case CVMX_HELPER_INTERFACE_MODE_SGMII:
dev->netdev_ops = &cvm_oct_sgmii_netdev_ops;
strcpy(dev->name, "eth%d");
break;
case CVMX_HELPER_INTERFACE_MODE_SPI:
dev->netdev_ops = &cvm_oct_spi_netdev_ops;
strcpy(dev->name, "spi%d");
break;
case CVMX_HELPER_INTERFACE_MODE_RGMII:
case CVMX_HELPER_INTERFACE_MODE_GMII:
dev->netdev_ops = &cvm_oct_rgmii_netdev_ops;
strcpy(dev->name, "eth%d");
break;
}
if (!dev->netdev_ops) {
free_netdev(dev);
} else if (register_netdev(dev) < 0) {
pr_err("Failed to register ethernet device "
"for interface %d, port %d\n",
interface, priv->port);
free_netdev(dev);
} else {
cvm_oct_device[priv->port] = dev;
fau -=
cvmx_pko_get_num_queues(priv->port) *
sizeof(uint32_t);
queue_delayed_work(cvm_oct_poll_queue,
&priv->port_periodic_work, HZ);
}
}
}
cvm_oct_tx_initialize();
cvm_oct_rx_initialize();
/*
* 150 uS: about 10 1500-byte packtes at 1GE.
*/
cvm_oct_tx_poll_interval = 150 * (octeon_get_clock_rate() / 1000000);
queue_delayed_work(cvm_oct_poll_queue, &cvm_oct_rx_refill_work, HZ);
return 0;
}
/* Here is the description of the parameters that are passed to QLM configuration
* param0 : The QLM to configure
* param1 : Speed to configure the QLM at
* param2 : Mode the QLM to configure
* param3 : 1 = RC, 0 = EP
* param4 : 0 = GEN1, 1 = GEN2, 2 = GEN3
* param5 : ref clock select, 0 = 100Mhz, 1 = 125MHz, 2 = 156MHz
* param6 : ref clock input to use:
* 0 - external reference (QLMx_REF_CLK)
* 1 = common clock 0 (QLMC_REF_CLK0)
* 2 = common_clock 1 (QLMC_REF_CLK1)
*/
int checkboard(void)
{
int qlm;
char env_var[16];
int node = 0;
/* Since i2c is broken on pass 1.0 we use an environment variable */
if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) {
ulong board_version;
board_version = getenv_ulong("board_version", 10, 1);
gd->arch.board_desc.rev_major = board_version;
}
octeon_init_qlm(0);
for (node = 0; node < CVMX_MAX_NODES; node++) {
int speed[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
int mode[8] = { -1, -1, -1, -1, -1, -1, -1, -1 };
int pcie_rc[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
int pcie_gen[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
int ref_clock_sel[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
int ref_clock_input[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
if (!(gd->arch.node_mask & (1 << node)))
continue;
for (qlm = 0; qlm < 8; qlm++) {
const char *mode_str;
mode[qlm] = CVMX_QLM_MODE_DISABLED;
sprintf(env_var, "qlm%d:%d_mode", qlm, node);
mode_str = getenv(env_var);
if (!mode_str)
continue;
if (!strncmp(mode_str, "sgmii", 5)
|| !strncmp(mode_str, "xaui", 4)
|| !strncmp(mode_str, "dxaui", 5)
|| !strncmp(mode_str, "rxaui", 5)) {
/* BGX0 is QLM0 or QLM2 */
if (qlm == 2
&& mode[0] != -1
&& mode[0] != CVMX_QLM_MODE_PCIE
&& mode[0] != CVMX_QLM_MODE_PCIE_1X8) {
printf("NODE %d: Not configuring QLM2, as QLM0 is already set for BGX0\n", node);
continue;
}
/* BGX1 is QLM1 or QLM3 */
if (qlm == 3
&& mode[1] != -1
&& mode[1] != CVMX_QLM_MODE_PCIE
&& mode[1] != CVMX_QLM_MODE_PCIE_1X8) {
printf("NODE %d: Not configuring QLM2, as QLM1 is already set for BGX1\n", node);
continue;
}
}
if (!strncmp(mode_str, "sgmii", 5)) {
speed[qlm] = 1250;
mode[qlm] = CVMX_QLM_MODE_SGMII;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: SGMII\n", node, qlm);
} else if (!strncmp(mode_str, "xaui", 4)) {
speed[qlm] = 3125;
mode[qlm] = CVMX_QLM_MODE_XAUI;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: XAUI\n", node, qlm);
} else if (!strncmp(mode_str, "dxaui", 5)) {
speed[qlm] = 6250;
mode[qlm] = CVMX_QLM_MODE_XAUI;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: DXAUI\n", node, qlm);
} else if (!strncmp(mode_str, "rxaui", 5)) {
speed[qlm] = 6250;
mode[qlm] = CVMX_QLM_MODE_RXAUI;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: RXAUI\n", node, qlm);
} else if (!strcmp(mode_str, "ila")) {
if (qlm != 2 && qlm != 3) {
printf("Error: ILA not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 6250;
mode[qlm] = CVMX_QLM_MODE_ILK;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: ILA\n", node, qlm);
}
} else if (!strcmp(mode_str, "ilk")) {
int lanes = 0;
char ilk_env[16];
if (qlm < 4) {
printf("Error: ILK not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 6250;
mode[qlm] = CVMX_QLM_MODE_ILK;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: ILK\n", node, qlm);
}
sprintf(ilk_env, "ilk%d:%d_lanes", qlm, node);
if (getenv(ilk_env))
lanes = getenv_ulong(ilk_env, 0, 16);
if (lanes > 4)
ref_clock_input[qlm] = 2;
} else if (!strncmp(mode_str, "xlaui", 5)) {
if (qlm < 4) {
printf("Error: XLAUI not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 103125;
mode[qlm] = CVMX_QLM_MODE_XLAUI;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: XLAUI\n", node, qlm);
}
} else if (!strncmp(mode_str, "xfi", 3)) {
if (qlm < 4) {
printf("Error: XFI not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 103125;
mode[qlm] = CVMX_QLM_MODE_XFI;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: XFI\n", node, qlm);
}
} else if (!strncmp(mode_str, "10G_KR", 6)) {
if (qlm < 4) {
printf("Error: 10G_KR not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 103125;
mode[qlm] = CVMX_QLM_MODE_10G_KR;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: 10G_KR\n", node, qlm);
}
} else if (!strncmp(mode_str, "40G_KR4", 7)) {
if (qlm < 4) {
printf("Error: 40G_KR4 not supported on NODE%d:QLM %d\n",
node, qlm);
} else {
speed[qlm] = 103125;
mode[qlm] = CVMX_QLM_MODE_40G_KR4;
ref_clock_sel[qlm] = 2;
printf("NODE %d:QLM %d: 40G_KR4\n", node, qlm);
}
} else if (!strcmp(mode_str, "pcie")) {
char *pmode;
int lanes = 0;
sprintf(env_var, "pcie%d:%d_mode", qlm, node);
pmode = getenv(env_var);
if (pmode && !strcmp(pmode, "ep"))
pcie_rc[qlm] = 0;
else
pcie_rc[qlm] = 1;
sprintf(env_var, "pcie%d:%d_gen", qlm, node);
pcie_gen[qlm] = getenv_ulong(env_var, 0, 3);
sprintf(env_var, "pcie%d:%d_lanes", qlm, node);
lanes = getenv_ulong(env_var, 0, 8);
if (lanes == 8)
mode[qlm] = CVMX_QLM_MODE_PCIE_1X8;
else
mode[qlm] = CVMX_QLM_MODE_PCIE;
ref_clock_sel[qlm] = 0;
printf("NODE %d:QLM %d: PCIe gen%d %s\n", node, qlm, pcie_gen[qlm] + 1,
pcie_rc[qlm] ? "root complex" : "endpoint");
} else {
printf("NODE %d:QLM %d: disabled\n", node, qlm);
}
}
for (qlm = 0; qlm < 8; qlm++) {
if (mode[qlm] == -1)
continue;
debug("Configuring node%d qlm%d with speed(%d), mode(%d), RC(%d), Gen(%d), REF_CLK(%d), CLK_SOURCE(%d)\n",
node, qlm, speed[qlm], mode[qlm], pcie_rc[qlm],
pcie_gen[qlm] + 1, ref_clock_sel[qlm], ref_clock_input[qlm]);
octeon_configure_qlm_cn78xx(node, qlm, speed[qlm], mode[qlm], pcie_rc[qlm],
pcie_gen[qlm], ref_clock_sel[qlm],
ref_clock_input[qlm]);
}
}
checkboardinfo();
return 0;
}
void __init arch_init_irq(void)
{
int irq;
struct irq_chip *chip0;
struct irq_chip *chip0_timer;
struct irq_chip *chip1;
#ifdef CONFIG_SMP
/* Set the default affinity to the boot cpu. */
cpumask_clear(irq_default_affinity);
cpumask_set_cpu(smp_processor_id(), irq_default_affinity);
#endif
if (NR_IRQS < OCTEON_IRQ_LAST)
pr_err("octeon_irq_init: NR_IRQS is set too low\n");
if (OCTEON_IS_MODEL(OCTEON_CN58XX_PASS2_X) ||
OCTEON_IS_MODEL(OCTEON_CN56XX_PASS2_X) ||
OCTEON_IS_MODEL(OCTEON_CN52XX_PASS2_X)) {
chip0 = &octeon_irq_chip_ciu0_v2;
chip0_timer = &octeon_irq_chip_ciu0_timer_v2;
chip1 = &octeon_irq_chip_ciu1_v2;
} else {
chip0 = &octeon_irq_chip_ciu0;
chip0_timer = &octeon_irq_chip_ciu0_timer;
chip1 = &octeon_irq_chip_ciu1;
}
/* 0 - 15 reserved for i8259 master and slave controller. */
/* 17 - 23 Mips internal */
for (irq = OCTEON_IRQ_SW0; irq <= OCTEON_IRQ_TIMER; irq++) {
set_irq_chip_and_handler(irq, &octeon_irq_chip_core,
handle_percpu_irq);
}
/* 24 - 87 CIU_INT_SUM0 */
for (irq = OCTEON_IRQ_WORKQ0; irq <= OCTEON_IRQ_BOOTDMA; irq++) {
switch (irq) {
case OCTEON_IRQ_GMX_DRP0:
case OCTEON_IRQ_GMX_DRP1:
case OCTEON_IRQ_IPD_DRP:
case OCTEON_IRQ_KEY_ZERO:
case OCTEON_IRQ_TIMER0:
case OCTEON_IRQ_TIMER1:
case OCTEON_IRQ_TIMER2:
case OCTEON_IRQ_TIMER3:
set_irq_chip_and_handler(irq, chip0_timer, handle_percpu_irq);
break;
default:
set_irq_chip_and_handler(irq, chip0, handle_percpu_irq);
break;
}
}
/* 88 - 151 CIU_INT_SUM1 */
for (irq = OCTEON_IRQ_WDOG0; irq <= OCTEON_IRQ_RESERVED151; irq++) {
set_irq_chip_and_handler(irq, chip1, handle_percpu_irq);
}
#ifdef CONFIG_PCI_MSI
/* 152 - 215 PCI/PCIe MSI interrupts */
for (irq = OCTEON_IRQ_MSI_BIT0; irq <= OCTEON_IRQ_MSI_BIT63; irq++) {
set_irq_chip_and_handler(irq, &octeon_irq_chip_msi,
handle_percpu_irq);
}
#endif
set_c0_status(0x300 << 2);
}
/**
* Initialize and start the ILK interface.
*
* @param interface The identifier of the packet interface to configure and
* use as a ILK interface. cn68xx has 2 interfaces: ilk0 and
* ilk1.
*
* @param lane_mask the lane group for this interface
*
* @return Zero on success, negative of failure.
*/
int cvmx_ilk_start_interface (int interface, unsigned char lane_mask)
{
int res = -1;
int other_intf, this_qlm, other_qlm;
unsigned char uni_mask;
cvmx_mio_qlmx_cfg_t mio_qlmx_cfg, other_mio_qlmx_cfg;
cvmx_ilk_txx_cfg0_t ilk_txx_cfg0;
cvmx_ilk_rxx_cfg0_t ilk_rxx_cfg0;
cvmx_ilk_ser_cfg_t ilk_ser_cfg;
if (!(OCTEON_IS_MODEL(OCTEON_CN68XX)))
return res;
if (interface >= CVMX_NUM_ILK_INTF)
return res;
if (lane_mask == 0)
return res;
/* check conflicts between 2 ilk interfaces. 1 lane can be assigned to 1
* interface only */
other_intf = !interface;
this_qlm = interface + CVMX_ILK_QLM_BASE;
other_qlm = other_intf + CVMX_ILK_QLM_BASE;
if (cvmx_ilk_intf_cfg[other_intf].lane_en_mask & lane_mask)
{
cvmx_dprintf ("ILK%d: %s: lane assignment conflict\n", interface,
__FUNCTION__);
return res;
}
/* check the legality of the lane mask. interface 0 can have 8 lanes,
* while interface 1 can have 4 lanes at most */
uni_mask = lane_mask >> (interface * 4);
if ((uni_mask != 0x1 && uni_mask != 0x3 && uni_mask != 0xf &&
uni_mask != 0xff) || (interface == 1 && lane_mask > 0xf0))
{
#if CVMX_ENABLE_DEBUG_PRINTS
cvmx_dprintf ("ILK%d: %s: incorrect lane mask: 0x%x \n", interface,
__FUNCTION__, uni_mask);
#endif
return res;
}
/* check the availability of qlms. qlm_cfg = 001 means the chip is fused
* to give this qlm to ilk */
mio_qlmx_cfg.u64 = cvmx_read_csr (CVMX_MIO_QLMX_CFG(this_qlm));
other_mio_qlmx_cfg.u64 = cvmx_read_csr (CVMX_MIO_QLMX_CFG(other_qlm));
if (mio_qlmx_cfg.s.qlm_cfg != 1 ||
(uni_mask == 0xff && other_mio_qlmx_cfg.s.qlm_cfg != 1))
{
#if CVMX_ENABLE_DEBUG_PRINTS
cvmx_dprintf ("ILK%d: %s: qlm unavailable\n", interface, __FUNCTION__);
#endif
return res;
}
/* power up the serdes */
ilk_ser_cfg.u64 = cvmx_read_csr (CVMX_ILK_SER_CFG);
if (ilk_ser_cfg.s.ser_pwrup == 0)
{
ilk_ser_cfg.s.ser_rxpol_auto = 1;
ilk_ser_cfg.s.ser_rxpol = 0;
ilk_ser_cfg.s.ser_txpol = 0;
ilk_ser_cfg.s.ser_reset_n = 0xff;
ilk_ser_cfg.s.ser_haul = 0;
}
ilk_ser_cfg.s.ser_pwrup |= ((interface ==0) && (lane_mask > 0xf)) ?
0x3 : (1 << interface);
cvmx_write_csr (CVMX_ILK_SER_CFG, ilk_ser_cfg.u64);
/* configure the lane enable of the interface */
ilk_txx_cfg0.u64 = cvmx_read_csr (CVMX_ILK_TXX_CFG0(interface));
ilk_rxx_cfg0.u64 = cvmx_read_csr (CVMX_ILK_RXX_CFG0(interface));
ilk_txx_cfg0.s.lane_ena = ilk_rxx_cfg0.s.lane_ena = lane_mask;
cvmx_write_csr (CVMX_ILK_TXX_CFG0(interface), ilk_txx_cfg0.u64);
cvmx_write_csr (CVMX_ILK_RXX_CFG0(interface), ilk_rxx_cfg0.u64);
/* write to local cache. for lane speed, if interface 0 has 8 lanes,
* assume both qlms have the same speed */
cvmx_ilk_intf_cfg[interface].intf_en = 1;
cvmx_ilk_intf_cfg[interface].lane_en_mask = lane_mask;
res = 0;
return res;
}
/**
* Initialize a USB port for use. This must be called before any
* other access to the Octeon USB port is made. The port starts
* off in the disabled state.
*
* @param usb Pointer to an empty cvmx_usbd_state_t structure
* that will be populated by the initialize call.
* This structure is then passed to all other USB
* functions.
* @param usb_port_number
* Which Octeon USB port to initialize.
* @param flags Flags to control hardware initialization. See
* cvmx_usbd_initialize_flags_t for the flag
* definitions. Some flags are mandatory.
*
* @return Zero or a negative on error.
*/
int cvmx_usbd_initialize(cvmx_usbd_state_t *usb,
int usb_port_number,
cvmx_usbd_initialize_flags_t flags)
{
cvmx_usbnx_clk_ctl_t usbn_clk_ctl;
cvmx_usbnx_usbp_ctl_status_t usbn_usbp_ctl_status;
if (cvmx_unlikely(flags & CVMX_USBD_INITIALIZE_FLAGS_DEBUG))
cvmx_dprintf("%s: Called\n", __FUNCTION__);
memset(usb, 0, sizeof(usb));
usb->init_flags = flags;
usb->index = usb_port_number;
/* Try to determine clock type automatically */
if ((usb->init_flags & (CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_XI |
CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_GND)) == 0)
{
if (__cvmx_helper_board_usb_get_clock_type() == USB_CLOCK_TYPE_CRYSTAL_12)
usb->init_flags |= CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_XI; /* Only 12 MHZ crystals are supported */
else
usb->init_flags |= CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_GND;
}
if (usb->init_flags & CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_GND)
{
/* Check for auto ref clock frequency */
if (!(usb->init_flags & CVMX_USBD_INITIALIZE_FLAGS_CLOCK_MHZ_MASK))
switch (__cvmx_helper_board_usb_get_clock_type())
{
case USB_CLOCK_TYPE_REF_12:
usb->init_flags |= CVMX_USBD_INITIALIZE_FLAGS_CLOCK_12MHZ;
break;
case USB_CLOCK_TYPE_REF_24:
usb->init_flags |= CVMX_USBD_INITIALIZE_FLAGS_CLOCK_24MHZ;
break;
case USB_CLOCK_TYPE_REF_48:
default:
usb->init_flags |= CVMX_USBD_INITIALIZE_FLAGS_CLOCK_48MHZ;
break;
}
}
/* Power On Reset and PHY Initialization */
/* 1. Wait for DCOK to assert (nothing to do) */
/* 2a. Write USBN0/1_CLK_CTL[POR] = 1 and
USBN0/1_CLK_CTL[HRST,PRST,HCLK_RST] = 0 */
usbn_clk_ctl.u64 = cvmx_read_csr(CVMX_USBNX_CLK_CTL(usb->index));
usbn_clk_ctl.s.por = 1;
usbn_clk_ctl.s.hrst = 0;
usbn_clk_ctl.s.prst = 0;
usbn_clk_ctl.s.hclk_rst = 0;
usbn_clk_ctl.s.enable = 0;
/* 2b. Select the USB reference clock/crystal parameters by writing
appropriate values to USBN0/1_CLK_CTL[P_C_SEL, P_RTYPE, P_COM_ON] */
if (usb->init_flags & CVMX_USBD_INITIALIZE_FLAGS_CLOCK_XO_GND)
{
/* The USB port uses 12/24/48MHz 2.5V board clock
source at USB_XO. USB_XI should be tied to GND.
