u-boot/drivers/net/sja1105.c

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net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright 2016-2018 NXP
* Copyright 2018, Sensor-Technik Wiedemann GmbH
* Copyright 2018-2019, Vladimir Oltean <olteanv@gmail.com>
* Copyright 2020-2021 NXP
*
* Ported from Linux (drivers/net/dsa/sja1105/).
*/
#include <common.h>
#include <dm/device_compat.h>
#include <linux/bitops.h>
#include <linux/bitrev.h>
#include <linux/errno.h>
#include <linux/delay.h>
#include <linux/if_ether.h>
#include <linux/if_vlan.h>
#include <linux/types.h>
#include <net/dsa.h>
#include <stdlib.h>
#include <spi.h>
#include <miiphy.h>
#include <dm/of_extra.h>
enum packing_op {
PACK,
UNPACK,
};
#define ETHER_CRC32_POLY 0x04C11DB7
#define ETH_P_SJA1105 0xdadb
#define SJA1105_NUM_PORTS 5
#define SJA1110_NUM_PORTS 11
#define SJA1105_MAX_NUM_PORTS SJA1110_NUM_PORTS
#define SJA1105_NUM_TC 8
#define SJA1105ET_FDB_BIN_SIZE 4
#define SJA1105_SIZE_CGU_CMD 4
#define SJA1105_SIZE_RESET_CMD 4
#define SJA1105_SIZE_MDIO_CMD 4
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
#define SJA1105_SIZE_SPI_MSG_HEADER 4
#define SJA1105_SIZE_SPI_MSG_MAXLEN (64 * 4)
#define SJA1105_SIZE_DEVICE_ID 4
#define SJA1105_SIZE_TABLE_HEADER 12
#define SJA1105_SIZE_L2_POLICING_ENTRY 8
#define SJA1105_SIZE_VLAN_LOOKUP_ENTRY 8
#define SJA1110_SIZE_VLAN_LOOKUP_ENTRY 12
#define SJA1105_SIZE_L2_FORWARDING_ENTRY 8
#define SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY 12
#define SJA1105_SIZE_XMII_PARAMS_ENTRY 4
#define SJA1110_SIZE_XMII_PARAMS_ENTRY 8
#define SJA1105ET_SIZE_MAC_CONFIG_ENTRY 28
#define SJA1105ET_SIZE_GENERAL_PARAMS_ENTRY 40
#define SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY 32
#define SJA1105PQRS_SIZE_GENERAL_PARAMS_ENTRY 44
#define SJA1110_SIZE_GENERAL_PARAMS_ENTRY 56
#define SJA1105_MAX_L2_LOOKUP_COUNT 1024
#define SJA1105_MAX_L2_POLICING_COUNT 45
#define SJA1110_MAX_L2_POLICING_COUNT 110
#define SJA1105_MAX_VLAN_LOOKUP_COUNT 4096
#define SJA1105_MAX_L2_FORWARDING_COUNT 13
#define SJA1110_MAX_L2_FORWARDING_COUNT 19
#define SJA1105_MAX_MAC_CONFIG_COUNT 5
#define SJA1110_MAX_MAC_CONFIG_COUNT 11
#define SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT 1
#define SJA1105_MAX_GENERAL_PARAMS_COUNT 1
#define SJA1105_MAX_XMII_PARAMS_COUNT 1
#define SJA1105_MAX_FRAME_MEMORY 929
#define SJA1105E_DEVICE_ID 0x9C00000Cull
#define SJA1105T_DEVICE_ID 0x9E00030Eull
#define SJA1105PR_DEVICE_ID 0xAF00030Eull
#define SJA1105QS_DEVICE_ID 0xAE00030Eull
#define SJA1110_DEVICE_ID 0xB700030Full
#define SJA1105ET_PART_NO 0x9A83
#define SJA1105P_PART_NO 0x9A84
#define SJA1105Q_PART_NO 0x9A85
#define SJA1105R_PART_NO 0x9A86
#define SJA1105S_PART_NO 0x9A87
#define SJA1110A_PART_NO 0x1110
#define SJA1110B_PART_NO 0x1111
#define SJA1110C_PART_NO 0x1112
#define SJA1110D_PART_NO 0x1113
#define SJA1110_ACU 0x1c4400
#define SJA1110_RGU 0x1c6000
#define SJA1110_CGU 0x1c6400
#define SJA1110_SPI_ADDR(x) ((x) / 4)
#define SJA1110_ACU_ADDR(x) (SJA1110_ACU + SJA1110_SPI_ADDR(x))
#define SJA1110_CGU_ADDR(x) (SJA1110_CGU + SJA1110_SPI_ADDR(x))
#define SJA1110_RGU_ADDR(x) (SJA1110_RGU + SJA1110_SPI_ADDR(x))
#define SJA1105_RSV_ADDR 0xffffffffffffffffull
#define SJA1110_PCS_BANK_REG SJA1110_SPI_ADDR(0x3fc)
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
#define DSA_8021Q_DIR_TX BIT(11)
#define DSA_8021Q_PORT_SHIFT 0
#define DSA_8021Q_PORT_MASK GENMASK(3, 0)
#define DSA_8021Q_PORT(x) (((x) << DSA_8021Q_PORT_SHIFT) & \
DSA_8021Q_PORT_MASK)
#define SJA1105_RATE_MBPS(speed) (((speed) * 64000) / 1000)
/* XPCS registers */
/* VR MII MMD registers offsets */
#define DW_VR_MII_DIG_CTRL1 0x8000
#define DW_VR_MII_AN_CTRL 0x8001
#define DW_VR_MII_DIG_CTRL2 0x80e1
/* VR_MII_DIG_CTRL1 */
#define DW_VR_MII_DIG_CTRL1_MAC_AUTO_SW BIT(9)
/* VR_MII_DIG_CTRL2 */
#define DW_VR_MII_DIG_CTRL2_TX_POL_INV BIT(4)
/* VR_MII_AN_CTRL */
#define DW_VR_MII_AN_CTRL_TX_CONFIG_SHIFT 3
#define DW_VR_MII_TX_CONFIG_MASK BIT(3)
#define DW_VR_MII_TX_CONFIG_MAC_SIDE_SGMII 0x0
#define DW_VR_MII_AN_CTRL_PCS_MODE_SHIFT 1
#define DW_VR_MII_PCS_MODE_MASK GENMASK(2, 1)
#define DW_VR_MII_PCS_MODE_C37_SGMII 0x2
/* PMA registers */
/* LANE_DRIVER1_0 register */
#define SJA1110_LANE_DRIVER1_0 0x8038
#define SJA1110_TXDRV(x) (((x) << 12) & GENMASK(14, 12))
/* LANE_DRIVER2_0 register */
#define SJA1110_LANE_DRIVER2_0 0x803a
#define SJA1110_TXDRVTRIM_LSB(x) ((x) & GENMASK_ULL(15, 0))
/* LANE_DRIVER2_1 register */
#define SJA1110_LANE_DRIVER2_1 0x803b
#define SJA1110_LANE_DRIVER2_1_RSV BIT(9)
#define SJA1110_TXDRVTRIM_MSB(x) (((x) & GENMASK_ULL(23, 16)) >> 16)
/* LANE_TRIM register */
#define SJA1110_LANE_TRIM 0x8040
#define SJA1110_TXTEN BIT(11)
#define SJA1110_TXRTRIM(x) (((x) << 8) & GENMASK(10, 8))
#define SJA1110_TXPLL_BWSEL BIT(7)
#define SJA1110_RXTEN BIT(6)
#define SJA1110_RXRTRIM(x) (((x) << 3) & GENMASK(5, 3))
#define SJA1110_CDR_GAIN BIT(2)
#define SJA1110_ACCOUPLE_RXVCM_EN BIT(0)
/* LANE_DATAPATH_1 register */
#define SJA1110_LANE_DATAPATH_1 0x8037
/* POWERDOWN_ENABLE register */
#define SJA1110_POWERDOWN_ENABLE 0x8041
#define SJA1110_TXPLL_PD BIT(12)
#define SJA1110_TXPD BIT(11)
#define SJA1110_RXPKDETEN BIT(10)
#define SJA1110_RXCH_PD BIT(9)
#define SJA1110_RXBIAS_PD BIT(8)
#define SJA1110_RESET_SER_EN BIT(7)
#define SJA1110_RESET_SER BIT(6)
#define SJA1110_RESET_DES BIT(5)
#define SJA1110_RCVEN BIT(4)
/* RXPLL_CTRL0 register */
#define SJA1110_RXPLL_CTRL0 0x8065
#define SJA1110_RXPLL_FBDIV(x) (((x) << 2) & GENMASK(9, 2))
/* RXPLL_CTRL1 register */
#define SJA1110_RXPLL_CTRL1 0x8066
#define SJA1110_RXPLL_REFDIV(x) ((x) & GENMASK(4, 0))
/* TXPLL_CTRL0 register */
#define SJA1110_TXPLL_CTRL0 0x806d
#define SJA1110_TXPLL_FBDIV(x) ((x) & GENMASK(11, 0))
/* TXPLL_CTRL1 register */
#define SJA1110_TXPLL_CTRL1 0x806e
#define SJA1110_TXPLL_REFDIV(x) ((x) & GENMASK(5, 0))
/* RX_DATA_DETECT register */
#define SJA1110_RX_DATA_DETECT 0x8045
/* RX_CDR_CTLE register */
#define SJA1110_RX_CDR_CTLE 0x8042
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
/* UM10944.pdf Page 11, Table 2. Configuration Blocks */
enum {
BLKID_L2_POLICING = 0x06,
BLKID_VLAN_LOOKUP = 0x07,
BLKID_L2_FORWARDING = 0x08,
BLKID_MAC_CONFIG = 0x09,
BLKID_L2_FORWARDING_PARAMS = 0x0E,
BLKID_GENERAL_PARAMS = 0x11,
BLKID_XMII_PARAMS = 0x4E,
};
enum sja1105_blk_idx {
BLK_IDX_L2_POLICING = 0,
BLK_IDX_VLAN_LOOKUP,
BLK_IDX_L2_FORWARDING,
BLK_IDX_MAC_CONFIG,
BLK_IDX_L2_FORWARDING_PARAMS,
BLK_IDX_GENERAL_PARAMS,
BLK_IDX_XMII_PARAMS,
BLK_IDX_MAX,
};
struct sja1105_general_params_entry {
u64 mac_fltres1;
u64 mac_fltres0;
u64 mac_flt1;
u64 mac_flt0;
u64 casc_port;
u64 host_port;
u64 mirr_port;
u64 tpid;
u64 tpid2;
};
struct sja1105_vlan_lookup_entry {
u64 vmemb_port;
u64 vlan_bc;
u64 tag_port;
u64 vlanid;
u64 type_entry; /* SJA1110 only */
};
struct sja1105_l2_forwarding_entry {
u64 bc_domain;
u64 reach_port;
u64 fl_domain;
};
struct sja1105_l2_forwarding_params_entry {
u64 part_spc[SJA1105_NUM_TC];
};
struct sja1105_l2_policing_entry {
u64 sharindx;
u64 smax;
u64 rate;
u64 maxlen;
u64 partition;
};
struct sja1105_mac_config_entry {
u64 top[SJA1105_NUM_TC];
u64 base[SJA1105_NUM_TC];
u64 enabled[SJA1105_NUM_TC];
u64 speed;
u64 vlanid;
u64 egress;
u64 ingress;
};
struct sja1105_xmii_params_entry {
u64 phy_mac[SJA1105_MAX_NUM_PORTS];
u64 xmii_mode[SJA1105_MAX_NUM_PORTS];
u64 special[SJA1105_MAX_NUM_PORTS];
};
struct sja1105_table_header {
u64 block_id;
u64 len;
u64 crc;
};
struct sja1105_table_ops {
size_t (*packing)(void *buf, void *entry_ptr, enum packing_op op);
size_t unpacked_entry_size;
size_t packed_entry_size;
size_t max_entry_count;
};
struct sja1105_table {
const struct sja1105_table_ops *ops;
size_t entry_count;
void *entries;
};
struct sja1105_static_config {
u64 device_id;
struct sja1105_table tables[BLK_IDX_MAX];
};
struct sja1105_xpcs_cfg {
bool inband_an;
int speed;
};
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
struct sja1105_private {
struct sja1105_static_config static_config;
bool rgmii_rx_delay[SJA1105_MAX_NUM_PORTS];
bool rgmii_tx_delay[SJA1105_MAX_NUM_PORTS];
u16 pvid[SJA1105_MAX_NUM_PORTS];
struct sja1105_xpcs_cfg xpcs_cfg[SJA1105_MAX_NUM_PORTS];
struct mii_dev *mdio_pcs;
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
const struct sja1105_info *info;
struct udevice *dev;
};
typedef enum {
SPI_READ = 0,
SPI_WRITE = 1,
} sja1105_spi_rw_mode_t;
typedef enum {
XMII_MAC = 0,
XMII_PHY = 1,
