drivers/arm/gic/v3/gic600_multichip.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2019-2023, Arm Limited. All rights reserved.
  * Copyright (c) 2022-2023, NVIDIA Corporation. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 /*
  * GIC-600 driver extension for multichip setup
  */

 #include <assert.h>

 #include <common/debug.h>
 #include <drivers/arm/arm_gicv3_common.h>
 #include <drivers/arm/gic600_multichip.h>
 #include <drivers/arm/gicv3.h>

 #include "../common/gic_common_private.h"
 #include "gic600_multichip_private.h"

 static struct gic600_multichip_data *plat_gic_multichip_data;

 /*******************************************************************************
  * Retrieve the address of the chip owner for a given SPI ID
  ******************************************************************************/
 uintptr_t gic600_multichip_gicd_base_for_spi(uint32_t spi_id)
 {
 	unsigned int i;

 	/* Find the multichip instance */
 	for (i = 0U; i < GIC600_MAX_MULTICHIP; i++) {
 		if ((spi_id <= plat_gic_multichip_data->spi_ids[i].spi_id_max) &&
 		     (spi_id >= plat_gic_multichip_data->spi_ids[i].spi_id_min)) {
 			break;
 		}
 	}

 	/* Ensure that plat_gic_multichip_data contains valid values */
 	assert(i < GIC600_MAX_MULTICHIP);

 	return plat_gic_multichip_data->spi_ids[i].gicd_base;
 }

 /*******************************************************************************
  * GIC-600 multichip operation related helper functions
  ******************************************************************************/
 static void gicd_dchipr_wait_for_power_update_progress(uintptr_t base)
 {
 	unsigned int retry = GICD_PUP_UPDATE_RETRIES;

 	while ((read_gicd_dchipr(base) & GICD_DCHIPR_PUP_BIT) != 0U) {
 		if (retry-- == 0U) {
 			ERROR("GIC-600 connection to Routing Table Owner timed "
 					 "out\n");
 			panic();
 		}
 	}
 }

 /*******************************************************************************
  * Sets up the routing table owner.
  ******************************************************************************/
 static void set_gicd_dchipr_rt_owner(uintptr_t base, unsigned int rt_owner)
 {
 	/*
 	 * Ensure that Group enables in GICD_CTLR are disabled and no pending
 	 * register writes to GICD_CTLR.
 	 */
 	if ((gicd_read_ctlr(base) &
 			(CTLR_ENABLE_G0_BIT | CTLR_ENABLE_G1S_BIT |
 			 CTLR_ENABLE_G1NS_BIT | GICD_CTLR_RWP_BIT)) != 0) {
 		ERROR("GICD_CTLR group interrupts are either enabled or have "
 				"pending writes. Cannot set RT owner.\n");
 		panic();
 	}

 	/* Poll till PUP is zero before intiating write */
 	gicd_dchipr_wait_for_power_update_progress(base);

 	write_gicd_dchipr(base, read_gicd_dchipr(base) |
 			(rt_owner << GICD_DCHIPR_RT_OWNER_SHIFT));

 	/* Poll till PUP is zero to ensure write is complete */
 	gicd_dchipr_wait_for_power_update_progress(base);
 }

 /*******************************************************************************
  * Configures the Chip Register to make connections to GICDs on
  * a multichip platform.
  ******************************************************************************/
 static void set_gicd_chipr_n(uintptr_t base,
 				unsigned int chip_id,
 				uint64_t chip_addr,
 				unsigned int spi_id_min,
 				unsigned int spi_id_max)
 {
 	unsigned int spi_block_min, spi_blocks;
 	unsigned int gicd_iidr_val = gicd_read_iidr(base);
 	uint64_t chipr_n_val;

