drivers/net/ethernet/ti/icssg/icssg_classifier.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /* Texas Instruments ICSSG Ethernet Driver
  *
  * Copyright (C) 2018-2022 Texas Instruments Incorporated - https://www.ti.com/
  *
  */

 #include <linux/etherdevice.h>
 #include <linux/types.h>
 #include <linux/regmap.h>

 #include "icssg_prueth.h"

 #define ICSSG_NUM_CLASSIFIERS	16
 #define ICSSG_NUM_FT1_SLOTS	8
 #define ICSSG_NUM_FT3_SLOTS	16

 #define ICSSG_NUM_CLASSIFIERS_IN_USE	5

 /* Filter 1 - FT1 */
 #define FT1_NUM_SLOTS	8
 #define FT1_SLOT_SIZE	0x10	/* bytes */

 /* offsets from FT1 slot base i.e. slot 1 start */
 #define FT1_DA0		0x0
 #define FT1_DA1		0x4
 #define FT1_DA0_MASK	0x8
 #define FT1_DA1_MASK	0xc

 #define FT1_N_REG(slize, n, reg)	\
 	(offs[slice].ft1_slot_base + FT1_SLOT_SIZE * (n) + (reg))

 #define FT1_LEN_MASK		GENMASK(19, 16)
 #define FT1_LEN_SHIFT		16
 #define FT1_LEN(len)		(((len) << FT1_LEN_SHIFT) & FT1_LEN_MASK)
 #define FT1_START_MASK		GENMASK(14, 0)
 #define FT1_START(start)	((start) & FT1_START_MASK)
 #define FT1_MATCH_SLOT(n)	(GENMASK(23, 16) & (BIT(n) << 16))

 /* FT1 config type */
 enum ft1_cfg_type {
 	FT1_CFG_TYPE_DISABLED = 0,
 	FT1_CFG_TYPE_EQ,
 	FT1_CFG_TYPE_GT,
 	FT1_CFG_TYPE_LT,
 };

 #define FT1_CFG_SHIFT(n)	(2 * (n))
 #define FT1_CFG_MASK(n)		(0x3 << FT1_CFG_SHIFT((n)))

 /* Filter 3 -  FT3 */
 #define FT3_NUM_SLOTS	16
 #define FT3_SLOT_SIZE	0x20	/* bytes */

 /* offsets from FT3 slot n's base */
 #define FT3_START		0
 #define FT3_START_AUTO		0x4
 #define FT3_START_OFFSET	0x8
 #define FT3_JUMP_OFFSET		0xc
 #define FT3_LEN			0x10
 #define FT3_CFG			0x14
 #define FT3_T			0x18
 #define FT3_T_MASK		0x1c

 #define FT3_N_REG(slize, n, reg)	\
 	(offs[slice].ft3_slot_base + FT3_SLOT_SIZE * (n) + (reg))

 /* offsets from rx_class n's base */
 #define RX_CLASS_AND_EN		0
 #define RX_CLASS_OR_EN		0x4
 #define RX_CLASS_NUM_SLOTS	16
 #define RX_CLASS_EN_SIZE	0x8	/* bytes */

 #define RX_CLASS_N_REG(slice, n, reg)	\
 	(offs[slice].rx_class_base + RX_CLASS_EN_SIZE * (n) + (reg))

 /* RX Class Gates */
 #define RX_CLASS_GATES_SIZE	0x4	/* bytes */

 #define RX_CLASS_GATES_N_REG(slice, n)	\
 	(offs[slice].rx_class_gates_base + RX_CLASS_GATES_SIZE * (n))

 #define RX_CLASS_GATES_ALLOW_MASK	BIT(6)
 #define RX_CLASS_GATES_RAW_MASK		BIT(5)
 #define RX_CLASS_GATES_PHASE_MASK	BIT(4)