} sja1105_mii_role_t;
typedef enum {
XMII_MODE_MII = 0,
XMII_MODE_RMII = 1,
XMII_MODE_RGMII = 2,
XMII_MODE_SGMII = 3,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
} sja1105_phy_interface_t;
enum {
SJA1105_SPEED_AUTO,
SJA1105_SPEED_10MBPS,
SJA1105_SPEED_100MBPS,
SJA1105_SPEED_1000MBPS,
SJA1105_SPEED_MAX,
};
enum sja1110_vlan_type {
SJA1110_VLAN_INVALID = 0,
SJA1110_VLAN_C_TAG = 1, /* Single inner VLAN tag */
SJA1110_VLAN_S_TAG = 2, /* Single outer VLAN tag */
SJA1110_VLAN_D_TAG = 3, /* Double tagged, use outer tag for lookup */
};
/* Keeps the different addresses between E/T and P/Q/R/S */
struct sja1105_regs {
u64 device_id;
u64 prod_id;
u64 status;
u64 port_control;
u64 rgu;
u64 config;
u64 rmii_pll1;
u64 pad_mii_tx[SJA1105_MAX_NUM_PORTS];
u64 pad_mii_rx[SJA1105_MAX_NUM_PORTS];
u64 pad_mii_id[SJA1105_MAX_NUM_PORTS];
u64 cgu_idiv[SJA1105_MAX_NUM_PORTS];
u64 mii_tx_clk[SJA1105_MAX_NUM_PORTS];
u64 mii_rx_clk[SJA1105_MAX_NUM_PORTS];
u64 mii_ext_tx_clk[SJA1105_MAX_NUM_PORTS];
u64 mii_ext_rx_clk[SJA1105_MAX_NUM_PORTS];
u64 rgmii_tx_clk[SJA1105_MAX_NUM_PORTS];
u64 rmii_ref_clk[SJA1105_MAX_NUM_PORTS];
u64 rmii_ext_tx_clk[SJA1105_MAX_NUM_PORTS];
u64 pcs_base[SJA1105_MAX_NUM_PORTS];
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
};
struct sja1105_info {
u64 device_id;
u64 part_no;
const struct sja1105_table_ops *static_ops;
const struct sja1105_regs *regs;
int (*reset_cmd)(struct sja1105_private *priv);
int (*setup_rgmii_delay)(struct sja1105_private *priv, int port);
int (*pcs_mdio_read)(struct mii_dev *bus, int phy, int mmd, int reg);
int (*pcs_mdio_write)(struct mii_dev *bus, int phy, int mmd, int reg,
u16 val);
int (*pma_config)(struct sja1105_private *priv, int port);
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
const char *name;
bool supports_mii[SJA1105_MAX_NUM_PORTS];
bool supports_rmii[SJA1105_MAX_NUM_PORTS];
bool supports_rgmii[SJA1105_MAX_NUM_PORTS];
bool supports_sgmii[SJA1105_MAX_NUM_PORTS];
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
const u64 port_speed[SJA1105_SPEED_MAX];
};
struct sja1105_chunk {
u8 *buf;
size_t len;
u64 reg_addr;
};
struct sja1105_spi_message {
u64 access;
u64 read_count;
u64 address;
};
/* Common structure for CFG_PAD_MIIx_RX and CFG_PAD_MIIx_TX */
struct sja1105_cfg_pad_mii {
u64 d32_os;
u64 d32_ih;
u64 d32_ipud;
u64 d10_ih;
u64 d10_os;
u64 d10_ipud;
u64 ctrl_os;
u64 ctrl_ih;
u64 ctrl_ipud;
u64 clk_os;
u64 clk_ih;
u64 clk_ipud;
};
struct sja1105_cfg_pad_mii_id {
u64 rxc_stable_ovr;
u64 rxc_delay;
u64 rxc_bypass;
u64 rxc_pd;
u64 txc_stable_ovr;
u64 txc_delay;
u64 txc_bypass;
u64 txc_pd;
};
struct sja1105_cgu_idiv {
u64 clksrc;
u64 autoblock;
u64 idiv;
u64 pd;
};
struct sja1105_cgu_pll_ctrl {
u64 pllclksrc;
u64 msel;
u64 autoblock;
u64 psel;
u64 direct;
u64 fbsel;
u64 bypass;
u64 pd;
};
enum {
CLKSRC_MII0_TX_CLK = 0x00,
CLKSRC_MII0_RX_CLK = 0x01,
CLKSRC_MII1_TX_CLK = 0x02,
CLKSRC_MII1_RX_CLK = 0x03,
CLKSRC_MII2_TX_CLK = 0x04,
CLKSRC_MII2_RX_CLK = 0x05,
CLKSRC_MII3_TX_CLK = 0x06,
CLKSRC_MII3_RX_CLK = 0x07,
CLKSRC_MII4_TX_CLK = 0x08,
CLKSRC_MII4_RX_CLK = 0x09,
CLKSRC_PLL0 = 0x0B,
CLKSRC_PLL1 = 0x0E,
CLKSRC_IDIV0 = 0x11,
CLKSRC_IDIV1 = 0x12,
CLKSRC_IDIV2 = 0x13,
CLKSRC_IDIV3 = 0x14,
CLKSRC_IDIV4 = 0x15,
};
struct sja1105_cgu_mii_ctrl {
u64 clksrc;
u64 autoblock;
u64 pd;
};
static int get_reverse_lsw32_offset(int offset, size_t len)
{
int closest_multiple_of_4;
int word_index;
word_index = offset / 4;
closest_multiple_of_4 = word_index * 4;
offset -= closest_multiple_of_4;
word_index = (len / 4) - word_index - 1;
return word_index * 4 + offset;
}
/* Simplified version of the "packing" function from Linux, adapted
* to support only sja1105's quirk: QUIRK_LSW32_IS_FIRST
*/
static void sja1105_packing(void *pbuf, u64 *uval, int startbit, int endbit,
size_t pbuflen, enum packing_op op)
{
int plogical_first_u8, plogical_last_u8, box;
if (op == UNPACK)
*uval = 0;
plogical_first_u8 = startbit / 8;
plogical_last_u8 = endbit / 8;
for (box = plogical_first_u8; box >= plogical_last_u8; box--) {
int box_start_bit, box_end_bit, box_addr;
int proj_start_bit, proj_end_bit;
u64 proj_mask;
u8 box_mask;
if (box == plogical_first_u8)
box_start_bit = startbit % 8;
else
box_start_bit = 7;
if (box == plogical_last_u8)
box_end_bit = endbit % 8;
else
box_end_bit = 0;
proj_start_bit = ((box * 8) + box_start_bit) - endbit;
proj_end_bit = ((box * 8) + box_end_bit) - endbit;
proj_mask = GENMASK_ULL(proj_start_bit, proj_end_bit);
box_mask = GENMASK_ULL(box_start_bit, box_end_bit);
box_addr = pbuflen - box - 1;
box_addr = get_reverse_lsw32_offset(box_addr, pbuflen);
if (op == UNPACK) {
u64 pval;
/* Read from pbuf, write to uval */
pval = ((u8 *)pbuf)[box_addr] & box_mask;
pval >>= box_end_bit;
pval <<= proj_end_bit;
*uval &= ~proj_mask;
*uval |= pval;
} else {
u64 pval;
/* Write to pbuf, read from uval */
pval = (*uval) & proj_mask;
pval >>= proj_end_bit;
pval <<= box_end_bit;
((u8 *)pbuf)[box_addr] &= ~box_mask;
((u8 *)pbuf)[box_addr] |= pval;
}
}
}
static u32 crc32_add(u32 crc, u8 byte)
{
u32 byte32 = bitrev32(byte);
int i;
for (i = 0; i < 8; i++) {
if ((crc ^ byte32) & BIT(31)) {
crc <<= 1;
crc ^= ETHER_CRC32_POLY;
} else {
crc <<= 1;
}
byte32 <<= 1;
}
return crc;
}
/* Little-endian Ethernet CRC32 of data packed as big-endian u32 words */
static uint32_t sja1105_crc32(void *buf, size_t len)
{
unsigned int i;
u64 chunk;
u32 crc;
/* seed */
crc = 0xFFFFFFFF;
for (i = 0; i < len; i += 4) {
sja1105_packing(buf + i, &chunk, 31, 0, 4, UNPACK);
crc = crc32_add(crc, chunk & 0xFF);
crc = crc32_add(crc, (chunk >> 8) & 0xFF);
crc = crc32_add(crc, (chunk >> 16) & 0xFF);
crc = crc32_add(crc, (chunk >> 24) & 0xFF);
}
return bitrev32(~crc);
}
static void sja1105_spi_message_pack(void *buf, struct sja1105_spi_message *msg)
{
const int size = SJA1105_SIZE_SPI_MSG_HEADER;
memset(buf, 0, size);
sja1105_packing(buf, &msg->access, 31, 31, size, PACK);
sja1105_packing(buf, &msg->read_count, 30, 25, size, PACK);
sja1105_packing(buf, &msg->address, 24, 4, size, PACK);
}
static int sja1105_xfer_buf(const struct sja1105_private *priv,
sja1105_spi_rw_mode_t rw, u64 reg_addr,
u8 *buf, size_t len)
{
struct udevice *dev = priv->dev;
struct sja1105_chunk chunk = {
.len = min_t(size_t, len, SJA1105_SIZE_SPI_MSG_MAXLEN),
.reg_addr = reg_addr,
.buf = buf,
};
int num_chunks;
int rc, i;
rc = dm_spi_claim_bus(dev);
if (rc)
return rc;
num_chunks = DIV_ROUND_UP(len, SJA1105_SIZE_SPI_MSG_MAXLEN);
for (i = 0; i < num_chunks; i++) {
u8 hdr_buf[SJA1105_SIZE_SPI_MSG_HEADER];
struct sja1105_spi_message msg;
u8 *rx_buf = NULL;
u8 *tx_buf = NULL;
/* Populate the transfer's header buffer */
msg.address = chunk.reg_addr;
msg.access = rw;
if (rw == SPI_READ)
msg.read_count = chunk.len / 4;
else
/* Ignored */
msg.read_count = 0;
sja1105_spi_message_pack(hdr_buf, &msg);
rc = dm_spi_xfer(dev, SJA1105_SIZE_SPI_MSG_HEADER * 8, hdr_buf,
NULL, SPI_XFER_BEGIN);
if (rc)
goto out;
/* Populate the transfer's data buffer */
if (rw == SPI_READ)
rx_buf = chunk.buf;
else
tx_buf = chunk.buf;
rc = dm_spi_xfer(dev, chunk.len * 8, tx_buf, rx_buf,
SPI_XFER_END);
if (rc)
goto out;
/* Calculate next chunk */
chunk.buf += chunk.len;
chunk.reg_addr += chunk.len / 4;
chunk.len = min_t(size_t, (ptrdiff_t)(buf + len - chunk.buf),
SJA1105_SIZE_SPI_MSG_MAXLEN);
}
out:
dm_spi_release_bus(dev);
return rc;
}
static int sja1105et_reset_cmd(struct sja1105_private *priv)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_RESET_CMD] = {0};
const int size = SJA1105_SIZE_RESET_CMD;
u64 cold_rst = 1;
sja1105_packing(packed_buf, &cold_rst, 3, 3, size, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rgu, packed_buf,
SJA1105_SIZE_RESET_CMD);
}
static int sja1105pqrs_reset_cmd(struct sja1105_private *priv)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_RESET_CMD] = {0};
const int size = SJA1105_SIZE_RESET_CMD;
u64 cold_rst = 1;
sja1105_packing(packed_buf, &cold_rst, 2, 2, size, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rgu, packed_buf,
SJA1105_SIZE_RESET_CMD);
}
static int sja1110_reset_cmd(struct sja1105_private *priv)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_RESET_CMD] = {0};
const int size = SJA1105_SIZE_RESET_CMD;
u64 switch_rst = 1;
/* Only reset the switch core.
* A full cold reset would re-enable the BASE_MCSS_CLOCK PLL which
* would turn on the microcontroller, potentially letting it execute
* code which could interfere with our configuration.