 	/*
 	 * Ensure that group enables in GICD_CTLR are disabled and no pending
 	 * register writes to GICD_CTLR.
 	 */
 	if ((gicd_read_ctlr(base) &
 			(CTLR_ENABLE_G0_BIT | CTLR_ENABLE_G1S_BIT |
 			 CTLR_ENABLE_G1NS_BIT | GICD_CTLR_RWP_BIT)) != 0) {
 		ERROR("GICD_CTLR group interrupts are either enabled or have "
 				"pending writes. Cannot set CHIPR register.\n");
 		panic();
 	}

 	/*
 	 * spi_id_min and spi_id_max of value 0 is used to intidicate that the
 	 * chip doesn't own any SPI block. Re-assign min and max values as SPI
 	 * id starts from 32.
 	 */
 	if (spi_id_min == 0 && spi_id_max == 0) {
 		spi_id_min = GIC600_SPI_ID_MIN;
 		spi_id_max = GIC600_SPI_ID_MIN;
 	}

 	switch ((gicd_iidr_val & IIDR_MODEL_MASK)) {
 	case IIDR_MODEL_ARM_GIC_600:
 		spi_block_min = SPI_BLOCK_MIN_VALUE(spi_id_min);
 		spi_blocks    = SPI_BLOCKS_VALUE(spi_id_min, spi_id_max);

 		chipr_n_val = GICD_CHIPR_VALUE_GIC_600(chip_addr,
 						       spi_block_min,
 						       spi_blocks);
 		break;
 	case IIDR_MODEL_ARM_GIC_700:
 		/* Calculate the SPI_ID_MIN value for ESPI */
 		if (spi_id_min >= GIC700_ESPI_ID_MIN) {
 			spi_block_min = ESPI_BLOCK_MIN_VALUE(spi_id_min);
 			spi_block_min += SPI_BLOCKS_VALUE(GIC700_SPI_ID_MIN,
 				GIC700_SPI_ID_MAX);
 		} else {
 			spi_block_min = SPI_BLOCK_MIN_VALUE(spi_id_min);
 		}

 		/* Calculate the total number of blocks */
 		spi_blocks = SPI_BLOCKS_VALUE(spi_id_min, spi_id_max);

 		chipr_n_val = GICD_CHIPR_VALUE_GIC_700(chip_addr,
 						       spi_block_min,
 						       spi_blocks);
 		break;
 	default:
 		ERROR("Unsupported GIC model 0x%x for multichip setup.\n",
 		      gicd_iidr_val);
 		panic();
 		break;
 	}
 	chipr_n_val |= GICD_CHIPRx_SOCKET_STATE;

 	/*
 	 * Wait for DCHIPR.PUP to be zero before commencing writes to
 	 * GICD_CHIPRx.
 	 */
 	gicd_dchipr_wait_for_power_update_progress(base);

 	/*
 	 * Assign chip addr, spi min block, number of spi blocks and bring chip
 	 * online by setting SocketState.
 	 */
 	write_gicd_chipr_n(base, chip_id, chipr_n_val);

 	/*
 	 * Poll until DCHIP.PUP is zero to verify connection to rt_owner chip
 	 * is complete.
 	 */
 	gicd_dchipr_wait_for_power_update_progress(base);

 	/*
 	 * Ensure that write to GICD_CHIPRx is successful and the chip_n came
 	 * online.
 	 */
 	if (read_gicd_chipr_n(base, chip_id) != chipr_n_val) {
 		ERROR("GICD_CHIPR%u write failed\n", chip_id);
 		panic();
 	}

 	/* Ensure that chip is in consistent state */
 	if (((read_gicd_chipsr(base) & GICD_CHIPSR_RTS_MASK) >>
 				GICD_CHIPSR_RTS_SHIFT) !=
 			GICD_CHIPSR_RTS_STATE_CONSISTENT) {
 		ERROR("Chip %u routing table is not in consistent state\n",
 				chip_id);
 		panic();
 	}
 }