 /* RX Class traffic data matching bits */
 #define RX_CLASS_FT_UC				BIT(31)
 #define RX_CLASS_FT_MC			BIT(30)
 #define RX_CLASS_FT_BC			BIT(29)
 #define RX_CLASS_FT_FW			BIT(28)
 #define RX_CLASS_FT_RCV			BIT(27)
 #define RX_CLASS_FT_VLAN		BIT(26)
 #define RX_CLASS_FT_DA_P		BIT(25)
 #define RX_CLASS_FT_DA_I		BIT(24)
 #define RX_CLASS_FT_FT1_MATCH_MASK	GENMASK(23, 16)
 #define RX_CLASS_FT_FT1_MATCH_SHIFT	16
 #define RX_CLASS_FT_FT3_MATCH_MASK	GENMASK(15, 0)
 #define RX_CLASS_FT_FT3_MATCH_SHIFT	0

 #define RX_CLASS_FT_FT1_MATCH(slot)	\
 	((BIT(slot) << RX_CLASS_FT_FT1_MATCH_SHIFT) & \
 	RX_CLASS_FT_FT1_MATCH_MASK)

 /* RX class type */
 enum rx_class_sel_type {
 	RX_CLASS_SEL_TYPE_OR = 0,
 	RX_CLASS_SEL_TYPE_AND = 1,
 	RX_CLASS_SEL_TYPE_OR_AND_AND = 2,
 	RX_CLASS_SEL_TYPE_OR_OR_AND = 3,
 };

 #define FT1_CFG_SHIFT(n)	(2 * (n))
 #define FT1_CFG_MASK(n)		(0x3 << FT1_CFG_SHIFT((n)))

 #define RX_CLASS_SEL_SHIFT(n)	(2 * (n))
 #define RX_CLASS_SEL_MASK(n)	(0x3 << RX_CLASS_SEL_SHIFT((n)))

 #define ICSSG_CFG_OFFSET	0
 #define MAC_INTERFACE_0		0x18
 #define MAC_INTERFACE_1		0x1c

 #define ICSSG_CFG_RX_L2_G_EN	BIT(2)

 /* These are register offsets per PRU */
 struct miig_rt_offsets {
 	u32 mac0;
 	u32 mac1;
 	u32 ft1_start_len;
 	u32 ft1_cfg;
 	u32 ft1_slot_base;
 	u32 ft3_slot_base;
 	u32 ft3_p_base;
 	u32 ft_rx_ptr;
 	u32 rx_class_base;
 	u32 rx_class_cfg1;
 	u32 rx_class_cfg2;
 	u32 rx_class_gates_base;
 	u32 rx_green;
 	u32 rx_rate_cfg_base;
 	u32 rx_rate_src_sel0;
 	u32 rx_rate_src_sel1;
 	u32 tx_rate_cfg_base;
 	u32 stat_base;
 	u32 tx_hsr_tag;
 	u32 tx_hsr_seq;
 	u32 tx_vlan_type;
 	u32 tx_vlan_ins;
 };

 /* These are the offset values for miig_rt_offsets registers */
 static const struct miig_rt_offsets offs[] = {
 	/* PRU0 */
 	{
 		0x8,
 		0xc,
 		0x80,
 		0x84,
 		0x88,
 		0x108,
 		0x308,
 		0x408,
 		0x40c,
 		0x48c,
 		0x490,
 		0x494,
 		0x4d4,
 		0x4e4,
 		0x504,
 		0x508,
 		0x50c,
 		0x54c,
 		0x63c,
 		0x640,
 		0x644,
 		0x648,
 	},
 	/* PRU1 */
 	{
 		0x10,
 		0x14,
 		0x64c,
 		0x650,
 		0x654,
 		0x6d4,
 		0x8d4,
 		0x9d4,
 		0x9d8,
 		0xa58,
 		0xa5c,
 		0xa60,
 		0xaa0,
 		0xab0,
 		0xad0,
 		0xad4,
 		0xad8,
 		0xb18,
 		0xc08,
 		0xc0c,
 		0xc10,
 		0xc14,
 	},
 };

 static void rx_class_ft1_set_start_len(struct regmap *miig_rt, int slice,
 				       u16 start, u8 len)
 {
 	u32 offset, val;

 	offset = offs[slice].ft1_start_len;
 	val = FT1_LEN(len) | FT1_START(start);
 	regmap_write(miig_rt, offset, val);
 }

 static void rx_class_ft1_set_da(struct regmap *miig_rt, int slice,
 				int n, const u8 *addr)
 {
 	u32 offset;