*/
sja1105_packing(packed_buf, &switch_rst, 20, 20, size, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rgu, packed_buf,
SJA1105_SIZE_RESET_CMD);
}
static size_t sja1105et_general_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105ET_SIZE_GENERAL_PARAMS_ENTRY;
struct sja1105_general_params_entry *entry = entry_ptr;
sja1105_packing(buf, &entry->mac_fltres1, 311, 264, size, op);
sja1105_packing(buf, &entry->mac_fltres0, 263, 216, size, op);
sja1105_packing(buf, &entry->mac_flt1, 215, 168, size, op);
sja1105_packing(buf, &entry->mac_flt0, 167, 120, size, op);
sja1105_packing(buf, &entry->casc_port, 115, 113, size, op);
sja1105_packing(buf, &entry->host_port, 112, 110, size, op);
sja1105_packing(buf, &entry->mirr_port, 109, 107, size, op);
sja1105_packing(buf, &entry->tpid, 42, 27, size, op);
sja1105_packing(buf, &entry->tpid2, 25, 10, size, op);
return size;
}
static size_t sja1110_general_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_general_params_entry *entry = entry_ptr;
const size_t size = SJA1110_SIZE_GENERAL_PARAMS_ENTRY;
sja1105_packing(buf, &entry->mac_fltres1, 438, 391, size, op);
sja1105_packing(buf, &entry->mac_fltres0, 390, 343, size, op);
sja1105_packing(buf, &entry->mac_flt1, 342, 295, size, op);
sja1105_packing(buf, &entry->mac_flt0, 294, 247, size, op);
sja1105_packing(buf, &entry->casc_port, 242, 232, size, op);
sja1105_packing(buf, &entry->host_port, 231, 228, size, op);
sja1105_packing(buf, &entry->mirr_port, 227, 224, size, op);
sja1105_packing(buf, &entry->tpid2, 159, 144, size, op);
sja1105_packing(buf, &entry->tpid, 142, 127, size, op);
return size;
}
static size_t
sja1105pqrs_general_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105PQRS_SIZE_GENERAL_PARAMS_ENTRY;
struct sja1105_general_params_entry *entry = entry_ptr;
sja1105_packing(buf, &entry->mac_fltres1, 343, 296, size, op);
sja1105_packing(buf, &entry->mac_fltres0, 295, 248, size, op);
sja1105_packing(buf, &entry->mac_flt1, 247, 200, size, op);
sja1105_packing(buf, &entry->mac_flt0, 199, 152, size, op);
sja1105_packing(buf, &entry->casc_port, 147, 145, size, op);
sja1105_packing(buf, &entry->host_port, 144, 142, size, op);
sja1105_packing(buf, &entry->mirr_port, 141, 139, size, op);
sja1105_packing(buf, &entry->tpid, 74, 59, size, op);
sja1105_packing(buf, &entry->tpid2, 57, 42, size, op);
return size;
}
static size_t
sja1105_l2_forwarding_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY;
struct sja1105_l2_forwarding_params_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 13; i < SJA1105_NUM_TC; i++, offset += 10)
sja1105_packing(buf, &entry->part_spc[i],
offset + 9, offset + 0, size, op);
return size;
}
static size_t
sja1110_l2_forwarding_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_forwarding_params_entry *entry = entry_ptr;
const size_t size = SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY;
int offset, i;
for (i = 0, offset = 5; i < 8; i++, offset += 11)
sja1105_packing(buf, &entry->part_spc[i],
offset + 10, offset + 0, size, op);
return size;
}
static size_t sja1105_l2_forwarding_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105_SIZE_L2_FORWARDING_ENTRY;
struct sja1105_l2_forwarding_entry *entry = entry_ptr;
sja1105_packing(buf, &entry->bc_domain, 63, 59, size, op);
sja1105_packing(buf, &entry->reach_port, 58, 54, size, op);
sja1105_packing(buf, &entry->fl_domain, 53, 49, size, op);
return size;
}
static size_t sja1110_l2_forwarding_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_forwarding_entry *entry = entry_ptr;
const size_t size = SJA1105_SIZE_L2_FORWARDING_ENTRY;
sja1105_packing(buf, &entry->bc_domain, 63, 53, size, op);
sja1105_packing(buf, &entry->reach_port, 52, 42, size, op);
sja1105_packing(buf, &entry->fl_domain, 41, 31, size, op);
return size;
}
static size_t sja1105_l2_policing_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_policing_entry *entry = entry_ptr;
const size_t size = SJA1105_SIZE_L2_POLICING_ENTRY;
sja1105_packing(buf, &entry->sharindx, 63, 58, size, op);
sja1105_packing(buf, &entry->smax, 57, 42, size, op);
sja1105_packing(buf, &entry->rate, 41, 26, size, op);
sja1105_packing(buf, &entry->maxlen, 25, 15, size, op);
sja1105_packing(buf, &entry->partition, 14, 12, size, op);
return size;
}
static size_t sja1110_l2_policing_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_policing_entry *entry = entry_ptr;
const size_t size = SJA1105_SIZE_L2_POLICING_ENTRY;
sja1105_packing(buf, &entry->sharindx, 63, 57, size, op);
sja1105_packing(buf, &entry->smax, 56, 39, size, op);
sja1105_packing(buf, &entry->rate, 38, 21, size, op);
sja1105_packing(buf, &entry->maxlen, 20, 10, size, op);
sja1105_packing(buf, &entry->partition, 9, 7, size, op);
return size;
}
static size_t sja1105et_mac_config_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105ET_SIZE_MAC_CONFIG_ENTRY;
struct sja1105_mac_config_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 72; i < SJA1105_NUM_TC; i++, offset += 19) {
sja1105_packing(buf, &entry->enabled[i],
offset + 0, offset + 0, size, op);
sja1105_packing(buf, &entry->base[i],
offset + 9, offset + 1, size, op);
sja1105_packing(buf, &entry->top[i],
offset + 18, offset + 10, size, op);
}
sja1105_packing(buf, &entry->speed, 66, 65, size, op);
sja1105_packing(buf, &entry->vlanid, 21, 10, size, op);
sja1105_packing(buf, &entry->egress, 2, 2, size, op);
sja1105_packing(buf, &entry->ingress, 1, 1, size, op);
return size;
}
static size_t sja1105pqrs_mac_config_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY;
struct sja1105_mac_config_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 104; i < SJA1105_NUM_TC; i++, offset += 19) {
sja1105_packing(buf, &entry->enabled[i],
offset + 0, offset + 0, size, op);
sja1105_packing(buf, &entry->base[i],
offset + 9, offset + 1, size, op);
sja1105_packing(buf, &entry->top[i],
offset + 18, offset + 10, size, op);
}
sja1105_packing(buf, &entry->speed, 98, 97, size, op);
sja1105_packing(buf, &entry->vlanid, 53, 42, size, op);
sja1105_packing(buf, &entry->egress, 32, 32, size, op);
sja1105_packing(buf, &entry->ingress, 31, 31, size, op);
return size;
}
static size_t sja1110_mac_config_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY;
struct sja1105_mac_config_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 104; i < 8; i++, offset += 19) {
sja1105_packing(buf, &entry->enabled[i],
offset + 0, offset + 0, size, op);
sja1105_packing(buf, &entry->base[i],
offset + 9, offset + 1, size, op);
sja1105_packing(buf, &entry->top[i],
offset + 18, offset + 10, size, op);
}
sja1105_packing(buf, &entry->speed, 98, 96, size, op);
sja1105_packing(buf, &entry->vlanid, 52, 41, size, op);
sja1105_packing(buf, &entry->egress, 31, 31, size, op);
sja1105_packing(buf, &entry->ingress, 30, 30, size, op);
return size;
}
static size_t sja1105_vlan_lookup_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105_SIZE_VLAN_LOOKUP_ENTRY;
struct sja1105_vlan_lookup_entry *entry = entry_ptr;
sja1105_packing(buf, &entry->vmemb_port, 53, 49, size, op);
sja1105_packing(buf, &entry->vlan_bc, 48, 44, size, op);
sja1105_packing(buf, &entry->tag_port, 43, 39, size, op);
sja1105_packing(buf, &entry->vlanid, 38, 27, size, op);
return size;
}
static size_t sja1110_vlan_lookup_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_vlan_lookup_entry *entry = entry_ptr;
const size_t size = SJA1110_SIZE_VLAN_LOOKUP_ENTRY;
sja1105_packing(buf, &entry->vmemb_port, 73, 63, size, op);
sja1105_packing(buf, &entry->vlan_bc, 62, 52, size, op);
sja1105_packing(buf, &entry->tag_port, 51, 41, size, op);
sja1105_packing(buf, &entry->type_entry, 40, 39, size, op);
sja1105_packing(buf, &entry->vlanid, 38, 27, size, op);
return size;
}
static size_t sja1105_xmii_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105_SIZE_XMII_PARAMS_ENTRY;
struct sja1105_xmii_params_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 17; i < SJA1105_NUM_PORTS; i++, offset += 3) {
sja1105_packing(buf, &entry->xmii_mode[i],
offset + 1, offset + 0, size, op);
sja1105_packing(buf, &entry->phy_mac[i],
offset + 2, offset + 2, size, op);
}
return size;
}
static size_t sja1110_xmii_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1110_SIZE_XMII_PARAMS_ENTRY;
struct sja1105_xmii_params_entry *entry = entry_ptr;
int offset, i;
for (i = 0, offset = 20; i < SJA1110_NUM_PORTS; i++, offset += 4) {
sja1105_packing(buf, &entry->xmii_mode[i],
offset + 1, offset + 0, size, op);
sja1105_packing(buf, &entry->phy_mac[i],
offset + 2, offset + 2, size, op);
sja1105_packing(buf, &entry->special[i],
offset + 3, offset + 3, size, op);
}
return size;
}
static size_t sja1105_table_header_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105_SIZE_TABLE_HEADER;
struct sja1105_table_header *entry = entry_ptr;
sja1105_packing(buf, &entry->block_id, 31, 24, size, op);
sja1105_packing(buf, &entry->len, 55, 32, size, op);
sja1105_packing(buf, &entry->crc, 95, 64, size, op);
return size;
}
static void
sja1105_table_header_pack_with_crc(void *buf, struct sja1105_table_header *hdr)
{
/* First pack the table as-is, then calculate the CRC, and
* finally put the proper CRC into the packed buffer
*/
memset(buf, 0, SJA1105_SIZE_TABLE_HEADER);
sja1105_table_header_packing(buf, hdr, PACK);
hdr->crc = sja1105_crc32(buf, SJA1105_SIZE_TABLE_HEADER - 4);
sja1105_packing(buf + SJA1105_SIZE_TABLE_HEADER - 4, &hdr->crc,
31, 0, 4, PACK);
}
static void sja1105_table_write_crc(u8 *table_start, u8 *crc_ptr)
{
u64 computed_crc;
int len_bytes;
len_bytes = (uintptr_t)(crc_ptr - table_start);
computed_crc = sja1105_crc32(table_start, len_bytes);
sja1105_packing(crc_ptr, &computed_crc, 31, 0, 4, PACK);
}
/* The block IDs that the switches support are unfortunately sparse, so keep a
* mapping table to "block indices" and translate back and forth.
*/
static const u64 blk_id_map[BLK_IDX_MAX] = {
[BLK_IDX_L2_POLICING] = BLKID_L2_POLICING,
[BLK_IDX_VLAN_LOOKUP] = BLKID_VLAN_LOOKUP,
[BLK_IDX_L2_FORWARDING] = BLKID_L2_FORWARDING,
[BLK_IDX_MAC_CONFIG] = BLKID_MAC_CONFIG,
[BLK_IDX_L2_FORWARDING_PARAMS] = BLKID_L2_FORWARDING_PARAMS,
[BLK_IDX_GENERAL_PARAMS] = BLKID_GENERAL_PARAMS,
[BLK_IDX_XMII_PARAMS] = BLKID_XMII_PARAMS,
};
static void
sja1105_static_config_pack(void *buf, struct sja1105_static_config *config)
{
struct sja1105_table_header header = {0};
enum sja1105_blk_idx i;
u8 *p = buf;
int j;
sja1105_packing(p, &config->device_id, 31, 0, 4, PACK);
p += SJA1105_SIZE_DEVICE_ID;
for (i = 0; i < BLK_IDX_MAX; i++) {
const struct sja1105_table *table;
u8 *table_start;
table = &config->tables[i];
if (!table->entry_count)
continue;
header.block_id = blk_id_map[i];
header.len = table->entry_count *
table->ops->packed_entry_size / 4;
sja1105_table_header_pack_with_crc(p, &header);
p += SJA1105_SIZE_TABLE_HEADER;
table_start = p;
for (j = 0; j < table->entry_count; j++) {
u8 *entry_ptr = table->entries;
entry_ptr += j * table->ops->unpacked_entry_size;
memset(p, 0, table->ops->packed_entry_size);
table->ops->packing(p, entry_ptr, PACK);
p += table->ops->packed_entry_size;
}
sja1105_table_write_crc(table_start, p);
p += 4;
}
/* Final header:
* Block ID does not matter
* Length of 0 marks that header is final
* CRC will be replaced on-the-fly
*/
header.block_id = 0;
header.len = 0;
header.crc = 0xDEADBEEF;
memset(p, 0, SJA1105_SIZE_TABLE_HEADER);
sja1105_table_header_packing(p, &header, PACK);
}
static size_t
sja1105_static_config_get_length(const struct sja1105_static_config *config)
{
unsigned int header_count;
enum sja1105_blk_idx i;
unsigned int sum;
/* Ending header */
header_count = 1;
sum = SJA1105_SIZE_DEVICE_ID;
/* Tables (headers and entries) */
for (i = 0; i < BLK_IDX_MAX; i++) {
const struct sja1105_table *table;
table = &config->tables[i];
if (table->entry_count)
header_count++;
sum += table->ops->packed_entry_size * table->entry_count;
}
/* Headers have an additional CRC at the end */
sum += header_count * (SJA1105_SIZE_TABLE_HEADER + 4);
/* Last header does not have an extra CRC because there is no data */
sum -= 4;
return sum;
}
/* Compatibility matrices */
static const struct sja1105_table_ops sja1105et_table_ops[BLK_IDX_MAX] = {
[BLK_IDX_L2_POLICING] = {
.packing = sja1105_l2_policing_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_policing_entry),
.packed_entry_size = SJA1105_SIZE_L2_POLICING_ENTRY,
.max_entry_count = SJA1105_MAX_L2_POLICING_COUNT,
},
[BLK_IDX_VLAN_LOOKUP] = {
.packing = sja1105_vlan_lookup_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_vlan_lookup_entry),
.packed_entry_size = SJA1105_SIZE_VLAN_LOOKUP_ENTRY,
.max_entry_count = SJA1105_MAX_VLAN_LOOKUP_COUNT,
},
[BLK_IDX_L2_FORWARDING] = {
.packing = sja1105_l2_forwarding_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_ENTRY,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_COUNT,
},
[BLK_IDX_MAC_CONFIG] = {
.packing = sja1105et_mac_config_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_mac_config_entry),
.packed_entry_size = SJA1105ET_SIZE_MAC_CONFIG_ENTRY,
.max_entry_count = SJA1105_MAX_MAC_CONFIG_COUNT,
},
[BLK_IDX_L2_FORWARDING_PARAMS] = {
.packing = sja1105_l2_forwarding_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_params_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT,
},
[BLK_IDX_GENERAL_PARAMS] = {
.packing = sja1105et_general_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_general_params_entry),
.packed_entry_size = SJA1105ET_SIZE_GENERAL_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT,
},
[BLK_IDX_XMII_PARAMS] = {
.packing = sja1105_xmii_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_xmii_params_entry),
.packed_entry_size = SJA1105_SIZE_XMII_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_XMII_PARAMS_COUNT,
},
};
static const struct sja1105_table_ops sja1105pqrs_table_ops[BLK_IDX_MAX] = {
[BLK_IDX_L2_POLICING] = {
.packing = sja1105_l2_policing_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_policing_entry),
.packed_entry_size = SJA1105_SIZE_L2_POLICING_ENTRY,
.max_entry_count = SJA1105_MAX_L2_POLICING_COUNT,
},
[BLK_IDX_VLAN_LOOKUP] = {
.packing = sja1105_vlan_lookup_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_vlan_lookup_entry),