 /*******************************************************************************
  * Validates the GIC-600 Multichip data structure passed by the platform.
  ******************************************************************************/
 static void gic600_multichip_validate_data(
 		struct gic600_multichip_data *multichip_data)
 {
 	unsigned int i, spi_id_min, spi_id_max, blocks_of_32;
 	unsigned int multichip_spi_blocks = 0;

 	assert(multichip_data != NULL);

 	if (multichip_data->chip_count > GIC600_MAX_MULTICHIP) {
 		ERROR("GIC-600 Multichip count should not exceed %d\n",
 				GIC600_MAX_MULTICHIP);
 		panic();
 	}

 	for (i = 0U; i < multichip_data->chip_count; i++) {
 		spi_id_min = multichip_data->spi_ids[i].spi_id_min;
 		spi_id_max = multichip_data->spi_ids[i].spi_id_max;

 		if ((spi_id_min != 0U) || (spi_id_max != 0U)) {

 			/* SPI IDs range check */
 			if (!(spi_id_min >= GIC600_SPI_ID_MIN) ||
 			    !(spi_id_max <= GIC600_SPI_ID_MAX) ||
 			    !(spi_id_min <= spi_id_max) ||
 			    !((spi_id_max - spi_id_min + 1) % 32 == 0)) {
 				ERROR("Invalid SPI IDs {%u, %u} passed for "
 						"Chip %u\n", spi_id_min,
 						spi_id_max, i);
 				panic();
 			}

 			/* SPI IDs overlap check */
 			blocks_of_32 = BLOCKS_OF_32(spi_id_min, spi_id_max);
 			if ((multichip_spi_blocks & blocks_of_32) != 0) {
 				ERROR("SPI IDs of Chip %u overlapping\n", i);
 				panic();
 			}
 			multichip_spi_blocks |= blocks_of_32;
 		}
 	}
 }

 /*******************************************************************************
  * Validates the GIC-700 Multichip data structure passed by the platform.
  ******************************************************************************/
 static void gic700_multichip_validate_data(
 		struct gic600_multichip_data *multichip_data)
 {
 	unsigned int i, spi_id_min, spi_id_max, blocks_of_32;
 	unsigned int multichip_spi_blocks = 0U, multichip_espi_blocks = 0U;

 	assert(multichip_data != NULL);

 	if (multichip_data->chip_count > GIC600_MAX_MULTICHIP) {
 		ERROR("GIC-700 Multichip count (%u) should not exceed %u\n",
 				multichip_data->chip_count, GIC600_MAX_MULTICHIP);
 		panic();
 	}

 	for (i = 0U; i < multichip_data->chip_count; i++) {
 		spi_id_min = multichip_data->spi_ids[i].spi_id_min;
 		spi_id_max = multichip_data->spi_ids[i].spi_id_max;

 		if ((spi_id_min == 0U) || (spi_id_max == 0U)) {
 			continue;
 		}

 		/* MIN SPI ID check */
 		if ((spi_id_min < GIC700_SPI_ID_MIN) ||
 		    ((spi_id_min >= GIC700_SPI_ID_MAX) &&
 		     (spi_id_min < GIC700_ESPI_ID_MIN))) {
 			ERROR("Invalid MIN SPI ID {%u} passed for "
 					"Chip %u\n", spi_id_min, i);
 			panic();
 		}

 		if ((spi_id_min > spi_id_max) ||
 		    ((spi_id_max - spi_id_min + 1) % 32 != 0)) {
 			ERROR("Unaligned SPI IDs {%u, %u} passed for "
 					"Chip %u\n", spi_id_min,
 					spi_id_max, i);
 			panic();
 		}

 		/* ESPI IDs range check */
 		if ((spi_id_min >= GIC700_ESPI_ID_MIN) &&
 		    (spi_id_max > GIC700_ESPI_ID_MAX)) {
 			ERROR("Invalid ESPI IDs {%u, %u} passed for "
 					"Chip %u\n", spi_id_min,
 					spi_id_max, i);
 			panic();