 	offset = FT1_N_REG(slice, n, FT1_DA0);
 	regmap_write(miig_rt, offset, (u32)(addr[0] | addr[1] << 8 |
 		     addr[2] << 16 | addr[3] << 24));
 	offset = FT1_N_REG(slice, n, FT1_DA1);
 	regmap_write(miig_rt, offset, (u32)(addr[4] | addr[5] << 8));
 }

 static void rx_class_ft1_set_da_mask(struct regmap *miig_rt, int slice,
 				     int n, const u8 *addr)
 {
 	u32 offset;

 	offset = FT1_N_REG(slice, n, FT1_DA0_MASK);
 	regmap_write(miig_rt, offset, (u32)(addr[0] | addr[1] << 8 |
 		     addr[2] << 16 | addr[3] << 24));
 	offset = FT1_N_REG(slice, n, FT1_DA1_MASK);
 	regmap_write(miig_rt, offset, (u32)(addr[4] | addr[5] << 8));
 }

 static void rx_class_ft1_cfg_set_type(struct regmap *miig_rt, int slice, int n,
 				      enum ft1_cfg_type type)
 {
 	u32 offset;

 	offset = offs[slice].ft1_cfg;
 	regmap_update_bits(miig_rt, offset, FT1_CFG_MASK(n),
 			   type << FT1_CFG_SHIFT(n));
 }

 static void rx_class_sel_set_type(struct regmap *miig_rt, int slice, int n,
 				  enum rx_class_sel_type type)
 {
 	u32 offset;

 	offset = offs[slice].rx_class_cfg1;
 	regmap_update_bits(miig_rt, offset, RX_CLASS_SEL_MASK(n),
 			   type << RX_CLASS_SEL_SHIFT(n));
 }

 static void rx_class_set_and(struct regmap *miig_rt, int slice, int n,
 			     u32 data)
 {
 	u32 offset;

 	offset = RX_CLASS_N_REG(slice, n, RX_CLASS_AND_EN);
 	regmap_write(miig_rt, offset, data);
 }

 static void rx_class_set_or(struct regmap *miig_rt, int slice, int n,
 			    u32 data)
 {
 	u32 offset;

 	offset = RX_CLASS_N_REG(slice, n, RX_CLASS_OR_EN);
 	regmap_write(miig_rt, offset, data);
 }

 void icssg_class_set_host_mac_addr(struct regmap *miig_rt, const u8 *mac)
 {
 	regmap_write(miig_rt, MAC_INTERFACE_0, (u32)(mac[0] | mac[1] << 8 |
 		     mac[2] << 16 | mac[3] << 24));
 	regmap_write(miig_rt, MAC_INTERFACE_1, (u32)(mac[4] | mac[5] << 8));
 }

 void icssg_class_set_mac_addr(struct regmap *miig_rt, int slice, u8 *mac)
 {
 	regmap_write(miig_rt, offs[slice].mac0, (u32)(mac[0] | mac[1] << 8 |
 		     mac[2] << 16 | mac[3] << 24));
 	regmap_write(miig_rt, offs[slice].mac1, (u32)(mac[4] | mac[5] << 8));
 }

 /* disable all RX traffic */
 void icssg_class_disable(struct regmap *miig_rt, int slice)
 {
 	u32 data, offset;
 	int n;

 	/* Enable RX_L2_G */
 	regmap_update_bits(miig_rt, ICSSG_CFG_OFFSET, ICSSG_CFG_RX_L2_G_EN,
 			   ICSSG_CFG_RX_L2_G_EN);

 	for (n = 0; n < ICSSG_NUM_CLASSIFIERS; n++) {
 		/* AND_EN = 0 */
 		rx_class_set_and(miig_rt, slice, n, 0);
 		/* OR_EN = 0 */
 		rx_class_set_or(miig_rt, slice, n, 0);

 		/* set CFG1 to OR */
 		rx_class_sel_set_type(miig_rt, slice, n, RX_CLASS_SEL_TYPE_OR);

