drivers/firmware/arm_ffa/driver.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /*
  * Arm Firmware Framework for ARMv8-A(FFA) interface driver
  *
  * The Arm FFA specification[1] describes a software architecture to
  * leverages the virtualization extension to isolate software images
  * provided by an ecosystem of vendors from each other and describes
  * interfaces that standardize communication between the various software
  * images including communication between images in the Secure world and
  * Normal world. Any Hypervisor could use the FFA interfaces to enable
  * communication between VMs it manages.
  *
  * The Hypervisor a.k.a Partition managers in FFA terminology can assign
  * system resources(Memory regions, Devices, CPU cycles) to the partitions
  * and manage isolation amongst them.
  *
  * [1] https://developer.arm.com/docs/den0077/latest
  *
  * Copyright (C) 2021 ARM Ltd.
  */

 #define DRIVER_NAME "ARM FF-A"
 #define pr_fmt(fmt) DRIVER_NAME ": " fmt

 #include <linux/arm_ffa.h>
 #include <linux/bitfield.h>
 #include <linux/device.h>
 #include <linux/io.h>
 #include <linux/kernel.h>
 #include <linux/module.h>
 #include <linux/mm.h>
 #include <linux/scatterlist.h>
 #include <linux/slab.h>
 #include <linux/uuid.h>

 #include "common.h"

 #define FFA_DRIVER_VERSION	FFA_VERSION_1_0

 #define FFA_SMC(calling_convention, func_num)				\
 	ARM_SMCCC_CALL_VAL(ARM_SMCCC_FAST_CALL, (calling_convention),	\
 			   ARM_SMCCC_OWNER_STANDARD, (func_num))

 #define FFA_SMC_32(func_num)	FFA_SMC(ARM_SMCCC_SMC_32, (func_num))
 #define FFA_SMC_64(func_num)	FFA_SMC(ARM_SMCCC_SMC_64, (func_num))

 #define FFA_ERROR			FFA_SMC_32(0x60)
 #define FFA_SUCCESS			FFA_SMC_32(0x61)
 #define FFA_INTERRUPT			FFA_SMC_32(0x62)
 #define FFA_VERSION			FFA_SMC_32(0x63)
 #define FFA_FEATURES			FFA_SMC_32(0x64)
 #define FFA_RX_RELEASE			FFA_SMC_32(0x65)
 #define FFA_RXTX_MAP			FFA_SMC_32(0x66)
 #define FFA_FN64_RXTX_MAP		FFA_SMC_64(0x66)
 #define FFA_RXTX_UNMAP			FFA_SMC_32(0x67)
 #define FFA_PARTITION_INFO_GET		FFA_SMC_32(0x68)
 #define FFA_ID_GET			FFA_SMC_32(0x69)
 #define FFA_MSG_POLL			FFA_SMC_32(0x6A)
 #define FFA_MSG_WAIT			FFA_SMC_32(0x6B)
 #define FFA_YIELD			FFA_SMC_32(0x6C)
 #define FFA_RUN				FFA_SMC_32(0x6D)
 #define FFA_MSG_SEND			FFA_SMC_32(0x6E)
 #define FFA_MSG_SEND_DIRECT_REQ		FFA_SMC_32(0x6F)
 #define FFA_FN64_MSG_SEND_DIRECT_REQ	FFA_SMC_64(0x6F)
 #define FFA_MSG_SEND_DIRECT_RESP	FFA_SMC_32(0x70)
 #define FFA_FN64_MSG_SEND_DIRECT_RESP	FFA_SMC_64(0x70)
 #define FFA_MEM_DONATE			FFA_SMC_32(0x71)
 #define FFA_FN64_MEM_DONATE		FFA_SMC_64(0x71)
 #define FFA_MEM_LEND			FFA_SMC_32(0x72)
 #define FFA_FN64_MEM_LEND		FFA_SMC_64(0x72)
 #define FFA_MEM_SHARE			FFA_SMC_32(0x73)
 #define FFA_FN64_MEM_SHARE		FFA_SMC_64(0x73)
 #define FFA_MEM_RETRIEVE_REQ		FFA_SMC_32(0x74)
 #define FFA_FN64_MEM_RETRIEVE_REQ	FFA_SMC_64(0x74)
 #define FFA_MEM_RETRIEVE_RESP		FFA_SMC_32(0x75)
 #define FFA_MEM_RELINQUISH		FFA_SMC_32(0x76)
 #define FFA_MEM_RECLAIM			FFA_SMC_32(0x77)
 #define FFA_MEM_OP_PAUSE		FFA_SMC_32(0x78)
 #define FFA_MEM_OP_RESUME		FFA_SMC_32(0x79)
 #define FFA_MEM_FRAG_RX			FFA_SMC_32(0x7A)
 #define FFA_MEM_FRAG_TX			FFA_SMC_32(0x7B)
 #define FFA_NORMAL_WORLD_RESUME		FFA_SMC_32(0x7C)

 /*
  * For some calls it is necessary to use SMC64 to pass or return 64-bit values.
  * For such calls FFA_FN_NATIVE(name) will choose the appropriate
  * (native-width) function ID.
  */
 #ifdef CONFIG_64BIT
 #define FFA_FN_NATIVE(name)	FFA_FN64_##name
 #else
 #define FFA_FN_NATIVE(name)	FFA_##name
 #endif

 /* FFA error codes. */
 #define FFA_RET_SUCCESS            (0)
 #define FFA_RET_NOT_SUPPORTED      (-1)
 #define FFA_RET_INVALID_PARAMETERS (-2)
 #define FFA_RET_NO_MEMORY          (-3)
 #define FFA_RET_BUSY               (-4)
 #define FFA_RET_INTERRUPTED        (-5)
 #define FFA_RET_DENIED             (-6)
 #define FFA_RET_RETRY              (-7)
 #define FFA_RET_ABORTED            (-8)

 #define MAJOR_VERSION_MASK	GENMASK(30, 16)
 #define MINOR_VERSION_MASK	GENMASK(15, 0)
 #define MAJOR_VERSION(x)	((u16)(FIELD_GET(MAJOR_VERSION_MASK, (x))))
 #define MINOR_VERSION(x)	((u16)(FIELD_GET(MINOR_VERSION_MASK, (x))))
 #define PACK_VERSION_INFO(major, minor)			\
 	(FIELD_PREP(MAJOR_VERSION_MASK, (major)) |	\
 	 FIELD_PREP(MINOR_VERSION_MASK, (minor)))
 #define FFA_VERSION_1_0		PACK_VERSION_INFO(1, 0)
 #define FFA_MIN_VERSION		FFA_VERSION_1_0

 #define SENDER_ID_MASK		GENMASK(31, 16)
 #define RECEIVER_ID_MASK	GENMASK(15, 0)
 #define SENDER_ID(x)		((u16)(FIELD_GET(SENDER_ID_MASK, (x))))
 #define RECEIVER_ID(x)		((u16)(FIELD_GET(RECEIVER_ID_MASK, (x))))
 #define PACK_TARGET_INFO(s, r)		\
 	(FIELD_PREP(SENDER_ID_MASK, (s)) | FIELD_PREP(RECEIVER_ID_MASK, (r)))