 		}

 		/* SPI IDs range check */
 		if (((spi_id_min < GIC700_SPI_ID_MAX) &&
 		     (spi_id_max > GIC700_SPI_ID_MAX))) {
 			ERROR("Invalid SPI IDs {%u, %u} passed for "
 					"Chip %u\n", spi_id_min,
 					spi_id_max, i);
 			panic();
 		}

 		/* SPI IDs overlap check */
 		if (spi_id_max < GIC700_SPI_ID_MAX) {
 			blocks_of_32 = BLOCKS_OF_32(spi_id_min, spi_id_max);
 			if ((multichip_spi_blocks & blocks_of_32) != 0) {
 				ERROR("SPI IDs of Chip %u overlapping\n", i);
 				panic();
 			}
 			multichip_spi_blocks |= blocks_of_32;
 		}

 		/* ESPI IDs overlap check */
 		if (spi_id_max > GIC700_ESPI_ID_MIN) {
 			blocks_of_32 = BLOCKS_OF_32(spi_id_min - GIC700_ESPI_ID_MIN,
 					spi_id_max - GIC700_ESPI_ID_MIN);
 			if ((multichip_espi_blocks & blocks_of_32) != 0) {
 				ERROR("SPI IDs of Chip %u overlapping\n", i);
 				panic();
 			}
 			multichip_espi_blocks |= blocks_of_32;
 		}
 	}
 }

 /*******************************************************************************
  * Initialize GIC-600 and GIC-700 Multichip operation.
  ******************************************************************************/
 void gic600_multichip_init(struct gic600_multichip_data *multichip_data)
 {
 	unsigned int i;
 	uint32_t gicd_iidr_val = gicd_read_iidr(multichip_data->rt_owner_base);

 	if ((gicd_iidr_val & IIDR_MODEL_MASK) == IIDR_MODEL_ARM_GIC_600) {
 		gic600_multichip_validate_data(multichip_data);
 	}

 	if ((gicd_iidr_val & IIDR_MODEL_MASK) == IIDR_MODEL_ARM_GIC_700) {
 		gic700_multichip_validate_data(multichip_data);
 	}

 	/*
 	 * Ensure that G0/G1S/G1NS interrupts are disabled. This also ensures
 	 * that GIC-600 Multichip configuration is done first.
 	 */
 	if ((gicd_read_ctlr(multichip_data->rt_owner_base) &
 			(CTLR_ENABLE_G0_BIT | CTLR_ENABLE_G1S_BIT |
 			 CTLR_ENABLE_G1NS_BIT | GICD_CTLR_RWP_BIT)) != 0) {
 		ERROR("GICD_CTLR group interrupts are either enabled or have "
 				"pending writes.\n");
 		panic();
 	}

 	/* Ensure that the routing table owner is in disconnected state */
 	if (((read_gicd_chipsr(multichip_data->rt_owner_base) &
 		GICD_CHIPSR_RTS_MASK) >> GICD_CHIPSR_RTS_SHIFT) !=
 			GICD_CHIPSR_RTS_STATE_DISCONNECTED) {
 		ERROR("GIC-600 routing table owner is not in disconnected "
 				"state to begin multichip configuration\n");
 		panic();
 	}

 	/* Initialize the GICD which is marked as routing table owner first */
 	set_gicd_dchipr_rt_owner(multichip_data->rt_owner_base,
 			multichip_data->rt_owner);

 	set_gicd_chipr_n(multichip_data->rt_owner_base, multichip_data->rt_owner,
 			multichip_data->chip_addrs[multichip_data->rt_owner],
 			multichip_data->
 			spi_ids[multichip_data->rt_owner].spi_id_min,
 			multichip_data->
 			spi_ids[multichip_data->rt_owner].spi_id_max);

 	for (i = 0; i < multichip_data->chip_count; i++) {
 		if (i == multichip_data->rt_owner)
 			continue;

 		set_gicd_chipr_n(multichip_data->rt_owner_base, i,
 				multichip_data->chip_addrs[i],
 				multichip_data->spi_ids[i].spi_id_min,
 				multichip_data->spi_ids[i].spi_id_max);
 	}