 		/* configure gate */
 		offset = RX_CLASS_GATES_N_REG(slice, n);
 		regmap_read(miig_rt, offset, &data);
 		/* clear class_raw so we go through filters */
 		data &= ~RX_CLASS_GATES_RAW_MASK;
 		/* set allow and phase mask */
 		data |= RX_CLASS_GATES_ALLOW_MASK | RX_CLASS_GATES_PHASE_MASK;
 		regmap_write(miig_rt, offset, data);
 	}

 	/* FT1 Disabled */
 	for (n = 0; n < ICSSG_NUM_FT1_SLOTS; n++) {
 		const u8 addr[] = { 0, 0, 0, 0, 0, 0, };

 		rx_class_ft1_cfg_set_type(miig_rt, slice, n,
 					  FT1_CFG_TYPE_DISABLED);
 		rx_class_ft1_set_da(miig_rt, slice, n, addr);
 		rx_class_ft1_set_da_mask(miig_rt, slice, n, addr);
 	}

 	/* clear CFG2 */
 	regmap_write(miig_rt, offs[slice].rx_class_cfg2, 0);
 }

 void icssg_class_default(struct regmap *miig_rt, int slice, bool allmulti)
 {
 	u32 data;

 	/* defaults */
 	icssg_class_disable(miig_rt, slice);

 	/* Setup Classifier */
 	/* match on Broadcast or MAC_PRU address */
 	data = RX_CLASS_FT_BC | RX_CLASS_FT_DA_P;

 	/* multicast */
 	if (allmulti)
 		data |= RX_CLASS_FT_MC;

 	rx_class_set_or(miig_rt, slice, 0, data);

 	/* set CFG1 for OR_OR_AND for classifier */
 	rx_class_sel_set_type(miig_rt, slice, 0, RX_CLASS_SEL_TYPE_OR_OR_AND);

 	/* clear CFG2 */
 	regmap_write(miig_rt, offs[slice].rx_class_cfg2, 0);
 }

 /* required for SAV check */
 void icssg_ft1_set_mac_addr(struct regmap *miig_rt, int slice, u8 *mac_addr)
 {
 	const u8 mask_addr[] = { 0, 0, 0, 0, 0, 0, };

 	rx_class_ft1_set_start_len(miig_rt, slice, 0, 6);
 	rx_class_ft1_set_da(miig_rt, slice, 0, mac_addr);
 	rx_class_ft1_set_da_mask(miig_rt, slice, 0, mask_addr);
 	rx_class_ft1_cfg_set_type(miig_rt, slice, 0, FT1_CFG_TYPE_EQ);
 }
	// SPDX-License-Identifier: GPL-2.0
	/* Texas Instruments ICSSG Ethernet Driver
	*
	* Copyright (C) 2018-2022 Texas Instruments Incorporated - https://www.ti.com/
	*
	*/

	#include <linux/etherdevice.h>
	#include <linux/types.h>
	#include <linux/regmap.h>

	#include "icssg_prueth.h"

	#define ICSSG_NUM_CLASSIFIERS 16
	#define ICSSG_NUM_FT1_SLOTS 8
	#define ICSSG_NUM_FT3_SLOTS 16

	#define ICSSG_NUM_CLASSIFIERS_IN_USE 5

	/* Filter 1 - FT1 */
	#define FT1_NUM_SLOTS 8
	#define FT1_SLOT_SIZE 0x10 /* bytes */

	/* offsets from FT1 slot base i.e. slot 1 start */
	#define FT1_DA0 0x0
	#define FT1_DA1 0x4
	#define FT1_DA0_MASK 0x8
	#define FT1_DA1_MASK 0xc

	#define FT1_N_REG(slize, n, reg) \
	(offs[slice].ft1_slot_base + FT1_SLOT_SIZE * (n) + (reg))

	#define FT1_LEN_MASK GENMASK(19, 16)
	#define FT1_LEN_SHIFT 16
	#define FT1_LEN(len) (((len) << FT1_LEN_SHIFT) & FT1_LEN_MASK)
	#define FT1_START_MASK GENMASK(14, 0)
	#define FT1_START(start) ((start) & FT1_START_MASK)
	#define FT1_MATCH_SLOT(n) (GENMASK(23, 16) & (BIT(n) << 16))

	/* FT1 config type */
	enum ft1_cfg_type {
	FT1_CFG_TYPE_DISABLED = 0,
	FT1_CFG_TYPE_EQ,
	FT1_CFG_TYPE_GT,
	FT1_CFG_TYPE_LT,
	};