Most Octeon evaluation boards require this setting */
if (OCTEON_IS_MODEL(OCTEON_CN3XXX))
{
usbn_clk_ctl.cn31xx.p_rclk = 1; /* From CN31XX,CN30XX manual */
usbn_clk_ctl.cn31xx.p_xenbn = 0;
}
else if (OCTEON_IS_MODEL(OCTEON_CN56XX) || OCTEON_IS_MODEL(OCTEON_CN50XX))
usbn_clk_ctl.cn56xx.p_rtype = 2; /* From CN56XX,CN50XX manual */
else
usbn_clk_ctl.cn52xx.p_rtype = 1; /* From CN52XX manual */
switch (usb->init_flags & CVMX_USBD_INITIALIZE_FLAGS_CLOCK_MHZ_MASK)
{
case CVMX_USBD_INITIALIZE_FLAGS_CLOCK_12MHZ:
usbn_clk_ctl.s.p_c_sel = 0;
break;
case CVMX_USBD_INITIALIZE_FLAGS_CLOCK_24MHZ:
usbn_clk_ctl.s.p_c_sel = 1;
break;
case CVMX_USBD_INITIALIZE_FLAGS_CLOCK_48MHZ:
usbn_clk_ctl.s.p_c_sel = 2;
break;
}
}
else
{
/* The USB port uses a 12MHz crystal as clock source
at USB_XO and USB_XI */
if (OCTEON_IS_MODEL(OCTEON_CN3XXX))
{
usbn_clk_ctl.cn31xx.p_rclk = 1; /* From CN31XX,CN30XX manual */
usbn_clk_ctl.cn31xx.p_xenbn = 1;
}
else if (OCTEON_IS_MODEL(OCTEON_CN56XX) || OCTEON_IS_MODEL(OCTEON_CN50XX))
usbn_clk_ctl.cn56xx.p_rtype = 0; /* From CN56XX,CN50XX manual */
else
usbn_clk_ctl.cn52xx.p_rtype = 0; /* From CN52XX manual */
usbn_clk_ctl.s.p_c_sel = 0;
}
/* 2c. Select the HCLK via writing USBN0/1_CLK_CTL[DIVIDE, DIVIDE2] and
setting USBN0/1_CLK_CTL[ENABLE] = 1. Divide the core clock down such
that USB is as close as possible to 125Mhz */
{
int divisor = (cvmx_clock_get_rate(CVMX_CLOCK_CORE)+125000000-1)/125000000;
if (divisor < 4) /* Lower than 4 doesn't seem to work properly */
divisor = 4;
usbn_clk_ctl.s.divide = divisor;
usbn_clk_ctl.s.divide2 = 0;
}
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
/* 2d. Write USBN0/1_CLK_CTL[HCLK_RST] = 1 */
usbn_clk_ctl.s.hclk_rst = 1;
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
/* 2e. Wait 64 core-clock cycles for HCLK to stabilize */
cvmx_wait(64);
/* 3. Program the power-on reset field in the USBN clock-control register:
USBN_CLK_CTL[POR] = 0 */
usbn_clk_ctl.s.por = 0;
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
/* 4. Wait 1 ms for PHY clock to start */
cvmx_wait_usec(1000);
/* 5. Program the Reset input from automatic test equipment field in the
USBP control and status register: USBN_USBP_CTL_STATUS[ATE_RESET] = 1 */
usbn_usbp_ctl_status.u64 = cvmx_read_csr(CVMX_USBNX_USBP_CTL_STATUS(usb->index));
usbn_usbp_ctl_status.s.ate_reset = 1;
cvmx_write_csr(CVMX_USBNX_USBP_CTL_STATUS(usb->index), usbn_usbp_ctl_status.u64);
/* 6. Wait 10 cycles */
cvmx_wait(10);
/* 7. Clear ATE_RESET field in the USBN clock-control register:
USBN_USBP_CTL_STATUS[ATE_RESET] = 0 */
usbn_usbp_ctl_status.s.ate_reset = 0;
cvmx_write_csr(CVMX_USBNX_USBP_CTL_STATUS(usb->index), usbn_usbp_ctl_status.u64);
/* 8. Program the PHY reset field in the USBN clock-control register:
USBN_CLK_CTL[PRST] = 1 */
usbn_clk_ctl.s.prst = 1;
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
/* 9. Program the USBP control and status register to select host or
device mode. USBN_USBP_CTL_STATUS[HST_MODE] = 0 for host, = 1 for
device */
usbn_usbp_ctl_status.s.hst_mode = 1;
usbn_usbp_ctl_status.s.dm_pulld = 0;
usbn_usbp_ctl_status.s.dp_pulld = 0;
cvmx_write_csr(CVMX_USBNX_USBP_CTL_STATUS(usb->index), usbn_usbp_ctl_status.u64);
/* 10. Wait 1 µs */
cvmx_wait_usec(1);
/* 11. Program the hreset_n field in the USBN clock-control register:
USBN_CLK_CTL[HRST] = 1 */
usbn_clk_ctl.s.hrst = 1;
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
/* 12. Proceed to USB core initialization */
usbn_clk_ctl.s.enable = 1;
cvmx_write_csr(CVMX_USBNX_CLK_CTL(usb->index), usbn_clk_ctl.u64);
cvmx_wait_usec(1);
/* Program the following fields in the global AHB configuration
register (USBC_GAHBCFG)
DMA mode, USBC_GAHBCFG[DMAEn]: 1 = DMA mode, 0 = slave mode
Burst length, USBC_GAHBCFG[HBSTLEN] = 0
Nonperiodic TxFIFO empty level (slave mode only),
USBC_GAHBCFG[NPTXFEMPLVL]
Periodic TxFIFO empty level (slave mode only),
USBC_GAHBCFG[PTXFEMPLVL]
Global interrupt mask, USBC_GAHBCFG[GLBLINTRMSK] = 1 */
{
cvmx_usbcx_gahbcfg_t usbcx_gahbcfg;
usbcx_gahbcfg.u32 = 0;
usbcx_gahbcfg.s.dmaen = 1;
usbcx_gahbcfg.s.hbstlen = 0;
usbcx_gahbcfg.s.nptxfemplvl = 1;
usbcx_gahbcfg.s.ptxfemplvl = 1;
usbcx_gahbcfg.s.glblintrmsk = 1;
__cvmx_usbd_write_csr32(usb, CVMX_USBCX_GAHBCFG(usb->index), usbcx_gahbcfg.u32);
}
/* Program the following fields in USBC_GUSBCFG register.
HS/FS timeout calibration, USBC_GUSBCFG[TOUTCAL] = 0
ULPI DDR select, USBC_GUSBCFG[DDRSEL] = 0
USB turnaround time, USBC_GUSBCFG[USBTRDTIM] = 0x5
PHY low-power clock select, USBC_GUSBCFG[PHYLPWRCLKSEL] = 0 */
{
cvmx_usbcx_gusbcfg_t usbcx_gusbcfg;
usbcx_gusbcfg.u32 = __cvmx_usbd_read_csr32(usb, CVMX_USBCX_GUSBCFG(usb->index));
usbcx_gusbcfg.s.toutcal = 0;
usbcx_gusbcfg.s.ddrsel = 0;
usbcx_gusbcfg.s.usbtrdtim = 0x5;
usbcx_gusbcfg.s.phylpwrclksel = 0;
__cvmx_usbd_write_csr32(usb, CVMX_USBCX_GUSBCFG(usb->index), usbcx_gusbcfg.u32);
}
/* Program the following fields in the USBC0/1_DCFG register:
Device speed, USBC0/1_DCFG[DEVSPD] = 0 (high speed)
Non-zero-length status OUT handshake, USBC0/1_DCFG[NZSTSOUTHSHK]=0
Periodic frame interval (if periodic endpoints are supported),
USBC0/1_DCFG[PERFRINT] = 1 */
{
cvmx_usbcx_dcfg_t usbcx_dcfg;
usbcx_dcfg.u32 = __cvmx_usbd_read_csr32(usb, CVMX_USBCX_DCFG(usb->index));
usbcx_dcfg.s.devspd = 0;
usbcx_dcfg.s.nzstsouthshk = 0;
usbcx_dcfg.s.perfrint = 1;
__cvmx_usbd_write_csr32(usb, CVMX_USBCX_DCFG(usb->index), usbcx_dcfg.u32);
}
/* Program the USBC0/1_GINTMSK register */
{
cvmx_usbcx_gintmsk_t usbcx_gintmsk;
usbcx_gintmsk.u32 = __cvmx_usbd_read_csr32(usb, CVMX_USBCX_GINTMSK(usb->index));
usbcx_gintmsk.s.oepintmsk = 1;
usbcx_gintmsk.s.inepintmsk = 1;
usbcx_gintmsk.s.enumdonemsk = 1;
usbcx_gintmsk.s.usbrstmsk = 1;
usbcx_gintmsk.s.usbsuspmsk = 1;
__cvmx_usbd_write_csr32(usb, CVMX_USBCX_GINTMSK(usb->index), usbcx_gintmsk.u32);
}
cvmx_usbd_disable(usb);
return 0;
}
static enum cvmx_qlm_mode __cvmx_qlm_get_mode_cn6xxx(int qlm)
{
cvmx_mio_qlmx_cfg_t qlmx_cfg;
if (OCTEON_IS_MODEL(OCTEON_CN68XX)) {
qlmx_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
/* QLM is disabled when QLM SPD is 15. */
if (qlmx_cfg.s.qlm_spd == 15)
return CVMX_QLM_MODE_DISABLED;
switch (qlmx_cfg.s.qlm_cfg) {
case 0: /* PCIE */
return CVMX_QLM_MODE_PCIE;
case 1: /* ILK */
return CVMX_QLM_MODE_ILK;
case 2: /* SGMII */
return CVMX_QLM_MODE_SGMII;
case 3: /* XAUI */
return CVMX_QLM_MODE_XAUI;
case 7: /* RXAUI */
return CVMX_QLM_MODE_RXAUI;
default:
return CVMX_QLM_MODE_DISABLED;
}
} else if (OCTEON_IS_MODEL(OCTEON_CN66XX)) {
qlmx_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
/* QLM is disabled when QLM SPD is 15. */
if (qlmx_cfg.s.qlm_spd == 15)
return CVMX_QLM_MODE_DISABLED;
switch (qlmx_cfg.s.qlm_cfg) {
case 0x9: /* SGMII */
return CVMX_QLM_MODE_SGMII;
case 0xb: /* XAUI */
return CVMX_QLM_MODE_XAUI;
case 0x0: /* PCIE gen2 */
case 0x8: /* PCIE gen2 (alias) */
case 0x2: /* PCIE gen1 */
case 0xa: /* PCIE gen1 (alias) */
return CVMX_QLM_MODE_PCIE;
case 0x1: /* SRIO 1x4 short */
case 0x3: /* SRIO 1x4 long */
return CVMX_QLM_MODE_SRIO_1X4;
case 0x4: /* SRIO 2x2 short */
case 0x6: /* SRIO 2x2 long */
return CVMX_QLM_MODE_SRIO_2X2;
case 0x5: /* SRIO 4x1 short */
case 0x7: /* SRIO 4x1 long */
if (!OCTEON_IS_MODEL(OCTEON_CN66XX_PASS1_0))
return CVMX_QLM_MODE_SRIO_4X1;
/* fallthrough */
default:
return CVMX_QLM_MODE_DISABLED;
}
} else if (OCTEON_IS_MODEL(OCTEON_CN63XX)) {
cvmx_sriox_status_reg_t status_reg;
/* For now skip qlm2 */
if (qlm == 2) {
cvmx_gmxx_inf_mode_t inf_mode;
inf_mode.u64 = cvmx_read_csr(CVMX_GMXX_INF_MODE(0));
if (inf_mode.s.speed == 15)
return CVMX_QLM_MODE_DISABLED;
else if (inf_mode.s.mode == 0)
return CVMX_QLM_MODE_SGMII;
else
return CVMX_QLM_MODE_XAUI;
}
status_reg.u64 = cvmx_read_csr(CVMX_SRIOX_STATUS_REG(qlm));
if (status_reg.s.srio)
return CVMX_QLM_MODE_SRIO_1X4;
else
return CVMX_QLM_MODE_PCIE;
} else if (OCTEON_IS_MODEL(OCTEON_CN61XX)) {
qlmx_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
/* QLM is disabled when QLM SPD is 15. */
if (qlmx_cfg.s.qlm_spd == 15)
return CVMX_QLM_MODE_DISABLED;
switch (qlm) {
case 0:
switch (qlmx_cfg.s.qlm_cfg) {
case 0: /* PCIe 1x4 gen2 / gen1 */
return CVMX_QLM_MODE_PCIE;
case 2: /* SGMII */
return CVMX_QLM_MODE_SGMII;
case 3: /* XAUI */
return CVMX_QLM_MODE_XAUI;
default:
return CVMX_QLM_MODE_DISABLED;
}
break;
case 1:
switch (qlmx_cfg.s.qlm_cfg) {
case 0: /* PCIe 1x2 gen2 / gen1 */
return CVMX_QLM_MODE_PCIE_1X2;
case 1: /* PCIe 2x1 gen2 / gen1 */
return CVMX_QLM_MODE_PCIE_2X1;
default:
return CVMX_QLM_MODE_DISABLED;
}
break;
case 2:
switch (qlmx_cfg.s.qlm_cfg) {
case 2: /* SGMII */
return CVMX_QLM_MODE_SGMII;
case 3: /* XAUI */
return CVMX_QLM_MODE_XAUI;
default:
return CVMX_QLM_MODE_DISABLED;
}
break;
}
} else if (OCTEON_IS_MODEL(OCTEON_CNF71XX)) {
qlmx_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
/* QLM is disabled when QLM SPD is 15. */
if (qlmx_cfg.s.qlm_spd == 15)
return CVMX_QLM_MODE_DISABLED;
switch (qlm) {
case 0:
if (qlmx_cfg.s.qlm_cfg == 2) /* SGMII */
return CVMX_QLM_MODE_SGMII;
break;
case 1:
switch (qlmx_cfg.s.qlm_cfg) {
case 0: /* PCIe 1x2 gen2 / gen1 */
return CVMX_QLM_MODE_PCIE_1X2;
case 1: /* PCIe 2x1 gen2 / gen1 */
return CVMX_QLM_MODE_PCIE_2X1;
default:
return CVMX_QLM_MODE_DISABLED;
}
break;
}
}
return CVMX_QLM_MODE_DISABLED;
}
//#define CVMX_ILK_STATS_ENA 1
int cvmx_ilk_enable (int interface)
{
int res = -1;
int retry_count = 0;
cvmx_helper_link_info_t result;
cvmx_ilk_txx_cfg1_t ilk_txx_cfg1;
cvmx_ilk_rxx_cfg1_t ilk_rxx_cfg1;
#ifdef CVMX_ILK_STATS_ENA
cvmx_ilk_rxx_cfg0_t ilk_rxx_cfg0;
cvmx_ilk_txx_cfg0_t ilk_txx_cfg0;
#endif
if (!(OCTEON_IS_MODEL(OCTEON_CN68XX)))
return res;
if (interface >= CVMX_NUM_ILK_INTF)
return res;
result.u64 = 0;
#ifdef CVMX_ILK_STATS_ENA
cvmx_dprintf ("\n");
cvmx_dprintf ("<<<< ILK%d: Before enabling ilk\n", interface);
cvmx_ilk_reg_dump_rx (interface);
cvmx_ilk_reg_dump_tx (interface);
#endif
/* RX packet will be enabled only if link is up */
/* TX side */
ilk_txx_cfg1.u64 = cvmx_read_csr (CVMX_ILK_TXX_CFG1(interface));
ilk_txx_cfg1.s.pkt_ena = 1;
ilk_txx_cfg1.s.rx_link_fc_ign = 1; /* cannot use link fc workaround */
cvmx_write_csr (CVMX_ILK_TXX_CFG1(interface), ilk_txx_cfg1.u64);
cvmx_read_csr (CVMX_ILK_TXX_CFG1(interface));
#ifdef CVMX_ILK_STATS_ENA
/* RX side stats */
ilk_rxx_cfg0.u64 = cvmx_read_csr (CVMX_ILK_RXX_CFG0(interface));
ilk_rxx_cfg0.s.lnk_stats_ena = 1;
cvmx_write_csr (CVMX_ILK_RXX_CFG0(interface), ilk_rxx_cfg0.u64);
/* TX side stats */
ilk_txx_cfg0.u64 = cvmx_read_csr (CVMX_ILK_TXX_CFG0(interface));
ilk_txx_cfg0.s.lnk_stats_ena = 1;
cvmx_write_csr (CVMX_ILK_TXX_CFG0(interface), ilk_txx_cfg0.u64);
#endif
retry:
retry_count++;
if (retry_count > 10)
goto out;
/* Make sure the link is up, so that packets can be sent. */
result = __cvmx_helper_ilk_link_get(cvmx_helper_get_ipd_port(interface + CVMX_ILK_GBL_BASE, 0));
/* Small delay before another retry. */
cvmx_wait_usec(100);
ilk_rxx_cfg1.u64 = cvmx_read_csr(CVMX_ILK_RXX_CFG1(interface));
if (ilk_rxx_cfg1.s.pkt_ena == 0)
goto retry;
out:
#ifdef CVMX_ILK_STATS_ENA
cvmx_dprintf (">>>> ILK%d: After ILK is enabled\n", interface);
cvmx_ilk_reg_dump_rx (interface);
cvmx_ilk_reg_dump_tx (interface);
#endif
if (result.s.link_up)
return 0;
return -1;
}
static int octeon_mgmt_open(struct net_device *netdev)
{
struct octeon_mgmt *p = netdev_priv(netdev);
union cvmx_mixx_ctl mix_ctl;
union cvmx_agl_gmx_inf_mode agl_gmx_inf_mode;
union cvmx_mixx_oring1 oring1;
union cvmx_mixx_iring1 iring1;
union cvmx_agl_gmx_rxx_frm_ctl rxx_frm_ctl;
union cvmx_mixx_irhwm mix_irhwm;
union cvmx_mixx_orhwm mix_orhwm;
union cvmx_mixx_intena mix_intena;
struct sockaddr sa;
/* Allocate ring buffers. */
p->tx_ring = kzalloc(ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
GFP_KERNEL);
if (!p->tx_ring)
return -ENOMEM;
p->tx_ring_handle =
dma_map_single(p->dev, p->tx_ring,
ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
DMA_BIDIRECTIONAL);
p->tx_next = 0;
p->tx_next_clean = 0;
p->tx_current_fill = 0;
p->rx_ring = kzalloc(ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
GFP_KERNEL);
if (!p->rx_ring)
goto err_nomem;
p->rx_ring_handle =
dma_map_single(p->dev, p->rx_ring,
ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
DMA_BIDIRECTIONAL);
p->rx_next = 0;
p->rx_next_fill = 0;
p->rx_current_fill = 0;
octeon_mgmt_reset_hw(p);
mix_ctl.u64 = cvmx_read_csr(p->mix + MIX_CTL);
/* Bring it out of reset if needed. */
if (mix_ctl.s.reset) {
mix_ctl.s.reset = 0;
cvmx_write_csr(p->mix + MIX_CTL, mix_ctl.u64);
do {
mix_ctl.u64 = cvmx_read_csr(p->mix + MIX_CTL);
} while (mix_ctl.s.reset);
}
if (OCTEON_IS_MODEL(OCTEON_CN5XXX)) {
agl_gmx_inf_mode.u64 = 0;
agl_gmx_inf_mode.s.en = 1;
cvmx_write_csr(CVMX_AGL_GMX_INF_MODE, agl_gmx_inf_mode.u64);
}
if (OCTEON_IS_MODEL(OCTEON_CN56XX_PASS1_X)
|| OCTEON_IS_MODEL(OCTEON_CN52XX_PASS1_X)) {
/* Force compensation values, as they are not
* determined properly by HW
*/
union cvmx_agl_gmx_drv_ctl drv_ctl;
drv_ctl.u64 = cvmx_read_csr(CVMX_AGL_GMX_DRV_CTL);
if (p->port) {
drv_ctl.s.byp_en1 = 1;
drv_ctl.s.nctl1 = 6;
drv_ctl.s.pctl1 = 6;
} else {
drv_ctl.s.byp_en = 1;
drv_ctl.s.nctl = 6;
drv_ctl.s.pctl = 6;
}
cvmx_write_csr(CVMX_AGL_GMX_DRV_CTL, drv_ctl.u64);
}
oring1.u64 = 0;
oring1.s.obase = p->tx_ring_handle >> 3;
oring1.s.osize = OCTEON_MGMT_TX_RING_SIZE;
cvmx_write_csr(p->mix + MIX_ORING1, oring1.u64);
iring1.u64 = 0;
iring1.s.ibase = p->rx_ring_handle >> 3;
iring1.s.isize = OCTEON_MGMT_RX_RING_SIZE;
cvmx_write_csr(p->mix + MIX_IRING1, iring1.u64);
memcpy(sa.sa_data, netdev->dev_addr, ETH_ALEN);
octeon_mgmt_set_mac_address(netdev, &sa);
octeon_mgmt_change_mtu(netdev, netdev->mtu);
/* Enable the port HW. Packets are not allowed until
* cvmx_mgmt_port_enable() is called.
*/
mix_ctl.u64 = 0;
mix_ctl.s.crc_strip = 1; /* Strip the ending CRC */
mix_ctl.s.en = 1; /* Enable the port */
mix_ctl.s.nbtarb = 0; /* Arbitration mode */
/* MII CB-request FIFO programmable high watermark */
mix_ctl.s.mrq_hwm = 1;
#ifdef __LITTLE_ENDIAN
mix_ctl.s.lendian = 1;
#endif
cvmx_write_csr(p->mix + MIX_CTL, mix_ctl.u64);
/* Read the PHY to find the mode of the interface. */
if (octeon_mgmt_init_phy(netdev)) {
dev_err(p->dev, "Cannot initialize PHY on MIX%d.\n", p->port);
goto err_noirq;
}
/* Set the mode of the interface, RGMII/MII. */
if (OCTEON_IS_MODEL(OCTEON_CN6XXX) && netdev->phydev) {
union cvmx_agl_prtx_ctl agl_prtx_ctl;
int rgmii_mode = (netdev->phydev->supported &
(SUPPORTED_1000baseT_Half | SUPPORTED_1000baseT_Full)) != 0;
agl_prtx_ctl.u64 = cvmx_read_csr(p->agl_prt_ctl);
agl_prtx_ctl.s.mode = rgmii_mode ? 0 : 1;
cvmx_write_csr(p->agl_prt_ctl, agl_prtx_ctl.u64);
/* MII clocks counts are based on the 125Mhz
* reference, which has an 8nS period. So our delays
* need to be multiplied by this factor.
*/
#define NS_PER_PHY_CLK 8
/* Take the DLL and clock tree out of reset */
agl_prtx_ctl.u64 = cvmx_read_csr(p->agl_prt_ctl);
agl_prtx_ctl.s.clkrst = 0;
if (rgmii_mode) {
agl_prtx_ctl.s.dllrst = 0;
agl_prtx_ctl.s.clktx_byp = 0;
}
cvmx_write_csr(p->agl_prt_ctl, agl_prtx_ctl.u64);
cvmx_read_csr(p->agl_prt_ctl); /* Force write out before wait */
/* Wait for the DLL to lock. External 125 MHz
* reference clock must be stable at this point.
*/
ndelay(256 * NS_PER_PHY_CLK);
/* Enable the interface */
agl_prtx_ctl.u64 = cvmx_read_csr(p->agl_prt_ctl);
agl_prtx_ctl.s.enable = 1;
cvmx_write_csr(p->agl_prt_ctl, agl_prtx_ctl.u64);
/* Read the value back to force the previous write */
agl_prtx_ctl.u64 = cvmx_read_csr(p->agl_prt_ctl);
/* Enable the compensation controller */
agl_prtx_ctl.s.comp = 1;
agl_prtx_ctl.s.drv_byp = 0;
cvmx_write_csr(p->agl_prt_ctl, agl_prtx_ctl.u64);
/* Force write out before wait. */
cvmx_read_csr(p->agl_prt_ctl);
/* For compensation state to lock. */
ndelay(1040 * NS_PER_PHY_CLK);
/* Default Interframe Gaps are too small. Recommended
* workaround is.