 	plat_gic_multichip_data = multichip_data;
 }

 /*******************************************************************************
  * Allow a way to query the status of the GIC600 multichip driver
  ******************************************************************************/
 bool gic600_multichip_is_initialized(void)
 {
 	return (plat_gic_multichip_data != NULL);
 }
	/*
	* Copyright (c) 2019-2023, Arm Limited. All rights reserved.
	* Copyright (c) 2022-2023, NVIDIA Corporation. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	/*
	* GIC-600 driver extension for multichip setup
	*/

	#include <assert.h>

	#include <common/debug.h>
	#include <drivers/arm/arm_gicv3_common.h>
	#include <drivers/arm/gic600_multichip.h>
	#include <drivers/arm/gicv3.h>

	#include "../common/gic_common_private.h"
	#include "gic600_multichip_private.h"

	static struct gic600_multichip_data *plat_gic_multichip_data;

	/*******************************************************************************
	* Retrieve the address of the chip owner for a given SPI ID
	******************************************************************************/
	uintptr_t gic600_multichip_gicd_base_for_spi(uint32_t spi_id)
	{
	unsigned int i;

	/* Find the multichip instance */
	for (i = 0U; i < GIC600_MAX_MULTICHIP; i++) {
	if ((spi_id <= plat_gic_multichip_data->spi_ids[i].spi_id_max) &&
	(spi_id >= plat_gic_multichip_data->spi_ids[i].spi_id_min)) {
	break;
	}
	}

	/* Ensure that plat_gic_multichip_data contains valid values */
	assert(i < GIC600_MAX_MULTICHIP);

	return plat_gic_multichip_data->spi_ids[i].gicd_base;
	}

	/*******************************************************************************
	* GIC-600 multichip operation related helper functions
	******************************************************************************/
	static void gicd_dchipr_wait_for_power_update_progress(uintptr_t base)
	{
	unsigned int retry = GICD_PUP_UPDATE_RETRIES;

	while ((read_gicd_dchipr(base) & GICD_DCHIPR_PUP_BIT) != 0U) {
	if (retry-- == 0U) {
	ERROR("GIC-600 connection to Routing Table Owner timed "
	"out\n");
	panic();
	}
	}
	}

	/*******************************************************************************
	* Sets up the routing table owner.
	******************************************************************************/
	static void set_gicd_dchipr_rt_owner(uintptr_t base, unsigned int rt_owner)
	{
	/*
	* Ensure that Group enables in GICD_CTLR are disabled and no pending
	* register writes to GICD_CTLR.
	*/
	if ((gicd_read_ctlr(base) &
	(CTLR_ENABLE_G0_BIT \| CTLR_ENABLE_G1S_BIT \|
	CTLR_ENABLE_G1NS_BIT \| GICD_CTLR_RWP_BIT)) != 0) {
	ERROR("GICD_CTLR group interrupts are either enabled or have "
	"pending writes. Cannot set RT owner.\n");
	panic();
	}

	/* Poll till PUP is zero before intiating write */
	gicd_dchipr_wait_for_power_update_progress(base);

	write_gicd_dchipr(base, read_gicd_dchipr(base) \|
	(rt_owner << GICD_DCHIPR_RT_OWNER_SHIFT));

	/* Poll till PUP is zero to ensure write is complete */
	gicd_dchipr_wait_for_power_update_progress(base);
	}

	/*******************************************************************************
	* Configures the Chip Register to make connections to GICDs on
	* a multichip platform.
	******************************************************************************/
	static void set_gicd_chipr_n(uintptr_t base,
	unsigned int chip_id,
	uint64_t chip_addr,
	unsigned int spi_id_min,
	unsigned int spi_id_max)
	{
	unsigned int spi_block_min, spi_blocks;
	unsigned int gicd_iidr_val = gicd_read_iidr(base);
	uint64_t chipr_n_val;