	#define FT1_CFG_SHIFT(n) (2 * (n))
	#define FT1_CFG_MASK(n) (0x3 << FT1_CFG_SHIFT((n)))

	/* Filter 3 - FT3 */
	#define FT3_NUM_SLOTS 16
	#define FT3_SLOT_SIZE 0x20 /* bytes */

	/* offsets from FT3 slot n's base */
	#define FT3_START 0
	#define FT3_START_AUTO 0x4
	#define FT3_START_OFFSET 0x8
	#define FT3_JUMP_OFFSET 0xc
	#define FT3_LEN 0x10
	#define FT3_CFG 0x14
	#define FT3_T 0x18
	#define FT3_T_MASK 0x1c

	#define FT3_N_REG(slize, n, reg) \
	(offs[slice].ft3_slot_base + FT3_SLOT_SIZE * (n) + (reg))

	/* offsets from rx_class n's base */
	#define RX_CLASS_AND_EN 0
	#define RX_CLASS_OR_EN 0x4
	#define RX_CLASS_NUM_SLOTS 16
	#define RX_CLASS_EN_SIZE 0x8 /* bytes */

	#define RX_CLASS_N_REG(slice, n, reg) \
	(offs[slice].rx_class_base + RX_CLASS_EN_SIZE * (n) + (reg))

	/* RX Class Gates */
	#define RX_CLASS_GATES_SIZE 0x4 /* bytes */

	#define RX_CLASS_GATES_N_REG(slice, n) \
	(offs[slice].rx_class_gates_base + RX_CLASS_GATES_SIZE * (n))

	#define RX_CLASS_GATES_ALLOW_MASK BIT(6)
	#define RX_CLASS_GATES_RAW_MASK BIT(5)
	#define RX_CLASS_GATES_PHASE_MASK BIT(4)

	/* RX Class traffic data matching bits */
	#define RX_CLASS_FT_UC BIT(31)
	#define RX_CLASS_FT_MC BIT(30)
	#define RX_CLASS_FT_BC BIT(29)
	#define RX_CLASS_FT_FW BIT(28)
	#define RX_CLASS_FT_RCV BIT(27)
	#define RX_CLASS_FT_VLAN BIT(26)
	#define RX_CLASS_FT_DA_P BIT(25)
	#define RX_CLASS_FT_DA_I BIT(24)
	#define RX_CLASS_FT_FT1_MATCH_MASK GENMASK(23, 16)
	#define RX_CLASS_FT_FT1_MATCH_SHIFT 16
	#define RX_CLASS_FT_FT3_MATCH_MASK GENMASK(15, 0)
	#define RX_CLASS_FT_FT3_MATCH_SHIFT 0

	#define RX_CLASS_FT_FT1_MATCH(slot) \
	((BIT(slot) << RX_CLASS_FT_FT1_MATCH_SHIFT) & \
	RX_CLASS_FT_FT1_MATCH_MASK)

	/* RX class type */
	enum rx_class_sel_type {
	RX_CLASS_SEL_TYPE_OR = 0,
	RX_CLASS_SEL_TYPE_AND = 1,
	RX_CLASS_SEL_TYPE_OR_AND_AND = 2,
	RX_CLASS_SEL_TYPE_OR_OR_AND = 3,
	};

	#define FT1_CFG_SHIFT(n) (2 * (n))
	#define FT1_CFG_MASK(n) (0x3 << FT1_CFG_SHIFT((n)))

	#define RX_CLASS_SEL_SHIFT(n) (2 * (n))
	#define RX_CLASS_SEL_MASK(n) (0x3 << RX_CLASS_SEL_SHIFT((n)))

	#define ICSSG_CFG_OFFSET 0
	#define MAC_INTERFACE_0 0x18
	#define MAC_INTERFACE_1 0x1c

	#define ICSSG_CFG_RX_L2_G_EN BIT(2)