*
* AGL_GMX_TX_IFG[IFG1]=14
* AGL_GMX_TX_IFG[IFG2]=10
*/
cvmx_write_csr(CVMX_AGL_GMX_TX_IFG, 0xae);
}
octeon_mgmt_rx_fill_ring(netdev);
/* Clear statistics. */
/* Clear on read. */
cvmx_write_csr(p->agl + AGL_GMX_RX_STATS_CTL, 1);
cvmx_write_csr(p->agl + AGL_GMX_RX_STATS_PKTS_DRP, 0);
cvmx_write_csr(p->agl + AGL_GMX_RX_STATS_PKTS_BAD, 0);
cvmx_write_csr(p->agl + AGL_GMX_TX_STATS_CTL, 1);
cvmx_write_csr(p->agl + AGL_GMX_TX_STAT0, 0);
cvmx_write_csr(p->agl + AGL_GMX_TX_STAT1, 0);
/* Clear any pending interrupts */
cvmx_write_csr(p->mix + MIX_ISR, cvmx_read_csr(p->mix + MIX_ISR));
if (request_irq(p->irq, octeon_mgmt_interrupt, 0, netdev->name,
netdev)) {
dev_err(p->dev, "request_irq(%d) failed.\n", p->irq);
goto err_noirq;
}
/* Interrupt every single RX packet */
mix_irhwm.u64 = 0;
mix_irhwm.s.irhwm = 0;
cvmx_write_csr(p->mix + MIX_IRHWM, mix_irhwm.u64);
/* Interrupt when we have 1 or more packets to clean. */
mix_orhwm.u64 = 0;
mix_orhwm.s.orhwm = 0;
cvmx_write_csr(p->mix + MIX_ORHWM, mix_orhwm.u64);
/* Enable receive and transmit interrupts */
mix_intena.u64 = 0;
mix_intena.s.ithena = 1;
mix_intena.s.othena = 1;
cvmx_write_csr(p->mix + MIX_INTENA, mix_intena.u64);
/* Enable packet I/O. */
rxx_frm_ctl.u64 = 0;
rxx_frm_ctl.s.ptp_mode = p->has_rx_tstamp ? 1 : 0;
rxx_frm_ctl.s.pre_align = 1;
/* When set, disables the length check for non-min sized pkts
* with padding in the client data.
*/
rxx_frm_ctl.s.pad_len = 1;
/* When set, disables the length check for VLAN pkts */
rxx_frm_ctl.s.vlan_len = 1;
/* When set, PREAMBLE checking is less strict */
rxx_frm_ctl.s.pre_free = 1;
/* Control Pause Frames can match station SMAC */
rxx_frm_ctl.s.ctl_smac = 0;
/* Control Pause Frames can match globally assign Multicast address */
rxx_frm_ctl.s.ctl_mcst = 1;
/* Forward pause information to TX block */
rxx_frm_ctl.s.ctl_bck = 1;
/* Drop Control Pause Frames */
rxx_frm_ctl.s.ctl_drp = 1;
/* Strip off the preamble */
rxx_frm_ctl.s.pre_strp = 1;
/* This port is configured to send PREAMBLE+SFD to begin every
* frame. GMX checks that the PREAMBLE is sent correctly.
*/
rxx_frm_ctl.s.pre_chk = 1;
cvmx_write_csr(p->agl + AGL_GMX_RX_FRM_CTL, rxx_frm_ctl.u64);
/* Configure the port duplex, speed and enables */
octeon_mgmt_disable_link(p);
if (netdev->phydev)
octeon_mgmt_update_link(p);
octeon_mgmt_enable_link(p);
p->last_link = 0;
p->last_speed = 0;
/* PHY is not present in simulator. The carrier is enabled
* while initializing the phy for simulator, leave it enabled.
*/
if (netdev->phydev) {
netif_carrier_off(netdev);
phy_start_aneg(netdev->phydev);
}
netif_wake_queue(netdev);
napi_enable(&p->napi);
return 0;
err_noirq:
octeon_mgmt_reset_hw(p);
dma_unmap_single(p->dev, p->rx_ring_handle,
ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
DMA_BIDIRECTIONAL);
kfree(p->rx_ring);
err_nomem:
dma_unmap_single(p->dev, p->tx_ring_handle,
ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
DMA_BIDIRECTIONAL);
kfree(p->tx_ring);
return -ENOMEM;
}
int cvmx_spi_reset_cb(int interface, cvmx_spi_mode_t mode)
{
union cvmx_spxx_dbg_deskew_ctl spxx_dbg_deskew_ctl;
union cvmx_spxx_clk_ctl spxx_clk_ctl;
union cvmx_spxx_bist_stat spxx_bist_stat;
union cvmx_spxx_int_msk spxx_int_msk;
union cvmx_stxx_int_msk stxx_int_msk;
union cvmx_spxx_trn4_ctl spxx_trn4_ctl;
int index;
uint64_t MS = cvmx_sysinfo_get()->cpu_clock_hz / 1000;
spxx_int_msk.u64 = cvmx_read_csr(CVMX_SPXX_INT_MSK(interface));
cvmx_write_csr(CVMX_SPXX_INT_MSK(interface), 0);
stxx_int_msk.u64 = cvmx_read_csr(CVMX_STXX_INT_MSK(interface));
cvmx_write_csr(CVMX_STXX_INT_MSK(interface), 0);
cvmx_write_csr(CVMX_SRXX_COM_CTL(interface), 0);
cvmx_write_csr(CVMX_STXX_COM_CTL(interface), 0);
spxx_clk_ctl.u64 = 0;
spxx_clk_ctl.s.runbist = 1;
cvmx_write_csr(CVMX_SPXX_CLK_CTL(interface), spxx_clk_ctl.u64);
cvmx_wait(10 * MS);
spxx_bist_stat.u64 = cvmx_read_csr(CVMX_SPXX_BIST_STAT(interface));
if (spxx_bist_stat.s.stat0)
cvmx_dprintf
("ERROR SPI%d: BIST failed on receive datapath FIFO\n",
interface);
if (spxx_bist_stat.s.stat1)
cvmx_dprintf("ERROR SPI%d: BIST failed on RX calendar table\n",
interface);
if (spxx_bist_stat.s.stat2)
cvmx_dprintf("ERROR SPI%d: BIST failed on TX calendar table\n",
interface);
for (index = 0; index < 32; index++) {
union cvmx_srxx_spi4_calx srxx_spi4_calx;
union cvmx_stxx_spi4_calx stxx_spi4_calx;
srxx_spi4_calx.u64 = 0;
srxx_spi4_calx.s.oddpar = 1;
cvmx_write_csr(CVMX_SRXX_SPI4_CALX(index, interface),
srxx_spi4_calx.u64);
stxx_spi4_calx.u64 = 0;
stxx_spi4_calx.s.oddpar = 1;
cvmx_write_csr(CVMX_STXX_SPI4_CALX(index, interface),
stxx_spi4_calx.u64);
}
cvmx_write_csr(CVMX_SPXX_INT_REG(interface),
cvmx_read_csr(CVMX_SPXX_INT_REG(interface)));
cvmx_write_csr(CVMX_SPXX_INT_MSK(interface), spxx_int_msk.u64);
cvmx_write_csr(CVMX_STXX_INT_REG(interface),
cvmx_read_csr(CVMX_STXX_INT_REG(interface)));
cvmx_write_csr(CVMX_STXX_INT_MSK(interface), stxx_int_msk.u64);
spxx_clk_ctl.u64 = 0;
spxx_clk_ctl.s.seetrn = 0;
spxx_clk_ctl.s.clkdly = 0x10;
spxx_clk_ctl.s.runbist = 0;
spxx_clk_ctl.s.statdrv = 0;
spxx_clk_ctl.s.statrcv = 1;
spxx_clk_ctl.s.sndtrn = 0;
spxx_clk_ctl.s.drptrn = 0;
spxx_clk_ctl.s.rcvtrn = 0;
spxx_clk_ctl.s.srxdlck = 0;
cvmx_write_csr(CVMX_SPXX_CLK_CTL(interface), spxx_clk_ctl.u64);
cvmx_wait(100 * MS);
spxx_clk_ctl.s.srxdlck = 1;
cvmx_write_csr(CVMX_SPXX_CLK_CTL(interface), spxx_clk_ctl.u64);
cvmx_wait(100 * MS);
spxx_trn4_ctl.s.trntest = 0;
spxx_trn4_ctl.s.jitter = 1;
spxx_trn4_ctl.s.clr_boot = 1;
spxx_trn4_ctl.s.set_boot = 0;
if (OCTEON_IS_MODEL(OCTEON_CN58XX))
spxx_trn4_ctl.s.maxdist = 3;
else
spxx_trn4_ctl.s.maxdist = 8;
spxx_trn4_ctl.s.macro_en = 1;
spxx_trn4_ctl.s.mux_en = 1;
cvmx_write_csr(CVMX_SPXX_TRN4_CTL(interface), spxx_trn4_ctl.u64);
spxx_dbg_deskew_ctl.u64 = 0;
cvmx_write_csr(CVMX_SPXX_DBG_DESKEW_CTL(interface),
spxx_dbg_deskew_ctl.u64);
return 0;
}
static int octeon_mgmt_ioctl_hwtstamp(struct net_device *netdev,
struct ifreq *rq, int cmd)
{
struct octeon_mgmt *p = netdev_priv(netdev);
struct hwtstamp_config config;
union cvmx_mio_ptp_clock_cfg ptp;
union cvmx_agl_gmx_rxx_frm_ctl rxx_frm_ctl;
bool have_hw_timestamps = false;
if (copy_from_user(&config, rq->ifr_data, sizeof(config)))
return -EFAULT;
if (config.flags) /* reserved for future extensions */
return -EINVAL;
/* Check the status of hardware for tiemstamps */
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
/* Get the current state of the PTP clock */
ptp.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG);
if (!ptp.s.ext_clk_en) {
/* The clock has not been configured to use an
* external source. Program it to use the main clock
* reference.
*/
u64 clock_comp = (NSEC_PER_SEC << 32) / octeon_get_io_clock_rate();
if (!ptp.s.ptp_en)
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_COMP, clock_comp);
netdev_info(netdev,
"PTP Clock using sclk reference @ %lldHz\n",
(NSEC_PER_SEC << 32) / clock_comp);
} else {
/* The clock is already programmed to use a GPIO */
u64 clock_comp = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_COMP);
netdev_info(netdev,
"PTP Clock using GPIO%d @ %lld Hz\n",
ptp.s.ext_clk_in, (NSEC_PER_SEC << 32) / clock_comp);
}
/* Enable the clock if it wasn't done already */
if (!ptp.s.ptp_en) {
ptp.s.ptp_en = 1;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp.u64);
}
have_hw_timestamps = true;
}
if (!have_hw_timestamps)
return -EINVAL;
switch (config.tx_type) {
case HWTSTAMP_TX_OFF:
case HWTSTAMP_TX_ON:
break;
default:
return -ERANGE;
}
switch (config.rx_filter) {
case HWTSTAMP_FILTER_NONE:
p->has_rx_tstamp = false;
rxx_frm_ctl.u64 = cvmx_read_csr(p->agl + AGL_GMX_RX_FRM_CTL);
rxx_frm_ctl.s.ptp_mode = 0;
cvmx_write_csr(p->agl + AGL_GMX_RX_FRM_CTL, rxx_frm_ctl.u64);
break;
case HWTSTAMP_FILTER_ALL:
case HWTSTAMP_FILTER_SOME:
case HWTSTAMP_FILTER_PTP_V1_L4_EVENT:
case HWTSTAMP_FILTER_PTP_V1_L4_SYNC:
case HWTSTAMP_FILTER_PTP_V1_L4_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_L4_EVENT:
case HWTSTAMP_FILTER_PTP_V2_L4_SYNC:
case HWTSTAMP_FILTER_PTP_V2_L4_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_L2_EVENT:
case HWTSTAMP_FILTER_PTP_V2_L2_SYNC:
case HWTSTAMP_FILTER_PTP_V2_L2_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_EVENT:
case HWTSTAMP_FILTER_PTP_V2_SYNC:
case HWTSTAMP_FILTER_PTP_V2_DELAY_REQ:
case HWTSTAMP_FILTER_NTP_ALL:
p->has_rx_tstamp = have_hw_timestamps;
config.rx_filter = HWTSTAMP_FILTER_ALL;
if (p->has_rx_tstamp) {
rxx_frm_ctl.u64 = cvmx_read_csr(p->agl + AGL_GMX_RX_FRM_CTL);
rxx_frm_ctl.s.ptp_mode = 1;
cvmx_write_csr(p->agl + AGL_GMX_RX_FRM_CTL, rxx_frm_ctl.u64);
}
break;
default:
return -ERANGE;
}
if (copy_to_user(rq->ifr_data, &config, sizeof(config)))
return -EFAULT;
return 0;
}
static void octeon_mgmt_update_link(struct octeon_mgmt *p)
{
struct net_device *ndev = p->netdev;
struct phy_device *phydev = ndev->phydev;
union cvmx_agl_gmx_prtx_cfg prtx_cfg;
prtx_cfg.u64 = cvmx_read_csr(p->agl + AGL_GMX_PRT_CFG);
if (!phydev->link)
prtx_cfg.s.duplex = 1;
else
prtx_cfg.s.duplex = phydev->duplex;
switch (phydev->speed) {
case 10:
prtx_cfg.s.speed = 0;
prtx_cfg.s.slottime = 0;
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
prtx_cfg.s.burst = 1;
prtx_cfg.s.speed_msb = 1;
}
break;
case 100:
prtx_cfg.s.speed = 0;
prtx_cfg.s.slottime = 0;
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
prtx_cfg.s.burst = 1;
prtx_cfg.s.speed_msb = 0;
}
break;
case 1000:
/* 1000 MBits is only supported on 6XXX chips */
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
prtx_cfg.s.speed = 1;
prtx_cfg.s.speed_msb = 0;
/* Only matters for half-duplex */
prtx_cfg.s.slottime = 1;
prtx_cfg.s.burst = phydev->duplex;
}
break;
case 0: /* No link */
default:
break;
}
/* Write the new GMX setting with the port still disabled. */
cvmx_write_csr(p->agl + AGL_GMX_PRT_CFG, prtx_cfg.u64);
/* Read GMX CFG again to make sure the config is completed. */
prtx_cfg.u64 = cvmx_read_csr(p->agl + AGL_GMX_PRT_CFG);
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
union cvmx_agl_gmx_txx_clk agl_clk;
union cvmx_agl_prtx_ctl prtx_ctl;
prtx_ctl.u64 = cvmx_read_csr(p->agl_prt_ctl);
agl_clk.u64 = cvmx_read_csr(p->agl + AGL_GMX_TX_CLK);
/* MII (both speeds) and RGMII 1000 speed. */
agl_clk.s.clk_cnt = 1;
if (prtx_ctl.s.mode == 0) { /* RGMII mode */
if (phydev->speed == 10)
agl_clk.s.clk_cnt = 50;
else if (phydev->speed == 100)
agl_clk.s.clk_cnt = 5;
}
cvmx_write_csr(p->agl + AGL_GMX_TX_CLK, agl_clk.u64);
}
}
/**
* Configure a output port and the associated queues for use.
*
* @port: Port to configure.
* @base_queue: First queue number to associate with this port.
* @num_queues: Number of queues to associate with this port
* @priority: Array of priority levels for each queue. Values are
* allowed to be 0-8. A value of 8 get 8 times the traffic
* of a value of 1. A value of 0 indicates that no rounds
* will be participated in. These priorities can be changed
* on the fly while the pko is enabled. A priority of 9
* indicates that static priority should be used. If static
* priority is used all queues with static priority must be
* contiguous starting at the base_queue, and lower numbered
* queues have higher priority than higher numbered queues.
* There must be num_queues elements in the array.
*/
cvmx_pko_status_t cvmx_pko_config_port(uint64_t port, uint64_t base_queue,
uint64_t num_queues,
const uint64_t priority[])
{
cvmx_pko_status_t result_code;
uint64_t queue;
union cvmx_pko_mem_queue_ptrs config;
union cvmx_pko_reg_queue_ptrs1 config1;
int static_priority_base = -1;
int static_priority_end = -1;
if ((port >= CVMX_PKO_NUM_OUTPUT_PORTS)
&& (port != CVMX_PKO_MEM_QUEUE_PTRS_ILLEGAL_PID)) {
cvmx_dprintf("ERROR: cvmx_pko_config_port: Invalid port %llu\n",
(unsigned long long)port);
return CVMX_PKO_INVALID_PORT;
}
if (base_queue + num_queues > CVMX_PKO_MAX_OUTPUT_QUEUES) {
cvmx_dprintf
("ERROR: cvmx_pko_config_port: Invalid queue range %llu\n",
(unsigned long long)(base_queue + num_queues));
return CVMX_PKO_INVALID_QUEUE;
}
if (port != CVMX_PKO_MEM_QUEUE_PTRS_ILLEGAL_PID) {
/*
* Validate the static queue priority setup and set
* static_priority_base and static_priority_end
* accordingly.
*/
for (queue = 0; queue < num_queues; queue++) {
/* Find first queue of static priority */
if (static_priority_base == -1
&& priority[queue] ==
CVMX_PKO_QUEUE_STATIC_PRIORITY)
static_priority_base = queue;
/* Find last queue of static priority */
if (static_priority_base != -1
&& static_priority_end == -1
&& priority[queue] != CVMX_PKO_QUEUE_STATIC_PRIORITY
&& queue)
static_priority_end = queue - 1;
else if (static_priority_base != -1
&& static_priority_end == -1
&& queue == num_queues - 1)
/* all queues are static priority */
static_priority_end = queue;
/*
* Check to make sure all static priority
* queues are contiguous. Also catches some
* cases of static priorites not starting at
* queue 0.
*/
if (static_priority_end != -1
&& (int)queue > static_priority_end
&& priority[queue] ==
CVMX_PKO_QUEUE_STATIC_PRIORITY) {
cvmx_dprintf("ERROR: cvmx_pko_config_port: "
"Static priority queues aren't "
"contiguous or don't start at "
"base queue. q: %d, eq: %d\n",
(int)queue, static_priority_end);
return CVMX_PKO_INVALID_PRIORITY;
}
}
if (static_priority_base > 0) {
cvmx_dprintf("ERROR: cvmx_pko_config_port: Static "
"priority queues don't start at base "
"queue. sq: %d\n",
static_priority_base);
return CVMX_PKO_INVALID_PRIORITY;
}
#if 0
cvmx_dprintf("Port %d: Static priority queue base: %d, "
"end: %d\n", port,
static_priority_base, static_priority_end);
#endif
}
/*
* At this point, static_priority_base and static_priority_end
* are either both -1, or are valid start/end queue
* numbers.
*/
result_code = CVMX_PKO_SUCCESS;
#ifdef PKO_DEBUG
cvmx_dprintf("num queues: %d (%lld,%lld)\n", num_queues,
CVMX_PKO_QUEUES_PER_PORT_INTERFACE0,
CVMX_PKO_QUEUES_PER_PORT_INTERFACE1);
#endif
for (queue = 0; queue < num_queues; queue++) {
uint64_t *buf_ptr = NULL;
config1.u64 = 0;
config1.s.idx3 = queue >> 3;
config1.s.qid7 = (base_queue + queue) >> 7;
config.u64 = 0;
config.s.tail = queue == (num_queues - 1);
config.s.index = queue;
config.s.port = port;
config.s.queue = base_queue + queue;
if (!cvmx_octeon_is_pass1()) {
config.s.static_p = static_priority_base >= 0;
config.s.static_q = (int)queue <= static_priority_end;
config.s.s_tail = (int)queue == static_priority_end;
}
/*
* Convert the priority into an enable bit field. Try
* to space the bits out evenly so the packet don't
* get grouped up
*/
switch ((int)priority[queue]) {
case 0:
config.s.qos_mask = 0x00;
break;
case 1:
config.s.qos_mask = 0x01;
break;
case 2:
config.s.qos_mask = 0x11;
break;
case 3:
config.s.qos_mask = 0x49;
break;
case 4:
config.s.qos_mask = 0x55;
break;
case 5:
config.s.qos_mask = 0x57;
break;
case 6:
config.s.qos_mask = 0x77;
break;
case 7:
config.s.qos_mask = 0x7f;
break;
case 8:
config.s.qos_mask = 0xff;
break;
case CVMX_PKO_QUEUE_STATIC_PRIORITY:
/* Pass 1 will fall through to the error case */
if (!cvmx_octeon_is_pass1()) {
config.s.qos_mask = 0xff;
break;
}
default:
cvmx_dprintf("ERROR: cvmx_pko_config_port: Invalid "
"priority %llu\n",
(unsigned long long)priority[queue]);
config.s.qos_mask = 0xff;
result_code = CVMX_PKO_INVALID_PRIORITY;
break;
}
if (port != CVMX_PKO_MEM_QUEUE_PTRS_ILLEGAL_PID) {
cvmx_cmd_queue_result_t cmd_res =
cvmx_cmd_queue_initialize(CVMX_CMD_QUEUE_PKO
(base_queue + queue),
CVMX_PKO_MAX_QUEUE_DEPTH,
CVMX_FPA_OUTPUT_BUFFER_POOL,
CVMX_FPA_OUTPUT_BUFFER_POOL_SIZE
-
CVMX_PKO_COMMAND_BUFFER_SIZE_ADJUST
* 8);
if (cmd_res != CVMX_CMD_QUEUE_SUCCESS) {
switch (cmd_res) {
case CVMX_CMD_QUEUE_NO_MEMORY:
cvmx_dprintf("ERROR: "
"cvmx_pko_config_port: "
"Unable to allocate "
"output buffer.\n");
return CVMX_PKO_NO_MEMORY;
case CVMX_CMD_QUEUE_ALREADY_SETUP:
cvmx_dprintf
("ERROR: cvmx_pko_config_port: Port already setup.\n");
return CVMX_PKO_PORT_ALREADY_SETUP;
case CVMX_CMD_QUEUE_INVALID_PARAM:
default:
cvmx_dprintf
("ERROR: cvmx_pko_config_port: Command queue initialization failed.\n");
return CVMX_PKO_CMD_QUEUE_INIT_ERROR;
}
}
buf_ptr =
(uint64_t *)
cvmx_cmd_queue_buffer(CVMX_CMD_QUEUE_PKO
(base_queue + queue));
config.s.buf_ptr = cvmx_ptr_to_phys(buf_ptr);
} else
config.s.buf_ptr = 0;
CVMX_SYNCWS;
if (!OCTEON_IS_MODEL(OCTEON_CN3XXX))
cvmx_write_csr(CVMX_PKO_REG_QUEUE_PTRS1, config1.u64);
cvmx_write_csr(CVMX_PKO_MEM_QUEUE_PTRS, config.u64);
}
return result_code;
}
/**
* cvm_oct_ioctl_hwtstamp - IOCTL support for timestamping
* @dev: Device to change
* @rq: the request
* @cmd: the command
*
* Returns Zero on success
*/
static int cvm_oct_ioctl_hwtstamp(struct net_device *dev,
struct ifreq *rq, int cmd)
{
struct octeon_ethernet *priv = netdev_priv(dev);
struct hwtstamp_config config;
union cvmx_mio_ptp_clock_cfg ptp;
int have_hw_timestamps = 0;
if (copy_from_user(&config, rq->ifr_data, sizeof(config)))
return -EFAULT;
if (config.flags) /* reserved for future extensions */
return -EINVAL;
/* Check the status of hardware for tiemstamps */
if (OCTEON_IS_MODEL(OCTEON_CN6XXX)) {
/* Write TX timestamp into word 4 */
cvmx_write_csr(CVMX_PKO_REG_TIMESTAMP, 4);
/* Get the current state of the PTP clock */
ptp.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG);
if (!ptp.s.ext_clk_en) {
/*
* The clock has not been configured to use an
* external source. Program it to use the main clock
* reference.