 /*
  * FF-A specification mentions explicitly about '4K pages'. This should
  * not be confused with the kernel PAGE_SIZE, which is the translation
  * granule kernel is configured and may be one among 4K, 16K and 64K.
  */
 #define FFA_PAGE_SIZE		SZ_4K
 /*
  * Keeping RX TX buffer size as 4K for now
  * 64K may be preferred to keep it min a page in 64K PAGE_SIZE config
  */
 #define RXTX_BUFFER_SIZE	SZ_4K

 static ffa_fn *invoke_ffa_fn;

 static const int ffa_linux_errmap[] = {
 	/* better than switch case as long as return value is continuous */
 	0,		/* FFA_RET_SUCCESS */
 	-EOPNOTSUPP,	/* FFA_RET_NOT_SUPPORTED */
 	-EINVAL,	/* FFA_RET_INVALID_PARAMETERS */
 	-ENOMEM,	/* FFA_RET_NO_MEMORY */
 	-EBUSY,		/* FFA_RET_BUSY */
 	-EINTR,		/* FFA_RET_INTERRUPTED */
 	-EACCES,	/* FFA_RET_DENIED */
 	-EAGAIN,	/* FFA_RET_RETRY */
 	-ECANCELED,	/* FFA_RET_ABORTED */
 };

 static inline int ffa_to_linux_errno(int errno)
 {
 	int err_idx = -errno;

 	if (err_idx >= 0 && err_idx < ARRAY_SIZE(ffa_linux_errmap))
 		return ffa_linux_errmap[err_idx];
 	return -EINVAL;
 }

 struct ffa_drv_info {
 	u32 version;
 	u16 vm_id;
 	struct mutex rx_lock; /* lock to protect Rx buffer */
 	struct mutex tx_lock; /* lock to protect Tx buffer */
 	void *rx_buffer;
 	void *tx_buffer;
 };

 static struct ffa_drv_info *drv_info;

 /*
  * The driver must be able to support all the versions from the earliest
  * supported FFA_MIN_VERSION to the latest supported FFA_DRIVER_VERSION.
  * The specification states that if firmware supports a FFA implementation
  * that is incompatible with and at a greater version number than specified
  * by the caller(FFA_DRIVER_VERSION passed as parameter to FFA_VERSION),
  * it must return the NOT_SUPPORTED error code.
  */
 static u32 ffa_compatible_version_find(u32 version)
 {
 	u16 major = MAJOR_VERSION(version), minor = MINOR_VERSION(version);
 	u16 drv_major = MAJOR_VERSION(FFA_DRIVER_VERSION);
 	u16 drv_minor = MINOR_VERSION(FFA_DRIVER_VERSION);

 	if ((major < drv_major) || (major == drv_major && minor <= drv_minor))
 		return version;

 	pr_info("Firmware version higher than driver version, downgrading\n");
 	return FFA_DRIVER_VERSION;
 }

 static int ffa_version_check(u32 *version)
 {
 	ffa_value_t ver;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_VERSION, .a1 = FFA_DRIVER_VERSION,
 		      }, &ver);

 	if (ver.a0 == FFA_RET_NOT_SUPPORTED) {
 		pr_info("FFA_VERSION returned not supported\n");
 		return -EOPNOTSUPP;
 	}

 	if (ver.a0 < FFA_MIN_VERSION) {
 		pr_err("Incompatible v%d.%d! Earliest supported v%d.%d\n",
 		       MAJOR_VERSION(ver.a0), MINOR_VERSION(ver.a0),
 		       MAJOR_VERSION(FFA_MIN_VERSION),
 		       MINOR_VERSION(FFA_MIN_VERSION));
 		return -EINVAL;
 	}

 	pr_info("Driver version %d.%d\n", MAJOR_VERSION(FFA_DRIVER_VERSION),
 		MINOR_VERSION(FFA_DRIVER_VERSION));
 	pr_info("Firmware version %d.%d found\n", MAJOR_VERSION(ver.a0),
 		MINOR_VERSION(ver.a0));
 	*version = ffa_compatible_version_find(ver.a0);

 	return 0;
 }

 static int ffa_rx_release(void)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_RX_RELEASE,
 		      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	/* check for ret.a0 == FFA_RX_RELEASE ? */

 	return 0;
 }

 static int ffa_rxtx_map(phys_addr_t tx_buf, phys_addr_t rx_buf, u32 pg_cnt)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_FN_NATIVE(RXTX_MAP),
 		      .a1 = tx_buf, .a2 = rx_buf, .a3 = pg_cnt,
 		      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	return 0;
 }

 static int ffa_rxtx_unmap(u16 vm_id)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_RXTX_UNMAP, .a1 = PACK_TARGET_INFO(vm_id, 0),
 		      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	return 0;
 }

 /* buffer must be sizeof(struct ffa_partition_info) * num_partitions */
 static int
 __ffa_partition_info_get(u32 uuid0, u32 uuid1, u32 uuid2, u32 uuid3,
 			 struct ffa_partition_info *buffer, int num_partitions)
 {
 	int count;
 	ffa_value_t partition_info;

 	mutex_lock(&drv_info->rx_lock);
 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_PARTITION_INFO_GET,
 		      .a1 = uuid0, .a2 = uuid1, .a3 = uuid2, .a4 = uuid3,
 		      }, &partition_info);

 	if (partition_info.a0 == FFA_ERROR) {
 		mutex_unlock(&drv_info->rx_lock);
 		return ffa_to_linux_errno((int)partition_info.a2);
 	}

 	count = partition_info.a2;

 	if (buffer && count <= num_partitions)
 		memcpy(buffer, drv_info->rx_buffer, sizeof(*buffer) * count);

 	ffa_rx_release();

 	mutex_unlock(&drv_info->rx_lock);

 	return count;
 }

 /* buffer is allocated and caller must free the same if returned count > 0 */
 static int
 ffa_partition_probe(const uuid_t *uuid, struct ffa_partition_info **buffer)
 {
 	int count;
 	u32 uuid0_4[4];
 	struct ffa_partition_info *pbuf;

 	export_uuid((u8 *)uuid0_4, uuid);
 	count = __ffa_partition_info_get(uuid0_4[0], uuid0_4[1], uuid0_4[2],
 					 uuid0_4[3], NULL, 0);
 	if (count <= 0)
 		return count;

 	pbuf = kcalloc(count, sizeof(*pbuf), GFP_KERNEL);
 	if (!pbuf)
 		return -ENOMEM;

 	count = __ffa_partition_info_get(uuid0_4[0], uuid0_4[1], uuid0_4[2],
 					 uuid0_4[3], pbuf, count);
 	if (count <= 0)
 		kfree(pbuf);
 	else
 		*buffer = pbuf;

 	return count;
 }

 #define VM_ID_MASK	GENMASK(15, 0)
 static int ffa_id_get(u16 *vm_id)
 {
 	ffa_value_t id;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_ID_GET,
 		      }, &id);

 	if (id.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)id.a2);