.packed_entry_size = SJA1105_SIZE_VLAN_LOOKUP_ENTRY,
.max_entry_count = SJA1105_MAX_VLAN_LOOKUP_COUNT,
},
[BLK_IDX_L2_FORWARDING] = {
.packing = sja1105_l2_forwarding_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_ENTRY,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_COUNT,
},
[BLK_IDX_MAC_CONFIG] = {
.packing = sja1105pqrs_mac_config_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_mac_config_entry),
.packed_entry_size = SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY,
.max_entry_count = SJA1105_MAX_MAC_CONFIG_COUNT,
},
[BLK_IDX_L2_FORWARDING_PARAMS] = {
.packing = sja1105_l2_forwarding_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_params_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT,
},
[BLK_IDX_GENERAL_PARAMS] = {
.packing = sja1105pqrs_general_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_general_params_entry),
.packed_entry_size = SJA1105PQRS_SIZE_GENERAL_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT,
},
[BLK_IDX_XMII_PARAMS] = {
.packing = sja1105_xmii_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_xmii_params_entry),
.packed_entry_size = SJA1105_SIZE_XMII_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_XMII_PARAMS_COUNT,
},
};
static const struct sja1105_table_ops sja1110_table_ops[BLK_IDX_MAX] = {
[BLK_IDX_L2_POLICING] = {
.packing = sja1110_l2_policing_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_policing_entry),
.packed_entry_size = SJA1105_SIZE_L2_POLICING_ENTRY,
.max_entry_count = SJA1110_MAX_L2_POLICING_COUNT,
},
[BLK_IDX_VLAN_LOOKUP] = {
.packing = sja1110_vlan_lookup_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_vlan_lookup_entry),
.packed_entry_size = SJA1110_SIZE_VLAN_LOOKUP_ENTRY,
.max_entry_count = SJA1105_MAX_VLAN_LOOKUP_COUNT,
},
[BLK_IDX_L2_FORWARDING] = {
.packing = sja1110_l2_forwarding_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_ENTRY,
.max_entry_count = SJA1110_MAX_L2_FORWARDING_COUNT,
},
[BLK_IDX_MAC_CONFIG] = {
.packing = sja1110_mac_config_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_mac_config_entry),
.packed_entry_size = SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY,
.max_entry_count = SJA1110_MAX_MAC_CONFIG_COUNT,
},
[BLK_IDX_L2_FORWARDING_PARAMS] = {
.packing = sja1110_l2_forwarding_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_l2_forwarding_params_entry),
.packed_entry_size = SJA1105_SIZE_L2_FORWARDING_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT,
},
[BLK_IDX_GENERAL_PARAMS] = {
.packing = sja1110_general_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_general_params_entry),
.packed_entry_size = SJA1110_SIZE_GENERAL_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT,
},
[BLK_IDX_XMII_PARAMS] = {
.packing = sja1110_xmii_params_entry_packing,
.unpacked_entry_size = sizeof(struct sja1105_xmii_params_entry),
.packed_entry_size = SJA1110_SIZE_XMII_PARAMS_ENTRY,
.max_entry_count = SJA1105_MAX_XMII_PARAMS_COUNT,
},
};
static int sja1105_init_mii_settings(struct sja1105_private *priv)
{
struct sja1105_table *table;
table = &priv->static_config.tables[BLK_IDX_XMII_PARAMS];
table->entries = calloc(SJA1105_MAX_XMII_PARAMS_COUNT,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
/* Table will be populated at runtime */
table->entry_count = SJA1105_MAX_XMII_PARAMS_COUNT;
return 0;
}
static void sja1105_setup_tagging(struct sja1105_private *priv, int port)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_vlan_lookup_entry *vlan;
int cpu = pdata->cpu_port;
/* The CPU port is implicitly configured by
* configuring the front-panel ports
*/
if (port == cpu)
return;
vlan = priv->static_config.tables[BLK_IDX_VLAN_LOOKUP].entries;
priv->pvid[port] = DSA_8021Q_DIR_TX | DSA_8021Q_PORT(port);
vlan[port].vmemb_port = BIT(port) | BIT(cpu);
vlan[port].vlan_bc = BIT(port) | BIT(cpu);
vlan[port].tag_port = BIT(cpu);
vlan[port].vlanid = priv->pvid[port];
vlan[port].type_entry = SJA1110_VLAN_D_TAG;
}
static int sja1105_init_vlan(struct sja1105_private *priv)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_table *table;
int port;
table = &priv->static_config.tables[BLK_IDX_VLAN_LOOKUP];
table->entries = calloc(pdata->num_ports,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = pdata->num_ports;
for (port = 0; port < pdata->num_ports; port++)
sja1105_setup_tagging(priv, port);
return 0;
}
static void
sja1105_port_allow_traffic(struct sja1105_l2_forwarding_entry *l2_fwd,
int from, int to)
{
l2_fwd[from].bc_domain |= BIT(to);
l2_fwd[from].reach_port |= BIT(to);
l2_fwd[from].fl_domain |= BIT(to);
}
static int sja1105_init_l2_forwarding(struct sja1105_private *priv)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_l2_forwarding_entry *l2fwd;
struct sja1105_table *table;
int cpu = pdata->cpu_port;
int i;
table = &priv->static_config.tables[BLK_IDX_L2_FORWARDING];
table->entries = calloc(SJA1105_MAX_L2_FORWARDING_COUNT,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = SJA1105_MAX_L2_FORWARDING_COUNT;
l2fwd = table->entries;
/* First 5 entries define the forwarding rules */
for (i = 0; i < pdata->num_ports; i++) {
if (i == cpu)
continue;
sja1105_port_allow_traffic(l2fwd, i, cpu);
sja1105_port_allow_traffic(l2fwd, cpu, i);
}
/* Next 8 entries define VLAN PCP mapping from ingress to egress.
* Leave them unpopulated (implicitly 0) but present.
*/
return 0;
}
static int sja1105_init_l2_forwarding_params(struct sja1105_private *priv)
{
struct sja1105_l2_forwarding_params_entry default_l2fwd_params = {
/* Use a single memory partition for all ingress queues */
.part_spc = { SJA1105_MAX_FRAME_MEMORY, 0, 0, 0, 0, 0, 0, 0 },
};
struct sja1105_table *table;
table = &priv->static_config.tables[BLK_IDX_L2_FORWARDING_PARAMS];
table->entries = calloc(SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = SJA1105_MAX_L2_FORWARDING_PARAMS_COUNT;
/* This table only has a single entry */
((struct sja1105_l2_forwarding_params_entry *)table->entries)[0] =
default_l2fwd_params;
return 0;
}
static int sja1105_init_general_params(struct sja1105_private *priv)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_general_params_entry default_general_params = {
/* No frame trapping */
.mac_fltres1 = 0x0,
.mac_flt1 = 0xffffffffffff,
.mac_fltres0 = 0x0,
.mac_flt0 = 0xffffffffffff,
.host_port = pdata->num_ports,
/* No mirroring => specify an out-of-range port value */
.mirr_port = pdata->num_ports,
/* No link-local trapping => specify an out-of-range port value
*/
.casc_port = pdata->num_ports,
/* Force the switch to see all traffic as untagged. */
.tpid = ETH_P_SJA1105,
.tpid2 = ETH_P_SJA1105,
};
struct sja1105_table *table;
table = &priv->static_config.tables[BLK_IDX_GENERAL_PARAMS];
table->entries = calloc(SJA1105_MAX_GENERAL_PARAMS_COUNT,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT;
/* This table only has a single entry */
((struct sja1105_general_params_entry *)table->entries)[0] =
default_general_params;
return 0;
}
static void sja1105_setup_policer(struct sja1105_l2_policing_entry *policing,
int index, int mtu)
{
policing[index].sharindx = index;
policing[index].smax = 65535; /* Burst size in bytes */
policing[index].rate = SJA1105_RATE_MBPS(1000);
policing[index].maxlen = mtu;
policing[index].partition = 0;
}
static int sja1105_init_l2_policing(struct sja1105_private *priv)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_l2_policing_entry *policing;
struct sja1105_table *table;
int cpu = pdata->cpu_port;
int i, j, k;
table = &priv->static_config.tables[BLK_IDX_L2_POLICING];
table->entries = calloc(SJA1105_MAX_L2_POLICING_COUNT,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = SJA1105_MAX_L2_POLICING_COUNT;
policing = table->entries;
/* k sweeps through all unicast policers (0-39).
* bcast sweeps through policers 40-44.
*/
for (i = 0, k = 0; i < pdata->num_ports; i++) {
int bcast = (pdata->num_ports * SJA1105_NUM_TC) + i;
int mtu = VLAN_ETH_FRAME_LEN + ETH_FCS_LEN;
if (i == cpu)
mtu += VLAN_HLEN;
for (j = 0; j < SJA1105_NUM_TC; j++, k++)
sja1105_setup_policer(policing, k, mtu);
/* Set up this port's policer for broadcast traffic */
sja1105_setup_policer(policing, bcast, mtu);
}
return 0;
}
static int sja1105_init_mac_settings(struct sja1105_private *priv)
{
struct sja1105_mac_config_entry default_mac = {
/* Enable 1 priority queue on egress. */
.top = {0x1FF, 0, 0, 0, 0, 0, 0},
.base = {0x0, 0, 0, 0, 0, 0, 0, 0},
.enabled = {1, 0, 0, 0, 0, 0, 0, 0},
/* Will be overridden in sja1105_port_enable. */
.speed = priv->info->port_speed[SJA1105_SPEED_AUTO],
.egress = true,
.ingress = true,
};
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
struct sja1105_mac_config_entry *mac;
struct sja1105_table *table;
int port;
table = &priv->static_config.tables[BLK_IDX_MAC_CONFIG];
table->entries = calloc(pdata->num_ports,
table->ops->unpacked_entry_size);
if (!table->entries)
return -ENOMEM;
table->entry_count = pdata->num_ports;
mac = table->entries;
for (port = 0; port < pdata->num_ports; port++) {
mac[port] = default_mac;
/* Internal VLAN (pvid) to apply to untagged ingress */
mac[port].vlanid = priv->pvid[port];
}
return 0;
}
static int sja1105_static_config_init(struct sja1105_private *priv)
{
struct sja1105_static_config *config = &priv->static_config;
const struct sja1105_table_ops *static_ops = priv->info->static_ops;
u64 device_id = priv->info->device_id;
enum sja1105_blk_idx i;
int rc;
*config = (struct sja1105_static_config) {0};
/* Transfer static_ops array from priv into per-table ops
* for handier access
*/
for (i = 0; i < BLK_IDX_MAX; i++)
config->tables[i].ops = &static_ops[i];
config->device_id = device_id;
/* Build initial static configuration, to be fixed up during runtime */
rc = sja1105_init_vlan(priv);
if (rc < 0)
return rc;
rc = sja1105_init_mac_settings(priv);
if (rc < 0)
return rc;
rc = sja1105_init_mii_settings(priv);
if (rc < 0)
return rc;
rc = sja1105_init_l2_forwarding(priv);
if (rc < 0)
return rc;
rc = sja1105_init_l2_forwarding_params(priv);
if (rc < 0)
return rc;
rc = sja1105_init_l2_policing(priv);
if (rc < 0)
return rc;
rc = sja1105_init_general_params(priv);
if (rc < 0)
return rc;
return 0;
}
static void sja1105_static_config_free(struct sja1105_static_config *config)
{
enum sja1105_blk_idx i;
for (i = 0; i < BLK_IDX_MAX; i++) {
if (config->tables[i].entry_count) {
free(config->tables[i].entries);
config->tables[i].entry_count = 0;
}
}
}
static void sja1105_cgu_idiv_packing(void *buf, struct sja1105_cgu_idiv *idiv,
enum packing_op op)
{
const int size = 4;
sja1105_packing(buf, &idiv->clksrc, 28, 24, size, op);
sja1105_packing(buf, &idiv->autoblock, 11, 11, size, op);
sja1105_packing(buf, &idiv->idiv, 5, 2, size, op);
sja1105_packing(buf, &idiv->pd, 0, 0, size, op);
}
static int sja1105_cgu_idiv_config(struct sja1105_private *priv, int port,
bool enabled, int factor)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
struct sja1105_cgu_idiv idiv;
if (regs->cgu_idiv[port] == SJA1105_RSV_ADDR)
return 0;
if (enabled && factor != 1 && factor != 10)
return -ERANGE;
/* Payload for packed_buf */
idiv.clksrc = 0x0A; /* 25MHz */
idiv.autoblock = 1; /* Block clk automatically */
idiv.idiv = factor - 1; /* Divide by 1 or 10 */
idiv.pd = enabled ? 0 : 1; /* Power down? */
sja1105_cgu_idiv_packing(packed_buf, &idiv, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->cgu_idiv[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static void
sja1105_cgu_mii_control_packing(void *buf, struct sja1105_cgu_mii_ctrl *cmd,
enum packing_op op)
{
const int size = 4;
sja1105_packing(buf, &cmd->clksrc, 28, 24, size, op);
sja1105_packing(buf, &cmd->autoblock, 11, 11, size, op);
sja1105_packing(buf, &cmd->pd, 0, 0, size, op);
}
static int sja1105_cgu_mii_tx_clk_config(struct sja1105_private *priv,
int port, sja1105_mii_role_t role)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cgu_mii_ctrl mii_tx_clk;
const int mac_clk_sources[] = {
CLKSRC_MII0_TX_CLK,
CLKSRC_MII1_TX_CLK,
CLKSRC_MII2_TX_CLK,
CLKSRC_MII3_TX_CLK,
CLKSRC_MII4_TX_CLK,
};
const int phy_clk_sources[] = {
CLKSRC_IDIV0,
CLKSRC_IDIV1,
CLKSRC_IDIV2,
CLKSRC_IDIV3,
CLKSRC_IDIV4,
};
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
int clksrc;
if (regs->mii_tx_clk[port] == SJA1105_RSV_ADDR)
return 0;
if (role == XMII_MAC)
clksrc = mac_clk_sources[port];
else
clksrc = phy_clk_sources[port];
/* Payload for packed_buf */
mii_tx_clk.clksrc = clksrc;
mii_tx_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
mii_tx_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &mii_tx_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->mii_tx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int
sja1105_cgu_mii_rx_clk_config(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
struct sja1105_cgu_mii_ctrl mii_rx_clk;
const int clk_sources[] = {
CLKSRC_MII0_RX_CLK,
CLKSRC_MII1_RX_CLK,
CLKSRC_MII2_RX_CLK,
CLKSRC_MII3_RX_CLK,
CLKSRC_MII4_RX_CLK,
};
if (regs->mii_rx_clk[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload for packed_buf */
mii_rx_clk.clksrc = clk_sources[port];
mii_rx_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
mii_rx_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &mii_rx_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->mii_rx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int
sja1105_cgu_mii_ext_tx_clk_config(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cgu_mii_ctrl mii_ext_tx_clk;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
const int clk_sources[] = {
CLKSRC_IDIV0,
CLKSRC_IDIV1,
CLKSRC_IDIV2,
CLKSRC_IDIV3,
CLKSRC_IDIV4,
};
if (regs->mii_ext_tx_clk[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload for packed_buf */
mii_ext_tx_clk.clksrc = clk_sources[port];
mii_ext_tx_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
mii_ext_tx_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &mii_ext_tx_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->mii_ext_tx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int
sja1105_cgu_mii_ext_rx_clk_config(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cgu_mii_ctrl mii_ext_rx_clk;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
const int clk_sources[] = {
CLKSRC_IDIV0,
CLKSRC_IDIV1,