*/
unsigned long long clock_comp = (NSEC_PER_SEC << 32) /
octeon_get_io_clock_rate();
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_COMP, clock_comp);
pr_info("PTP Clock: Using sclk reference at %lld Hz\n",
(NSEC_PER_SEC << 32) / clock_comp);
} else {
/* The clock is already programmed to use a GPIO */
unsigned long long clock_comp = cvmx_read_csr(
CVMX_MIO_PTP_CLOCK_COMP);
pr_info("PTP Clock: Using GPIO %d at %lld Hz\n",
ptp.s.ext_clk_in,
(NSEC_PER_SEC << 32) / clock_comp);
}
/* Enable the clock if it wasn't done already */
if (!ptp.s.ptp_en) {
ptp.s.ptp_en = 1;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp.u64);
}
have_hw_timestamps = 1;
/* Only the first two interfaces support hardware timestamps */
if (priv->port >= 32)
have_hw_timestamps = 0;
}
/* Require hardware if ALLOW_TIMESTAMPS_WITHOUT_HARDWARE=0 */
if (!ALLOW_TIMESTAMPS_WITHOUT_HARDWARE && !have_hw_timestamps)
return -EINVAL;
switch (config.tx_type) {
case HWTSTAMP_TX_OFF:
priv->flags &= ~(OCTEON_ETHERNET_FLAG_TX_TIMESTAMP_SW |
OCTEON_ETHERNET_FLAG_TX_TIMESTAMP_HW);
break;
case HWTSTAMP_TX_ON:
priv->flags |= (have_hw_timestamps) ?
OCTEON_ETHERNET_FLAG_TX_TIMESTAMP_HW :
OCTEON_ETHERNET_FLAG_TX_TIMESTAMP_SW;
break;
default:
return -ERANGE;
}
switch (config.rx_filter) {
case HWTSTAMP_FILTER_NONE:
priv->flags &= ~(OCTEON_ETHERNET_FLAG_RX_TIMESTAMP_HW |
OCTEON_ETHERNET_FLAG_RX_TIMESTAMP_SW);
if (have_hw_timestamps) {
int interface = INTERFACE(priv->port);
int index = INDEX(priv->port);
union cvmx_gmxx_rxx_frm_ctl gmxx_rxx_frm_ctl;
union cvmx_pip_prt_cfgx pip_prt_cfgx;
gmxx_rxx_frm_ctl.u64 = cvmx_read_csr(CVMX_GMXX_RXX_FRM_CTL(index, interface));
gmxx_rxx_frm_ctl.s.ptp_mode = 0;
cvmx_write_csr(CVMX_GMXX_RXX_FRM_CTL(index, interface), gmxx_rxx_frm_ctl.u64);
pip_prt_cfgx.u64 = cvmx_read_csr(CVMX_PIP_PRT_CFGX(priv->port));
pip_prt_cfgx.s.skip = 0;
cvmx_write_csr(CVMX_PIP_PRT_CFGX(priv->port), pip_prt_cfgx.u64);
}
break;
case HWTSTAMP_FILTER_ALL:
case HWTSTAMP_FILTER_SOME:
case HWTSTAMP_FILTER_PTP_V1_L4_EVENT:
case HWTSTAMP_FILTER_PTP_V1_L4_SYNC:
case HWTSTAMP_FILTER_PTP_V1_L4_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_L4_EVENT:
case HWTSTAMP_FILTER_PTP_V2_L4_SYNC:
case HWTSTAMP_FILTER_PTP_V2_L4_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_L2_EVENT:
case HWTSTAMP_FILTER_PTP_V2_L2_SYNC:
case HWTSTAMP_FILTER_PTP_V2_L2_DELAY_REQ:
case HWTSTAMP_FILTER_PTP_V2_EVENT:
case HWTSTAMP_FILTER_PTP_V2_SYNC:
case HWTSTAMP_FILTER_PTP_V2_DELAY_REQ:
priv->flags |= (have_hw_timestamps) ?
OCTEON_ETHERNET_FLAG_RX_TIMESTAMP_HW :
OCTEON_ETHERNET_FLAG_RX_TIMESTAMP_SW;
config.rx_filter = HWTSTAMP_FILTER_ALL;
if (have_hw_timestamps) {
int interface = INTERFACE(priv->port);
int index = INDEX(priv->port);
union cvmx_gmxx_rxx_frm_ctl gmxx_rxx_frm_ctl;
union cvmx_pip_prt_cfgx pip_prt_cfgx;
gmxx_rxx_frm_ctl.u64 = cvmx_read_csr(CVMX_GMXX_RXX_FRM_CTL(index, interface));
gmxx_rxx_frm_ctl.s.ptp_mode = 1;
cvmx_write_csr(CVMX_GMXX_RXX_FRM_CTL(index, interface), gmxx_rxx_frm_ctl.u64);
pip_prt_cfgx.u64 = cvmx_read_csr(CVMX_PIP_PRT_CFGX(priv->port));
pip_prt_cfgx.s.skip = 8;
cvmx_write_csr(CVMX_PIP_PRT_CFGX(priv->port), pip_prt_cfgx.u64);
}
break;
default:
return -ERANGE;
}
if (copy_to_user(rq->ifr_data, &config, sizeof(config)))
return -EFAULT;
return 0;
}
/**
* @INTERNAL
* Probe a ILK interface and determine the number of ports
* connected to it. The ILK interface should still be down
* after this call.
*
* @param interface Interface to probe
*
* @return Number of ports on the interface. Zero to disable.
*/
int __cvmx_helper_ilk_probe(int interface)
{
int i, j, res = -1;
static int pipe_base = 0, pknd_base = 0;
static cvmx_ilk_pipe_chan_t *pch = NULL, *tmp;
static cvmx_ilk_chan_pknd_t *chpknd = NULL, *tmp1;
static cvmx_ilk_cal_entry_t *calent = NULL, *tmp2;
if (!OCTEON_IS_MODEL(OCTEON_CN68XX))
return 0;
interface -= CVMX_ILK_GBL_BASE;
if (interface >= CVMX_NUM_ILK_INTF)
return 0;
/* the configuration should be done only once */
if (cvmx_ilk_get_intf_ena (interface))
return cvmx_ilk_chans[interface];
/* configure lanes and enable the link */
res = cvmx_ilk_start_interface (interface, cvmx_ilk_lane_mask[interface]);
if (res < 0)
return 0;
/* set up the group of pipes available to ilk */
if (pipe_base == 0)
pipe_base = __cvmx_pko_get_pipe (interface + CVMX_ILK_GBL_BASE, 0);
if (pipe_base == -1)
{
pipe_base = 0;
return 0;
}
res = cvmx_ilk_set_pipe (interface, pipe_base, cvmx_ilk_chans[interface]);
if (res < 0)
return 0;
/* set up pipe to channel mapping */
i = pipe_base;
if (pch == NULL)
{
pch = (cvmx_ilk_pipe_chan_t *)
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kmalloc(CVMX_MAX_ILK_CHANS * sizeof(cvmx_ilk_pipe_chan_t), GFP_KERNEL);
#else
cvmx_bootmem_alloc (CVMX_MAX_ILK_CHANS * sizeof(cvmx_ilk_pipe_chan_t),
sizeof(cvmx_ilk_pipe_chan_t));
#endif
if (pch == NULL)
return 0;
}
memset (pch, 0, CVMX_MAX_ILK_CHANS * sizeof(cvmx_ilk_pipe_chan_t));
tmp = pch;
for (j = 0; j < cvmx_ilk_chans[interface]; j++)
{
tmp->pipe = i++;
tmp->chan = cvmx_ilk_chan_map[interface][j];
tmp++;
}
res = cvmx_ilk_tx_set_channel (interface, pch, cvmx_ilk_chans[interface]);
if (res < 0)
{
res = 0;
goto err_free_pch;
}
pipe_base += cvmx_ilk_chans[interface];
/* set up channel to pkind mapping */
if (pknd_base == 0)
pknd_base = cvmx_helper_get_pknd (interface + CVMX_ILK_GBL_BASE, 0);
i = pknd_base;
if (chpknd == NULL)
{
chpknd = (cvmx_ilk_chan_pknd_t *)
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kmalloc(CVMX_MAX_ILK_PKNDS * sizeof(cvmx_ilk_chan_pknd_t), GFP_KERNEL);
#else
cvmx_bootmem_alloc (CVMX_MAX_ILK_PKNDS * sizeof(cvmx_ilk_chan_pknd_t),
sizeof(cvmx_ilk_chan_pknd_t));
#endif
if (chpknd == NULL)
{
pipe_base -= cvmx_ilk_chans[interface];
res = 0;
goto err_free_pch;
}
}
memset (chpknd, 0, CVMX_MAX_ILK_PKNDS * sizeof(cvmx_ilk_chan_pknd_t));
tmp1 = chpknd;
for (j = 0; j < cvmx_ilk_chans[interface]; j++)
{
tmp1->chan = cvmx_ilk_chan_map[interface][j];
tmp1->pknd = i++;
tmp1++;
}
res = cvmx_ilk_rx_set_pknd (interface, chpknd, cvmx_ilk_chans[interface]);
if (res < 0)
{
pipe_base -= cvmx_ilk_chans[interface];
res = 0;
goto err_free_chpknd;
}
pknd_base += cvmx_ilk_chans[interface];
/* Set up tx calendar */
if (calent == NULL)
{
calent = (cvmx_ilk_cal_entry_t *)
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kmalloc(CVMX_MAX_ILK_PIPES * sizeof(cvmx_ilk_cal_entry_t), GFP_KERNEL);
#else
cvmx_bootmem_alloc (CVMX_MAX_ILK_PIPES * sizeof(cvmx_ilk_cal_entry_t),
sizeof(cvmx_ilk_cal_entry_t));
#endif
if (calent == NULL)
{
pipe_base -= cvmx_ilk_chans[interface];
pknd_base -= cvmx_ilk_chans[interface];
res = 0;
goto err_free_chpknd;
}
}
memset (calent, 0, CVMX_MAX_ILK_PIPES * sizeof(cvmx_ilk_cal_entry_t));
tmp1 = chpknd;
tmp2 = calent;
for (j = 0; j < cvmx_ilk_chans[interface]; j++)
{
tmp2->pipe_bpid = tmp1->pknd;
tmp2->ent_ctrl = PIPE_BPID;
tmp1++;
tmp2++;
}
res = cvmx_ilk_cal_setup_tx (interface, cvmx_ilk_chans[interface],
calent, 1);
if (res < 0)
{
pipe_base -= cvmx_ilk_chans[interface];
pknd_base -= cvmx_ilk_chans[interface];
res = 0;
goto err_free_calent;
}
/* set up rx calendar. allocated memory can be reused.
* this is because max pkind is always less than max pipe */
memset (calent, 0, CVMX_MAX_ILK_PIPES * sizeof(cvmx_ilk_cal_entry_t));
tmp = pch;
tmp2 = calent;
for (j = 0; j < cvmx_ilk_chans[interface]; j++)
{
tmp2->pipe_bpid = tmp->pipe;
tmp2->ent_ctrl = PIPE_BPID;
tmp++;
tmp2++;
}
res = cvmx_ilk_cal_setup_rx (interface, cvmx_ilk_chans[interface],
calent, CVMX_ILK_RX_FIFO_WM, 1);
if (res < 0)
{
pipe_base -= cvmx_ilk_chans[interface];
pknd_base -= cvmx_ilk_chans[interface];
res = 0;
goto err_free_calent;
}
res = __cvmx_helper_ilk_enumerate(interface + CVMX_ILK_GBL_BASE);
goto out;
err_free_calent:
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kfree (calent);
#else
/* no free() for cvmx_bootmem_alloc() */
#endif
err_free_chpknd:
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kfree (chpknd);
#else
/* no free() for cvmx_bootmem_alloc() */
#endif
err_free_pch:
#ifdef CVMX_BUILD_FOR_LINUX_KERNEL
kfree (pch);
#else
/* no free() for cvmx_bootmem_alloc() */
#endif
out:
return res;
}
void __cvmx_qlm_pcie_cfg_rxd_set_tweak(int qlm, int lane)
{
if (OCTEON_IS_MODEL(OCTEON_CN6XXX) || OCTEON_IS_MODEL(OCTEON_CNF71XX)) {
cvmx_qlm_jtag_set(qlm, lane, "cfg_rxd_set", 0x1);
}
}
/* Version of octeon_model_get_string() that takes buffer as argument, as
** running early in u-boot static/global variables don't work when running from
** flash
*/
const char *octeon_model_get_string_buffer(uint32_t chip_id, char *buffer)
{
const char *family;
const char *core_model;
char pass[4];
#ifndef CVMX_BUILD_FOR_UBOOT
int clock_mhz;
#endif
const char *suffix;
cvmx_l2d_fus3_t fus3;
int num_cores;
cvmx_mio_fus_dat2_t fus_dat2;
cvmx_mio_fus_dat3_t fus_dat3;
char fuse_model[10];
char fuse_suffix[4] = {0};
uint64_t fuse_data = 0;
fus3.u64 = 0;
if (OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX))
fus3.u64 = cvmx_read_csr(CVMX_L2D_FUS3);
fus_dat2.u64 = cvmx_read_csr(CVMX_MIO_FUS_DAT2);
fus_dat3.u64 = cvmx_read_csr(CVMX_MIO_FUS_DAT3);
if (OCTEON_IS_MODEL(OCTEON_CN78XX))
num_cores = cvmx_pop(cvmx_read_csr(CVMX_CIU3_FUSE));
else
num_cores = cvmx_pop(cvmx_read_csr(CVMX_CIU_FUSE));
/* Make sure the non existent devices look disabled */
switch ((chip_id >> 8) & 0xff) {
case 6: /* CN50XX */
case 2: /* CN30XX */
fus_dat3.s.nodfa_dte = 1;
fus_dat3.s.nozip = 1;
break;
case 4: /* CN57XX or CN56XX */
fus_dat3.s.nodfa_dte = 1;
break;
default:
break;
}
/* Make a guess at the suffix */
/* NSP = everything */
/* EXP = No crypto */
/* SCP = No DFA, No zip */
/* CP = No DFA, No crypto, No zip */
if (fus_dat3.s.nodfa_dte) {
if (fus_dat2.s.nocrypto)
suffix = "CP";
else
suffix = "SCP";
} else if (fus_dat2.s.nocrypto)
suffix = "EXP";
else
suffix = "NSP";
/* Assume pass number is encoded using <5:3><2:0>. Exceptions will be
fixed later */
sprintf(pass, "%d.%d", (int)((chip_id >> 3) & 7) + 1, (int)chip_id & 7);
/* Use the number of cores to determine the last 2 digits of the model
number. There are some exceptions that are fixed later */
switch (num_cores) {
case 32:
core_model = "80";
break;
case 24:
core_model = "70";
break;
case 16:
core_model = "60";
break;
case 15:
core_model = "58";
break;
case 14:
core_model = "55";
break;
case 13:
core_model = "52";
break;
case 12:
core_model = "50";
break;
case 11:
core_model = "48";
break;
case 10:
core_model = "45";
break;
case 9:
core_model = "42";
break;
case 8:
core_model = "40";
break;
case 7:
core_model = "38";
break;
case 6:
core_model = "34";
break;
case 5:
core_model = "32";
break;
case 4:
core_model = "30";
break;
case 3:
core_model = "25";
break;
case 2:
core_model = "20";
break;
case 1:
core_model = "10";
break;
default:
core_model = "XX";
break;
}
/* Now figure out the family, the first two digits */
switch ((chip_id >> 8) & 0xff) {
case 0: /* CN38XX, CN37XX or CN36XX */
if (fus3.cn38xx.crip_512k) {
/* For some unknown reason, the 16 core one is called 37 instead of 36 */
if (num_cores >= 16)
family = "37";
else
family = "36";
} else
family = "38";
/* This series of chips didn't follow the standard pass numbering */
switch (chip_id & 0xf) {
case 0:
strcpy(pass, "1.X");
break;
case 1:
strcpy(pass, "2.X");
break;
case 3:
strcpy(pass, "3.X");
break;
default:
strcpy(pass, "X.X");
break;
}
break;
case 1: /* CN31XX or CN3020 */
if ((chip_id & 0x10) || fus3.cn31xx.crip_128k)
family = "30";
else
family = "31";
/* This series of chips didn't follow the standard pass numbering */
switch (chip_id & 0xf) {
case 0:
strcpy(pass, "1.0");
break;
case 2:
strcpy(pass, "1.1");
break;
default:
strcpy(pass, "X.X");
break;
}
break;
case 2: /* CN3010 or CN3005 */
family = "30";
/* A chip with half cache is an 05 */
if (fus3.cn30xx.crip_64k)
core_model = "05";
/* This series of chips didn't follow the standard pass numbering */
switch (chip_id & 0xf) {
case 0:
strcpy(pass, "1.0");
break;
case 2:
strcpy(pass, "1.1");
break;
default:
strcpy(pass, "X.X");
break;
}
break;
case 3: /* CN58XX */
family = "58";
/* Special case. 4 core, half cache (CP with half cache) */
if ((num_cores == 4) && fus3.cn58xx.crip_1024k && !strncmp(suffix, "CP", 2))
core_model = "29";
/* Pass 1 uses different encodings for pass numbers */
if ((chip_id & 0xFF) < 0x8) {
switch (chip_id & 0x3) {
case 0:
strcpy(pass, "1.0");
break;
case 1:
strcpy(pass, "1.1");
break;
case 3:
strcpy(pass, "1.2");
break;
default:
strcpy(pass, "1.X");
break;
}
}
break;
case 4: /* CN57XX, CN56XX, CN55XX, CN54XX */
if (fus_dat2.cn56xx.raid_en) {
if (fus3.cn56xx.crip_1024k)
family = "55";
else
family = "57";
if (fus_dat2.cn56xx.nocrypto)
suffix = "SP";
else
suffix = "SSP";
} else {
if (fus_dat2.cn56xx.nocrypto)
suffix = "CP";
else {
suffix = "NSP";
if (fus_dat3.s.nozip)
suffix = "SCP";
if (fus_dat3.cn56xx.bar2_en)
suffix = "NSPB2";
}
if (fus3.cn56xx.crip_1024k)
family = "54";
else
family = "56";
}
break;
case 6: /* CN50XX */
family = "50";
break;
case 7: /* CN52XX */
if (fus3.cn52xx.crip_256k)
family = "51";
else
family = "52";
break;
case 0x93: /* CN61XX/CN60XX */
family = "61";
if (fus_dat3.cn63xx.l2c_crip == 2)
family = "60";
if (fus_dat3.cn61xx.nozip)
suffix = "SCP";
else
suffix = "AAP";
break;
case 0x90: /* CN63XX/CN62XX */
family = "63";
if (fus_dat3.s.l2c_crip == 2)
family = "62";
if (num_cores == 6) /* Other core counts match generic */
core_model = "35";
if (fus_dat2.cn63xx.nocrypto)
suffix = "CP";
else if (fus_dat2.cn63xx.dorm_crypto)
suffix = "DAP";
else if (fus_dat3.cn63xx.nozip)
suffix = "SCP";
else
suffix = "AAP";
break;
case 0x92: /* CN66XX */
family = "66";
if (num_cores == 6) /* Other core counts match generic */
core_model = "35";
if (fus_dat2.cn66xx.nocrypto && fus_dat2.cn66xx.dorm_crypto)
suffix = "AP";
if (fus_dat2.cn66xx.nocrypto)
suffix = "CP";
else if (fus_dat2.cn66xx.dorm_crypto)
suffix = "DAP";
else if (fus_dat3.cn66xx.nozip && fus_dat2.cn66xx.raid_en)
suffix = "SCP";
else if (!fus_dat2.cn66xx.raid_en)
suffix = "HAP";
else
suffix = "AAP";
break;
case 0x91: /* CN68XX */
family = "68";
if (fus_dat2.cn68xx.nocrypto && fus_dat3.cn68xx.nozip)
suffix = "CP";
else if (fus_dat2.cn68xx.dorm_crypto)
suffix = "DAP";
else if (fus_dat3.cn68xx.nozip)
suffix = "SCP";
else if (fus_dat2.cn68xx.nocrypto)
suffix = "SP";
else if (!fus_dat2.cn68xx.raid_en)
suffix = "HAP";
else
suffix = "AAP";
break;
case 0x94: /* CNF71XX */
family = "F71";
if (fus_dat3.cnf71xx.nozip)
suffix = "SCP";
else
suffix = "AAP";
break;
case 0x95: /* CN78XX */
family = "78";
if (fus_dat3.cn70xx.nozip)
suffix = "SCP";
else
suffix = "AAP";
break;
case 0x96: /* CN70XX */
family = "70";
if (cvmx_read_csr(CVMX_MIO_FUS_PDF) & (0x1ULL << 32))
family = "71";
if (fus_dat2.cn70xx.nocrypto)
suffix = "CP";
else if (fus_dat3.cn70xx.nodfa_dte)
suffix = "SCP";
else
suffix = "AAP";
break;
default:
family = "XX";
core_model = "XX";
strcpy(pass, "X.X");
suffix = "XXX";
break;
}
#ifndef CVMX_BUILD_FOR_UBOOT
clock_mhz = cvmx_clock_get_rate(CVMX_CLOCK_RCLK) / 1000000;
#endif
if (family[0] != '3') {
if (OCTEON_IS_OCTEON1PLUS() || OCTEON_IS_OCTEON2()) {
int fuse_base = 384 / 8;
if (family[0] == '6' || OCTEON_IS_OCTEON3())
fuse_base = 832 / 8;
/* Check for model in fuses, overrides normal decode */
/* This is _not_ valid for Octeon CN3XXX models */
fuse_data |= cvmx_fuse_read_byte(fuse_base + 5);
fuse_data = fuse_data << 8;
fuse_data |= cvmx_fuse_read_byte(fuse_base + 4);
fuse_data = fuse_data << 8;
fuse_data |= cvmx_fuse_read_byte(fuse_base + 3);
fuse_data = fuse_data << 8;
fuse_data |= cvmx_fuse_read_byte(fuse_base + 2);
fuse_data = fuse_data << 8;
fuse_data |= cvmx_fuse_read_byte(fuse_base + 1);
fuse_data = fuse_data << 8;
fuse_data |= cvmx_fuse_read_byte(fuse_base);
if (fuse_data & 0x7ffff) {
int model = fuse_data & 0x3fff;
int suffix = (fuse_data >> 14) & 0x1f;
if (suffix && model) { /* Have both number and suffix in fuses, so both */
sprintf(fuse_model, "%d%c", model, 'A' + suffix - 1);
core_model = "";
family = fuse_model;
} else if (suffix && !model) { /* Only have suffix, so add suffix to 'normal' model number */
sprintf(fuse_model, "%s%c", core_model, 'A' + suffix - 1);
core_model = fuse_model;
} else { /* Don't have suffix, so just use model from fuses */
sprintf(fuse_model, "%d", model);
core_model = "";
family = fuse_model;
}
}
} else {
/**
* Get the speed (Gbaud) of the QLM in Mhz.