 	*vm_id = FIELD_GET(VM_ID_MASK, (id.a2));

 	return 0;
 }

 static int ffa_msg_send_direct_req(u16 src_id, u16 dst_id, bool mode_32bit,
 				   struct ffa_send_direct_data *data)
 {
 	u32 req_id, resp_id, src_dst_ids = PACK_TARGET_INFO(src_id, dst_id);
 	ffa_value_t ret;

 	if (mode_32bit) {
 		req_id = FFA_MSG_SEND_DIRECT_REQ;
 		resp_id = FFA_MSG_SEND_DIRECT_RESP;
 	} else {
 		req_id = FFA_FN_NATIVE(MSG_SEND_DIRECT_REQ);
 		resp_id = FFA_FN_NATIVE(MSG_SEND_DIRECT_RESP);
 	}

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = req_id, .a1 = src_dst_ids, .a2 = 0,
 		      .a3 = data->data0, .a4 = data->data1, .a5 = data->data2,
 		      .a6 = data->data3, .a7 = data->data4,
 		      }, &ret);

 	while (ret.a0 == FFA_INTERRUPT)
 		invoke_ffa_fn((ffa_value_t){
 			      .a0 = FFA_RUN, .a1 = ret.a1,
 			      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	if (ret.a0 == resp_id) {
 		data->data0 = ret.a3;
 		data->data1 = ret.a4;
 		data->data2 = ret.a5;
 		data->data3 = ret.a6;
 		data->data4 = ret.a7;
 		return 0;
 	}

 	return -EINVAL;
 }

 static int ffa_mem_first_frag(u32 func_id, phys_addr_t buf, u32 buf_sz,
 			      u32 frag_len, u32 len, u64 *handle)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = func_id, .a1 = len, .a2 = frag_len,
 		      .a3 = buf, .a4 = buf_sz,
 		      }, &ret);

 	while (ret.a0 == FFA_MEM_OP_PAUSE)
 		invoke_ffa_fn((ffa_value_t){
 			      .a0 = FFA_MEM_OP_RESUME,
 			      .a1 = ret.a1, .a2 = ret.a2,
 			      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	if (ret.a0 != FFA_SUCCESS)
 		return -EOPNOTSUPP;

 	if (handle)
 		*handle = PACK_HANDLE(ret.a2, ret.a3);

 	return frag_len;
 }

 static int ffa_mem_next_frag(u64 handle, u32 frag_len)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_MEM_FRAG_TX,
 		      .a1 = HANDLE_LOW(handle), .a2 = HANDLE_HIGH(handle),
 		      .a3 = frag_len,
 		      }, &ret);

 	while (ret.a0 == FFA_MEM_OP_PAUSE)
 		invoke_ffa_fn((ffa_value_t){
 			      .a0 = FFA_MEM_OP_RESUME,
 			      .a1 = ret.a1, .a2 = ret.a2,
 			      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	if (ret.a0 != FFA_MEM_FRAG_RX)
 		return -EOPNOTSUPP;

 	return ret.a3;
 }

 static int
 ffa_transmit_fragment(u32 func_id, phys_addr_t buf, u32 buf_sz, u32 frag_len,
 		      u32 len, u64 *handle, bool first)
 {
 	if (!first)
 		return ffa_mem_next_frag(*handle, frag_len);

 	return ffa_mem_first_frag(func_id, buf, buf_sz, frag_len, len, handle);
 }

 static u32 ffa_get_num_pages_sg(struct scatterlist *sg)
 {
 	u32 num_pages = 0;

 	do {
 		num_pages += sg->length / FFA_PAGE_SIZE;
 	} while ((sg = sg_next(sg)));

 	return num_pages;
 }

 static int
 ffa_setup_and_transmit(u32 func_id, void *buffer, u32 max_fragsize,
 		       struct ffa_mem_ops_args *args)
 {
 	int rc = 0;
 	bool first = true;
 	phys_addr_t addr = 0;
 	struct ffa_composite_mem_region *composite;
 	struct ffa_mem_region_addr_range *constituents;
 	struct ffa_mem_region_attributes *ep_mem_access;
 	struct ffa_mem_region *mem_region = buffer;
 	u32 idx, frag_len, length, buf_sz = 0, num_entries = sg_nents(args->sg);

 	mem_region->tag = args->tag;
 	mem_region->flags = args->flags;
 	mem_region->sender_id = drv_info->vm_id;
 	mem_region->attributes = FFA_MEM_NORMAL | FFA_MEM_WRITE_BACK |
 				 FFA_MEM_INNER_SHAREABLE;
 	ep_mem_access = &mem_region->ep_mem_access[0];

 	for (idx = 0; idx < args->nattrs; idx++, ep_mem_access++) {
 		ep_mem_access->receiver = args->attrs[idx].receiver;
 		ep_mem_access->attrs = args->attrs[idx].attrs;
 		ep_mem_access->composite_off = COMPOSITE_OFFSET(args->nattrs);
 	}
 	mem_region->ep_count = args->nattrs;

 	composite = buffer + COMPOSITE_OFFSET(args->nattrs);
 	composite->total_pg_cnt = ffa_get_num_pages_sg(args->sg);
 	composite->addr_range_cnt = num_entries;

 	length = COMPOSITE_CONSTITUENTS_OFFSET(args->nattrs, num_entries);
 	frag_len = COMPOSITE_CONSTITUENTS_OFFSET(args->nattrs, 0);
 	if (frag_len > max_fragsize)
 		return -ENXIO;

 	if (!args->use_txbuf) {
 		addr = virt_to_phys(buffer);
 		buf_sz = max_fragsize / FFA_PAGE_SIZE;
 	}

 	constituents = buffer + frag_len;
 	idx = 0;
 	do {
 		if (frag_len == max_fragsize) {
 			rc = ffa_transmit_fragment(func_id, addr, buf_sz,
 						   frag_len, length,
 						   &args->g_handle, first);
 			if (rc < 0)
 				return -ENXIO;

 			first = false;
 			idx = 0;
 			frag_len = 0;
 			constituents = buffer;
 		}

 		if ((void *)constituents - buffer > max_fragsize) {
 			pr_err("Memory Region Fragment > Tx Buffer size\n");
 			return -EFAULT;
 		}

 		constituents->address = sg_phys(args->sg);
 		constituents->pg_cnt = args->sg->length / FFA_PAGE_SIZE;
 		constituents++;
 		frag_len += sizeof(struct ffa_mem_region_addr_range);
 	} while ((args->sg = sg_next(args->sg)));

 	return ffa_transmit_fragment(func_id, addr, buf_sz, frag_len,
 				     length, &args->g_handle, first);
 }

 static int ffa_memory_ops(u32 func_id, struct ffa_mem_ops_args *args)
 {
 	int ret;
 	void *buffer;

 	if (!args->use_txbuf) {
 		buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
 		if (!buffer)
 			return -ENOMEM;
 	} else {
 		buffer = drv_info->tx_buffer;
 		mutex_lock(&drv_info->tx_lock);
 	}

 	ret = ffa_setup_and_transmit(func_id, buffer, RXTX_BUFFER_SIZE, args);

 	if (args->use_txbuf)
 		mutex_unlock(&drv_info->tx_lock);
 	else
 		free_pages_exact(buffer, RXTX_BUFFER_SIZE);