CLKSRC_IDIV2,
CLKSRC_IDIV3,
CLKSRC_IDIV4,
};
if (regs->mii_ext_rx_clk[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload for packed_buf */
mii_ext_rx_clk.clksrc = clk_sources[port];
mii_ext_rx_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
mii_ext_rx_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &mii_ext_rx_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->mii_ext_rx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int sja1105_mii_clocking_setup(struct sja1105_private *priv, int port,
sja1105_mii_role_t role)
{
int rc;
rc = sja1105_cgu_idiv_config(priv, port, (role == XMII_PHY), 1);
if (rc < 0)
return rc;
rc = sja1105_cgu_mii_tx_clk_config(priv, port, role);
if (rc < 0)
return rc;
rc = sja1105_cgu_mii_rx_clk_config(priv, port);
if (rc < 0)
return rc;
if (role == XMII_PHY) {
rc = sja1105_cgu_mii_ext_tx_clk_config(priv, port);
if (rc < 0)
return rc;
rc = sja1105_cgu_mii_ext_rx_clk_config(priv, port);
if (rc < 0)
return rc;
}
return 0;
}
static void
sja1105_cgu_pll_control_packing(void *buf, struct sja1105_cgu_pll_ctrl *cmd,
enum packing_op op)
{
const int size = 4;
sja1105_packing(buf, &cmd->pllclksrc, 28, 24, size, op);
sja1105_packing(buf, &cmd->msel, 23, 16, size, op);
sja1105_packing(buf, &cmd->autoblock, 11, 11, size, op);
sja1105_packing(buf, &cmd->psel, 9, 8, size, op);
sja1105_packing(buf, &cmd->direct, 7, 7, size, op);
sja1105_packing(buf, &cmd->fbsel, 6, 6, size, op);
sja1105_packing(buf, &cmd->bypass, 1, 1, size, op);
sja1105_packing(buf, &cmd->pd, 0, 0, size, op);
}
static int sja1105_cgu_rgmii_tx_clk_config(struct sja1105_private *priv,
int port, u64 speed)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cgu_mii_ctrl txc;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
int clksrc;
if (regs->rgmii_tx_clk[port] == SJA1105_RSV_ADDR)
return 0;
if (speed == priv->info->port_speed[SJA1105_SPEED_1000MBPS]) {
clksrc = CLKSRC_PLL0;
} else {
int clk_sources[] = {CLKSRC_IDIV0, CLKSRC_IDIV1, CLKSRC_IDIV2,
CLKSRC_IDIV3, CLKSRC_IDIV4};
clksrc = clk_sources[port];
}
/* RGMII: 125MHz for 1000, 25MHz for 100, 2.5MHz for 10 */
txc.clksrc = clksrc;
/* Autoblock clk while changing clksrc */
txc.autoblock = 1;
/* Power Down off => enabled */
txc.pd = 0;
sja1105_cgu_mii_control_packing(packed_buf, &txc, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rgmii_tx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
/* AGU */
static void
sja1105_cfg_pad_mii_packing(void *buf, struct sja1105_cfg_pad_mii *cmd,
enum packing_op op)
{
const int size = 4;
sja1105_packing(buf, &cmd->d32_os, 28, 27, size, op);
sja1105_packing(buf, &cmd->d32_ih, 26, 26, size, op);
sja1105_packing(buf, &cmd->d32_ipud, 25, 24, size, op);
sja1105_packing(buf, &cmd->d10_os, 20, 19, size, op);
sja1105_packing(buf, &cmd->d10_ih, 18, 18, size, op);
sja1105_packing(buf, &cmd->d10_ipud, 17, 16, size, op);
sja1105_packing(buf, &cmd->ctrl_os, 12, 11, size, op);
sja1105_packing(buf, &cmd->ctrl_ih, 10, 10, size, op);
sja1105_packing(buf, &cmd->ctrl_ipud, 9, 8, size, op);
sja1105_packing(buf, &cmd->clk_os, 4, 3, size, op);
sja1105_packing(buf, &cmd->clk_ih, 2, 2, size, op);
sja1105_packing(buf, &cmd->clk_ipud, 1, 0, size, op);
}
static void
sja1110_cfg_pad_mii_id_packing(void *buf, struct sja1105_cfg_pad_mii_id *cmd,
enum packing_op op)
{
const int size = SJA1105_SIZE_CGU_CMD;
u64 range = 4;
/* Fields RXC_RANGE and TXC_RANGE select the input frequency range:
* 0 = 2.5MHz
* 1 = 25MHz
* 2 = 50MHz
* 3 = 125MHz
* 4 = Automatically determined by port speed.
* There's no point in defining a structure different than the one for
* SJA1105, so just hardcode the frequency range to automatic, just as
* before.
*/
sja1105_packing(buf, &cmd->rxc_stable_ovr, 26, 26, size, op);
sja1105_packing(buf, &cmd->rxc_delay, 25, 21, size, op);
sja1105_packing(buf, &range, 20, 18, size, op);
sja1105_packing(buf, &cmd->rxc_bypass, 17, 17, size, op);
sja1105_packing(buf, &cmd->rxc_pd, 16, 16, size, op);
sja1105_packing(buf, &cmd->txc_stable_ovr, 10, 10, size, op);
sja1105_packing(buf, &cmd->txc_delay, 9, 5, size, op);
sja1105_packing(buf, &range, 4, 2, size, op);
sja1105_packing(buf, &cmd->txc_bypass, 1, 1, size, op);
sja1105_packing(buf, &cmd->txc_pd, 0, 0, size, op);
}
static int sja1105_rgmii_cfg_pad_tx_config(struct sja1105_private *priv,
int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cfg_pad_mii pad_mii_tx = {0};
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
if (regs->pad_mii_tx[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload */
pad_mii_tx.d32_os = 3; /* TXD[3:2] output stage: */
/* high noise/high speed */
pad_mii_tx.d10_os = 3; /* TXD[1:0] output stage: */
/* high noise/high speed */
pad_mii_tx.d32_ipud = 2; /* TXD[3:2] input stage: */
/* plain input (default) */
pad_mii_tx.d10_ipud = 2; /* TXD[1:0] input stage: */
/* plain input (default) */
pad_mii_tx.ctrl_os = 3; /* TX_CTL / TX_ER output stage */
pad_mii_tx.ctrl_ipud = 2; /* TX_CTL / TX_ER input stage (default) */
pad_mii_tx.clk_os = 3; /* TX_CLK output stage */
pad_mii_tx.clk_ih = 0; /* TX_CLK input hysteresis (default) */
pad_mii_tx.clk_ipud = 2; /* TX_CLK input stage (default) */
sja1105_cfg_pad_mii_packing(packed_buf, &pad_mii_tx, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->pad_mii_tx[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int sja1105_cfg_pad_rx_config(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cfg_pad_mii pad_mii_rx = {0};
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
if (regs->pad_mii_rx[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload */
pad_mii_rx.d32_ih = 0; /* RXD[3:2] input stage hysteresis: */
/* non-Schmitt (default) */
pad_mii_rx.d32_ipud = 2; /* RXD[3:2] input weak pull-up/down */
/* plain input (default) */
pad_mii_rx.d10_ih = 0; /* RXD[1:0] input stage hysteresis: */
/* non-Schmitt (default) */
pad_mii_rx.d10_ipud = 2; /* RXD[1:0] input weak pull-up/down */
/* plain input (default) */
pad_mii_rx.ctrl_ih = 0; /* RX_DV/CRS_DV/RX_CTL and RX_ER */
/* input stage hysteresis: */
/* non-Schmitt (default) */
pad_mii_rx.ctrl_ipud = 3; /* RX_DV/CRS_DV/RX_CTL and RX_ER */
/* input stage weak pull-up/down: */
/* pull-down */
pad_mii_rx.clk_os = 2; /* RX_CLK/RXC output stage: */
/* medium noise/fast speed (default) */
pad_mii_rx.clk_ih = 0; /* RX_CLK/RXC input hysteresis: */
/* non-Schmitt (default) */
pad_mii_rx.clk_ipud = 2; /* RX_CLK/RXC input pull-up/down: */
/* plain input (default) */
sja1105_cfg_pad_mii_packing(packed_buf, &pad_mii_rx, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->pad_mii_rx[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static void
sja1105_cfg_pad_mii_id_packing(void *buf, struct sja1105_cfg_pad_mii_id *cmd,
enum packing_op op)
{
const int size = SJA1105_SIZE_CGU_CMD;
sja1105_packing(buf, &cmd->rxc_stable_ovr, 15, 15, size, op);
sja1105_packing(buf, &cmd->rxc_delay, 14, 10, size, op);
sja1105_packing(buf, &cmd->rxc_bypass, 9, 9, size, op);
sja1105_packing(buf, &cmd->rxc_pd, 8, 8, size, op);
sja1105_packing(buf, &cmd->txc_stable_ovr, 7, 7, size, op);
sja1105_packing(buf, &cmd->txc_delay, 6, 2, size, op);
sja1105_packing(buf, &cmd->txc_bypass, 1, 1, size, op);
sja1105_packing(buf, &cmd->txc_pd, 0, 0, size, op);
}
/* Valid range in degrees is an integer between 73.8 and 101.7 */
static u64 sja1105_rgmii_delay(u64 phase)
{
/* UM11040.pdf: The delay in degree phase is 73.8 + delay_tune * 0.9.
* To avoid floating point operations we'll multiply by 10
* and get 1 decimal point precision.
*/
phase *= 10;
return (phase - 738) / 9;
}
static int sja1105pqrs_setup_rgmii_delay(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cfg_pad_mii_id pad_mii_id = {0};
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
int rc;
if (priv->rgmii_rx_delay[port])
pad_mii_id.rxc_delay = sja1105_rgmii_delay(90);
if (priv->rgmii_tx_delay[port])
pad_mii_id.txc_delay = sja1105_rgmii_delay(90);
/* Stage 1: Turn the RGMII delay lines off. */
pad_mii_id.rxc_bypass = 1;
pad_mii_id.rxc_pd = 1;
pad_mii_id.txc_bypass = 1;
pad_mii_id.txc_pd = 1;
sja1105_cfg_pad_mii_id_packing(packed_buf, &pad_mii_id, PACK);
rc = sja1105_xfer_buf(priv, SPI_WRITE, regs->pad_mii_id[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
if (rc < 0)
return rc;
/* Stage 2: Turn the RGMII delay lines on. */
if (priv->rgmii_rx_delay[port]) {
pad_mii_id.rxc_bypass = 0;
pad_mii_id.rxc_pd = 0;
}
if (priv->rgmii_tx_delay[port]) {
pad_mii_id.txc_bypass = 0;
pad_mii_id.txc_pd = 0;
}
sja1105_cfg_pad_mii_id_packing(packed_buf, &pad_mii_id, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->pad_mii_id[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int sja1110_setup_rgmii_delay(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cfg_pad_mii_id pad_mii_id = {0};
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
pad_mii_id.rxc_pd = 1;
pad_mii_id.txc_pd = 1;
if (priv->rgmii_rx_delay[port]) {
pad_mii_id.rxc_delay = sja1105_rgmii_delay(90);
/* The "BYPASS" bit in SJA1110 is actually a "don't bypass" */
pad_mii_id.rxc_bypass = 1;
pad_mii_id.rxc_pd = 0;
}
if (priv->rgmii_tx_delay[port]) {
pad_mii_id.txc_delay = sja1105_rgmii_delay(90);
pad_mii_id.txc_bypass = 1;
pad_mii_id.txc_pd = 0;
}
sja1110_cfg_pad_mii_id_packing(packed_buf, &pad_mii_id, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->pad_mii_id[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int sja1105_rgmii_clocking_setup(struct sja1105_private *priv, int port,
sja1105_mii_role_t role)
{
struct sja1105_mac_config_entry *mac;
struct udevice *dev = priv->dev;
u64 speed;
int rc;
mac = priv->static_config.tables[BLK_IDX_MAC_CONFIG].entries;
speed = mac[port].speed;
if (speed == priv->info->port_speed[SJA1105_SPEED_1000MBPS]) {
/* 1000Mbps, IDIV disabled (125 MHz) */
rc = sja1105_cgu_idiv_config(priv, port, false, 1);
} else if (speed == priv->info->port_speed[SJA1105_SPEED_100MBPS]) {
/* 100Mbps, IDIV enabled, divide by 1 (25 MHz) */
rc = sja1105_cgu_idiv_config(priv, port, true, 1);
} else if (speed == priv->info->port_speed[SJA1105_SPEED_10MBPS]) {
/* 10Mbps, IDIV enabled, divide by 10 (2.5 MHz) */
rc = sja1105_cgu_idiv_config(priv, port, true, 10);
} else if (speed == priv->info->port_speed[SJA1105_SPEED_AUTO]) {
/* Skip CGU configuration if there is no speed available
* (e.g. link is not established yet)
*/
dev_dbg(dev, "Speed not available, skipping CGU config\n");
return 0;
} else {
rc = -EINVAL;
}
if (rc < 0) {
dev_err(dev, "Failed to configure idiv\n");
return rc;
}
rc = sja1105_cgu_rgmii_tx_clk_config(priv, port, speed);
if (rc < 0) {
dev_err(dev, "Failed to configure RGMII Tx clock\n");
return rc;
}
rc = sja1105_rgmii_cfg_pad_tx_config(priv, port);
if (rc < 0) {
dev_err(dev, "Failed to configure Tx pad registers\n");
return rc;
}
if (!priv->info->setup_rgmii_delay)
return 0;
return priv->info->setup_rgmii_delay(priv, port);
}
static int sja1105_cgu_rmii_ref_clk_config(struct sja1105_private *priv,
int port)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
struct sja1105_cgu_mii_ctrl ref_clk;
const int clk_sources[] = {
CLKSRC_MII0_TX_CLK,
CLKSRC_MII1_TX_CLK,
CLKSRC_MII2_TX_CLK,
CLKSRC_MII3_TX_CLK,
CLKSRC_MII4_TX_CLK,
};
if (regs->rmii_ref_clk[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload for packed_buf */
ref_clk.clksrc = clk_sources[port];
ref_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
ref_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &ref_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rmii_ref_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int
sja1105_cgu_rmii_ext_tx_clk_config(struct sja1105_private *priv, int port)
{
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_cgu_mii_ctrl ext_tx_clk;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
if (regs->rmii_ext_tx_clk[port] == SJA1105_RSV_ADDR)
return 0;
/* Payload for packed_buf */
ext_tx_clk.clksrc = CLKSRC_PLL1;
ext_tx_clk.autoblock = 1; /* Autoblock clk while changing clksrc */
ext_tx_clk.pd = 0; /* Power Down off => enabled */
sja1105_cgu_mii_control_packing(packed_buf, &ext_tx_clk, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->rmii_ext_tx_clk[port],
packed_buf, SJA1105_SIZE_CGU_CMD);
}
static int sja1105_cgu_rmii_pll_config(struct sja1105_private *priv)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_CGU_CMD] = {0};
struct sja1105_cgu_pll_ctrl pll = {0};
int rc;
if (regs->rmii_pll1 == SJA1105_RSV_ADDR)
return 0;
/* Step 1: PLL1 setup for 50Mhz */
pll.pllclksrc = 0xA;
pll.msel = 0x1;
pll.autoblock = 0x1;
pll.psel = 0x1;
pll.direct = 0x0;
pll.fbsel = 0x1;
pll.bypass = 0x0;
pll.pd = 0x1;
sja1105_cgu_pll_control_packing(packed_buf, &pll, PACK);
rc = sja1105_xfer_buf(priv, SPI_WRITE, regs->rmii_pll1, packed_buf,
SJA1105_SIZE_CGU_CMD);
if (rc < 0)
return rc;
/* Step 2: Enable PLL1 */
pll.pd = 0x0;
sja1105_cgu_pll_control_packing(packed_buf, &pll, PACK);
rc = sja1105_xfer_buf(priv, SPI_WRITE, regs->rmii_pll1, packed_buf,
SJA1105_SIZE_CGU_CMD);
return rc;
}
static int sja1105_rmii_clocking_setup(struct sja1105_private *priv, int port,
sja1105_mii_role_t role)
{
int rc;
/* AH1601.pdf chapter 2.5.1. Sources */
if (role == XMII_MAC) {
/* Configure and enable PLL1 for 50Mhz output */
rc = sja1105_cgu_rmii_pll_config(priv);
if (rc < 0)
return rc;
}
/* Disable IDIV for this port */
rc = sja1105_cgu_idiv_config(priv, port, false, 1);
if (rc < 0)
return rc;
/* Source to sink mappings */
rc = sja1105_cgu_rmii_ref_clk_config(priv, port);
if (rc < 0)
return rc;
if (role == XMII_MAC) {
rc = sja1105_cgu_rmii_ext_tx_clk_config(priv, port);
if (rc < 0)
return rc;
}
return 0;
}
static int sja1105_pcs_read(struct sja1105_private *priv, int addr,
int devad, int regnum)
{
return priv->mdio_pcs->read(priv->mdio_pcs, addr, devad, regnum);
}
static int sja1105_pcs_write(struct sja1105_private *priv, int addr,
int devad, int regnum, u16 val)
{
return priv->mdio_pcs->write(priv->mdio_pcs, addr, devad, regnum, val);
}
/* In NXP SJA1105, the PCS is integrated with a PMA that has the TX lane
* polarity inverted by default (PLUS is MINUS, MINUS is PLUS). To obtain
* normal non-inverted behavior, the TX lane polarity must be inverted in the
* PCS, via the DIGITAL_CONTROL_2 register.