	/*
	* Ensure that group enables in GICD_CTLR are disabled and no pending
	* register writes to GICD_CTLR.
	*/
	if ((gicd_read_ctlr(base) &
	(CTLR_ENABLE_G0_BIT \| CTLR_ENABLE_G1S_BIT \|
	CTLR_ENABLE_G1NS_BIT \| GICD_CTLR_RWP_BIT)) != 0) {
	ERROR("GICD_CTLR group interrupts are either enabled or have "
	"pending writes. Cannot set CHIPR register.\n");
	panic();
	}

	/*
	* spi_id_min and spi_id_max of value 0 is used to intidicate that the
	* chip doesn't own any SPI block. Re-assign min and max values as SPI
	* id starts from 32.
	*/
	if (spi_id_min == 0 && spi_id_max == 0) {
	spi_id_min = GIC600_SPI_ID_MIN;
	spi_id_max = GIC600_SPI_ID_MIN;
	}

	switch ((gicd_iidr_val & IIDR_MODEL_MASK)) {
	case IIDR_MODEL_ARM_GIC_600:
	spi_block_min = SPI_BLOCK_MIN_VALUE(spi_id_min);
	spi_blocks = SPI_BLOCKS_VALUE(spi_id_min, spi_id_max);

	chipr_n_val = GICD_CHIPR_VALUE_GIC_600(chip_addr,
	spi_block_min,
	spi_blocks);
	break;
	case IIDR_MODEL_ARM_GIC_700:
	/* Calculate the SPI_ID_MIN value for ESPI */
	if (spi_id_min >= GIC700_ESPI_ID_MIN) {
	spi_block_min = ESPI_BLOCK_MIN_VALUE(spi_id_min);
	spi_block_min += SPI_BLOCKS_VALUE(GIC700_SPI_ID_MIN,
	GIC700_SPI_ID_MAX);
	} else {
	spi_block_min = SPI_BLOCK_MIN_VALUE(spi_id_min);
	}

	/* Calculate the total number of blocks */
	spi_blocks = SPI_BLOCKS_VALUE(spi_id_min, spi_id_max);

	chipr_n_val = GICD_CHIPR_VALUE_GIC_700(chip_addr,
	spi_block_min,
	spi_blocks);
	break;
	default:
	ERROR("Unsupported GIC model 0x%x for multichip setup.\n",
	gicd_iidr_val);
	panic();
	break;
	}
	chipr_n_val \|= GICD_CHIPRx_SOCKET_STATE;

	/*
	* Wait for DCHIPR.PUP to be zero before commencing writes to
	* GICD_CHIPRx.
	*/
	gicd_dchipr_wait_for_power_update_progress(base);

	/*
	* Assign chip addr, spi min block, number of spi blocks and bring chip
	* online by setting SocketState.
	*/
	write_gicd_chipr_n(base, chip_id, chipr_n_val);

	/*
	* Poll until DCHIP.PUP is zero to verify connection to rt_owner chip
	* is complete.
	*/
	gicd_dchipr_wait_for_power_update_progress(base);

	/*
	* Ensure that write to GICD_CHIPRx is successful and the chip_n came
	* online.
	*/
	if (read_gicd_chipr_n(base, chip_id) != chipr_n_val) {
	ERROR("GICD_CHIPR%u write failed\n", chip_id);
	panic();
	}

	/* Ensure that chip is in consistent state */
	if (((read_gicd_chipsr(base) & GICD_CHIPSR_RTS_MASK) >>
	GICD_CHIPSR_RTS_SHIFT) !=
	GICD_CHIPSR_RTS_STATE_CONSISTENT) {
	ERROR("Chip %u routing table is not in consistent state\n",
	chip_id);
	panic();
	}
	}