 	return ret < 0 ? ret : 0;
 }

 static int ffa_memory_reclaim(u64 g_handle, u32 flags)
 {
 	ffa_value_t ret;

 	invoke_ffa_fn((ffa_value_t){
 		      .a0 = FFA_MEM_RECLAIM,
 		      .a1 = HANDLE_LOW(g_handle), .a2 = HANDLE_HIGH(g_handle),
 		      .a3 = flags,
 		      }, &ret);

 	if (ret.a0 == FFA_ERROR)
 		return ffa_to_linux_errno((int)ret.a2);

 	return 0;
 }

 static u32 ffa_api_version_get(void)
 {
 	return drv_info->version;
 }

 static int ffa_partition_info_get(const char *uuid_str,
 				  struct ffa_partition_info *buffer)
 {
 	int count;
 	uuid_t uuid;
 	struct ffa_partition_info *pbuf;

 	if (uuid_parse(uuid_str, &uuid)) {
 		pr_err("invalid uuid (%s)\n", uuid_str);
 		return -ENODEV;
 	}

 	count = ffa_partition_probe(&uuid_null, &pbuf);
 	if (count <= 0)
 		return -ENOENT;

 	memcpy(buffer, pbuf, sizeof(*pbuf) * count);
 	kfree(pbuf);
 	return 0;
 }

 static void ffa_mode_32bit_set(struct ffa_device *dev)
 {
 	dev->mode_32bit = true;
 }

 static int ffa_sync_send_receive(struct ffa_device *dev,
 				 struct ffa_send_direct_data *data)
 {
 	return ffa_msg_send_direct_req(drv_info->vm_id, dev->vm_id,
 				       dev->mode_32bit, data);
 }

 static int
 ffa_memory_share(struct ffa_device *dev, struct ffa_mem_ops_args *args)
 {
 	if (dev->mode_32bit)
 		return ffa_memory_ops(FFA_MEM_SHARE, args);

 	return ffa_memory_ops(FFA_FN_NATIVE(MEM_SHARE), args);
 }

 static int
 ffa_memory_lend(struct ffa_device *dev, struct ffa_mem_ops_args *args)
 {
 	/* Note that upon a successful MEM_LEND request the caller
 	 * must ensure that the memory region specified is not accessed
 	 * until a successful MEM_RECALIM call has been made.
 	 * On systems with a hypervisor present this will been enforced,
 	 * however on systems without a hypervisor the responsibility
 	 * falls to the calling kernel driver to prevent access.
 	 */
 	if (dev->mode_32bit)
 		return ffa_memory_ops(FFA_MEM_LEND, args);

 	return ffa_memory_ops(FFA_FN_NATIVE(MEM_LEND), args);
 }

 static const struct ffa_dev_ops ffa_ops = {
 	.api_version_get = ffa_api_version_get,
 	.partition_info_get = ffa_partition_info_get,
 	.mode_32bit_set = ffa_mode_32bit_set,
 	.sync_send_receive = ffa_sync_send_receive,
 	.memory_reclaim = ffa_memory_reclaim,
 	.memory_share = ffa_memory_share,
 	.memory_lend = ffa_memory_lend,
 };

 const struct ffa_dev_ops *ffa_dev_ops_get(struct ffa_device *dev)
 {
 	if (ffa_device_is_valid(dev))
 		return &ffa_ops;

 	return NULL;
 }
 EXPORT_SYMBOL_GPL(ffa_dev_ops_get);

 void ffa_device_match_uuid(struct ffa_device *ffa_dev, const uuid_t *uuid)
 {
 	int count, idx;
 	struct ffa_partition_info *pbuf, *tpbuf;

 	count = ffa_partition_probe(uuid, &pbuf);
 	if (count <= 0)
 		return;

 	for (idx = 0, tpbuf = pbuf; idx < count; idx++, tpbuf++)
 		if (tpbuf->id == ffa_dev->vm_id)
 			uuid_copy(&ffa_dev->uuid, uuid);
 	kfree(pbuf);
 }

 static void ffa_setup_partitions(void)
 {
 	int count, idx;
 	struct ffa_device *ffa_dev;
 	struct ffa_partition_info *pbuf, *tpbuf;

 	count = ffa_partition_probe(&uuid_null, &pbuf);
 	if (count <= 0) {
 		pr_info("%s: No partitions found, error %d\n", __func__, count);
 		return;
 	}

 	for (idx = 0, tpbuf = pbuf; idx < count; idx++, tpbuf++) {
 		/* Note that the &uuid_null parameter will require
 		 * ffa_device_match() to find the UUID of this partition id
 		 * with help of ffa_device_match_uuid(). Once the FF-A spec
 		 * is updated to provide correct UUID here for each partition
 		 * as part of the discovery API, we need to pass the
 		 * discovered UUID here instead.
 		 */
 		ffa_dev = ffa_device_register(&uuid_null, tpbuf->id);
 		if (!ffa_dev) {
 			pr_err("%s: failed to register partition ID 0x%x\n",
 			       __func__, tpbuf->id);
 			continue;
 		}

 		ffa_dev_set_drvdata(ffa_dev, drv_info);
 	}
 	kfree(pbuf);
 }

 static int __init ffa_init(void)
 {
 	int ret;

 	ret = ffa_transport_init(&invoke_ffa_fn);
 	if (ret)
 		return ret;

 	ret = arm_ffa_bus_init();
 	if (ret)
 		return ret;

 	drv_info = kzalloc(sizeof(*drv_info), GFP_KERNEL);
 	if (!drv_info) {
 		ret = -ENOMEM;
 		goto ffa_bus_exit;
 	}

 	ret = ffa_version_check(&drv_info->version);
 	if (ret)
 		goto free_drv_info;

 	if (ffa_id_get(&drv_info->vm_id)) {
 		pr_err("failed to obtain VM id for self\n");
 		ret = -ENODEV;
 		goto free_drv_info;
 	}

 	drv_info->rx_buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
 	if (!drv_info->rx_buffer) {
 		ret = -ENOMEM;
 		goto free_pages;
 	}

 	drv_info->tx_buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
 	if (!drv_info->tx_buffer) {
 		ret = -ENOMEM;
 		goto free_pages;
 	}

 	ret = ffa_rxtx_map(virt_to_phys(drv_info->tx_buffer),
 			   virt_to_phys(drv_info->rx_buffer),
 			   RXTX_BUFFER_SIZE / FFA_PAGE_SIZE);
 	if (ret) {
 		pr_err("failed to register FFA RxTx buffers\n");
 		goto free_pages;
 	}

 	mutex_init(&drv_info->rx_lock);
 	mutex_init(&drv_info->tx_lock);

 	ffa_setup_partitions();

 	return 0;
 free_pages:
 	if (drv_info->tx_buffer)
 		free_pages_exact(drv_info->tx_buffer, RXTX_BUFFER_SIZE);
 	free_pages_exact(drv_info->rx_buffer, RXTX_BUFFER_SIZE);
 free_drv_info:
 	kfree(drv_info);
 ffa_bus_exit:
 	arm_ffa_bus_exit();
 	return ret;
 }
 subsys_initcall(ffa_init);

 static void __exit ffa_exit(void)
 {
 	ffa_rxtx_unmap(drv_info->vm_id);
 	free_pages_exact(drv_info->tx_buffer, RXTX_BUFFER_SIZE);
 	free_pages_exact(drv_info->rx_buffer, RXTX_BUFFER_SIZE);
 	kfree(drv_info);
 	arm_ffa_bus_exit();
 }
 module_exit(ffa_exit);