*
* @param qlm QLM to examine
*
* @return Speed in Mhz
*/
int cvmx_qlm_get_gbaud_mhz(int qlm)
{
if (OCTEON_IS_MODEL(OCTEON_CN63XX)) {
if (qlm == 2) {
cvmx_gmxx_inf_mode_t inf_mode;
inf_mode.u64 = cvmx_read_csr(CVMX_GMXX_INF_MODE(0));
switch (inf_mode.s.speed) {
case 0:
return 5000; /* 5 Gbaud */
case 1:
return 2500; /* 2.5 Gbaud */
case 2:
return 2500; /* 2.5 Gbaud */
case 3:
return 1250; /* 1.25 Gbaud */
case 4:
return 1250; /* 1.25 Gbaud */
case 5:
return 6250; /* 6.25 Gbaud */
case 6:
return 5000; /* 5 Gbaud */
case 7:
return 2500; /* 2.5 Gbaud */
case 8:
return 3125; /* 3.125 Gbaud */
case 9:
return 2500; /* 2.5 Gbaud */
case 10:
return 1250; /* 1.25 Gbaud */
case 11:
return 5000; /* 5 Gbaud */
case 12:
return 6250; /* 6.25 Gbaud */
case 13:
return 3750; /* 3.75 Gbaud */
case 14:
return 3125; /* 3.125 Gbaud */
default:
return 0; /* Disabled */
}
} else {
cvmx_sriox_status_reg_t status_reg;
status_reg.u64 = cvmx_read_csr(CVMX_SRIOX_STATUS_REG(qlm));
if (status_reg.s.srio) {
cvmx_sriomaintx_port_0_ctl2_t sriomaintx_port_0_ctl2;
sriomaintx_port_0_ctl2.u32 = cvmx_read_csr(CVMX_SRIOMAINTX_PORT_0_CTL2(qlm));
switch (sriomaintx_port_0_ctl2.s.sel_baud) {
case 1:
return 1250; /* 1.25 Gbaud */
case 2:
return 2500; /* 2.5 Gbaud */
case 3:
return 3125; /* 3.125 Gbaud */
case 4:
return 5000; /* 5 Gbaud */
case 5:
return 6250; /* 6.250 Gbaud */
default:
return 0; /* Disabled */
}
} else {
cvmx_pciercx_cfg032_t pciercx_cfg032;
pciercx_cfg032.u32 = cvmx_read_csr(CVMX_PCIERCX_CFG032(qlm));
switch (pciercx_cfg032.s.ls) {
case 1:
return 2500;
case 2:
return 5000;
case 4:
return 8000;
default:
{
cvmx_mio_rst_boot_t mio_rst_boot;
mio_rst_boot.u64 = cvmx_read_csr(CVMX_MIO_RST_BOOT);
if ((qlm == 0) && mio_rst_boot.s.qlm0_spd == 0xf)
return 0;
if ((qlm == 1) && mio_rst_boot.s.qlm1_spd == 0xf)
return 0;
return 5000; /* Best guess I can make */
}
}
}
}
} else if (OCTEON_IS_OCTEON2()) {
cvmx_mio_qlmx_cfg_t qlm_cfg;
qlm_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
switch (qlm_cfg.s.qlm_spd) {
case 0:
return 5000; /* 5 Gbaud */
case 1:
return 2500; /* 2.5 Gbaud */
case 2:
return 2500; /* 2.5 Gbaud */
case 3:
return 1250; /* 1.25 Gbaud */
case 4:
return 1250; /* 1.25 Gbaud */
case 5:
return 6250; /* 6.25 Gbaud */
case 6:
return 5000; /* 5 Gbaud */
case 7:
return 2500; /* 2.5 Gbaud */
case 8:
return 3125; /* 3.125 Gbaud */
case 9:
return 2500; /* 2.5 Gbaud */
case 10:
return 1250; /* 1.25 Gbaud */
case 11:
return 5000; /* 5 Gbaud */
case 12:
return 6250; /* 6.25 Gbaud */
case 13:
return 3750; /* 3.75 Gbaud */
case 14:
return 3125; /* 3.125 Gbaud */
default:
return 0; /* Disabled */
}
} else if (OCTEON_IS_MODEL(OCTEON_CN70XX)) {
cvmx_gserx_dlmx_mpll_multiplier_t mpll_multiplier;
uint64_t meas_refclock;
uint64_t freq;
/* Measure the reference clock */
meas_refclock = cvmx_qlm_measure_clock(qlm);
/* Multiply to get the final frequency */
mpll_multiplier.u64 = cvmx_read_csr(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0));
freq = meas_refclock * mpll_multiplier.s.mpll_multiplier;
freq = (freq + 500000) / 1000000;
return freq;
}
return 0;
}
/**
* Packet transmit
*
* @param m Packet to send
* @param dev Device info structure
* @return Always returns zero
*/
int cvm_oct_xmit(struct mbuf *m, struct ifnet *ifp)
{
cvmx_pko_command_word0_t pko_command;
cvmx_buf_ptr_t hw_buffer;
int dropped;
int qos;
cvm_oct_private_t *priv = (cvm_oct_private_t *)ifp->if_softc;
int32_t in_use;
int32_t buffers_to_free;
cvmx_wqe_t *work;
/* Prefetch the private data structure.
It is larger that one cache line */
CVMX_PREFETCH(priv, 0);
/* Start off assuming no drop */
dropped = 0;
/* The check on CVMX_PKO_QUEUES_PER_PORT_* is designed to completely
remove "qos" in the event neither interface supports multiple queues
per port */
if ((CVMX_PKO_QUEUES_PER_PORT_INTERFACE0 > 1) ||
(CVMX_PKO_QUEUES_PER_PORT_INTERFACE1 > 1)) {
qos = GET_MBUF_QOS(m);
if (qos <= 0)
qos = 0;
else if (qos >= cvmx_pko_get_num_queues(priv->port))
qos = 0;
} else
qos = 0;
/* The CN3XXX series of parts has an errata (GMX-401) which causes the
GMX block to hang if a collision occurs towards the end of a
<68 byte packet. As a workaround for this, we pad packets to be
68 bytes whenever we are in half duplex mode. We don't handle
the case of having a small packet but no room to add the padding.
The kernel should always give us at least a cache line */
if (__predict_false(m->m_pkthdr.len < 64) && OCTEON_IS_MODEL(OCTEON_CN3XXX)) {
cvmx_gmxx_prtx_cfg_t gmx_prt_cfg;
int interface = INTERFACE(priv->port);
int index = INDEX(priv->port);
if (interface < 2) {
/* We only need to pad packet in half duplex mode */
gmx_prt_cfg.u64 = cvmx_read_csr(CVMX_GMXX_PRTX_CFG(index, interface));
if (gmx_prt_cfg.s.duplex == 0) {
static uint8_t pad[64];
if (!m_append(m, sizeof pad - m->m_pkthdr.len, pad))
printf("%s: unable to padd small packet.", __func__);
}
}
}
#ifdef OCTEON_VENDOR_RADISYS
/*
* The RSYS4GBE will hang if asked to transmit a packet less than 60 bytes.
*/
if (__predict_false(m->m_pkthdr.len < 60) &&
cvmx_sysinfo_get()->board_type == CVMX_BOARD_TYPE_CUST_RADISYS_RSYS4GBE) {
static uint8_t pad[60];
if (!m_append(m, sizeof pad - m->m_pkthdr.len, pad))
printf("%s: unable to pad small packet.", __func__);
}
#endif
/*
* If the packet is not fragmented.
*/
if (m->m_pkthdr.len == m->m_len) {
/* Build the PKO buffer pointer */
hw_buffer.u64 = 0;
hw_buffer.s.addr = cvmx_ptr_to_phys(m->m_data);
hw_buffer.s.pool = 0;
hw_buffer.s.size = m->m_len;
/* Build the PKO command */
pko_command.u64 = 0;
pko_command.s.segs = 1;
pko_command.s.dontfree = 1; /* Do not put this buffer into the FPA. */
work = NULL;
} else {
struct mbuf *n;
unsigned segs;
uint64_t *gp;
/*
* The packet is fragmented, we need to send a list of segments
* in memory we borrow from the WQE pool.
*/
work = cvmx_fpa_alloc(CVMX_FPA_WQE_POOL);
if (work == NULL) {
m_freem(m);
if_inc_counter(ifp, IFCOUNTER_OERRORS, 1);
return 1;
}
segs = 0;
gp = (uint64_t *)work;
for (n = m; n != NULL; n = n->m_next) {
if (segs == CVMX_FPA_WQE_POOL_SIZE / sizeof (uint64_t))
panic("%s: too many segments in packet; call m_collapse().", __func__);
/* Build the PKO buffer pointer */
hw_buffer.u64 = 0;
hw_buffer.s.i = 1; /* Do not put this buffer into the FPA. */
hw_buffer.s.addr = cvmx_ptr_to_phys(n->m_data);
hw_buffer.s.pool = 0;
hw_buffer.s.size = n->m_len;
*gp++ = hw_buffer.u64;
segs++;
}
/* Build the PKO buffer gather list pointer */
hw_buffer.u64 = 0;
hw_buffer.s.addr = cvmx_ptr_to_phys(work);
hw_buffer.s.pool = CVMX_FPA_WQE_POOL;
hw_buffer.s.size = segs;
/* Build the PKO command */
pko_command.u64 = 0;
pko_command.s.segs = segs;
pko_command.s.gather = 1;
pko_command.s.dontfree = 0; /* Put the WQE above back into the FPA. */
}
/* Finish building the PKO command */
pko_command.s.n2 = 1; /* Don't pollute L2 with the outgoing packet */
pko_command.s.reg0 = priv->fau+qos*4;
pko_command.s.total_bytes = m->m_pkthdr.len;
pko_command.s.size0 = CVMX_FAU_OP_SIZE_32;
pko_command.s.subone0 = 1;
/* Check if we can use the hardware checksumming */
if ((m->m_pkthdr.csum_flags & (CSUM_TCP | CSUM_UDP)) != 0) {
/* Use hardware checksum calc */
pko_command.s.ipoffp1 = ETHER_HDR_LEN + 1;
}
/*
* XXX
* Could use a different free queue (and different FAU address) per
* core instead of per QoS, to reduce contention here.
*/
IF_LOCK(&priv->tx_free_queue[qos]);
/* Get the number of mbufs in use by the hardware */
in_use = cvmx_fau_fetch_and_add32(priv->fau+qos*4, 1);
buffers_to_free = cvmx_fau_fetch_and_add32(FAU_NUM_PACKET_BUFFERS_TO_FREE, 0);
cvmx_pko_send_packet_prepare(priv->port, priv->queue + qos, CVMX_PKO_LOCK_CMD_QUEUE);
/* Drop this packet if we have too many already queued to the HW */
if (_IF_QFULL(&priv->tx_free_queue[qos])) {
dropped = 1;
}
/* Send the packet to the output queue */
else
if (__predict_false(cvmx_pko_send_packet_finish(priv->port, priv->queue + qos, pko_command, hw_buffer, CVMX_PKO_LOCK_CMD_QUEUE))) {
DEBUGPRINT("%s: Failed to send the packet\n", if_name(ifp));
dropped = 1;
}
if (__predict_false(dropped)) {
m_freem(m);
cvmx_fau_atomic_add32(priv->fau+qos*4, -1);
if_inc_counter(ifp, IFCOUNTER_OERRORS, 1);
} else {
/* Put this packet on the queue to be freed later */
_IF_ENQUEUE(&priv->tx_free_queue[qos], m);
/* Pass it to any BPF listeners. */
ETHER_BPF_MTAP(ifp, m);
if_inc_counter(ifp, IFCOUNTER_OPACKETS, 1);
if_inc_counter(ifp, IFCOUNTER_OBYTES, m->m_pkthdr.len);
}
/* Free mbufs not in use by the hardware */
if (_IF_QLEN(&priv->tx_free_queue[qos]) > in_use) {
while (_IF_QLEN(&priv->tx_free_queue[qos]) > in_use) {
_IF_DEQUEUE(&priv->tx_free_queue[qos], m);
m_freem(m);
}
}
IF_UNLOCK(&priv->tx_free_queue[qos]);
return dropped;
}
static int octeon_mgmt_open(struct net_device *netdev)
{
struct octeon_mgmt *p = netdev_priv(netdev);
int port = p->port;
union cvmx_mixx_ctl mix_ctl;
union cvmx_agl_gmx_inf_mode agl_gmx_inf_mode;
union cvmx_mixx_oring1 oring1;
union cvmx_mixx_iring1 iring1;
union cvmx_agl_gmx_prtx_cfg prtx_cfg;
union cvmx_agl_gmx_rxx_frm_ctl rxx_frm_ctl;
union cvmx_mixx_irhwm mix_irhwm;
union cvmx_mixx_orhwm mix_orhwm;
union cvmx_mixx_intena mix_intena;
struct sockaddr sa;
/* Allocate ring buffers. */
p->tx_ring = kzalloc(ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
GFP_KERNEL);
if (!p->tx_ring)
return -ENOMEM;
p->tx_ring_handle =
dma_map_single(p->dev, p->tx_ring,
ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
DMA_BIDIRECTIONAL);
p->tx_next = 0;
p->tx_next_clean = 0;
p->tx_current_fill = 0;
p->rx_ring = kzalloc(ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
GFP_KERNEL);
if (!p->rx_ring)
goto err_nomem;
p->rx_ring_handle =
dma_map_single(p->dev, p->rx_ring,
ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
DMA_BIDIRECTIONAL);
p->rx_next = 0;
p->rx_next_fill = 0;
p->rx_current_fill = 0;
octeon_mgmt_reset_hw(p);
mix_ctl.u64 = cvmx_read_csr(CVMX_MIXX_CTL(port));
/* Bring it out of reset if needed. */
if (mix_ctl.s.reset) {
mix_ctl.s.reset = 0;
cvmx_write_csr(CVMX_MIXX_CTL(port), mix_ctl.u64);
do {
mix_ctl.u64 = cvmx_read_csr(CVMX_MIXX_CTL(port));
} while (mix_ctl.s.reset);
}
agl_gmx_inf_mode.u64 = 0;
agl_gmx_inf_mode.s.en = 1;
cvmx_write_csr(CVMX_AGL_GMX_INF_MODE, agl_gmx_inf_mode.u64);
oring1.u64 = 0;
oring1.s.obase = p->tx_ring_handle >> 3;
oring1.s.osize = OCTEON_MGMT_TX_RING_SIZE;
cvmx_write_csr(CVMX_MIXX_ORING1(port), oring1.u64);
iring1.u64 = 0;
iring1.s.ibase = p->rx_ring_handle >> 3;
iring1.s.isize = OCTEON_MGMT_RX_RING_SIZE;
cvmx_write_csr(CVMX_MIXX_IRING1(port), iring1.u64);
/* Disable packet I/O. */
prtx_cfg.u64 = cvmx_read_csr(CVMX_AGL_GMX_PRTX_CFG(port));
prtx_cfg.s.en = 0;
cvmx_write_csr(CVMX_AGL_GMX_PRTX_CFG(port), prtx_cfg.u64);
memcpy(sa.sa_data, netdev->dev_addr, ETH_ALEN);
octeon_mgmt_set_mac_address(netdev, &sa);
octeon_mgmt_change_mtu(netdev, netdev->mtu);
/*
* Enable the port HW. Packets are not allowed until
* cvmx_mgmt_port_enable() is called.
*/
mix_ctl.u64 = 0;
mix_ctl.s.crc_strip = 1; /* Strip the ending CRC */
mix_ctl.s.en = 1; /* Enable the port */
mix_ctl.s.nbtarb = 0; /* Arbitration mode */
/* MII CB-request FIFO programmable high watermark */
mix_ctl.s.mrq_hwm = 1;
cvmx_write_csr(CVMX_MIXX_CTL(port), mix_ctl.u64);
if (OCTEON_IS_MODEL(OCTEON_CN56XX_PASS1_X)
|| OCTEON_IS_MODEL(OCTEON_CN52XX_PASS1_X)) {
/*
* Force compensation values, as they are not
* determined properly by HW
*/
union cvmx_agl_gmx_drv_ctl drv_ctl;
drv_ctl.u64 = cvmx_read_csr(CVMX_AGL_GMX_DRV_CTL);
if (port) {
drv_ctl.s.byp_en1 = 1;
drv_ctl.s.nctl1 = 6;
drv_ctl.s.pctl1 = 6;
} else {
drv_ctl.s.byp_en = 1;
drv_ctl.s.nctl = 6;
drv_ctl.s.pctl = 6;
}
cvmx_write_csr(CVMX_AGL_GMX_DRV_CTL, drv_ctl.u64);
}
octeon_mgmt_rx_fill_ring(netdev);
/* Clear statistics. */
/* Clear on read. */
cvmx_write_csr(CVMX_AGL_GMX_RXX_STATS_CTL(port), 1);
cvmx_write_csr(CVMX_AGL_GMX_RXX_STATS_PKTS_DRP(port), 0);
cvmx_write_csr(CVMX_AGL_GMX_RXX_STATS_PKTS_BAD(port), 0);
cvmx_write_csr(CVMX_AGL_GMX_TXX_STATS_CTL(port), 1);
cvmx_write_csr(CVMX_AGL_GMX_TXX_STAT0(port), 0);
cvmx_write_csr(CVMX_AGL_GMX_TXX_STAT1(port), 0);
/* Clear any pending interrupts */
cvmx_write_csr(CVMX_MIXX_ISR(port), cvmx_read_csr(CVMX_MIXX_ISR(port)));
if (request_irq(p->irq, octeon_mgmt_interrupt, 0, netdev->name,
netdev)) {
dev_err(p->dev, "request_irq(%d) failed.\n", p->irq);
goto err_noirq;
}
/* Interrupt every single RX packet */
mix_irhwm.u64 = 0;
mix_irhwm.s.irhwm = 0;
cvmx_write_csr(CVMX_MIXX_IRHWM(port), mix_irhwm.u64);
/* Interrupt when we have 1 or more packets to clean. */
mix_orhwm.u64 = 0;
mix_orhwm.s.orhwm = 1;
cvmx_write_csr(CVMX_MIXX_ORHWM(port), mix_orhwm.u64);
/* Enable receive and transmit interrupts */
mix_intena.u64 = 0;
mix_intena.s.ithena = 1;
mix_intena.s.othena = 1;
cvmx_write_csr(CVMX_MIXX_INTENA(port), mix_intena.u64);
/* Enable packet I/O. */
rxx_frm_ctl.u64 = 0;
rxx_frm_ctl.s.pre_align = 1;
/*
* When set, disables the length check for non-min sized pkts
* with padding in the client data.
*/
rxx_frm_ctl.s.pad_len = 1;
/* When set, disables the length check for VLAN pkts */
rxx_frm_ctl.s.vlan_len = 1;
/* When set, PREAMBLE checking is less strict */
rxx_frm_ctl.s.pre_free = 1;
/* Control Pause Frames can match station SMAC */
rxx_frm_ctl.s.ctl_smac = 0;
/* Control Pause Frames can match globally assign Multicast address */
rxx_frm_ctl.s.ctl_mcst = 1;
/* Forward pause information to TX block */
rxx_frm_ctl.s.ctl_bck = 1;
/* Drop Control Pause Frames */
rxx_frm_ctl.s.ctl_drp = 1;
/* Strip off the preamble */
rxx_frm_ctl.s.pre_strp = 1;
/*
* This port is configured to send PREAMBLE+SFD to begin every
* frame. GMX checks that the PREAMBLE is sent correctly.