*/
static int sja1105_pma_config(struct sja1105_private *priv, int port)
{
return sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
DW_VR_MII_DIG_CTRL2,
DW_VR_MII_DIG_CTRL2_TX_POL_INV);
}
static int sja1110_pma_config(struct sja1105_private *priv, int port)
{
u16 txpll_fbdiv = 0x19, txpll_refdiv = 0x1;
u16 rxpll_fbdiv = 0x19, rxpll_refdiv = 0x1;
u16 rx_cdr_ctle = 0x212a;
u16 val;
int rc;
/* Program TX PLL feedback divider and reference divider settings for
* correct oscillation frequency.
*/
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_TXPLL_CTRL0,
SJA1110_TXPLL_FBDIV(txpll_fbdiv));
if (rc < 0)
return rc;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_TXPLL_CTRL1,
SJA1110_TXPLL_REFDIV(txpll_refdiv));
if (rc < 0)
return rc;
/* Program transmitter amplitude and disable amplitude trimming */
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_LANE_DRIVER1_0, SJA1110_TXDRV(0x5));
if (rc < 0)
return rc;
val = SJA1110_TXDRVTRIM_LSB(0xffffffull);
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_LANE_DRIVER2_0, val);
if (rc < 0)
return rc;
val = SJA1110_TXDRVTRIM_MSB(0xffffffull) | SJA1110_LANE_DRIVER2_1_RSV;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_LANE_DRIVER2_1, val);
if (rc < 0)
return rc;
/* Enable input and output resistor terminations for low BER. */
val = SJA1110_ACCOUPLE_RXVCM_EN | SJA1110_CDR_GAIN |
SJA1110_RXRTRIM(4) | SJA1110_RXTEN | SJA1110_TXPLL_BWSEL |
SJA1110_TXRTRIM(3) | SJA1110_TXTEN;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_LANE_TRIM,
val);
if (rc < 0)
return rc;
/* Select PCS as transmitter data source. */
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_LANE_DATAPATH_1, 0);
if (rc < 0)
return rc;
/* Program RX PLL feedback divider and reference divider for correct
* oscillation frequency.
*/
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_RXPLL_CTRL0,
SJA1110_RXPLL_FBDIV(rxpll_fbdiv));
if (rc < 0)
return rc;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_RXPLL_CTRL1,
SJA1110_RXPLL_REFDIV(rxpll_refdiv));
if (rc < 0)
return rc;
/* Program threshold for receiver signal detector.
* Enable control of RXPLL by receiver signal detector to disable RXPLL
* when an input signal is not present.
*/
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_RX_DATA_DETECT, 0x0005);
if (rc < 0)
return rc;
/* Enable TX and RX PLLs and circuits.
* Release reset of PMA to enable data flow to/from PCS.
*/
rc = sja1105_pcs_read(priv, port, MDIO_MMD_VEND2,
SJA1110_POWERDOWN_ENABLE);
if (rc < 0)
return rc;
val = rc & ~(SJA1110_TXPLL_PD | SJA1110_TXPD | SJA1110_RXCH_PD |
SJA1110_RXBIAS_PD | SJA1110_RESET_SER_EN |
SJA1110_RESET_SER | SJA1110_RESET_DES);
val |= SJA1110_RXPKDETEN | SJA1110_RCVEN;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2,
SJA1110_POWERDOWN_ENABLE, val);
if (rc < 0)
return rc;
/* Program continuous-time linear equalizer (CTLE) settings. */
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, SJA1110_RX_CDR_CTLE,
rx_cdr_ctle);
if (rc < 0)
return rc;
return 0;
}
static int sja1105_xpcs_config_aneg_c37_sgmii(struct sja1105_private *priv,
int port)
{
int rc;
rc = sja1105_pcs_read(priv, port, MDIO_MMD_VEND2, MDIO_CTRL1);
if (rc < 0)
return rc;
rc &= ~MDIO_AN_CTRL1_ENABLE;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, MDIO_CTRL1,
rc);
if (rc < 0)
return rc;
rc = sja1105_pcs_read(priv, port, MDIO_MMD_VEND2, DW_VR_MII_AN_CTRL);
if (rc < 0)
return rc;
rc &= ~(DW_VR_MII_PCS_MODE_MASK | DW_VR_MII_TX_CONFIG_MASK);
rc |= (DW_VR_MII_PCS_MODE_C37_SGMII <<
DW_VR_MII_AN_CTRL_PCS_MODE_SHIFT &
DW_VR_MII_PCS_MODE_MASK);
rc |= (DW_VR_MII_TX_CONFIG_MAC_SIDE_SGMII <<
DW_VR_MII_AN_CTRL_TX_CONFIG_SHIFT &
DW_VR_MII_TX_CONFIG_MASK);
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, DW_VR_MII_AN_CTRL,
rc);
if (rc < 0)
return rc;
rc = sja1105_pcs_read(priv, port, MDIO_MMD_VEND2, DW_VR_MII_DIG_CTRL1);
if (rc < 0)
return rc;
if (priv->xpcs_cfg[port].inband_an)
rc |= DW_VR_MII_DIG_CTRL1_MAC_AUTO_SW;
else
rc &= ~DW_VR_MII_DIG_CTRL1_MAC_AUTO_SW;
rc = sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, DW_VR_MII_DIG_CTRL1,
rc);
if (rc < 0)
return rc;
rc = sja1105_pcs_read(priv, port, MDIO_MMD_VEND2, MDIO_CTRL1);
if (rc < 0)
return rc;
if (priv->xpcs_cfg[port].inband_an)
rc |= MDIO_AN_CTRL1_ENABLE;
else
rc &= ~MDIO_AN_CTRL1_ENABLE;
return sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, MDIO_CTRL1, rc);
}
static int sja1105_xpcs_link_up_sgmii(struct sja1105_private *priv, int port)
{
int val = BMCR_FULLDPLX;
if (priv->xpcs_cfg[port].inband_an)
return 0;
switch (priv->xpcs_cfg[port].speed) {
case SPEED_1000:
val = BMCR_SPEED1000;
break;
case SPEED_100:
val = BMCR_SPEED100;
break;
case SPEED_10:
val = BMCR_SPEED10;
break;
default:
dev_err(priv->dev, "Invalid PCS speed %d\n",
priv->xpcs_cfg[port].speed);
return -EINVAL;
}
return sja1105_pcs_write(priv, port, MDIO_MMD_VEND2, MDIO_CTRL1, val);
}
static int sja1105_sgmii_setup(struct sja1105_private *priv, int port)
{
int rc;
rc = sja1105_xpcs_config_aneg_c37_sgmii(priv, port);
if (rc)
return rc;
rc = sja1105_xpcs_link_up_sgmii(priv, port);
if (rc)
return rc;
return priv->info->pma_config(priv, port);
}
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
static int sja1105_clocking_setup_port(struct sja1105_private *priv, int port)
{
struct sja1105_xmii_params_entry *mii;
sja1105_phy_interface_t phy_mode;
sja1105_mii_role_t role;
int rc;
mii = priv->static_config.tables[BLK_IDX_XMII_PARAMS].entries;
/* RGMII etc */
phy_mode = mii->xmii_mode[port];
/* MAC or PHY, for applicable types (not RGMII) */
role = mii->phy_mac[port];
switch (phy_mode) {
case XMII_MODE_MII:
rc = sja1105_mii_clocking_setup(priv, port, role);
break;
case XMII_MODE_RMII:
rc = sja1105_rmii_clocking_setup(priv, port, role);
break;
case XMII_MODE_RGMII:
rc = sja1105_rgmii_clocking_setup(priv, port, role);
break;
case XMII_MODE_SGMII:
rc = sja1105_sgmii_setup(priv, port);
break;
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
default:
return -EINVAL;
}
if (rc)
return rc;
/* Internally pull down the RX_DV/CRS_DV/RX_CTL and RX_ER inputs */
return sja1105_cfg_pad_rx_config(priv, port);
}
static int sja1105_clocking_setup(struct sja1105_private *priv)
{
struct dsa_pdata *pdata = dev_get_uclass_plat(priv->dev);
int port, rc;
for (port = 0; port < pdata->num_ports; port++) {
rc = sja1105_clocking_setup_port(priv, port);
if (rc < 0)
return rc;
}
return 0;
}
static int sja1105_pcs_mdio_read(struct mii_dev *bus, int phy, int mmd, int reg)
{
u8 packed_buf[SJA1105_SIZE_MDIO_CMD] = {0};
struct sja1105_private *priv = bus->priv;
const int size = SJA1105_SIZE_MDIO_CMD;
u64 addr, tmp;
int rc;
if (mmd == MDIO_DEVAD_NONE)
return -ENODEV;
if (!priv->info->supports_sgmii[phy])
return -ENODEV;
addr = (mmd << 16) | (reg & GENMASK(15, 0));
if (mmd != MDIO_MMD_VEND1 && mmd != MDIO_MMD_VEND2)
return 0xffff;
rc = sja1105_xfer_buf(priv, SPI_READ, addr, packed_buf, size);
if (rc < 0)
return rc;
sja1105_packing(packed_buf, &tmp, 31, 0, size, UNPACK);
return tmp & 0xffff;
}
static int sja1105_pcs_mdio_write(struct mii_dev *bus, int phy, int mmd,
int reg, u16 val)
{
u8 packed_buf[SJA1105_SIZE_MDIO_CMD] = {0};
struct sja1105_private *priv = bus->priv;
const int size = SJA1105_SIZE_MDIO_CMD;
u64 addr, tmp;
if (mmd == MDIO_DEVAD_NONE)
return -ENODEV;
if (!priv->info->supports_sgmii[phy])
return -ENODEV;
addr = (mmd << 16) | (reg & GENMASK(15, 0));
tmp = val;
if (mmd != MDIO_MMD_VEND1 && mmd != MDIO_MMD_VEND2)
return -ENODEV;
sja1105_packing(packed_buf, &tmp, 31, 0, size, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, addr, packed_buf, size);
}
static int sja1110_pcs_mdio_read(struct mii_dev *bus, int phy, int mmd, int reg)
{
struct sja1105_private *priv = bus->priv;
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_MDIO_CMD] = {0};
const int size = SJA1105_SIZE_MDIO_CMD;
int offset, bank;
u64 addr, tmp;
int rc;
if (mmd == MDIO_DEVAD_NONE)
return -ENODEV;
if (regs->pcs_base[phy] == SJA1105_RSV_ADDR)
return -ENODEV;
addr = (mmd << 16) | (reg & GENMASK(15, 0));
bank = addr >> 8;
offset = addr & GENMASK(7, 0);
/* This addressing scheme reserves register 0xff for the bank address
* register, so that can never be addressed.