	/* These are register offsets per PRU */
	struct miig_rt_offsets {
	u32 mac0;
	u32 mac1;
	u32 ft1_start_len;
	u32 ft1_cfg;
	u32 ft1_slot_base;
	u32 ft3_slot_base;
	u32 ft3_p_base;
	u32 ft_rx_ptr;
	u32 rx_class_base;
	u32 rx_class_cfg1;
	u32 rx_class_cfg2;
	u32 rx_class_gates_base;
	u32 rx_green;
	u32 rx_rate_cfg_base;
	u32 rx_rate_src_sel0;
	u32 rx_rate_src_sel1;
	u32 tx_rate_cfg_base;
	u32 stat_base;
	u32 tx_hsr_tag;
	u32 tx_hsr_seq;
	u32 tx_vlan_type;
	u32 tx_vlan_ins;
	};

	/* These are the offset values for miig_rt_offsets registers */
	static const struct miig_rt_offsets offs[] = {
	/* PRU0 */
	{
	0x8,
	0xc,
	0x80,
	0x84,
	0x88,
	0x108,
	0x308,
	0x408,
	0x40c,
	0x48c,
	0x490,
	0x494,
	0x4d4,
	0x4e4,
	0x504,
	0x508,
	0x50c,
	0x54c,
	0x63c,
	0x640,
	0x644,
	0x648,
	},
	/* PRU1 */
	{
	0x10,
	0x14,
	0x64c,
	0x650,
	0x654,
	0x6d4,
	0x8d4,
	0x9d4,
	0x9d8,
	0xa58,
	0xa5c,
	0xa60,
	0xaa0,
	0xab0,
	0xad0,
	0xad4,
	0xad8,
	0xb18,
	0xc08,
	0xc0c,
	0xc10,
	0xc14,
	},
	};

	static void rx_class_ft1_set_start_len(struct regmap *miig_rt, int slice,
	u16 start, u8 len)
	{
	u32 offset, val;

	offset = offs[slice].ft1_start_len;
	val = FT1_LEN(len) \| FT1_START(start);
	regmap_write(miig_rt, offset, val);
	}

	static void rx_class_ft1_set_da(struct regmap *miig_rt, int slice,
	int n, const u8 *addr)
	{
	u32 offset;

	offset = FT1_N_REG(slice, n, FT1_DA0);
	regmap_write(miig_rt, offset, (u32)(addr[0] \| addr[1] << 8 \|
	addr[2] << 16 \| addr[3] << 24));
	offset = FT1_N_REG(slice, n, FT1_DA1);
	regmap_write(miig_rt, offset, (u32)(addr[4] \| addr[5] << 8));
	}

	static void rx_class_ft1_set_da_mask(struct regmap *miig_rt, int slice,
	int n, const u8 *addr)
	{
	u32 offset;

	offset = FT1_N_REG(slice, n, FT1_DA0_MASK);
	regmap_write(miig_rt, offset, (u32)(addr[0] \| addr[1] << 8 \|
	addr[2] << 16 \| addr[3] << 24));
	offset = FT1_N_REG(slice, n, FT1_DA1_MASK);
	regmap_write(miig_rt, offset, (u32)(addr[4] \| addr[5] << 8));
	}

	static void rx_class_ft1_cfg_set_type(struct regmap *miig_rt, int slice, int n,
	enum ft1_cfg_type type)
	{
	u32 offset;

	offset = offs[slice].ft1_cfg;
	regmap_update_bits(miig_rt, offset, FT1_CFG_MASK(n),
	type << FT1_CFG_SHIFT(n));
	}

	static void rx_class_sel_set_type(struct regmap *miig_rt, int slice, int n,
	enum rx_class_sel_type type)
	{
	u32 offset;

	offset = offs[slice].rx_class_cfg1;
	regmap_update_bits(miig_rt, offset, RX_CLASS_SEL_MASK(n),
	type << RX_CLASS_SEL_SHIFT(n));
	}

	static void rx_class_set_and(struct regmap *miig_rt, int slice, int n,
	u32 data)
	{
	u32 offset;

	offset = RX_CLASS_N_REG(slice, n, RX_CLASS_AND_EN);
	regmap_write(miig_rt, offset, data);
	}

	static void rx_class_set_or(struct regmap *miig_rt, int slice, int n,
	u32 data)
	{
	u32 offset;

	offset = RX_CLASS_N_REG(slice, n, RX_CLASS_OR_EN);
	regmap_write(miig_rt, offset, data);
	}