*/
rxx_frm_ctl.s.pre_chk = 1;
cvmx_write_csr(CVMX_AGL_GMX_RXX_FRM_CTL(port), rxx_frm_ctl.u64);
/* Enable the AGL block */
agl_gmx_inf_mode.u64 = 0;
agl_gmx_inf_mode.s.en = 1;
cvmx_write_csr(CVMX_AGL_GMX_INF_MODE, agl_gmx_inf_mode.u64);
/* Configure the port duplex and enables */
prtx_cfg.u64 = cvmx_read_csr(CVMX_AGL_GMX_PRTX_CFG(port));
prtx_cfg.s.tx_en = 1;
prtx_cfg.s.rx_en = 1;
prtx_cfg.s.en = 1;
p->last_duplex = 1;
prtx_cfg.s.duplex = p->last_duplex;
cvmx_write_csr(CVMX_AGL_GMX_PRTX_CFG(port), prtx_cfg.u64);
p->last_link = 0;
netif_carrier_off(netdev);
if (octeon_mgmt_init_phy(netdev)) {
dev_err(p->dev, "Cannot initialize PHY.\n");
goto err_noirq;
}
netif_wake_queue(netdev);
napi_enable(&p->napi);
return 0;
err_noirq:
octeon_mgmt_reset_hw(p);
dma_unmap_single(p->dev, p->rx_ring_handle,
ring_size_to_bytes(OCTEON_MGMT_RX_RING_SIZE),
DMA_BIDIRECTIONAL);
kfree(p->rx_ring);
err_nomem:
dma_unmap_single(p->dev, p->tx_ring_handle,
ring_size_to_bytes(OCTEON_MGMT_TX_RING_SIZE),
DMA_BIDIRECTIONAL);
kfree(p->tx_ring);
return -ENOMEM;
}
static int __init octeon_serial_init(void)
{
int enable_uart0;
int enable_uart1;
int enable_uart2;
struct plat_serial8250_port *p;
#ifdef CONFIG_CAVIUM_OCTEON_2ND_KERNEL
/*
* If we are configured to run as the second of two kernels,
* disable uart0 and enable uart1. Uart0 is owned by the first
* kernel
*/
enable_uart0 = 0;
enable_uart1 = 1;
#else
/*
* We are configured for the first kernel. We'll enable uart0
* if the bootloader told us to use 0, otherwise will enable
* uart 1.
*/
enable_uart0 = (octeon_get_boot_uart() == 0);
enable_uart1 = (octeon_get_boot_uart() == 1);
#ifdef CONFIG_KGDB
enable_uart1 = 1;
#endif
#endif
#ifdef CONFIG_SG8200
enable_uart1 = 1;
#endif
/* Right now CN52XX is the only chip with a third uart */
enable_uart2 = OCTEON_IS_MODEL(OCTEON_CN52XX);
p = octeon_uart8250_data;
if (enable_uart0) {
/* Add a ttyS device for hardware uart 0 */
octeon_uart_set_common(p);
p->membase = (void *) CVMX_MIO_UARTX_RBR(0);
p->mapbase = CVMX_MIO_UARTX_RBR(0) & ((1ull << 49) - 1);
p->irq = OCTEON_IRQ_UART0;
p++;
}
if (enable_uart1) {
/* Add a ttyS device for hardware uart 1 */
octeon_uart_set_common(p);
p->membase = (void *) CVMX_MIO_UARTX_RBR(1);
p->mapbase = CVMX_MIO_UARTX_RBR(1) & ((1ull << 49) - 1);
p->irq = OCTEON_IRQ_UART1;
p++;
}
if (enable_uart2) {
/* Add a ttyS device for hardware uart 2 */
octeon_uart_set_common(p);
p->membase = (void *) CVMX_MIO_UART2_RBR;
p->mapbase = CVMX_MIO_UART2_RBR & ((1ull << 49) - 1);
p->irq = OCTEON_IRQ_UART2;
p++;
}
BUG_ON(p > &octeon_uart8250_data[OCTEON_MAX_UARTS]);
return platform_device_register(&octeon_uart8250_device);
}
/**
* Show channel statistics
*
* @param interface The identifier of the packet interface to disable. cn68xx
* has 2 interfaces: ilk0 and ilk1.
* @param pstats A pointer to cvmx_ilk_stats_ctrl_t that specifies which
* logical channels to access
*
* @return nothing
*/
void cvmx_ilk_show_stats (int interface, cvmx_ilk_stats_ctrl_t *pstats)
{
unsigned int i;
cvmx_ilk_rxx_idx_stat0_t ilk_rxx_idx_stat0;
cvmx_ilk_rxx_idx_stat1_t ilk_rxx_idx_stat1;
cvmx_ilk_rxx_mem_stat0_t ilk_rxx_mem_stat0;
cvmx_ilk_rxx_mem_stat1_t ilk_rxx_mem_stat1;
cvmx_ilk_txx_idx_stat0_t ilk_txx_idx_stat0;
cvmx_ilk_txx_idx_stat1_t ilk_txx_idx_stat1;
cvmx_ilk_txx_mem_stat0_t ilk_txx_mem_stat0;
cvmx_ilk_txx_mem_stat1_t ilk_txx_mem_stat1;
if (!(OCTEON_IS_MODEL(OCTEON_CN68XX)))
return;
if (interface >= CVMX_NUM_ILK_INTF)
return;
if (pstats == NULL)
return;
/* discrete channels */
if (pstats->chan_list != NULL)
{
for (i = 0; i < pstats->num_chans; i++)
{
/* get the number of rx packets */
ilk_rxx_idx_stat0.u64 = 0;
ilk_rxx_idx_stat0.s.index = *pstats->chan_list;
ilk_rxx_idx_stat0.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_RXX_IDX_STAT0(interface),
ilk_rxx_idx_stat0.u64);
ilk_rxx_mem_stat0.u64 = cvmx_read_csr
(CVMX_ILK_RXX_MEM_STAT0(interface));
/* get the number of rx bytes */
ilk_rxx_idx_stat1.u64 = 0;
ilk_rxx_idx_stat1.s.index = *pstats->chan_list;
ilk_rxx_idx_stat1.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_RXX_IDX_STAT1(interface),
ilk_rxx_idx_stat1.u64);
ilk_rxx_mem_stat1.u64 = cvmx_read_csr
(CVMX_ILK_RXX_MEM_STAT1(interface));
cvmx_dprintf ("ILK%d Channel%d Rx: %d packets %d bytes\n", interface,
*pstats->chan_list, ilk_rxx_mem_stat0.s.rx_pkt,
(unsigned int) ilk_rxx_mem_stat1.s.rx_bytes);
/* get the number of tx packets */
ilk_txx_idx_stat0.u64 = 0;
ilk_txx_idx_stat0.s.index = *pstats->chan_list;
ilk_txx_idx_stat0.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_TXX_IDX_STAT0(interface),
ilk_txx_idx_stat0.u64);
ilk_txx_mem_stat0.u64 = cvmx_read_csr
(CVMX_ILK_TXX_MEM_STAT0(interface));
/* get the number of tx bytes */
ilk_txx_idx_stat1.u64 = 0;
ilk_txx_idx_stat1.s.index = *pstats->chan_list;
ilk_txx_idx_stat1.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_TXX_IDX_STAT1(interface),
ilk_txx_idx_stat1.u64);
ilk_txx_mem_stat1.u64 = cvmx_read_csr
(CVMX_ILK_TXX_MEM_STAT1(interface));
cvmx_dprintf ("ILK%d Channel%d Tx: %d packets %d bytes\n", interface,
*pstats->chan_list, ilk_txx_mem_stat0.s.tx_pkt,
(unsigned int) ilk_txx_mem_stat1.s.tx_bytes);
pstats++;
}
return;
}
/* continuous channels */
ilk_rxx_idx_stat0.u64 = 0;
ilk_rxx_idx_stat0.s.index = pstats->chan_start;
ilk_rxx_idx_stat0.s.inc = pstats->chan_step;
ilk_rxx_idx_stat0.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_RXX_IDX_STAT0(interface), ilk_rxx_idx_stat0.u64);
ilk_rxx_idx_stat1.u64 = 0;
ilk_rxx_idx_stat1.s.index = pstats->chan_start;
ilk_rxx_idx_stat1.s.inc = pstats->chan_step;
ilk_rxx_idx_stat1.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_RXX_IDX_STAT1(interface), ilk_rxx_idx_stat1.u64);
ilk_txx_idx_stat0.u64 = 0;
ilk_txx_idx_stat0.s.index = pstats->chan_start;
ilk_txx_idx_stat0.s.inc = pstats->chan_step;
ilk_txx_idx_stat0.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_TXX_IDX_STAT0(interface), ilk_txx_idx_stat0.u64);
ilk_txx_idx_stat1.u64 = 0;
ilk_txx_idx_stat1.s.index = pstats->chan_start;
ilk_txx_idx_stat1.s.inc = pstats->chan_step;
ilk_txx_idx_stat1.s.clr = pstats->clr_on_rd;
cvmx_write_csr (CVMX_ILK_TXX_IDX_STAT1(interface), ilk_txx_idx_stat1.u64);
for (i = pstats->chan_start; i <= pstats->chan_end; i += pstats->chan_step)
{
ilk_rxx_mem_stat0.u64 = cvmx_read_csr
(CVMX_ILK_RXX_MEM_STAT0(interface));
ilk_rxx_mem_stat1.u64 = cvmx_read_csr
(CVMX_ILK_RXX_MEM_STAT1(interface));
cvmx_dprintf ("ILK%d Channel%d Rx: %d packets %d bytes\n", interface, i,
ilk_rxx_mem_stat0.s.rx_pkt,
(unsigned int) ilk_rxx_mem_stat1.s.rx_bytes);
ilk_txx_mem_stat0.u64 = cvmx_read_csr
(CVMX_ILK_TXX_MEM_STAT0(interface));
ilk_txx_mem_stat1.u64 = cvmx_read_csr
(CVMX_ILK_TXX_MEM_STAT1(interface));
cvmx_dprintf ("ILK%d Channel%d Tx: %d packets %d bytes\n", interface, i,
ilk_rxx_mem_stat0.s.rx_pkt,
(unsigned int) ilk_rxx_mem_stat1.s.rx_bytes);
}
return;
}
/**
* Initialize and start the SPI interface.
*
* @param interface The identifier of the packet interface to configure and
* use as a SPI interface.
* @param mode The operating mode for the SPI interface. The interface
* can operate as a full duplex (both Tx and Rx data paths
* active) or as a halfplex (either the Tx data path is
* active or the Rx data path is active, but not both).
* @param timeout Timeout to wait for clock synchronization in seconds
* @return Zero on success, negative of failure.
*/
int cvmx_spi_start_interface(int interface, cvmx_spi_mode_t mode, int timeout)
{
uint64_t timeout_time = cvmx_get_cycle() + 1000ull * MS * timeout;
cvmx_spxx_trn4_ctl_t spxx_trn4_ctl;
cvmx_spxx_clk_stat_t stat;
cvmx_stxx_com_ctl_t stxx_com_ctl;
cvmx_srxx_com_ctl_t srxx_com_ctl;
cvmx_stxx_spi4_dat_t stxx_spi4_dat;
uint64_t count;
cvmx_pko_reg_gmx_port_mode_t pko_mode;
if (!(OCTEON_IS_MODEL(OCTEON_CN38XX) || OCTEON_IS_MODEL(OCTEON_CN58XX)))
return -1;
cvmx_dprintf ("SPI%d: mode %s, cal_len: %d, cal_rep: %d\n",
interface, modes[mode], CAL_LEN, CAL_REP);
// Configure for 16 ports (PKO -> GMX FIFO partition setting)
// ----------------------------------------------------------
pko_mode.u64 = cvmx_read_csr(CVMX_PKO_REG_GMX_PORT_MODE);
if (interface == 0)
{
pko_mode.s.mode0 = 0;
}
else
{
pko_mode.s.mode1 = 0;
}
cvmx_write_csr(CVMX_PKO_REG_GMX_PORT_MODE, pko_mode.u64);
// Configure GMX
// -------------------------------------------------
cvmx_write_csr (CVMX_GMXX_TX_PRTS(interface), 0xA);
// PRTS [ 4: 0] ( 5b) = 10
// Bringing up Spi4 Interface
// -------------------------------------------------
// Reset the Spi4 deskew logic
// -------------------------------------------------
cvmx_write_csr (CVMX_SPXX_DBG_DESKEW_CTL(interface), 0x00200000);
// DLLDIS [ 0: 0] ( 1b) = 0
// DLLFRC [ 1: 1] ( 1b) = 0
// OFFDLY [ 7: 2] ( 6b) = 0
// BITSEL [12: 8] ( 5b) = 0
// OFFSET [17:13] ( 5b) = 0
// MUX [18:18] ( 1b) = 0
// INC [19:19] ( 1b) = 0
// DEC [20:20] ( 1b) = 0
// CLRDLY [21:21] ( 1b) = 1 // Forces a reset
cvmx_wait (100 * MS);
// Setup the CLKDLY right in the middle
// -------------------------------------------------
cvmx_write_csr (CVMX_SPXX_CLK_CTL(interface), 0x00000830);
// SRXDLCK [ 0: 0] ( 1b) = 0
// RCVTRN [ 1: 1] ( 1b) = 0
// DRPTRN [ 2: 2] ( 1b) = 0
// SNDTRN [ 3: 3] ( 1b) = 0
// STATRCV [ 4: 4] ( 1b) = 1 // Enable status channel Rx
// STATDRV [ 5: 5] ( 1b) = 1 // Enable status channel Tx
// RUNBIST [ 6: 6] ( 1b) = 0
// CLKDLY [11: 7] ( 5b) = 10 // 16 is the middle of the range
// SRXLCK [12:12] ( 1b) = 0
// STXLCK [13:13] ( 1b) = 0
// SEETRN [14:14] ( 1b) = 0
cvmx_wait (100 * MS);
// Reset SRX0 DLL
// -------------------------------------------------
cvmx_write_csr (CVMX_SPXX_CLK_CTL(interface), 0x00000831);
// SRXDLCK [ 0: 0] ( 1b) = 1 // Restart the DLL
// RCVTRN [ 1: 1] ( 1b) = 0
// DRPTRN [ 2: 2] ( 1b) = 0
// SNDTRN [ 3: 3] ( 1b) = 0
// STATRCV [ 4: 4] ( 1b) = 1
// STATDRV [ 5: 5] ( 1b) = 1
// RUNBIST [ 6: 6] ( 1b) = 0
// CLKDLY [11: 7] ( 5b) = 10
// SRXLCK [12:12] ( 1b) = 0
// STXLCK [13:13] ( 1b) = 0
// SEETRN [14:14] ( 1b) = 0
// Waiting for Inf0 Spi4 RX DLL to lock
// -------------------------------------------------
cvmx_wait (100 * MS);
// Enable dynamic alignment
// -------------------------------------------------
spxx_trn4_ctl.u64 = 0;
spxx_trn4_ctl.s.mux_en = 1;
spxx_trn4_ctl.s.macro_en = 1;
spxx_trn4_ctl.s.maxdist = 16;
spxx_trn4_ctl.s.jitter = 1;
cvmx_write_csr (CVMX_SPXX_TRN4_CTL(interface), spxx_trn4_ctl.u64);
// MUX_EN [ 0: 0] ( 1b) = 1
// MACRO_EN [ 1: 1] ( 1b) = 1
// MAXDIST [ 6: 2] ( 5b) = 16
// SET_BOOT [ 7: 7] ( 1b) = 0
// CLR_BOOT [ 8: 8] ( 1b) = 1
// JITTER [11: 9] ( 3b) = 1
// TRNTEST [12:12] ( 1b) = 0
cvmx_write_csr (CVMX_SPXX_DBG_DESKEW_CTL(interface), 0x0);
// DLLDIS [ 0: 0] ( 1b) = 0
// DLLFRC [ 1: 1] ( 1b) = 0
// OFFDLY [ 7: 2] ( 6b) = 0
// BITSEL [12: 8] ( 5b) = 0
// OFFSET [17:13] ( 5b) = 0
// MUX [18:18] ( 1b) = 0
// INC [19:19] ( 1b) = 0
// DEC [20:20] ( 1b) = 0
// CLRDLY [21:21] ( 1b) = 0
if (mode & CVMX_SPI_MODE_RX_HALFPLEX) {
// SRX0 Ports
// -------------------------------------------------
cvmx_write_csr (CVMX_SRXX_COM_CTL(interface), 0x00000090);
// INF_EN [ 0: 0] ( 1b) = 0
// ST_EN [ 3: 3] ( 1b) = 0
// PRTS [ 9: 4] ( 6b) = 9
// SRX0 Calendar Table
// -------------------------------------------------
cvmx_write_csr (CVMX_SRXX_SPI4_CALX(0, interface), 0x00013210);
// PRT0 [ 4: 0] ( 5b) = 0
// PRT1 [ 9: 5] ( 5b) = 1
// PRT2 [14:10] ( 5b) = 2
// PRT3 [19:15] ( 5b) = 3
// ODDPAR [20:20] ( 1b) = 1
cvmx_write_csr (CVMX_SRXX_SPI4_CALX(1, interface), 0x00017654);
// PRT0 [ 4: 0] ( 5b) = 4
// PRT1 [ 9: 5] ( 5b) = 5
// PRT2 [14:10] ( 5b) = 6
// PRT3 [19:15] ( 5b) = 7
// ODDPAR [20:20] ( 1b) = 1
cvmx_write_csr (CVMX_SRXX_SPI4_CALX(2, interface), 0x00000098);
// PRT0 [ 4: 0] ( 5b) = 8
// PRT1 [ 9: 5] ( 5b) = 9
// PRT2 [14:10] ( 5b) = 0
// PRT3 [19:15] ( 5b) = 0
// ODDPAR [20:20] ( 1b) = 0
cvmx_write_csr (CVMX_SRXX_SPI4_STAT(interface), (CAL_REP << 8) | CAL_LEN);
// LEN [ 7: 0] ( 8b) = a
// M [15: 8] ( 8b) = 1
}
if (mode & CVMX_SPI_MODE_TX_HALFPLEX) {
// STX0 Config
// -------------------------------------------------
cvmx_write_csr (CVMX_STXX_ARB_CTL(interface), 0x0);
// IGNTPA [ 3: 3] ( 1b) = 0
// MINTRN [ 5: 5] ( 1b) = 0
cvmx_write_csr (CVMX_GMXX_TX_SPI_MAX(interface), 0x0408);
// MAX2 [15: 8] ( 8b) = 4
// MAX1 [ 7: 0] ( 8b) = 8
cvmx_write_csr (CVMX_GMXX_TX_SPI_THRESH(interface), 0x4);
// THRESH [ 5: 0] ( 6b) = 4
cvmx_write_csr (CVMX_GMXX_TX_SPI_CTL(interface), 0x0);
// ENFORCE [ 2: 2] ( 1b) = 0
// TPA_CLR [ 1: 1] ( 1b) = 0
// CONT_PKT [ 0: 0] ( 1b) = 0
// STX0 Training Control
// -------------------------------------------------
stxx_spi4_dat.u64 = 0;
stxx_spi4_dat.s.alpha = 32; /*Minimum needed by dynamic alignment*/
stxx_spi4_dat.s.max_t = 0xFFFF; /*Minimum interval is 0x20*/
cvmx_write_csr (CVMX_STXX_SPI4_DAT(interface), stxx_spi4_dat.u64);
// MAX_T [15: 0] (16b) = 0
// ALPHA [31:16] (16b) = 0
// STX0 Calendar Table
// -------------------------------------------------
cvmx_write_csr (CVMX_STXX_SPI4_CALX(0, interface), 0x00013210);
// PRT0 [ 4: 0] ( 5b) = 0
// PRT1 [ 9: 5] ( 5b) = 1
// PRT2 [14:10] ( 5b) = 2
// PRT3 [19:15] ( 5b) = 3
// ODDPAR [20:20] ( 1b) = 1
cvmx_write_csr (CVMX_STXX_SPI4_CALX(1, interface), 0x00017654);
// PRT0 [ 4: 0] ( 5b) = 4
// PRT1 [ 9: 5] ( 5b) = 5
// PRT2 [14:10] ( 5b) = 6
// PRT3 [19:15] ( 5b) = 7
// ODDPAR [20:20] ( 1b) = 1
cvmx_write_csr (CVMX_STXX_SPI4_CALX(2, interface), 0x00000098);
// PRT0 [ 4: 0] ( 5b) = 8
// PRT1 [ 9: 5] ( 5b) = 9
// PRT2 [14:10] ( 5b) = 0
// PRT3 [19:15] ( 5b) = 0
// ODDPAR [20:20] ( 1b) = 0
cvmx_write_csr (CVMX_STXX_SPI4_STAT(interface), (CAL_REP << 8) | CAL_LEN);
// LEN [ 7: 0] ( 8b) = a
// M [15: 8] ( 8b) = 1
}
/* Regardless of operating mode, both Tx and Rx clocks must be present
* for the SPI interface to operate.