*/
if (offset == 0xff)
return -ENODEV;
tmp = bank;
sja1105_packing(packed_buf, &tmp, 31, 0, size, PACK);
rc = sja1105_xfer_buf(priv, SPI_WRITE,
regs->pcs_base[phy] + SJA1110_PCS_BANK_REG,
packed_buf, size);
if (rc < 0)
return rc;
rc = sja1105_xfer_buf(priv, SPI_READ, regs->pcs_base[phy] + offset,
packed_buf, size);
if (rc < 0)
return rc;
sja1105_packing(packed_buf, &tmp, 31, 0, size, UNPACK);
return tmp & 0xffff;
}
static int sja1110_pcs_mdio_write(struct mii_dev *bus, int phy, int mmd,
int reg, u16 val)
{
struct sja1105_private *priv = bus->priv;
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_MDIO_CMD] = {0};
const int size = SJA1105_SIZE_MDIO_CMD;
int offset, bank;
u64 addr, tmp;
int rc;
if (mmd == MDIO_DEVAD_NONE)
return -ENODEV;
if (regs->pcs_base[phy] == SJA1105_RSV_ADDR)
return -ENODEV;
addr = (mmd << 16) | (reg & GENMASK(15, 0));
bank = addr >> 8;
offset = addr & GENMASK(7, 0);
/* This addressing scheme reserves register 0xff for the bank address
* register, so that can never be addressed.
*/
if (offset == 0xff)
return -ENODEV;
tmp = bank;
sja1105_packing(packed_buf, &tmp, 31, 0, size, PACK);
rc = sja1105_xfer_buf(priv, SPI_WRITE,
regs->pcs_base[phy] + SJA1110_PCS_BANK_REG,
packed_buf, size);
if (rc < 0)
return rc;
tmp = val;
sja1105_packing(packed_buf, &tmp, 31, 0, size, PACK);
return sja1105_xfer_buf(priv, SPI_WRITE, regs->pcs_base[phy] + offset,
packed_buf, size);
}
static int sja1105_mdiobus_register(struct sja1105_private *priv)
{
struct udevice *dev = priv->dev;
struct mii_dev *bus;
int rc;
if (!priv->info->pcs_mdio_read || !priv->info->pcs_mdio_write)
return 0;
bus = mdio_alloc();
if (!bus)
return -ENOMEM;
snprintf(bus->name, MDIO_NAME_LEN, "%s-pcs", dev->name);
bus->read = priv->info->pcs_mdio_read;
bus->write = priv->info->pcs_mdio_write;
bus->priv = priv;
rc = mdio_register(bus);
if (rc) {
mdio_free(bus);
return rc;
}
priv->mdio_pcs = bus;
return 0;
}
static void sja1105_mdiobus_unregister(struct sja1105_private *priv)
{
if (!priv->mdio_pcs)
return;
mdio_unregister(priv->mdio_pcs);
mdio_free(priv->mdio_pcs);
}
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
static const struct sja1105_regs sja1105et_regs = {
.device_id = 0x0,
.prod_id = 0x100BC3,
.status = 0x1,
.port_control = 0x11,
.config = 0x020000,
.rgu = 0x100440,
/* UM10944.pdf, Table 86, ACU Register overview */
.pad_mii_tx = {0x100800, 0x100802, 0x100804, 0x100806, 0x100808},
.pad_mii_rx = {0x100801, 0x100803, 0x100805, 0x100807, 0x100809},
.rmii_pll1 = 0x10000A,
.cgu_idiv = {0x10000B, 0x10000C, 0x10000D, 0x10000E, 0x10000F},
/* UM10944.pdf, Table 78, CGU Register overview */
.mii_tx_clk = {0x100013, 0x10001A, 0x100021, 0x100028, 0x10002F},
.mii_rx_clk = {0x100014, 0x10001B, 0x100022, 0x100029, 0x100030},
.mii_ext_tx_clk = {0x100018, 0x10001F, 0x100026, 0x10002D, 0x100034},
.mii_ext_rx_clk = {0x100019, 0x100020, 0x100027, 0x10002E, 0x100035},
.rgmii_tx_clk = {0x100016, 0x10001D, 0x100024, 0x10002B, 0x100032},
.rmii_ref_clk = {0x100015, 0x10001C, 0x100023, 0x10002A, 0x100031},
.rmii_ext_tx_clk = {0x100018, 0x10001F, 0x100026, 0x10002D, 0x100034},
};
static const struct sja1105_regs sja1105pqrs_regs = {
.device_id = 0x0,
.prod_id = 0x100BC3,
.status = 0x1,
.port_control = 0x12,
.config = 0x020000,
.rgu = 0x100440,
/* UM10944.pdf, Table 86, ACU Register overview */
.pad_mii_tx = {0x100800, 0x100802, 0x100804, 0x100806, 0x100808},
.pad_mii_rx = {0x100801, 0x100803, 0x100805, 0x100807, 0x100809},
.pad_mii_id = {0x100810, 0x100811, 0x100812, 0x100813, 0x100814},
.rmii_pll1 = 0x10000A,
.cgu_idiv = {0x10000B, 0x10000C, 0x10000D, 0x10000E, 0x10000F},
/* UM11040.pdf, Table 114 */
.mii_tx_clk = {0x100013, 0x100019, 0x10001F, 0x100025, 0x10002B},
.mii_rx_clk = {0x100014, 0x10001A, 0x100020, 0x100026, 0x10002C},
.mii_ext_tx_clk = {0x100017, 0x10001D, 0x100023, 0x100029, 0x10002F},
.mii_ext_rx_clk = {0x100018, 0x10001E, 0x100024, 0x10002A, 0x100030},
.rgmii_tx_clk = {0x100016, 0x10001C, 0x100022, 0x100028, 0x10002E},
.rmii_ref_clk = {0x100015, 0x10001B, 0x100021, 0x100027, 0x10002D},
.rmii_ext_tx_clk = {0x100017, 0x10001D, 0x100023, 0x100029, 0x10002F},
};
static const struct sja1105_regs sja1110_regs = {
.device_id = SJA1110_SPI_ADDR(0x0),
.prod_id = SJA1110_ACU_ADDR(0xf00),
.status = SJA1110_SPI_ADDR(0x4),
.port_control = SJA1110_SPI_ADDR(0x50), /* actually INHIB_TX */
.config = 0x020000,
.rgu = SJA1110_RGU_ADDR(0x100), /* Reset Control Register 0 */
/* Ports 2 and 3 are capable of xMII, but there isn't anything to
* configure in the CGU/ACU for them.
*/
.pad_mii_tx = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR},
.pad_mii_rx = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR},
.pad_mii_id = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1110_ACU_ADDR(0x18), SJA1110_ACU_ADDR(0x28),
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR},
.rmii_pll1 = SJA1105_RSV_ADDR,
.cgu_idiv = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.mii_tx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.mii_rx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.mii_ext_tx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.mii_ext_rx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.rgmii_tx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.rmii_ref_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
.rmii_ext_tx_clk = {SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR},
.pcs_base = {SJA1105_RSV_ADDR, 0x1c1400, 0x1c1800, 0x1c1c00, 0x1c2000,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR,
SJA1105_RSV_ADDR, SJA1105_RSV_ADDR, SJA1105_RSV_ADDR},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
};
enum sja1105_switch_id {
SJA1105E = 0,
SJA1105T,
SJA1105P,
SJA1105Q,
SJA1105R,
SJA1105S,
SJA1110A,
SJA1110B,
SJA1110C,
SJA1110D,
SJA1105_MAX_SWITCH_ID,
};
static const struct sja1105_info sja1105_info[] = {
[SJA1105E] = {
.device_id = SJA1105E_DEVICE_ID,
.part_no = SJA1105ET_PART_NO,
.static_ops = sja1105et_table_ops,
.reset_cmd = sja1105et_reset_cmd,
.regs = &sja1105et_regs,
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.name = "SJA1105E",
},
[SJA1105T] = {
.device_id = SJA1105T_DEVICE_ID,
.part_no = SJA1105ET_PART_NO,
.static_ops = sja1105et_table_ops,
.reset_cmd = sja1105et_reset_cmd,
.regs = &sja1105et_regs,
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.name = "SJA1105T",
},
[SJA1105P] = {
.device_id = SJA1105PR_DEVICE_ID,
.part_no = SJA1105P_PART_NO,
.static_ops = sja1105pqrs_table_ops,
.setup_rgmii_delay = sja1105pqrs_setup_rgmii_delay,
.reset_cmd = sja1105pqrs_reset_cmd,
.regs = &sja1105pqrs_regs,
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.name = "SJA1105P",
},
[SJA1105Q] = {
.device_id = SJA1105QS_DEVICE_ID,
.part_no = SJA1105Q_PART_NO,
.static_ops = sja1105pqrs_table_ops,
.setup_rgmii_delay = sja1105pqrs_setup_rgmii_delay,
.reset_cmd = sja1105pqrs_reset_cmd,
.regs = &sja1105pqrs_regs,
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.name = "SJA1105Q",
},
[SJA1105R] = {
.device_id = SJA1105PR_DEVICE_ID,
.part_no = SJA1105R_PART_NO,
.static_ops = sja1105pqrs_table_ops,
.setup_rgmii_delay = sja1105pqrs_setup_rgmii_delay,
.reset_cmd = sja1105pqrs_reset_cmd,
.regs = &sja1105pqrs_regs,
.pcs_mdio_read = sja1105_pcs_mdio_read,
.pcs_mdio_write = sja1105_pcs_mdio_write,
.pma_config = sja1105_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.supports_sgmii = {false, false, false, false, true},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1105R",
},
[SJA1105S] = {
.device_id = SJA1105QS_DEVICE_ID,
.part_no = SJA1105S_PART_NO,
.static_ops = sja1105pqrs_table_ops,
.setup_rgmii_delay = sja1105pqrs_setup_rgmii_delay,
.reset_cmd = sja1105pqrs_reset_cmd,
.regs = &sja1105pqrs_regs,
.pcs_mdio_read = sja1105_pcs_mdio_read,
.pcs_mdio_write = sja1105_pcs_mdio_write,
.pma_config = sja1105_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 3,
[SJA1105_SPEED_100MBPS] = 2,
[SJA1105_SPEED_1000MBPS] = 1,
},
.supports_mii = {true, true, true, true, true},
.supports_rmii = {true, true, true, true, true},
.supports_rgmii = {true, true, true, true, true},
.supports_sgmii = {false, false, false, false, true},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1105S",
},
[SJA1110A] = {
.device_id = SJA1110_DEVICE_ID,
.part_no = SJA1110A_PART_NO,
.static_ops = sja1110_table_ops,
.setup_rgmii_delay = sja1110_setup_rgmii_delay,
.reset_cmd = sja1110_reset_cmd,
.regs = &sja1110_regs,
.pcs_mdio_read = sja1110_pcs_mdio_read,
.pcs_mdio_write = sja1110_pcs_mdio_write,
.pma_config = sja1110_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 4,
[SJA1105_SPEED_100MBPS] = 3,
[SJA1105_SPEED_1000MBPS] = 2,
},
.supports_mii = {true, true, true, true, false,
true, true, true, true, true, true},
.supports_rmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_rgmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_sgmii = {false, true, true, true, true,
false, false, false, false, false, false},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1110A",
},
[SJA1110B] = {
.device_id = SJA1110_DEVICE_ID,
.part_no = SJA1110B_PART_NO,
.static_ops = sja1110_table_ops,
.setup_rgmii_delay = sja1110_setup_rgmii_delay,
.reset_cmd = sja1110_reset_cmd,
.regs = &sja1110_regs,
.pcs_mdio_read = sja1110_pcs_mdio_read,
.pcs_mdio_write = sja1110_pcs_mdio_write,
.pma_config = sja1110_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 4,
[SJA1105_SPEED_100MBPS] = 3,
[SJA1105_SPEED_1000MBPS] = 2,
},
.supports_mii = {true, true, true, true, false,
true, true, true, true, true, false},
.supports_rmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_rgmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_sgmii = {false, false, false, true, true,
false, false, false, false, false, false},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1110B",
},
[SJA1110C] = {
.device_id = SJA1110_DEVICE_ID,
.part_no = SJA1110C_PART_NO,
.static_ops = sja1110_table_ops,
.setup_rgmii_delay = sja1110_setup_rgmii_delay,
.reset_cmd = sja1110_reset_cmd,
.regs = &sja1110_regs,
.pcs_mdio_read = sja1110_pcs_mdio_read,
.pcs_mdio_write = sja1110_pcs_mdio_write,
.pma_config = sja1110_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 4,
[SJA1105_SPEED_100MBPS] = 3,
[SJA1105_SPEED_1000MBPS] = 2,
},
.supports_mii = {true, true, true, true, false,
true, true, true, false, false, false},
.supports_rmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_rgmii = {false, false, true, true, false,
false, false, false, false, false, false},
.supports_sgmii = {false, false, false, false, true,
false, false, false, false, false, false},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1110C",
},
[SJA1110D] = {
.device_id = SJA1110_DEVICE_ID,
.part_no = SJA1110D_PART_NO,
.static_ops = sja1110_table_ops,
.setup_rgmii_delay = sja1110_setup_rgmii_delay,
.reset_cmd = sja1110_reset_cmd,
.regs = &sja1110_regs,
.pcs_mdio_read = sja1110_pcs_mdio_read,
.pcs_mdio_write = sja1110_pcs_mdio_write,
.pma_config = sja1110_pma_config,
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.port_speed = {
[SJA1105_SPEED_AUTO] = 0,
[SJA1105_SPEED_10MBPS] = 4,
[SJA1105_SPEED_100MBPS] = 3,
[SJA1105_SPEED_1000MBPS] = 2,
},
.supports_mii = {true, false, true, false, false,
true, true, true, false, false, false},
.supports_rmii = {false, false, true, false, false,
false, false, false, false, false, false},
.supports_rgmii = {false, false, true, false, false,
false, false, false, false, false, false},
.supports_sgmii = {false, true, true, true, true,
false, false, false, false, false, false},
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
.name = "SJA1110D",
},
};
struct sja1105_status {
u64 configs;
u64 crcchkl;
u64 ids;
u64 crcchkg;
};
static void sja1105_status_unpack(void *buf, struct sja1105_status *status)
{
sja1105_packing(buf, &status->configs, 31, 31, 4, UNPACK);
sja1105_packing(buf, &status->crcchkl, 30, 30, 4, UNPACK);
sja1105_packing(buf, &status->ids, 29, 29, 4, UNPACK);
sja1105_packing(buf, &status->crcchkg, 28, 28, 4, UNPACK);
}
static int sja1105_status_get(struct sja1105_private *priv,
struct sja1105_status *status)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[4];
int rc;
rc = sja1105_xfer_buf(priv, SPI_READ, regs->status, packed_buf, 4);
if (rc < 0)
return rc;
sja1105_status_unpack(packed_buf, status);
return 0;
}
/* Not const because unpacking priv->static_config into buffers and preparing
* for upload requires the recalculation of table CRCs and updating the
* structures with these.