 MODULE_ALIAS("arm-ffa");
 MODULE_AUTHOR("Sudeep Holla <sudeep.holla@arm.com>");
 MODULE_DESCRIPTION("Arm FF-A interface driver");
 MODULE_LICENSE("GPL v2");
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Arm Firmware Framework for ARMv8-A(FFA) interface driver
	*
	* The Arm FFA specification[1] describes a software architecture to
	* leverages the virtualization extension to isolate software images
	* provided by an ecosystem of vendors from each other and describes
	* interfaces that standardize communication between the various software
	* images including communication between images in the Secure world and
	* Normal world. Any Hypervisor could use the FFA interfaces to enable
	* communication between VMs it manages.
	*
	* The Hypervisor a.k.a Partition managers in FFA terminology can assign
	* system resources(Memory regions, Devices, CPU cycles) to the partitions
	* and manage isolation amongst them.
	*
	* [1] https://developer.arm.com/docs/den0077/latest
	*
	* Copyright (C) 2021 ARM Ltd.
	*/

	#define DRIVER_NAME "ARM FF-A"
	#define pr_fmt(fmt) DRIVER_NAME ": " fmt

	#include <linux/arm_ffa.h>
	#include <linux/bitfield.h>
	#include <linux/device.h>
	#include <linux/io.h>
	#include <linux/kernel.h>
	#include <linux/module.h>
	#include <linux/mm.h>
	#include <linux/scatterlist.h>
	#include <linux/slab.h>
	#include <linux/uuid.h>

	#include "common.h"

	#define FFA_DRIVER_VERSION FFA_VERSION_1_0

	#define FFA_SMC(calling_convention, func_num) \
	ARM_SMCCC_CALL_VAL(ARM_SMCCC_FAST_CALL, (calling_convention), \
	ARM_SMCCC_OWNER_STANDARD, (func_num))

	#define FFA_SMC_32(func_num) FFA_SMC(ARM_SMCCC_SMC_32, (func_num))
	#define FFA_SMC_64(func_num) FFA_SMC(ARM_SMCCC_SMC_64, (func_num))

	#define FFA_ERROR FFA_SMC_32(0x60)
	#define FFA_SUCCESS FFA_SMC_32(0x61)
	#define FFA_INTERRUPT FFA_SMC_32(0x62)
	#define FFA_VERSION FFA_SMC_32(0x63)
	#define FFA_FEATURES FFA_SMC_32(0x64)
	#define FFA_RX_RELEASE FFA_SMC_32(0x65)
	#define FFA_RXTX_MAP FFA_SMC_32(0x66)
	#define FFA_FN64_RXTX_MAP FFA_SMC_64(0x66)
	#define FFA_RXTX_UNMAP FFA_SMC_32(0x67)
	#define FFA_PARTITION_INFO_GET FFA_SMC_32(0x68)
	#define FFA_ID_GET FFA_SMC_32(0x69)
	#define FFA_MSG_POLL FFA_SMC_32(0x6A)
	#define FFA_MSG_WAIT FFA_SMC_32(0x6B)
	#define FFA_YIELD FFA_SMC_32(0x6C)
	#define FFA_RUN FFA_SMC_32(0x6D)
	#define FFA_MSG_SEND FFA_SMC_32(0x6E)
	#define FFA_MSG_SEND_DIRECT_REQ FFA_SMC_32(0x6F)
	#define FFA_FN64_MSG_SEND_DIRECT_REQ FFA_SMC_64(0x6F)
	#define FFA_MSG_SEND_DIRECT_RESP FFA_SMC_32(0x70)
	#define FFA_FN64_MSG_SEND_DIRECT_RESP FFA_SMC_64(0x70)
	#define FFA_MEM_DONATE FFA_SMC_32(0x71)
	#define FFA_FN64_MEM_DONATE FFA_SMC_64(0x71)
	#define FFA_MEM_LEND FFA_SMC_32(0x72)
	#define FFA_FN64_MEM_LEND FFA_SMC_64(0x72)
	#define FFA_MEM_SHARE FFA_SMC_32(0x73)
	#define FFA_FN64_MEM_SHARE FFA_SMC_64(0x73)
	#define FFA_MEM_RETRIEVE_REQ FFA_SMC_32(0x74)
	#define FFA_FN64_MEM_RETRIEVE_REQ FFA_SMC_64(0x74)
	#define FFA_MEM_RETRIEVE_RESP FFA_SMC_32(0x75)
	#define FFA_MEM_RELINQUISH FFA_SMC_32(0x76)
	#define FFA_MEM_RECLAIM FFA_SMC_32(0x77)
	#define FFA_MEM_OP_PAUSE FFA_SMC_32(0x78)
	#define FFA_MEM_OP_RESUME FFA_SMC_32(0x79)
	#define FFA_MEM_FRAG_RX FFA_SMC_32(0x7A)
	#define FFA_MEM_FRAG_TX FFA_SMC_32(0x7B)
	#define FFA_NORMAL_WORLD_RESUME FFA_SMC_32(0x7C)

	/*
	* For some calls it is necessary to use SMC64 to pass or return 64-bit values.
	* For such calls FFA_FN_NATIVE(name) will choose the appropriate
	* (native-width) function ID.
	*/
	#ifdef CONFIG_64BIT
	#define FFA_FN_NATIVE(name) FFA_FN64_##name
	#else
	#define FFA_FN_NATIVE(name) FFA_##name
	#endif

	/* FFA error codes. */
	#define FFA_RET_SUCCESS (0)
	#define FFA_RET_NOT_SUPPORTED (-1)
	#define FFA_RET_INVALID_PARAMETERS (-2)
	#define FFA_RET_NO_MEMORY (-3)
	#define FFA_RET_BUSY (-4)
	#define FFA_RET_INTERRUPTED (-5)
	#define FFA_RET_DENIED (-6)
	#define FFA_RET_RETRY (-7)
	#define FFA_RET_ABORTED (-8)

	#define MAJOR_VERSION_MASK GENMASK(30, 16)
	#define MINOR_VERSION_MASK GENMASK(15, 0)
	#define MAJOR_VERSION(x) ((u16)(FIELD_GET(MAJOR_VERSION_MASK, (x))))
	#define MINOR_VERSION(x) ((u16)(FIELD_GET(MINOR_VERSION_MASK, (x))))
	#define PACK_VERSION_INFO(major, minor) \
	(FIELD_PREP(MAJOR_VERSION_MASK, (major)) \| \
	FIELD_PREP(MINOR_VERSION_MASK, (minor)))
	#define FFA_VERSION_1_0 PACK_VERSION_INFO(1, 0)
	#define FFA_MIN_VERSION FFA_VERSION_1_0