*/
cvmx_dprintf ("SPI%d: Waiting to see TsClk...\n", interface);
count = 0;
timeout_time = cvmx_get_cycle() + 1000ull * MS * timeout;
do { /* Do we see the TsClk transitioning? */
stat.u64 = cvmx_read_csr (CVMX_SPXX_CLK_STAT(interface));
count = count + 1;
#ifdef DEBUG
if ((count % 5000000) == 10) {
cvmx_dprintf ("SPI%d: CLK_STAT 0x%016llX\n"
" s4 (%d,%d) d4 (%d,%d)\n",
interface, (unsigned long long)stat.u64,
stat.s.s4clk0, stat.s.s4clk1,
stat.s.d4clk0, stat.s.d4clk1);
}
#endif
if (cvmx_get_cycle() > timeout_time)
{
cvmx_dprintf ("SPI%d: Timeout\n", interface);
return -1;
}
} while (stat.s.s4clk0 == 0 || stat.s.s4clk1 == 0);
cvmx_dprintf ("SPI%d: Waiting to see RsClk...\n", interface);
timeout_time = cvmx_get_cycle() + 1000ull * MS * timeout;
do { /* Do we see the RsClk transitioning? */
stat.u64 = cvmx_read_csr (CVMX_SPXX_CLK_STAT(interface));
if (cvmx_get_cycle() > timeout_time)
{
cvmx_dprintf ("SPI%d: Timeout\n", interface);
return -1;
}
} while (stat.s.d4clk0 == 0 || stat.s.d4clk1 == 0);
// SRX0 & STX0 Inf0 Links are configured - begin training
// -------------------------------------------------
cvmx_write_csr (CVMX_SPXX_CLK_CTL(interface), 0x0000083f);
// SRXDLCK [ 0: 0] ( 1b) = 1
// RCVTRN [ 1: 1] ( 1b) = 1
// DRPTRN [ 2: 2] ( 1b) = 1 ...was 0
// SNDTRN [ 3: 3] ( 1b) = 1
// STATRCV [ 4: 4] ( 1b) = 1
// STATDRV [ 5: 5] ( 1b) = 1
// RUNBIST [ 6: 6] ( 1b) = 0
// CLKDLY [11: 7] ( 5b) = 10
// SRXLCK [12:12] ( 1b) = 0
// STXLCK [13:13] ( 1b) = 0
// SEETRN [14:14] ( 1b) = 0
cvmx_wait (1000 * MS);
// SRX0 clear the boot bit
// -------------------------------------------------
spxx_trn4_ctl.s.clr_boot = 1;
cvmx_write_csr (CVMX_SPXX_TRN4_CTL(interface), spxx_trn4_ctl.u64);
// Wait for the training sequence to complete
// -------------------------------------------------
// SPX0_CLK_STAT - SPX0_CLK_STAT[SRXTRN] should be 1 (bit8)
cvmx_dprintf ("SPI%d: Waiting for training\n", interface);
cvmx_wait (1000 * MS);
timeout_time = cvmx_get_cycle() + 1000ull * MS * 600; /* Wait a really long time here */
do {
stat.u64 = cvmx_read_csr (CVMX_SPXX_CLK_STAT(interface));
if (cvmx_get_cycle() > timeout_time)
{
cvmx_dprintf ("SPI%d: Timeout\n", interface);
return -1;
}
} while (stat.s.srxtrn == 0);
if (mode & CVMX_SPI_MODE_RX_HALFPLEX) {
// SRX0 interface should be good, send calendar data
// -------------------------------------------------
cvmx_dprintf ("SPI%d: Rx is synchronized, start sending calendar data\n", interface);
srxx_com_ctl.u64 = 0;
srxx_com_ctl.s.prts = 9;
srxx_com_ctl.s.inf_en = 1;
srxx_com_ctl.s.st_en = 1;
cvmx_write_csr (CVMX_SRXX_COM_CTL(interface), srxx_com_ctl.u64);
}
if (mode & CVMX_SPI_MODE_TX_HALFPLEX) {
// STX0 has achieved sync
// The corespondant board should be sending calendar data
// Enable the STX0 STAT receiver.
// -------------------------------------------------
stxx_com_ctl.u64 = 0;
stxx_com_ctl.s.inf_en = 1;
stxx_com_ctl.s.st_en = 1;
cvmx_write_csr (CVMX_STXX_COM_CTL(interface), stxx_com_ctl.u64);
// Waiting for calendar sync on STX0 STAT
// -------------------------------------------------
// SPX0_CLK_STAT - SPX0_CLK_STAT[STXCAL] should be 1 (bit10)
cvmx_dprintf ("SPI%d: Waiting to sync on STX[%d] STAT\n", interface, interface);
timeout_time = cvmx_get_cycle() + 1000ull * MS * timeout;
do {
stat.u64 = cvmx_read_csr (CVMX_SPXX_CLK_STAT (interface));
if (cvmx_get_cycle() > timeout_time)
{
cvmx_dprintf ("SPI%d: Timeout\n", interface);
return -1;
}
} while (stat.s.stxcal == 0);
}
// Inf0 is synched
// -------------------------------------------------
// SPX0 is up
if (mode & CVMX_SPI_MODE_RX_HALFPLEX) {
srxx_com_ctl.s.inf_en = 1;
cvmx_write_csr (CVMX_SRXX_COM_CTL(interface), srxx_com_ctl.u64);
cvmx_dprintf ("SPI%d: Rx is now up\n", interface);
}
if (mode & CVMX_SPI_MODE_TX_HALFPLEX) {
stxx_com_ctl.s.inf_en = 1;
cvmx_write_csr (CVMX_STXX_COM_CTL(interface), stxx_com_ctl.u64);
cvmx_dprintf ("SPI%d: Tx is now up\n", interface);
}
cvmx_write_csr (CVMX_GMXX_RXX_FRM_MIN (0,interface), 40);
cvmx_write_csr (CVMX_GMXX_RXX_FRM_MAX (0,interface), 64*1024 - 4);
cvmx_write_csr (CVMX_GMXX_RXX_JABBER (0,interface), 64*1024 - 4);
return 0;
}
/**
* configure calendar for tx
*
* @param interface The identifier of the packet interface to configure and
* use as a ILK interface. cn68xx has 2 interfaces: ilk0 and
* ilk1.
*
* @param cal_depth the number of calendar entries
* @param pent pointer to calendar entries
*
* @return Zero on success, negative of failure.
*/
static int cvmx_ilk_tx_cal_conf (int interface, int cal_depth,
cvmx_ilk_cal_entry_t *pent)
{
int res = -1, num_grp, num_rest, i, j;
cvmx_ilk_txx_cfg0_t ilk_txx_cfg0;
cvmx_ilk_txx_idx_cal_t ilk_txx_idx_cal;
cvmx_ilk_txx_mem_cal0_t ilk_txx_mem_cal0;
cvmx_ilk_txx_mem_cal1_t ilk_txx_mem_cal1;
unsigned long int tmp;
cvmx_ilk_cal_entry_t *ent_tmp;
if (!(OCTEON_IS_MODEL(OCTEON_CN68XX)))
return res;
if (interface >= CVMX_NUM_ILK_INTF)
return res;
if (cal_depth < CVMX_ILK_TX_MIN_CAL || cal_depth > CVMX_ILK_MAX_CAL
|| pent == NULL)
return res;
/* mandatory link-level fc as workarounds for ILK-15397 and ILK-15479 */
/* TODO: test effectiveness */
#if 0
if (OCTEON_IS_MODEL(OCTEON_CN68XX_PASS1_0) && pent->ent_ctrl == PIPE_BPID)
for (i = 0; i < cal_depth; i++)
pent->ent_ctrl = LINK;
#endif
/* tx calendar depth must be a multiple of 8 */
num_grp = (cal_depth - 1) / CVMX_ILK_CAL_GRP_SZ + 1;
num_rest = cal_depth % CVMX_ILK_CAL_GRP_SZ;
if (num_rest != 0)
{
ent_tmp = pent + cal_depth;
for (i = num_rest; i < 8; i++, ent_tmp++)
{
ent_tmp->pipe_bpid = 0;
ent_tmp->ent_ctrl = XOFF;
}
}
cal_depth = num_grp * 8;
/* set the depth */
ilk_txx_cfg0.u64 = cvmx_read_csr (CVMX_ILK_TXX_CFG0(interface));
ilk_txx_cfg0.s.cal_depth = cal_depth;
cvmx_write_csr (CVMX_ILK_TXX_CFG0(interface), ilk_txx_cfg0.u64);
/* set the calendar index */
ilk_txx_idx_cal.u64 = 0;
ilk_txx_idx_cal.s.inc = 1;
cvmx_write_csr (CVMX_ILK_TXX_IDX_CAL(interface), ilk_txx_idx_cal.u64);
/* set the calendar entries. each group has both cal0 and cal1 registers */
for (i = 0; i < num_grp; i++)
{
ilk_txx_mem_cal0.u64 = 0;
for (j = 0; j < CVMX_ILK_CAL_GRP_SZ/2; j++)
{
tmp = 0;
tmp = pent->pipe_bpid & ~(~tmp << CVMX_ILK_PIPE_BPID_SZ);
tmp <<= (CVMX_ILK_PIPE_BPID_SZ + CVMX_ILK_ENT_CTRL_SZ) * j;
ilk_txx_mem_cal0.u64 |= tmp;
tmp = 0;
tmp = pent->ent_ctrl & ~(~tmp << CVMX_ILK_ENT_CTRL_SZ);
tmp <<= (CVMX_ILK_PIPE_BPID_SZ + CVMX_ILK_ENT_CTRL_SZ) * j +
CVMX_ILK_PIPE_BPID_SZ;
ilk_txx_mem_cal0.u64 |= tmp;
pent++;
}
cvmx_write_csr(CVMX_ILK_TXX_MEM_CAL0(interface), ilk_txx_mem_cal0.u64);
ilk_txx_mem_cal1.u64 = 0;
for (j = 0; j < CVMX_ILK_CAL_GRP_SZ/2; j++)
{
tmp = 0;
tmp = pent->pipe_bpid & ~(~tmp << CVMX_ILK_PIPE_BPID_SZ);
tmp <<= (CVMX_ILK_PIPE_BPID_SZ + CVMX_ILK_ENT_CTRL_SZ) * j;
ilk_txx_mem_cal1.u64 |= tmp;
tmp = 0;
tmp = pent->ent_ctrl & ~(~tmp << CVMX_ILK_ENT_CTRL_SZ);
tmp <<= (CVMX_ILK_PIPE_BPID_SZ + CVMX_ILK_ENT_CTRL_SZ) * j +
CVMX_ILK_PIPE_BPID_SZ;
ilk_txx_mem_cal1.u64 |= tmp;
pent++;
}
cvmx_write_csr(CVMX_ILK_TXX_MEM_CAL1(interface), ilk_txx_mem_cal1.u64);
}
cvmx_read_csr (CVMX_ILK_TXX_MEM_CAL1(interface));
return 0;
}
int early_board_init(void)
{
const int cpu_ref = 33;
/* NOTE: this is early in the init process, so the serial port is not
* yet configured
*/
/* Populate global data from eeprom */
uint8_t ee_buf[OCTEON_EEPROM_MAX_TUPLE_LENGTH];
int addr;
addr = octeon_tlv_get_tuple_addr(CONFIG_SYS_DEF_EEPROM_ADDR,
EEPROM_CLOCK_DESC_TYPE, 0, ee_buf,
OCTEON_EEPROM_MAX_TUPLE_LENGTH);
if (addr >= 0) {
memcpy((void *)&(gd->arch.clock_desc), ee_buf,
sizeof(octeon_eeprom_clock_desc_t));
}
octeon_board_get_descriptor(CVMX_BOARD_TYPE_CUST_WSX16, 1, 0);
if (OCTEON_IS_MODEL(OCTEON_CN58XX))
gd->mem_clk = 333;
else
gd->mem_clk = 266;
/*
* For the cn58xx the DDR reference clock frequency is used to
* configure the appropriate internal DDR_CK/DDR2_REF_CLK ratio in
* order to generate the ddr clock frequency specified by
* ddr_clock_mhz. For cn38xx this setting should match the state
* of the DDR2 output clock divide by 2 pin DDR2_PLL_DIV2.
*
* For DDR@_PLL_DIV2 = 0 the DDR_CK/DDR2_REF_CLK ratio is 4
* For DDR@_PLL_DIV2 = 1 the DDR_CK/DDR2_REF_CLK ratio is 2
*/
#define FIXED_DDR_REF_CLOCK_RATIO 4
/*
* More details about DDR clock configuration used for LMC
* configuration for the CN58XX. Not used for CN38XX. Since the
* reference clock frequency is not known it is inferred from the
* specified DCLK frequency divided by the DDR_CK/DDR2_REF_CLK
* ratio.
*/
if (OCTEON_IS_MODEL(OCTEON_CN38XX))
gd->arch.ddr_ref_hertz =
gd->mem_clk * 1000000 / FIXED_DDR_REF_CLOCK_RATIO;
else
gd->arch.ddr_ref_hertz = gd->mem_clk * 1000000 / 2;
octeon_board_get_mac_addr();
/* Read CPU clock multiplier */
uint64_t data = cvmx_read_csr(CVMX_DBG_DATA);
data = data >> 18;
data &= 0x1f;
gd->cpu_clk = data * cpu_ref;
/* adjust for 33.33 Mhz clock */
if (cpu_ref == 33)
gd->cpu_clk += data / 4 + data / 8;
if (gd->cpu_clk < 100 || gd->cpu_clk > 600)
gd->cpu_clk = DEFAULT_ECLK_FREQ_MHZ;
gd->cpu_clk *= 1000000;
return 0;
}
static int cvm_oct_probe(struct platform_device *pdev)
{
int num_interfaces;
int interface;
int fau = FAU_NUM_PACKET_BUFFERS_TO_FREE;
int qos;
struct device_node *pip;
int mtu_overhead = ETH_HLEN + ETH_FCS_LEN;
#if IS_ENABLED(CONFIG_VLAN_8021Q)
mtu_overhead += VLAN_HLEN;
#endif
octeon_mdiobus_force_mod_depencency();
pip = pdev->dev.of_node;
if (!pip) {
pr_err("Error: No 'pip' in /aliases\n");
return -EINVAL;
}
cvm_oct_configure_common_hw();
cvmx_helper_initialize_packet_io_global();
if (receive_group_order) {
if (receive_group_order > 4)
receive_group_order = 4;
pow_receive_groups = (1 << (1 << receive_group_order)) - 1;
} else {
pow_receive_groups = BIT(pow_receive_group);
}
/* Change the input group for all ports before input is enabled */
num_interfaces = cvmx_helper_get_number_of_interfaces();
for (interface = 0; interface < num_interfaces; interface++) {
int num_ports = cvmx_helper_ports_on_interface(interface);
int port;
for (port = cvmx_helper_get_ipd_port(interface, 0);
port < cvmx_helper_get_ipd_port(interface, num_ports);
port++) {
union cvmx_pip_prt_tagx pip_prt_tagx;
pip_prt_tagx.u64 =
cvmx_read_csr(CVMX_PIP_PRT_TAGX(port));
if (receive_group_order) {
int tag_mask;
/* We support only 16 groups at the moment, so
* always disable the two additional "hidden"
* tag_mask bits on CN68XX.
*/
if (OCTEON_IS_MODEL(OCTEON_CN68XX))
pip_prt_tagx.u64 |= 0x3ull << 44;
tag_mask = ~((1 << receive_group_order) - 1);
pip_prt_tagx.s.grptagbase = 0;
pip_prt_tagx.s.grptagmask = tag_mask;
pip_prt_tagx.s.grptag = 1;
pip_prt_tagx.s.tag_mode = 0;
pip_prt_tagx.s.inc_prt_flag = 1;
pip_prt_tagx.s.ip6_dprt_flag = 1;
pip_prt_tagx.s.ip4_dprt_flag = 1;
pip_prt_tagx.s.ip6_sprt_flag = 1;
pip_prt_tagx.s.ip4_sprt_flag = 1;
pip_prt_tagx.s.ip6_dst_flag = 1;
pip_prt_tagx.s.ip4_dst_flag = 1;
pip_prt_tagx.s.ip6_src_flag = 1;
pip_prt_tagx.s.ip4_src_flag = 1;
pip_prt_tagx.s.grp = 0;
} else {
pip_prt_tagx.s.grptag = 0;
pip_prt_tagx.s.grp = pow_receive_group;
}
cvmx_write_csr(CVMX_PIP_PRT_TAGX(port),
pip_prt_tagx.u64);
}
}
cvmx_helper_ipd_and_packet_input_enable();
memset(cvm_oct_device, 0, sizeof(cvm_oct_device));
/*
* Initialize the FAU used for counting packet buffers that
* need to be freed.
*/
cvmx_fau_atomic_write32(FAU_NUM_PACKET_BUFFERS_TO_FREE, 0);
/* Initialize the FAU used for counting tx SKBs that need to be freed */
cvmx_fau_atomic_write32(FAU_TOTAL_TX_TO_CLEAN, 0);
if ((pow_send_group != -1)) {
struct net_device *dev;
dev = alloc_etherdev(sizeof(struct octeon_ethernet));
if (dev) {
/* Initialize the device private structure. */
struct octeon_ethernet *priv = netdev_priv(dev);
SET_NETDEV_DEV(dev, &pdev->dev);
dev->netdev_ops = &cvm_oct_pow_netdev_ops;
priv->imode = CVMX_HELPER_INTERFACE_MODE_DISABLED;
priv->port = CVMX_PIP_NUM_INPUT_PORTS;
priv->queue = -1;
strcpy(dev->name, "pow%d");
for (qos = 0; qos < 16; qos++)
skb_queue_head_init(&priv->tx_free_list[qos]);
dev->min_mtu = VLAN_ETH_ZLEN - mtu_overhead;
dev->max_mtu = OCTEON_MAX_MTU - mtu_overhead;
if (register_netdev(dev) < 0) {
pr_err("Failed to register ethernet device for POW\n");
free_netdev(dev);
} else {
cvm_oct_device[CVMX_PIP_NUM_INPUT_PORTS] = dev;
pr_info("%s: POW send group %d, receive group %d\n",
dev->name, pow_send_group,
pow_receive_group);
}
} else {
pr_err("Failed to allocate ethernet device for POW\n");
}
}
num_interfaces = cvmx_helper_get_number_of_interfaces();
for (interface = 0; interface < num_interfaces; interface++) {
cvmx_helper_interface_mode_t imode =
cvmx_helper_interface_get_mode(interface);
int num_ports = cvmx_helper_ports_on_interface(interface);
int port;
int port_index;
for (port_index = 0,
port = cvmx_helper_get_ipd_port(interface, 0);
port < cvmx_helper_get_ipd_port(interface, num_ports);
port_index++, port++) {
struct octeon_ethernet *priv;
struct net_device *dev =
alloc_etherdev(sizeof(struct octeon_ethernet));
if (!dev) {
pr_err("Failed to allocate ethernet device for port %d\n",
port);
continue;
}
/* Initialize the device private structure. */
SET_NETDEV_DEV(dev, &pdev->dev);
priv = netdev_priv(dev);
priv->netdev = dev;
priv->of_node = cvm_oct_node_for_port(pip, interface,
port_index);
INIT_DELAYED_WORK(&priv->port_periodic_work,
cvm_oct_periodic_worker);
priv->imode = imode;
priv->port = port;
priv->queue = cvmx_pko_get_base_queue(priv->port);
priv->fau = fau - cvmx_pko_get_num_queues(port) * 4;
for (qos = 0; qos < 16; qos++)
skb_queue_head_init(&priv->tx_free_list[qos]);
for (qos = 0; qos < cvmx_pko_get_num_queues(port);
qos++)
cvmx_fau_atomic_write32(priv->fau + qos * 4, 0);
dev->min_mtu = VLAN_ETH_ZLEN - mtu_overhead;
dev->max_mtu = OCTEON_MAX_MTU - mtu_overhead;
switch (priv->imode) {
/* These types don't support ports to IPD/PKO */
case CVMX_HELPER_INTERFACE_MODE_DISABLED:
case CVMX_HELPER_INTERFACE_MODE_PCIE:
case CVMX_HELPER_INTERFACE_MODE_PICMG:
break;
case CVMX_HELPER_INTERFACE_MODE_NPI:
dev->netdev_ops = &cvm_oct_npi_netdev_ops;
strcpy(dev->name, "npi%d");
break;
case CVMX_HELPER_INTERFACE_MODE_XAUI:
dev->netdev_ops = &cvm_oct_xaui_netdev_ops;
strcpy(dev->name, "xaui%d");
break;
case CVMX_HELPER_INTERFACE_MODE_LOOP:
dev->netdev_ops = &cvm_oct_npi_netdev_ops;
strcpy(dev->name, "loop%d");
break;
case CVMX_HELPER_INTERFACE_MODE_SGMII:
dev->netdev_ops = &cvm_oct_sgmii_netdev_ops;
strcpy(dev->name, "eth%d");
break;
case CVMX_HELPER_INTERFACE_MODE_SPI:
dev->netdev_ops = &cvm_oct_spi_netdev_ops;
strcpy(dev->name, "spi%d");
break;
case CVMX_HELPER_INTERFACE_MODE_RGMII:
case CVMX_HELPER_INTERFACE_MODE_GMII:
dev->netdev_ops = &cvm_oct_rgmii_netdev_ops;
strcpy(dev->name, "eth%d");
cvm_set_rgmii_delay(priv->of_node, interface,
port_index);
break;
}
if (!dev->netdev_ops) {
free_netdev(dev);
} else if (register_netdev(dev) < 0) {
pr_err("Failed to register ethernet device for interface %d, port %d\n",
interface, priv->port);
free_netdev(dev);
} else {
cvm_oct_device[priv->port] = dev;
fau -=
cvmx_pko_get_num_queues(priv->port) *
sizeof(u32);
schedule_delayed_work(&priv->port_periodic_work,
HZ);
}
}
}
cvm_oct_tx_initialize();
cvm_oct_rx_initialize();
/*
* 150 uS: about 10 1500-byte packets at 1GE.
*/
cvm_oct_tx_poll_interval = 150 * (octeon_get_clock_rate() / 1000000);
schedule_delayed_work(&cvm_oct_rx_refill_work, HZ);
return 0;
}
/**
* Measure the reference clock of a QLM
*
* @param qlm QLM to measure
*
* @return Clock rate in Hz
* */
int cvmx_qlm_measure_clock(int qlm)
{
cvmx_mio_ptp_clock_cfg_t ptp_clock;
uint64_t count;
uint64_t start_cycle, stop_cycle;
#ifdef CVMX_BUILD_FOR_UBOOT
int ref_clock[16] = {0};
#else
static int ref_clock[16] = {0};
#endif
if (ref_clock[qlm])
return ref_clock[qlm];
if (OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX))
return -1;
/* Force the reference to 156.25Mhz when running in simulation.