	/*******************************************************************************
	* Validates the GIC-600 Multichip data structure passed by the platform.
	******************************************************************************/
	static void gic600_multichip_validate_data(
	struct gic600_multichip_data *multichip_data)
	{
	unsigned int i, spi_id_min, spi_id_max, blocks_of_32;
	unsigned int multichip_spi_blocks = 0;

	assert(multichip_data != NULL);

	if (multichip_data->chip_count > GIC600_MAX_MULTICHIP) {
	ERROR("GIC-600 Multichip count should not exceed %d\n",
	GIC600_MAX_MULTICHIP);
	panic();
	}

	for (i = 0U; i < multichip_data->chip_count; i++) {
	spi_id_min = multichip_data->spi_ids[i].spi_id_min;
	spi_id_max = multichip_data->spi_ids[i].spi_id_max;

	if ((spi_id_min != 0U) \|\| (spi_id_max != 0U)) {

	/* SPI IDs range check */
	if (!(spi_id_min >= GIC600_SPI_ID_MIN) \|\|
	!(spi_id_max <= GIC600_SPI_ID_MAX) \|\|
	!(spi_id_min <= spi_id_max) \|\|
	!((spi_id_max - spi_id_min + 1) % 32 == 0)) {
	ERROR("Invalid SPI IDs {%u, %u} passed for "
	"Chip %u\n", spi_id_min,
	spi_id_max, i);
	panic();
	}

	/* SPI IDs overlap check */
	blocks_of_32 = BLOCKS_OF_32(spi_id_min, spi_id_max);
	if ((multichip_spi_blocks & blocks_of_32) != 0) {
	ERROR("SPI IDs of Chip %u overlapping\n", i);
	panic();
	}
	multichip_spi_blocks \|= blocks_of_32;
	}
	}
	}

	/*******************************************************************************
	* Validates the GIC-700 Multichip data structure passed by the platform.
	******************************************************************************/
	static void gic700_multichip_validate_data(
	struct gic600_multichip_data *multichip_data)
	{
	unsigned int i, spi_id_min, spi_id_max, blocks_of_32;
	unsigned int multichip_spi_blocks = 0U, multichip_espi_blocks = 0U;

	assert(multichip_data != NULL);

	if (multichip_data->chip_count > GIC600_MAX_MULTICHIP) {
	ERROR("GIC-700 Multichip count (%u) should not exceed %u\n",
	multichip_data->chip_count, GIC600_MAX_MULTICHIP);
	panic();
	}

	for (i = 0U; i < multichip_data->chip_count; i++) {
	spi_id_min = multichip_data->spi_ids[i].spi_id_min;
	spi_id_max = multichip_data->spi_ids[i].spi_id_max;

	if ((spi_id_min == 0U) \|\| (spi_id_max == 0U)) {
	continue;
	}

	/* MIN SPI ID check */
	if ((spi_id_min < GIC700_SPI_ID_MIN) \|\|
	((spi_id_min >= GIC700_SPI_ID_MAX) &&
	(spi_id_min < GIC700_ESPI_ID_MIN))) {
	ERROR("Invalid MIN SPI ID {%u} passed for "
	"Chip %u\n", spi_id_min, i);
	panic();
	}

	if ((spi_id_min > spi_id_max) \|\|
	((spi_id_max - spi_id_min + 1) % 32 != 0)) {
	ERROR("Unaligned SPI IDs {%u, %u} passed for "
	"Chip %u\n", spi_id_min,
	spi_id_max, i);
	panic();
	}

	/* ESPI IDs range check */
	if ((spi_id_min >= GIC700_ESPI_ID_MIN) &&
	(spi_id_max > GIC700_ESPI_ID_MAX)) {
	ERROR("Invalid ESPI IDs {%u, %u} passed for "
	"Chip %u\n", spi_id_min,
	spi_id_max, i);
	panic();

	}

	/* SPI IDs range check */
	if (((spi_id_min < GIC700_SPI_ID_MAX) &&
	(spi_id_max > GIC700_SPI_ID_MAX))) {
	ERROR("Invalid SPI IDs {%u, %u} passed for "
	"Chip %u\n", spi_id_min,
	spi_id_max, i);
	panic();
	}