	#define SENDER_ID_MASK GENMASK(31, 16)
	#define RECEIVER_ID_MASK GENMASK(15, 0)
	#define SENDER_ID(x) ((u16)(FIELD_GET(SENDER_ID_MASK, (x))))
	#define RECEIVER_ID(x) ((u16)(FIELD_GET(RECEIVER_ID_MASK, (x))))
	#define PACK_TARGET_INFO(s, r) \
	(FIELD_PREP(SENDER_ID_MASK, (s)) \| FIELD_PREP(RECEIVER_ID_MASK, (r)))

	/*
	* FF-A specification mentions explicitly about '4K pages'. This should
	* not be confused with the kernel PAGE_SIZE, which is the translation
	* granule kernel is configured and may be one among 4K, 16K and 64K.
	*/
	#define FFA_PAGE_SIZE SZ_4K
	/*
	* Keeping RX TX buffer size as 4K for now
	* 64K may be preferred to keep it min a page in 64K PAGE_SIZE config
	*/
	#define RXTX_BUFFER_SIZE SZ_4K

	static ffa_fn *invoke_ffa_fn;

	static const int ffa_linux_errmap[] = {
	/* better than switch case as long as return value is continuous */
	0, /* FFA_RET_SUCCESS */
	-EOPNOTSUPP, /* FFA_RET_NOT_SUPPORTED */
	-EINVAL, /* FFA_RET_INVALID_PARAMETERS */
	-ENOMEM, /* FFA_RET_NO_MEMORY */
	-EBUSY, /* FFA_RET_BUSY */
	-EINTR, /* FFA_RET_INTERRUPTED */
	-EACCES, /* FFA_RET_DENIED */
	-EAGAIN, /* FFA_RET_RETRY */
	-ECANCELED, /* FFA_RET_ABORTED */
	};

	static inline int ffa_to_linux_errno(int errno)
	{
	int err_idx = -errno;

	if (err_idx >= 0 && err_idx < ARRAY_SIZE(ffa_linux_errmap))
	return ffa_linux_errmap[err_idx];
	return -EINVAL;
	}

	struct ffa_drv_info {
	u32 version;
	u16 vm_id;
	struct mutex rx_lock; /* lock to protect Rx buffer */
	struct mutex tx_lock; /* lock to protect Tx buffer */
	void *rx_buffer;
	void *tx_buffer;
	};

	static struct ffa_drv_info *drv_info;

	/*
	* The driver must be able to support all the versions from the earliest
	* supported FFA_MIN_VERSION to the latest supported FFA_DRIVER_VERSION.
	* The specification states that if firmware supports a FFA implementation
	* that is incompatible with and at a greater version number than specified
	* by the caller(FFA_DRIVER_VERSION passed as parameter to FFA_VERSION),
	* it must return the NOT_SUPPORTED error code.
	*/
	static u32 ffa_compatible_version_find(u32 version)
	{
	u16 major = MAJOR_VERSION(version), minor = MINOR_VERSION(version);
	u16 drv_major = MAJOR_VERSION(FFA_DRIVER_VERSION);
	u16 drv_minor = MINOR_VERSION(FFA_DRIVER_VERSION);

	if ((major < drv_major) \|\| (major == drv_major && minor <= drv_minor))
	return version;

	pr_info("Firmware version higher than driver version, downgrading\n");
	return FFA_DRIVER_VERSION;
	}

	static int ffa_version_check(u32 *version)
	{
	ffa_value_t ver;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_VERSION, .a1 = FFA_DRIVER_VERSION,
	}, &ver);

	if (ver.a0 == FFA_RET_NOT_SUPPORTED) {
	pr_info("FFA_VERSION returned not supported\n");
	return -EOPNOTSUPP;
	}

	if (ver.a0 < FFA_MIN_VERSION) {
	pr_err("Incompatible v%d.%d! Earliest supported v%d.%d\n",
	MAJOR_VERSION(ver.a0), MINOR_VERSION(ver.a0),
	MAJOR_VERSION(FFA_MIN_VERSION),
	MINOR_VERSION(FFA_MIN_VERSION));
	return -EINVAL;
	}

	pr_info("Driver version %d.%d\n", MAJOR_VERSION(FFA_DRIVER_VERSION),
	MINOR_VERSION(FFA_DRIVER_VERSION));
	pr_info("Firmware version %d.%d found\n", MAJOR_VERSION(ver.a0),
	MINOR_VERSION(ver.a0));
	*version = ffa_compatible_version_find(ver.a0);

	return 0;
	}

	static int ffa_rx_release(void)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_RX_RELEASE,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	/* check for ret.a0 == FFA_RX_RELEASE ? */

	return 0;
	}

	static int ffa_rxtx_map(phys_addr_t tx_buf, phys_addr_t rx_buf, u32 pg_cnt)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_FN_NATIVE(RXTX_MAP),
	.a1 = tx_buf, .a2 = rx_buf, .a3 = pg_cnt,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	return 0;
	}

	static int ffa_rxtx_unmap(u16 vm_id)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_RXTX_UNMAP, .a1 = PACK_TARGET_INFO(vm_id, 0),
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	return 0;
	}

	/* buffer must be sizeof(struct ffa_partition_info) * num_partitions */
	static int
	__ffa_partition_info_get(u32 uuid0, u32 uuid1, u32 uuid2, u32 uuid3,
	struct ffa_partition_info *buffer, int num_partitions)
	{
	int count;
	ffa_value_t partition_info;

	mutex_lock(&drv_info->rx_lock);
	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_PARTITION_INFO_GET,
	.a1 = uuid0, .a2 = uuid1, .a3 = uuid2, .a4 = uuid3,
	}, &partition_info);

	if (partition_info.a0 == FFA_ERROR) {
	mutex_unlock(&drv_info->rx_lock);
	return ffa_to_linux_errno((int)partition_info.a2);
	}

	count = partition_info.a2;

	if (buffer && count <= num_partitions)
	memcpy(buffer, drv_info->rx_buffer, sizeof(buffer) count);

	ffa_rx_release();

	mutex_unlock(&drv_info->rx_lock);

	return count;
	}

	/* buffer is allocated and caller must free the same if returned count > 0 */
	static int
	ffa_partition_probe(const uuid_t uuid, struct ffa_partition_info *buffer)
	{
	int count;
	u32 uuid0_4[4];
	struct ffa_partition_info *pbuf;

	export_uuid((u8 *)uuid0_4, uuid);
	count = __ffa_partition_info_get(uuid0_4[0], uuid0_4[1], uuid0_4[2],
	uuid0_4[3], NULL, 0);
	if (count <= 0)
	return count;

	pbuf = kcalloc(count, sizeof(*pbuf), GFP_KERNEL);
	if (!pbuf)
	return -ENOMEM;

	count = __ffa_partition_info_get(uuid0_4[0], uuid0_4[1], uuid0_4[2],
	uuid0_4[3], pbuf, count);
	if (count <= 0)
	kfree(pbuf);
	else
	*buffer = pbuf;

	return count;
	}

	#define VM_ID_MASK GENMASK(15, 0)
	static int ffa_id_get(u16 *vm_id)
	{
	ffa_value_t id;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_ID_GET,
	}, &id);

	if (id.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)id.a2);