*/
static int
static_config_buf_prepare_for_upload(struct sja1105_private *priv,
void *config_buf, int buf_len)
{
struct sja1105_static_config *config = &priv->static_config;
struct sja1105_table_header final_header;
char *final_header_ptr;
int crc_len;
/* Write Device ID and config tables to config_buf */
sja1105_static_config_pack(config_buf, config);
/* Recalculate CRC of the last header (right now 0xDEADBEEF).
* Don't include the CRC field itself.
*/
crc_len = buf_len - 4;
/* Read the whole table header */
final_header_ptr = config_buf + buf_len - SJA1105_SIZE_TABLE_HEADER;
sja1105_table_header_packing(final_header_ptr, &final_header, UNPACK);
/* Modify */
final_header.crc = sja1105_crc32(config_buf, crc_len);
/* Rewrite */
sja1105_table_header_packing(final_header_ptr, &final_header, PACK);
return 0;
}
static int sja1105_static_config_upload(struct sja1105_private *priv)
{
struct sja1105_static_config *config = &priv->static_config;
const struct sja1105_regs *regs = priv->info->regs;
struct sja1105_status status;
u8 *config_buf;
int buf_len;
int rc;
buf_len = sja1105_static_config_get_length(config);
config_buf = calloc(buf_len, sizeof(char));
if (!config_buf)
return -ENOMEM;
rc = static_config_buf_prepare_for_upload(priv, config_buf, buf_len);
if (rc < 0) {
printf("Invalid config, cannot upload\n");
rc = -EINVAL;
goto out;
}
/* Put the SJA1105 in programming mode */
rc = priv->info->reset_cmd(priv);
if (rc < 0) {
printf("Failed to reset switch\n");
goto out;
}
/* Wait for the switch to come out of reset */
udelay(1000);
/* Upload the static config to the device */
rc = sja1105_xfer_buf(priv, SPI_WRITE, regs->config,
config_buf, buf_len);
if (rc < 0) {
printf("Failed to upload config\n");
goto out;
}
/* Check that SJA1105 responded well to the config upload */
rc = sja1105_status_get(priv, &status);
if (rc < 0)
goto out;
if (status.ids == 1) {
printf("Mismatch between hardware and static config device id. "
"Wrote 0x%llx, wants 0x%llx\n",
config->device_id, priv->info->device_id);
rc = -EIO;
goto out;
}
if (status.crcchkl == 1 || status.crcchkg == 1) {
printf("Switch reported invalid CRC on static config\n");
rc = -EIO;
goto out;
}
if (status.configs == 0) {
printf("Switch reported that config is invalid\n");
rc = -EIO;
goto out;
}
out:
free(config_buf);
return rc;
}
static int sja1105_static_config_reload(struct sja1105_private *priv)
{
int rc;
rc = sja1105_static_config_upload(priv);
if (rc < 0) {
printf("Failed to load static config: %d\n", rc);
return rc;
}
/* Configure the CGU (PHY link modes and speeds) */
rc = sja1105_clocking_setup(priv);
if (rc < 0) {
printf("Failed to configure MII clocking: %d\n", rc);
return rc;
}
return 0;
}
static int sja1105_port_probe(struct udevice *dev, int port,
struct phy_device *phy)
{
struct sja1105_private *priv = dev_get_priv(dev);
ofnode node = dsa_port_get_ofnode(dev, port);
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
phy_interface_t phy_mode = phy->interface;
priv->xpcs_cfg[port].inband_an = ofnode_eth_uses_inband_aneg(node);
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
if (phy_mode == PHY_INTERFACE_MODE_MII ||
phy_mode == PHY_INTERFACE_MODE_RMII) {
phy->supported &= PHY_BASIC_FEATURES;
phy->advertising &= PHY_BASIC_FEATURES;
} else {
phy->supported &= PHY_GBIT_FEATURES;
phy->advertising &= PHY_GBIT_FEATURES;
}
return phy_config(phy);
}
static int sja1105_port_enable(struct udevice *dev, int port,
struct phy_device *phy)
{
struct sja1105_private *priv = dev_get_priv(dev);
phy_interface_t phy_mode = phy->interface;
struct sja1105_xmii_params_entry *mii;
struct sja1105_mac_config_entry *mac;
int rc;
rc = phy_startup(phy);
if (rc)
return rc;
mii = priv->static_config.tables[BLK_IDX_XMII_PARAMS].entries;
mac = priv->static_config.tables[BLK_IDX_MAC_CONFIG].entries;
switch (phy_mode) {
case PHY_INTERFACE_MODE_MII:
if (!priv->info->supports_mii[port])
goto unsupported;
mii->xmii_mode[port] = XMII_MODE_MII;
break;
case PHY_INTERFACE_MODE_RMII:
if (!priv->info->supports_rmii[port])
goto unsupported;
mii->xmii_mode[port] = XMII_MODE_RMII;
break;
case PHY_INTERFACE_MODE_RGMII:
case PHY_INTERFACE_MODE_RGMII_ID:
case PHY_INTERFACE_MODE_RGMII_RXID:
case PHY_INTERFACE_MODE_RGMII_TXID:
if (!priv->info->supports_rgmii[port])
goto unsupported;
mii->xmii_mode[port] = XMII_MODE_RGMII;
break;
case PHY_INTERFACE_MODE_SGMII:
if (!priv->info->supports_sgmii[port])
goto unsupported;
mii->xmii_mode[port] = XMII_MODE_SGMII;
mii->special[port] = true;
break;
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
unsupported:
default:
dev_err(dev, "Unsupported PHY mode %d on port %d!\n",
phy_mode, port);
return -EINVAL;
}
/* RevMII, RevRMII not supported */
mii->phy_mac[port] = XMII_MAC;
/* Let the PHY handle the RGMII delays, if present. */
if (phy->phy_id == PHY_FIXED_ID) {
if (phy_mode == PHY_INTERFACE_MODE_RGMII_RXID ||
phy_mode == PHY_INTERFACE_MODE_RGMII_ID)
priv->rgmii_rx_delay[port] = true;
if (phy_mode == PHY_INTERFACE_MODE_RGMII_TXID ||
phy_mode == PHY_INTERFACE_MODE_RGMII_ID)
priv->rgmii_tx_delay[port] = true;
if ((priv->rgmii_rx_delay[port] ||
priv->rgmii_tx_delay[port]) &&
!priv->info->setup_rgmii_delay) {
printf("Chip does not support internal RGMII delays\n");
return -EINVAL;
}
}
if (mii->xmii_mode[port] == XMII_MODE_SGMII) {
mac[port].speed = priv->info->port_speed[SJA1105_SPEED_1000MBPS];
priv->xpcs_cfg[port].speed = phy->speed;
} else if (phy->speed == SPEED_1000) {
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
mac[port].speed = priv->info->port_speed[SJA1105_SPEED_1000MBPS];
} else if (phy->speed == SPEED_100) {
mac[port].speed = priv->info->port_speed[SJA1105_SPEED_100MBPS];
} else if (phy->speed == SPEED_10) {
mac[port].speed = priv->info->port_speed[SJA1105_SPEED_10MBPS];
} else {
printf("Invalid PHY speed %d on port %d\n", phy->speed, port);
return -EINVAL;
}
return sja1105_static_config_reload(priv);
}
static void sja1105_port_disable(struct udevice *dev, int port,
struct phy_device *phy)
{
phy_shutdown(phy);
}
static int sja1105_xmit(struct udevice *dev, int port, void *packet, int length)
{
struct sja1105_private *priv = dev_get_priv(dev);
u8 *from = (u8 *)packet + VLAN_HLEN;
struct vlan_ethhdr *hdr = packet;
u8 *dest = (u8 *)packet;
memmove(dest, from, 2 * ETH_ALEN);
hdr->h_vlan_proto = htons(ETH_P_SJA1105);
hdr->h_vlan_TCI = htons(priv->pvid[port]);
return 0;
}
static int sja1105_rcv(struct udevice *dev, int *port, void *packet, int length)
{
struct vlan_ethhdr *hdr = packet;
u8 *dest = packet + VLAN_HLEN;
u8 *from = packet;
if (ntohs(hdr->h_vlan_proto) != ETH_P_SJA1105)
return -EINVAL;
*port = ntohs(hdr->h_vlan_TCI) & DSA_8021Q_PORT_MASK;
memmove(dest, from, 2 * ETH_ALEN);
return 0;
}
static const struct dsa_ops sja1105_dsa_ops = {
.port_probe = sja1105_port_probe,
.port_enable = sja1105_port_enable,
.port_disable = sja1105_port_disable,
.xmit = sja1105_xmit,
.rcv = sja1105_rcv,
};
static int sja1105_init(struct sja1105_private *priv)
{
int rc;
rc = sja1105_static_config_init(priv);
if (rc) {
printf("Failed to initialize static config: %d\n", rc);
return rc;
}
rc = sja1105_mdiobus_register(priv);
if (rc) {
printf("Failed to register MDIO bus: %d\n", rc);
goto err_mdiobus_register;
}
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
return 0;
err_mdiobus_register:
sja1105_static_config_free(&priv->static_config);
return rc;
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
}
static int sja1105_check_device_id(struct sja1105_private *priv)
{
const struct sja1105_regs *regs = priv->info->regs;
u8 packed_buf[SJA1105_SIZE_DEVICE_ID] = {0};
enum sja1105_switch_id id;
u64 device_id;
u64 part_no;
int rc;
rc = sja1105_xfer_buf(priv, SPI_READ, regs->device_id, packed_buf,
SJA1105_SIZE_DEVICE_ID);
if (rc < 0)
return rc;
sja1105_packing(packed_buf, &device_id, 31, 0, SJA1105_SIZE_DEVICE_ID,
UNPACK);
rc = sja1105_xfer_buf(priv, SPI_READ, regs->prod_id, packed_buf,
SJA1105_SIZE_DEVICE_ID);
if (rc < 0)
return rc;
sja1105_packing(packed_buf, &part_no, 19, 4, SJA1105_SIZE_DEVICE_ID,
UNPACK);
for (id = 0; id < SJA1105_MAX_SWITCH_ID; id++) {
const struct sja1105_info *info = &sja1105_info[id];
/* Is what's been probed in our match table at all? */
if (info->device_id != device_id || info->part_no != part_no)
continue;
/* But is it what's in the device tree? */
if (priv->info->device_id != device_id ||
priv->info->part_no != part_no) {
printf("Device tree specifies chip %s but found %s, please fix it!\n",
priv->info->name, info->name);
/* It isn't. No problem, pick that up. */
priv->info = info;
}
return 0;
}
printf("Unexpected {device ID, part number}: 0x%llx 0x%llx\n",
device_id, part_no);
return -ENODEV;
}
static int sja1105_probe(struct udevice *dev)
{
enum sja1105_switch_id id = dev_get_driver_data(dev);
struct sja1105_private *priv = dev_get_priv(dev);
int rc;
if (ofnode_valid(dev_ofnode(dev)) &&
!ofnode_is_enabled(dev_ofnode(dev))) {
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
dev_dbg(dev, "switch disabled\n");
return -ENODEV;
}
priv->info = &sja1105_info[id];
priv->dev = dev;
rc = sja1105_check_device_id(priv);
if (rc < 0) {
dev_err(dev, "Device ID check failed: %d\n", rc);
return rc;
}
dsa_set_tagging(dev, VLAN_HLEN, 0);
return sja1105_init(priv);
}
static int sja1105_remove(struct udevice *dev)
{
struct sja1105_private *priv = dev_get_priv(dev);
sja1105_mdiobus_unregister(priv);
net: dsa: add driver for NXP SJA1105 L2 switch The SJA1105 driver is largely reused from Linux. Its programming model is that it is blank out of reset, and it waits for a static configuration stream over SPI, which contains all runtime parameters (it has no notion of "default values"). Keeping a binary array for the configuration stream would have meant that aspects such as the CPU port and the MAC speeds could have not been configured easily, and would have been static and board-dependent. Live-patching the binary array means recalculating the static config table CRCs, which is not a fun process. So we create an abstraction over the static config tables, using the packing API, same as in Linux. The tables are kept as C structures, and the binary configuration stream is constructed on-the-go, with CRC and all. All static config tables instantiated in this driver are mandatory. The hardware reference manual can be found at: https://www.nxp.com/docs/en/user-guide/UM10944.pdf For tagging, a simplified version of tag_8021q from Linux is used. The VLAN EtherType is the same (0xdadb) but since we don't want switching in U-Boot, there is no reason to have a TX VLAN and an RX VLAN for each port. We just need the RX VLANs to act as the unique pvid of each front-panel port, to decode the switch port number. The RX VLAN is used for both RX and TX. The device tree bindings are the same as in Linux. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Ramon Fried <rfried.dev@gmail.com>
2021-09-29 15:04:41 +00:00
sja1105_static_config_free(&priv->static_config);
return 0;
}
static const struct udevice_id sja1105_ids[] = {
{ .compatible = "nxp,sja1105e", .data = SJA1105E },
{ .compatible = "nxp,sja1105t", .data = SJA1105T },
{ .compatible = "nxp,sja1105p", .data = SJA1105P },
{ .compatible = "nxp,sja1105q", .data = SJA1105Q },
{ .compatible = "nxp,sja1105r", .data = SJA1105R },
{ .compatible = "nxp,sja1105s", .data = SJA1105S },
{ .compatible = "nxp,sja1110a", .data = SJA1110A },
{ .compatible = "nxp,sja1110b", .data = SJA1110B },
{ .compatible = "nxp,sja1110c", .data = SJA1110C },
{ .compatible = "nxp,sja1110d", .data = SJA1110D },
{ }
};
U_BOOT_DRIVER(sja1105) = {
.name = "sja1105",
.id = UCLASS_DSA,
.of_match = sja1105_ids,
.probe = sja1105_probe,
.remove = sja1105_remove,
.ops = &sja1105_dsa_ops,
.priv_auto = sizeof(struct sja1105_private),
};