	void icssg_class_set_host_mac_addr(struct regmap miig_rt, const u8 mac)
	{
	regmap_write(miig_rt, MAC_INTERFACE_0, (u32)(mac[0] \| mac[1] << 8 \|
	mac[2] << 16 \| mac[3] << 24));
	regmap_write(miig_rt, MAC_INTERFACE_1, (u32)(mac[4] \| mac[5] << 8));
	}

	void icssg_class_set_mac_addr(struct regmap miig_rt, int slice, u8 mac)
	{
	regmap_write(miig_rt, offs[slice].mac0, (u32)(mac[0] \| mac[1] << 8 \|
	mac[2] << 16 \| mac[3] << 24));
	regmap_write(miig_rt, offs[slice].mac1, (u32)(mac[4] \| mac[5] << 8));
	}

	/* disable all RX traffic */
	void icssg_class_disable(struct regmap *miig_rt, int slice)
	{
	u32 data, offset;
	int n;

	/* Enable RX_L2_G */
	regmap_update_bits(miig_rt, ICSSG_CFG_OFFSET, ICSSG_CFG_RX_L2_G_EN,
	ICSSG_CFG_RX_L2_G_EN);

	for (n = 0; n < ICSSG_NUM_CLASSIFIERS; n++) {
	/* AND_EN = 0 */
	rx_class_set_and(miig_rt, slice, n, 0);
	/* OR_EN = 0 */
	rx_class_set_or(miig_rt, slice, n, 0);

	/* set CFG1 to OR */
	rx_class_sel_set_type(miig_rt, slice, n, RX_CLASS_SEL_TYPE_OR);

	/* configure gate */
	offset = RX_CLASS_GATES_N_REG(slice, n);
	regmap_read(miig_rt, offset, &data);
	/* clear class_raw so we go through filters */
	data &= ~RX_CLASS_GATES_RAW_MASK;
	/* set allow and phase mask */
	data \|= RX_CLASS_GATES_ALLOW_MASK \| RX_CLASS_GATES_PHASE_MASK;
	regmap_write(miig_rt, offset, data);
	}

	/* FT1 Disabled */
	for (n = 0; n < ICSSG_NUM_FT1_SLOTS; n++) {
	const u8 addr[] = { 0, 0, 0, 0, 0, 0, };

	rx_class_ft1_cfg_set_type(miig_rt, slice, n,
	FT1_CFG_TYPE_DISABLED);
	rx_class_ft1_set_da(miig_rt, slice, n, addr);
	rx_class_ft1_set_da_mask(miig_rt, slice, n, addr);
	}

	/* clear CFG2 */
	regmap_write(miig_rt, offs[slice].rx_class_cfg2, 0);
	}

	void icssg_class_default(struct regmap *miig_rt, int slice, bool allmulti)
	{
	u32 data;

	/* defaults */
	icssg_class_disable(miig_rt, slice);

	/* Setup Classifier */
	/* match on Broadcast or MAC_PRU address */
	data = RX_CLASS_FT_BC \| RX_CLASS_FT_DA_P;

	/* multicast */
	if (allmulti)
	data \|= RX_CLASS_FT_MC;

	rx_class_set_or(miig_rt, slice, 0, data);

	/* set CFG1 for OR_OR_AND for classifier */
	rx_class_sel_set_type(miig_rt, slice, 0, RX_CLASS_SEL_TYPE_OR_OR_AND);

	/* clear CFG2 */
	regmap_write(miig_rt, offs[slice].rx_class_cfg2, 0);
	}

	/* required for SAV check */
	void icssg_ft1_set_mac_addr(struct regmap miig_rt, int slice, u8 mac_addr)
	{
	const u8 mask_addr[] = { 0, 0, 0, 0, 0, 0, };

	rx_class_ft1_set_start_len(miig_rt, slice, 0, 6);
	rx_class_ft1_set_da(miig_rt, slice, 0, mac_addr);
	rx_class_ft1_set_da_mask(miig_rt, slice, 0, mask_addr);
	rx_class_ft1_cfg_set_type(miig_rt, slice, 0, FT1_CFG_TYPE_EQ);
	}