	*vm_id = FIELD_GET(VM_ID_MASK, (id.a2));

	return 0;
	}

	static int ffa_msg_send_direct_req(u16 src_id, u16 dst_id, bool mode_32bit,
	struct ffa_send_direct_data *data)
	{
	u32 req_id, resp_id, src_dst_ids = PACK_TARGET_INFO(src_id, dst_id);
	ffa_value_t ret;

	if (mode_32bit) {
	req_id = FFA_MSG_SEND_DIRECT_REQ;
	resp_id = FFA_MSG_SEND_DIRECT_RESP;
	} else {
	req_id = FFA_FN_NATIVE(MSG_SEND_DIRECT_REQ);
	resp_id = FFA_FN_NATIVE(MSG_SEND_DIRECT_RESP);
	}

	invoke_ffa_fn((ffa_value_t){
	.a0 = req_id, .a1 = src_dst_ids, .a2 = 0,
	.a3 = data->data0, .a4 = data->data1, .a5 = data->data2,
	.a6 = data->data3, .a7 = data->data4,
	}, &ret);

	while (ret.a0 == FFA_INTERRUPT)
	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_RUN, .a1 = ret.a1,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	if (ret.a0 == resp_id) {
	data->data0 = ret.a3;
	data->data1 = ret.a4;
	data->data2 = ret.a5;
	data->data3 = ret.a6;
	data->data4 = ret.a7;
	return 0;
	}

	return -EINVAL;
	}

	static int ffa_mem_first_frag(u32 func_id, phys_addr_t buf, u32 buf_sz,
	u32 frag_len, u32 len, u64 *handle)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = func_id, .a1 = len, .a2 = frag_len,
	.a3 = buf, .a4 = buf_sz,
	}, &ret);

	while (ret.a0 == FFA_MEM_OP_PAUSE)
	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_MEM_OP_RESUME,
	.a1 = ret.a1, .a2 = ret.a2,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	if (ret.a0 != FFA_SUCCESS)
	return -EOPNOTSUPP;

	if (handle)
	*handle = PACK_HANDLE(ret.a2, ret.a3);

	return frag_len;
	}

	static int ffa_mem_next_frag(u64 handle, u32 frag_len)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_MEM_FRAG_TX,
	.a1 = HANDLE_LOW(handle), .a2 = HANDLE_HIGH(handle),
	.a3 = frag_len,
	}, &ret);

	while (ret.a0 == FFA_MEM_OP_PAUSE)
	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_MEM_OP_RESUME,
	.a1 = ret.a1, .a2 = ret.a2,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	if (ret.a0 != FFA_MEM_FRAG_RX)
	return -EOPNOTSUPP;

	return ret.a3;
	}

	static int
	ffa_transmit_fragment(u32 func_id, phys_addr_t buf, u32 buf_sz, u32 frag_len,
	u32 len, u64 *handle, bool first)
	{
	if (!first)
	return ffa_mem_next_frag(*handle, frag_len);

	return ffa_mem_first_frag(func_id, buf, buf_sz, frag_len, len, handle);
	}

	static u32 ffa_get_num_pages_sg(struct scatterlist *sg)
	{
	u32 num_pages = 0;

	do {
	num_pages += sg->length / FFA_PAGE_SIZE;
	} while ((sg = sg_next(sg)));

	return num_pages;
	}

	static int
	ffa_setup_and_transmit(u32 func_id, void *buffer, u32 max_fragsize,
	struct ffa_mem_ops_args *args)
	{
	int rc = 0;
	bool first = true;
	phys_addr_t addr = 0;
	struct ffa_composite_mem_region *composite;
	struct ffa_mem_region_addr_range *constituents;
	struct ffa_mem_region_attributes *ep_mem_access;
	struct ffa_mem_region *mem_region = buffer;
	u32 idx, frag_len, length, buf_sz = 0, num_entries = sg_nents(args->sg);

	mem_region->tag = args->tag;
	mem_region->flags = args->flags;
	mem_region->sender_id = drv_info->vm_id;
	mem_region->attributes = FFA_MEM_NORMAL \| FFA_MEM_WRITE_BACK \|
	FFA_MEM_INNER_SHAREABLE;
	ep_mem_access = &mem_region->ep_mem_access[0];

	for (idx = 0; idx < args->nattrs; idx++, ep_mem_access++) {
	ep_mem_access->receiver = args->attrs[idx].receiver;
	ep_mem_access->attrs = args->attrs[idx].attrs;
	ep_mem_access->composite_off = COMPOSITE_OFFSET(args->nattrs);
	}
	mem_region->ep_count = args->nattrs;

	composite = buffer + COMPOSITE_OFFSET(args->nattrs);
	composite->total_pg_cnt = ffa_get_num_pages_sg(args->sg);
	composite->addr_range_cnt = num_entries;

	length = COMPOSITE_CONSTITUENTS_OFFSET(args->nattrs, num_entries);
	frag_len = COMPOSITE_CONSTITUENTS_OFFSET(args->nattrs, 0);
	if (frag_len > max_fragsize)
	return -ENXIO;

	if (!args->use_txbuf) {
	addr = virt_to_phys(buffer);
	buf_sz = max_fragsize / FFA_PAGE_SIZE;
	}

	constituents = buffer + frag_len;
	idx = 0;
	do {
	if (frag_len == max_fragsize) {
	rc = ffa_transmit_fragment(func_id, addr, buf_sz,
	frag_len, length,
	&args->g_handle, first);
	if (rc < 0)
	return -ENXIO;

	first = false;
	idx = 0;
	frag_len = 0;
	constituents = buffer;
	}

	if ((void *)constituents - buffer > max_fragsize) {
	pr_err("Memory Region Fragment > Tx Buffer size\n");
	return -EFAULT;
	}

	constituents->address = sg_phys(args->sg);
	constituents->pg_cnt = args->sg->length / FFA_PAGE_SIZE;
	constituents++;
	frag_len += sizeof(struct ffa_mem_region_addr_range);
	} while ((args->sg = sg_next(args->sg)));

	return ffa_transmit_fragment(func_id, addr, buf_sz, frag_len,
	length, &args->g_handle, first);
	}

	static int ffa_memory_ops(u32 func_id, struct ffa_mem_ops_args *args)
	{
	int ret;
	void *buffer;

	if (!args->use_txbuf) {
	buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
	if (!buffer)
	return -ENOMEM;
	} else {
	buffer = drv_info->tx_buffer;
	mutex_lock(&drv_info->tx_lock);
	}

	ret = ffa_setup_and_transmit(func_id, buffer, RXTX_BUFFER_SIZE, args);

	if (args->use_txbuf)
	mutex_unlock(&drv_info->tx_lock);
	else
	free_pages_exact(buffer, RXTX_BUFFER_SIZE);

	return ret < 0 ? ret : 0;
	}

	static int ffa_memory_reclaim(u64 g_handle, u32 flags)
	{
	ffa_value_t ret;

	invoke_ffa_fn((ffa_value_t){
	.a0 = FFA_MEM_RECLAIM,
	.a1 = HANDLE_LOW(g_handle), .a2 = HANDLE_HIGH(g_handle),
	.a3 = flags,
	}, &ret);