	/* SPI IDs overlap check */
	if (spi_id_max < GIC700_SPI_ID_MAX) {
	blocks_of_32 = BLOCKS_OF_32(spi_id_min, spi_id_max);
	if ((multichip_spi_blocks & blocks_of_32) != 0) {
	ERROR("SPI IDs of Chip %u overlapping\n", i);
	panic();
	}
	multichip_spi_blocks \|= blocks_of_32;
	}

	/* ESPI IDs overlap check */
	if (spi_id_max > GIC700_ESPI_ID_MIN) {
	blocks_of_32 = BLOCKS_OF_32(spi_id_min - GIC700_ESPI_ID_MIN,
	spi_id_max - GIC700_ESPI_ID_MIN);
	if ((multichip_espi_blocks & blocks_of_32) != 0) {
	ERROR("SPI IDs of Chip %u overlapping\n", i);
	panic();
	}
	multichip_espi_blocks \|= blocks_of_32;
	}
	}
	}

	/*******************************************************************************
	* Initialize GIC-600 and GIC-700 Multichip operation.
	******************************************************************************/
	void gic600_multichip_init(struct gic600_multichip_data *multichip_data)
	{
	unsigned int i;
	uint32_t gicd_iidr_val = gicd_read_iidr(multichip_data->rt_owner_base);

	if ((gicd_iidr_val & IIDR_MODEL_MASK) == IIDR_MODEL_ARM_GIC_600) {
	gic600_multichip_validate_data(multichip_data);
	}

	if ((gicd_iidr_val & IIDR_MODEL_MASK) == IIDR_MODEL_ARM_GIC_700) {
	gic700_multichip_validate_data(multichip_data);
	}

	/*
	* Ensure that G0/G1S/G1NS interrupts are disabled. This also ensures
	* that GIC-600 Multichip configuration is done first.
	*/
	if ((gicd_read_ctlr(multichip_data->rt_owner_base) &
	(CTLR_ENABLE_G0_BIT \| CTLR_ENABLE_G1S_BIT \|
	CTLR_ENABLE_G1NS_BIT \| GICD_CTLR_RWP_BIT)) != 0) {
	ERROR("GICD_CTLR group interrupts are either enabled or have "
	"pending writes.\n");
	panic();
	}

	/* Ensure that the routing table owner is in disconnected state */
	if (((read_gicd_chipsr(multichip_data->rt_owner_base) &
	GICD_CHIPSR_RTS_MASK) >> GICD_CHIPSR_RTS_SHIFT) !=
	GICD_CHIPSR_RTS_STATE_DISCONNECTED) {
	ERROR("GIC-600 routing table owner is not in disconnected "
	"state to begin multichip configuration\n");
	panic();
	}

	/* Initialize the GICD which is marked as routing table owner first */
	set_gicd_dchipr_rt_owner(multichip_data->rt_owner_base,
	multichip_data->rt_owner);

	set_gicd_chipr_n(multichip_data->rt_owner_base, multichip_data->rt_owner,
	multichip_data->chip_addrs[multichip_data->rt_owner],
	multichip_data->
	spi_ids[multichip_data->rt_owner].spi_id_min,
	multichip_data->
	spi_ids[multichip_data->rt_owner].spi_id_max);

	for (i = 0; i < multichip_data->chip_count; i++) {
	if (i == multichip_data->rt_owner)
	continue;

	set_gicd_chipr_n(multichip_data->rt_owner_base, i,
	multichip_data->chip_addrs[i],
	multichip_data->spi_ids[i].spi_id_min,
	multichip_data->spi_ids[i].spi_id_max);
	}

	plat_gic_multichip_data = multichip_data;
	}

	/*******************************************************************************
	* Allow a way to query the status of the GIC600 multichip driver
	******************************************************************************/
	bool gic600_multichip_is_initialized(void)
	{
	return (plat_gic_multichip_data != NULL);
	}