This supports the most speeds */
#ifdef CVMX_BUILD_FOR_UBOOT
if (gd->arch.board_desc.board_type == CVMX_BOARD_TYPE_SIM)
return 156250000;
#elif !defined(CVMX_BUILD_FOR_LINUX_HOST)
if (cvmx_sysinfo_get()->board_type == CVMX_BOARD_TYPE_SIM)
return 156250000;
#endif
/* Disable the PTP event counter while we configure it */
ptp_clock.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG); /* For CN63XXp1 errata */
ptp_clock.s.evcnt_en = 0;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp_clock.u64);
/* Count on rising edge, Choose which QLM to count */
ptp_clock.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG); /* For CN63XXp1 errata */
ptp_clock.s.evcnt_edge = 0;
ptp_clock.s.evcnt_in = 0x10 + qlm;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp_clock.u64);
/* Clear MIO_PTP_EVT_CNT */
cvmx_read_csr(CVMX_MIO_PTP_EVT_CNT); /* For CN63XXp1 errata */
count = cvmx_read_csr(CVMX_MIO_PTP_EVT_CNT);
cvmx_write_csr(CVMX_MIO_PTP_EVT_CNT, -count);
/* Set MIO_PTP_EVT_CNT to 1 billion */
cvmx_write_csr(CVMX_MIO_PTP_EVT_CNT, 1000000000);
/* Enable the PTP event counter */
ptp_clock.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG); /* For CN63XXp1 errata */
ptp_clock.s.evcnt_en = 1;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp_clock.u64);
start_cycle = cvmx_clock_get_count(CVMX_CLOCK_CORE);
/* Wait for 50ms */
cvmx_wait_usec(50000);
/* Read the counter */
cvmx_read_csr(CVMX_MIO_PTP_EVT_CNT); /* For CN63XXp1 errata */
count = cvmx_read_csr(CVMX_MIO_PTP_EVT_CNT);
stop_cycle = cvmx_clock_get_count(CVMX_CLOCK_CORE);
/* Disable the PTP event counter */
ptp_clock.u64 = cvmx_read_csr(CVMX_MIO_PTP_CLOCK_CFG); /* For CN63XXp1 errata */
ptp_clock.s.evcnt_en = 0;
cvmx_write_csr(CVMX_MIO_PTP_CLOCK_CFG, ptp_clock.u64);
/* Clock counted down, so reverse it */
count = 1000000000 - count;
/* Return the rate */
ref_clock[qlm] = count * cvmx_clock_get_rate(CVMX_CLOCK_CORE) / (stop_cycle - start_cycle);
return ref_clock[qlm];
}
int board_fixup_fdt(void)
{
char fdt_key[16];
int qlm;
char env_var[16];
const char *mode;
int node;
/* First patch the PHY configuration based on board revision */
octeon_fdt_patch_rename((void *)(gd->fdt_blob),
gd->arch.board_desc.rev_major == 1
? "0,rev1" : "0,notrev1",
"cavium,board-trim", false, NULL, NULL);
/* Next patch CPU revision chages */
for (node = 0; node < CVMX_MAX_NODES; node++) {
if (!(gd->arch.node_mask & (1 << node)))
continue;
if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0))
sprintf(fdt_key, "%d,rev1.0", node);
else
sprintf(fdt_key, "%d,notrev1.0", node);
octeon_fdt_patch((void *)(gd->fdt_blob), fdt_key, "cavium,cpu-trim");
}
for (qlm = 0; qlm < 8; qlm++) {
sprintf(env_var, "qlm%d:%d_mode", qlm, 0);
mode = getenv(env_var);
sprintf(fdt_key, "%d,none", qlm);
if (!mode) {
sprintf(fdt_key, "%d,none", qlm);
} else if (!strncmp(mode, "sgmii", 5)) {
sprintf(fdt_key, "%d,sgmii", qlm);
} else if (!strncmp(mode, "xaui", 4)) {
sprintf(fdt_key, "%d,xaui", qlm);
} else if (!strncmp(mode, "dxaui", 5)) {
sprintf(fdt_key, "%d,dxaui", qlm);
} else if (!strcmp(mode, "ilk")) {
if (qlm < 4)
printf("Error: ILK not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,ilk", qlm);
} else if (!strncmp(mode, "rxaui", 5)) {
sprintf(fdt_key, "%d,rxaui", qlm);
} else if (!strncmp(mode, "xlaui", 5)) {
if (qlm < 4)
printf("Error: XLAUI not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,xlaui", qlm);
} else if (!strncmp(mode, "xfi", 3)) {
if (qlm < 4)
printf("Error: XFI not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,xfi", qlm);
} else if (!strncmp(mode, "10G_KR", 6)) {
if (qlm < 4)
printf("Error: 10G_KR not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,10G_KR", qlm);
} else if (!strncmp(mode, "40G_KR4", 7)) {
if (qlm < 4)
printf("Error: 40G_KR4 not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,40G_KR4", qlm);
}
debug("Patching qlm %d for %s\n", qlm, fdt_key);
octeon_fdt_patch_rename((void *)gd->fdt_blob, fdt_key, NULL, true,
strstr(mode, ",no_phy") ? kill_fdt_phy : NULL, NULL);
}
/* Test for node 1 */
if (!(gd->arch.node_mask & (1 << 1))) {
octeon_fdt_patch((void *)(gd->fdt_blob), "1,none",
"cavium,node-trim");
goto final_cleanup;
}
/* This won't do anything if node 1 is missing */
for (qlm = 10; qlm < 18; qlm++) {
sprintf(env_var, "qlm%d:%d_mode", qlm - 10, 1);
mode = getenv(env_var);
sprintf(fdt_key, "%d,none", qlm);
if (!mode) {
sprintf(fdt_key, "%d,none", qlm);
} else if (!strncmp(mode, "sgmii", 5)) {
sprintf(fdt_key, "%d,sgmii", qlm);
} else if (!strncmp(mode, "xaui", 4)) {
sprintf(fdt_key, "%d,xaui", qlm);
} else if (!strncmp(mode, "dxaui", 5)) {
sprintf(fdt_key, "%d,dxaui", qlm);
} else if (!strcmp(mode, "ilk")) {
if (qlm < 4)
printf("Error: ILK not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,ilk", qlm);
} else if (!strncmp(mode, "rxaui", 5)) {
sprintf(fdt_key, "%d,rxaui", qlm);
} else if (!strncmp(mode, "xlaui", 5)) {
if (qlm < 4)
printf("Error: XLAUI not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,xlaui", qlm);
} else if (!strncmp(mode, "xfi", 3)) {
if (qlm < 4)
printf("Error: XFI not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,xfi", qlm);
} else if (!strncmp(mode, "10G_KR", 6)) {
if (qlm < 4)
printf("Error: 10G_KR not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,10G_KR", qlm);
} else if (!strncmp(mode, "40G_KR4", 7)) {
if (qlm < 4)
printf("Error: 40G_KR4 not supported on QLM %d\n",
qlm);
else
sprintf(fdt_key, "%d,40G_KR4", qlm);
}
debug("Patching qlm %d for %s\n", qlm, fdt_key);
octeon_fdt_patch_rename((void *)gd->fdt_blob, fdt_key, NULL, true,
strstr(mode, ",no_phy") ? kill_fdt_phy : NULL, NULL);
}
final_cleanup:
node = fdt_node_offset_by_compatible((void *)gd->fdt_blob, -1, "cavium,octeon-7890-bgx");
while (node != -FDT_ERR_NOTFOUND) {
int depth = 0;
int child = fdt_next_node((void *)gd->fdt_blob, node, &depth);
if (depth != 1)
fdt_nop_node((void *)gd->fdt_blob, node);
node = fdt_node_offset_by_compatible((void *)gd->fdt_blob, node, "cavium,octeon-7890-bgx");
}
return 0;
}
/**
* Errata G-16094: QLM Gen2 Equalizer Default Setting Change.
* CN68XX pass 1.x and CN66XX pass 1.x QLM tweak. This function tweaks the
* JTAG setting for a QLMs to run better at 5 and 6.25Ghz.
*/
void __cvmx_qlm_speed_tweak(void)
{
cvmx_mio_qlmx_cfg_t qlm_cfg;
int num_qlms = cvmx_qlm_get_num();
int qlm;
/* Workaround for Errata (G-16467) */
if (OCTEON_IS_MODEL(OCTEON_CN68XX_PASS2_X)) {
for (qlm = 0; qlm < num_qlms; qlm++) {
int ir50dac;
/* This workaround only applies to QLMs running at 6.25Ghz */
if (cvmx_qlm_get_gbaud_mhz(qlm) == 6250) {
#ifdef CVMX_QLM_DUMP_STATE
cvmx_dprintf("%s:%d: QLM%d: Applying workaround for Errata G-16467\n", __func__, __LINE__, qlm);
cvmx_qlm_display_registers(qlm);
cvmx_dprintf("\n");
#endif
cvmx_qlm_jtag_set(qlm, -1, "cfg_cdr_trunc", 0);
/* Hold the QLM in reset */
cvmx_qlm_jtag_set(qlm, -1, "cfg_rst_n_set", 0);
cvmx_qlm_jtag_set(qlm, -1, "cfg_rst_n_clr", 1);
/* Forcfe TX to be idle */
cvmx_qlm_jtag_set(qlm, -1, "cfg_tx_idle_clr", 0);
cvmx_qlm_jtag_set(qlm, -1, "cfg_tx_idle_set", 1);
if (OCTEON_IS_MODEL(OCTEON_CN68XX_PASS2_0)) {
ir50dac = cvmx_qlm_jtag_get(qlm, 0, "ir50dac");
while (++ir50dac <= 31)
cvmx_qlm_jtag_set(qlm, -1, "ir50dac", ir50dac);
}
cvmx_qlm_jtag_set(qlm, -1, "div4_byp", 0);
cvmx_qlm_jtag_set(qlm, -1, "clkf_byp", 16);
cvmx_qlm_jtag_set(qlm, -1, "serdes_pll_byp", 1);
cvmx_qlm_jtag_set(qlm, -1, "spdsel_byp", 1);
#ifdef CVMX_QLM_DUMP_STATE
cvmx_dprintf("%s:%d: QLM%d: Done applying workaround for Errata G-16467\n", __func__, __LINE__, qlm);
cvmx_qlm_display_registers(qlm);
cvmx_dprintf("\n\n");
#endif
/* The QLM will be taken out of reset later when ILK/XAUI are initialized. */
}
}
#ifndef CVMX_BUILD_FOR_LINUX_HOST
/* These QLM tuning parameters are specific to EBB6800
eval boards using Cavium QLM cables. These should be
removed or tunned based on customer boards. */
if (cvmx_sysinfo_get()->board_type == CVMX_BOARD_TYPE_EBB6800) {
for (qlm = 0; qlm < num_qlms; qlm++) {
#ifdef CVMX_QLM_DUMP_STATE
cvmx_dprintf("Setting tunning parameters for QLM%d\n", qlm);
#endif
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_hs_ls_byp", 12);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_hf_byp", 12);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_lf_ls_byp", 12);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_lf_byp", 12);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_hf_byp", 15);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_hf_ls_byp", 15);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_lf_ls_byp", 15);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_lf_byp", 15);
cvmx_qlm_jtag_set(qlm, -1, "rx_cap_gen2", 0);
cvmx_qlm_jtag_set(qlm, -1, "rx_eq_gen2", 11);
cvmx_qlm_jtag_set(qlm, -1, "serdes_tx_byp", 1);
}
}
else if (cvmx_sysinfo_get()->board_type == CVMX_BOARD_TYPE_NIC68_4) {
for (qlm = 0; qlm < num_qlms; qlm++) {
#ifdef CVMX_QLM_DUMP_STATE
cvmx_dprintf("Setting tunning parameters for QLM%d\n", qlm);
#endif
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_hs_ls_byp", 30);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_hf_byp", 30);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_lf_ls_byp", 30);
cvmx_qlm_jtag_set(qlm, -1, "biasdrv_lf_byp", 30);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_hf_byp", 0);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_hf_ls_byp", 0);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_lf_ls_byp", 0);
cvmx_qlm_jtag_set(qlm, -1, "tcoeff_lf_byp", 0);
cvmx_qlm_jtag_set(qlm, -1, "rx_cap_gen2", 1);
cvmx_qlm_jtag_set(qlm, -1, "rx_eq_gen2", 8);
cvmx_qlm_jtag_set(qlm, -1, "serdes_tx_byp", 1);
}
}
#endif
}
/* G-16094 QLM Gen2 Equalizer Default Setting Change */
else if (OCTEON_IS_MODEL(OCTEON_CN68XX_PASS1_X)
|| OCTEON_IS_MODEL(OCTEON_CN66XX_PASS1_X)) {
/* Loop through the QLMs */
for (qlm = 0; qlm < num_qlms; qlm++) {
/* Read the QLM speed */
qlm_cfg.u64 = cvmx_read_csr(CVMX_MIO_QLMX_CFG(qlm));
/* If the QLM is at 6.25Ghz or 5Ghz then program JTAG */
if ((qlm_cfg.s.qlm_spd == 5) || (qlm_cfg.s.qlm_spd == 12) || (qlm_cfg.s.qlm_spd == 0) || (qlm_cfg.s.qlm_spd == 6) || (qlm_cfg.s.qlm_spd == 11)) {
cvmx_qlm_jtag_set(qlm, -1, "rx_cap_gen2", 0x1);
cvmx_qlm_jtag_set(qlm, -1, "rx_eq_gen2", 0x8);
}
}
}
}
/**
* Configure common hardware for all interfaces
*/
static void cvm_oct_configure_common_hw(device_t bus)
{
struct octebus_softc *sc;
int pko_queues;
int error;
int rid;
sc = device_get_softc(bus);
/* Setup the FPA */
cvmx_fpa_enable();
cvm_oct_mem_fill_fpa(CVMX_FPA_PACKET_POOL, CVMX_FPA_PACKET_POOL_SIZE,
num_packet_buffers);
cvm_oct_mem_fill_fpa(CVMX_FPA_WQE_POOL, CVMX_FPA_WQE_POOL_SIZE,
num_packet_buffers);
if (CVMX_FPA_OUTPUT_BUFFER_POOL != CVMX_FPA_PACKET_POOL) {
/*
* If the FPA uses different pools for output buffers and
* packets, size the output buffer pool based on the number
* of PKO queues.
*/
if (OCTEON_IS_MODEL(OCTEON_CN38XX))
pko_queues = 128;
else if (OCTEON_IS_MODEL(OCTEON_CN3XXX))
pko_queues = 32;
else if (OCTEON_IS_MODEL(OCTEON_CN50XX))
pko_queues = 32;
else
pko_queues = 256;
cvm_oct_num_output_buffers = 4 * pko_queues;
cvm_oct_mem_fill_fpa(CVMX_FPA_OUTPUT_BUFFER_POOL,
CVMX_FPA_OUTPUT_BUFFER_POOL_SIZE,
cvm_oct_num_output_buffers);
}
if (USE_RED)
cvmx_helper_setup_red(num_packet_buffers/4,
num_packet_buffers/8);
/* Enable the MII interface */
if (cvmx_sysinfo_get()->board_type != CVMX_BOARD_TYPE_SIM)
cvmx_write_csr(CVMX_SMI_EN, 1);
/* Register an IRQ hander for to receive POW interrupts */
rid = 0;
sc->sc_rx_irq = bus_alloc_resource(bus, SYS_RES_IRQ, &rid,
OCTEON_IRQ_WORKQ0 + pow_receive_group,
OCTEON_IRQ_WORKQ0 + pow_receive_group,
1, RF_ACTIVE);
if (sc->sc_rx_irq == NULL) {
device_printf(bus, "could not allocate workq irq");
return;
}
error = bus_setup_intr(bus, sc->sc_rx_irq, INTR_TYPE_NET | INTR_MPSAFE,
cvm_oct_do_interrupt, NULL, cvm_oct_device,
&sc->sc_rx_intr_cookie);
if (error != 0) {
device_printf(bus, "could not setup workq irq");
return;
}
#ifdef SMP
{
cvmx_ciu_intx0_t en;
int core;
CPU_FOREACH(core) {
if (core == PCPU_GET(cpuid))
continue;
en.u64 = cvmx_read_csr(CVMX_CIU_INTX_EN0(core*2));
en.s.workq |= (1<<pow_receive_group);
cvmx_write_csr(CVMX_CIU_INTX_EN0(core*2), en.u64);
}
}
#endif
}
static void __cvmx_ipd_free_ptr_v1(void)
{
unsigned wqe_pool = cvmx_fpa_get_wqe_pool();
int i;
union cvmx_ipd_ptr_count ptr_count;
union cvmx_ipd_prc_port_ptr_fifo_ctl prc_port_fifo;
int packet_pool = (int)cvmx_fpa_get_packet_pool();
/* Only CN38XXp{1,2} cannot read pointer out of the IPD */
if (OCTEON_IS_MODEL(OCTEON_CN38XX_PASS2))
return;
ptr_count.u64 = cvmx_read_csr(CVMX_IPD_PTR_COUNT);
/* Handle Work Queue Entry in cn56xx and cn52xx */
if (octeon_has_feature(OCTEON_FEATURE_NO_WPTR)) {
union cvmx_ipd_ctl_status ctl_status;
ctl_status.u64 = cvmx_read_csr(CVMX_IPD_CTL_STATUS);
if (ctl_status.s.no_wptr)
wqe_pool = packet_pool;
}
/* Free the prefetched WQE */
if (ptr_count.s.wqev_cnt) {
union cvmx_ipd_wqe_ptr_valid wqe_ptr_valid;
wqe_ptr_valid.u64 = cvmx_read_csr(CVMX_IPD_WQE_PTR_VALID);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)wqe_ptr_valid.s.ptr << 7),
wqe_pool, 0);
}
/* Free all WQE in the fifo */
if (ptr_count.s.wqe_pcnt) {
int i;
union cvmx_ipd_pwp_ptr_fifo_ctl pwp_fifo;
pwp_fifo.u64 = cvmx_read_csr(CVMX_IPD_PWP_PTR_FIFO_CTL);
for (i = 0; i < ptr_count.s.wqe_pcnt; i++) {
pwp_fifo.s.cena = 0;
pwp_fifo.s.raddr = pwp_fifo.s.max_cnts + (pwp_fifo.s.wraddr + i) % pwp_fifo.s.max_cnts;
cvmx_write_csr(CVMX_IPD_PWP_PTR_FIFO_CTL, pwp_fifo.u64);
pwp_fifo.u64 = cvmx_read_csr(CVMX_IPD_PWP_PTR_FIFO_CTL);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)pwp_fifo.s.ptr << 7),
wqe_pool, 0);
}
pwp_fifo.s.cena = 1;
cvmx_write_csr(CVMX_IPD_PWP_PTR_FIFO_CTL, pwp_fifo.u64);
}
/* Free the prefetched packet */
if (ptr_count.s.pktv_cnt) {
union cvmx_ipd_pkt_ptr_valid pkt_ptr_valid;
pkt_ptr_valid.u64 = cvmx_read_csr(CVMX_IPD_PKT_PTR_VALID);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)pkt_ptr_valid.s.ptr << 7),
packet_pool, 0);
}
/* Free the per port prefetched packets */
prc_port_fifo.u64 = cvmx_read_csr(CVMX_IPD_PRC_PORT_PTR_FIFO_CTL);
for (i = 0; i < prc_port_fifo.s.max_pkt; i++) {
prc_port_fifo.s.cena = 0;
prc_port_fifo.s.raddr = i % prc_port_fifo.s.max_pkt;
cvmx_write_csr(CVMX_IPD_PRC_PORT_PTR_FIFO_CTL,
prc_port_fifo.u64);
prc_port_fifo.u64 = cvmx_read_csr(CVMX_IPD_PRC_PORT_PTR_FIFO_CTL);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)prc_port_fifo.s.ptr << 7),
packet_pool, 0);
}
prc_port_fifo.s.cena = 1;
cvmx_write_csr(CVMX_IPD_PRC_PORT_PTR_FIFO_CTL, prc_port_fifo.u64);
/* Free all packets in the holding fifo */
if (ptr_count.s.pfif_cnt) {
int i;
union cvmx_ipd_prc_hold_ptr_fifo_ctl prc_hold_fifo;
prc_hold_fifo.u64 = cvmx_read_csr(CVMX_IPD_PRC_HOLD_PTR_FIFO_CTL);
for (i = 0; i < ptr_count.s.pfif_cnt; i++) {
prc_hold_fifo.s.cena = 0;
prc_hold_fifo.s.raddr = (prc_hold_fifo.s.praddr + i) % prc_hold_fifo.s.max_pkt;
cvmx_write_csr(CVMX_IPD_PRC_HOLD_PTR_FIFO_CTL,
prc_hold_fifo.u64);
prc_hold_fifo.u64 = cvmx_read_csr(CVMX_IPD_PRC_HOLD_PTR_FIFO_CTL);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)prc_hold_fifo.s.ptr << 7),
packet_pool, 0);
}
prc_hold_fifo.s.cena = 1;
cvmx_write_csr(CVMX_IPD_PRC_HOLD_PTR_FIFO_CTL,
prc_hold_fifo.u64);
}
/* Free all packets in the fifo */
if (ptr_count.s.pkt_pcnt) {
int i;
union cvmx_ipd_pwp_ptr_fifo_ctl pwp_fifo;
pwp_fifo.u64 = cvmx_read_csr(CVMX_IPD_PWP_PTR_FIFO_CTL);
for (i = 0; i < ptr_count.s.pkt_pcnt; i++) {
pwp_fifo.s.cena = 0;
pwp_fifo.s.raddr = (pwp_fifo.s.praddr + i) % pwp_fifo.s.max_cnts;
cvmx_write_csr(CVMX_IPD_PWP_PTR_FIFO_CTL, pwp_fifo.u64);
pwp_fifo.u64 = cvmx_read_csr(CVMX_IPD_PWP_PTR_FIFO_CTL);
cvmx_fpa_free(cvmx_phys_to_ptr((uint64_t)pwp_fifo.s.ptr << 7),
packet_pool, 0);
}
pwp_fifo.s.cena = 1;
cvmx_write_csr(CVMX_IPD_PWP_PTR_FIFO_CTL, pwp_fifo.u64);
}
}