	if (ret.a0 == FFA_ERROR)
	return ffa_to_linux_errno((int)ret.a2);

	return 0;
	}

	static u32 ffa_api_version_get(void)
	{
	return drv_info->version;
	}

	static int ffa_partition_info_get(const char *uuid_str,
	struct ffa_partition_info *buffer)
	{
	int count;
	uuid_t uuid;
	struct ffa_partition_info *pbuf;

	if (uuid_parse(uuid_str, &uuid)) {
	pr_err("invalid uuid (%s)\n", uuid_str);
	return -ENODEV;
	}

	count = ffa_partition_probe(&uuid_null, &pbuf);
	if (count <= 0)
	return -ENOENT;

	memcpy(buffer, pbuf, sizeof(pbuf) count);
	kfree(pbuf);
	return 0;
	}

	static void ffa_mode_32bit_set(struct ffa_device *dev)
	{
	dev->mode_32bit = true;
	}

	static int ffa_sync_send_receive(struct ffa_device *dev,
	struct ffa_send_direct_data *data)
	{
	return ffa_msg_send_direct_req(drv_info->vm_id, dev->vm_id,
	dev->mode_32bit, data);
	}

	static int
	ffa_memory_share(struct ffa_device dev, struct ffa_mem_ops_args args)
	{
	if (dev->mode_32bit)
	return ffa_memory_ops(FFA_MEM_SHARE, args);

	return ffa_memory_ops(FFA_FN_NATIVE(MEM_SHARE), args);
	}

	static int
	ffa_memory_lend(struct ffa_device dev, struct ffa_mem_ops_args args)
	{
	/* Note that upon a successful MEM_LEND request the caller
	* must ensure that the memory region specified is not accessed
	* until a successful MEM_RECALIM call has been made.
	* On systems with a hypervisor present this will been enforced,
	* however on systems without a hypervisor the responsibility
	* falls to the calling kernel driver to prevent access.
	*/
	if (dev->mode_32bit)
	return ffa_memory_ops(FFA_MEM_LEND, args);

	return ffa_memory_ops(FFA_FN_NATIVE(MEM_LEND), args);
	}

	static const struct ffa_dev_ops ffa_ops = {
	.api_version_get = ffa_api_version_get,
	.partition_info_get = ffa_partition_info_get,
	.mode_32bit_set = ffa_mode_32bit_set,
	.sync_send_receive = ffa_sync_send_receive,
	.memory_reclaim = ffa_memory_reclaim,
	.memory_share = ffa_memory_share,
	.memory_lend = ffa_memory_lend,
	};

	const struct ffa_dev_ops ffa_dev_ops_get(struct ffa_device dev)
	{
	if (ffa_device_is_valid(dev))
	return &ffa_ops;

	return NULL;
	}
	EXPORT_SYMBOL_GPL(ffa_dev_ops_get);

	void ffa_device_match_uuid(struct ffa_device ffa_dev, const uuid_t uuid)
	{
	int count, idx;
	struct ffa_partition_info pbuf, tpbuf;

	count = ffa_partition_probe(uuid, &pbuf);
	if (count <= 0)
	return;

	for (idx = 0, tpbuf = pbuf; idx < count; idx++, tpbuf++)
	if (tpbuf->id == ffa_dev->vm_id)
	uuid_copy(&ffa_dev->uuid, uuid);
	kfree(pbuf);
	}

	static void ffa_setup_partitions(void)
	{
	int count, idx;
	struct ffa_device *ffa_dev;
	struct ffa_partition_info pbuf, tpbuf;

	count = ffa_partition_probe(&uuid_null, &pbuf);
	if (count <= 0) {
	pr_info("%s: No partitions found, error %d\n", __func__, count);
	return;
	}

	for (idx = 0, tpbuf = pbuf; idx < count; idx++, tpbuf++) {
	/* Note that the &uuid_null parameter will require
	* ffa_device_match() to find the UUID of this partition id
	* with help of ffa_device_match_uuid(). Once the FF-A spec
	* is updated to provide correct UUID here for each partition
	* as part of the discovery API, we need to pass the
	* discovered UUID here instead.
	*/
	ffa_dev = ffa_device_register(&uuid_null, tpbuf->id);
	if (!ffa_dev) {
	pr_err("%s: failed to register partition ID 0x%x\n",
	__func__, tpbuf->id);
	continue;
	}

	ffa_dev_set_drvdata(ffa_dev, drv_info);
	}
	kfree(pbuf);
	}

	static int __init ffa_init(void)
	{
	int ret;

	ret = ffa_transport_init(&invoke_ffa_fn);
	if (ret)
	return ret;

	ret = arm_ffa_bus_init();
	if (ret)
	return ret;

	drv_info = kzalloc(sizeof(*drv_info), GFP_KERNEL);
	if (!drv_info) {
	ret = -ENOMEM;
	goto ffa_bus_exit;
	}

	ret = ffa_version_check(&drv_info->version);
	if (ret)
	goto free_drv_info;

	if (ffa_id_get(&drv_info->vm_id)) {
	pr_err("failed to obtain VM id for self\n");
	ret = -ENODEV;
	goto free_drv_info;
	}

	drv_info->rx_buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
	if (!drv_info->rx_buffer) {
	ret = -ENOMEM;
	goto free_pages;
	}

	drv_info->tx_buffer = alloc_pages_exact(RXTX_BUFFER_SIZE, GFP_KERNEL);
	if (!drv_info->tx_buffer) {
	ret = -ENOMEM;
	goto free_pages;
	}

	ret = ffa_rxtx_map(virt_to_phys(drv_info->tx_buffer),
	virt_to_phys(drv_info->rx_buffer),
	RXTX_BUFFER_SIZE / FFA_PAGE_SIZE);
	if (ret) {
	pr_err("failed to register FFA RxTx buffers\n");
	goto free_pages;
	}

	mutex_init(&drv_info->rx_lock);
	mutex_init(&drv_info->tx_lock);

	ffa_setup_partitions();

	return 0;
	free_pages:
	if (drv_info->tx_buffer)
	free_pages_exact(drv_info->tx_buffer, RXTX_BUFFER_SIZE);
	free_pages_exact(drv_info->rx_buffer, RXTX_BUFFER_SIZE);
	free_drv_info:
	kfree(drv_info);
	ffa_bus_exit:
	arm_ffa_bus_exit();
	return ret;
	}
	subsys_initcall(ffa_init);

	static void __exit ffa_exit(void)
	{
	ffa_rxtx_unmap(drv_info->vm_id);
	free_pages_exact(drv_info->tx_buffer, RXTX_BUFFER_SIZE);
	free_pages_exact(drv_info->rx_buffer, RXTX_BUFFER_SIZE);
	kfree(drv_info);
	arm_ffa_bus_exit();
	}
	module_exit(ffa_exit);

	MODULE_ALIAS("arm-ffa");
	MODULE_AUTHOR("Sudeep Holla <sudeep.holla@arm.com>");
	MODULE_DESCRIPTION("Arm FF-A interface driver");
	MODULE_LICENSE("GPL v2");