drivers/net/ipa/ipa_data.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */

 /* Copyright (c) 2012-2018, The Linux Foundation. All rights reserved.
  * Copyright (C) 2019-2020 Linaro Ltd.
  */
 #ifndef _IPA_DATA_H_
 #define _IPA_DATA_H_

 #include <linux/types.h>

 #include "ipa_version.h"
 #include "ipa_endpoint.h"
 #include "ipa_mem.h"

 /**
  * DOC: IPA/GSI Configuration Data
  *
  * Boot-time configuration data is used to define the configuration of the
  * IPA and GSI resources to use for a given platform.  This data is supplied
  * via the Device Tree match table, associated with a particular compatible
  * string.  The data defines information about resources, endpoints, and
  * channels.
  *
  * Resources are data structures used internally by the IPA hardware.  The
  * configuration data defines the number (or limits of the number) of various
  * types of these resources.
  *
  * Endpoint configuration data defines properties of both IPA endpoints and
  * GSI channels.  A channel is a GSI construct, and represents a single
  * communication path between the IPA and a particular execution environment
  * (EE), such as the AP or Modem.  Each EE has a set of channels associated
  * with it, and each channel has an ID unique for that EE.  For the most part
  * the only GSI channels of concern to this driver belong to the AP
  *
  * An endpoint is an IPA construct representing a single channel anywhere
  * in the system.  An IPA endpoint ID maps directly to an (EE, channel_id)
  * pair.  Generally, this driver is concerned with only endpoints associated
  * with the AP, however this will change when support for routing (etc.) is
  * added.  IPA endpoint and GSI channel configuration data are defined
  * together, establishing the endpoint_id->(EE, channel_id) mapping.
  *
  * Endpoint configuration data consists of three parts:  properties that
  * are common to IPA and GSI (EE ID, channel ID, endpoint ID, and direction);
  * properties associated with the GSI channel; and properties associated with
  * the IPA endpoint.
  */

 /* The maximum value returned by ipa_resource_group_{src,dst}_count() */
 #define IPA_RESOURCE_GROUP_SRC_MAX	5
 #define IPA_RESOURCE_GROUP_DST_MAX	5

 /**
  * struct gsi_channel_data - GSI channel configuration data
  * @tre_count:		number of TREs in the channel ring
  * @event_count:	number of slots in the associated event ring
  * @tlv_count:		number of entries in channel's TLV FIFO
  *
  * A GSI channel is a unidirectional means of transferring data to or
  * from (and through) the IPA.  A GSI channel has a ring buffer made
  * up of "transfer elements" (TREs) that specify individual data transfers
  * or IPA immediate commands.  TREs are filled by the AP, and control
  * is passed to IPA hardware by writing the last written element
  * into a doorbell register.
  *
  * When data transfer commands have completed the GSI generates an
  * event (a structure of data) and optionally signals the AP with
  * an interrupt.  Event structures are implemented by another ring
  * buffer, directed toward the AP from the IPA.
  *
  * The input to a GSI channel is a FIFO of type/length/value (TLV)
  * elements, and the size of this FIFO limits the number of TREs
  * that can be included in a single transaction.
  */
 struct gsi_channel_data {
 	u16 tre_count;
 	u16 event_count;
 	u8 tlv_count;
 };

 /**
  * struct ipa_endpoint_tx_data - configuration data for TX endpoints
  * @status_endpoint:	endpoint to which status elements are sent
  *
  * The @status_endpoint is only valid if the endpoint's @status_enable
  * flag is set.
  */
 struct ipa_endpoint_tx_data {
 	enum ipa_endpoint_name status_endpoint;
 };

 /**
  * struct ipa_endpoint_rx_data - configuration data for RX endpoints
  * @pad_align:	power-of-2 boundary to which packet payload is aligned
  * @aggr_close_eof: whether aggregation closes on end-of-frame
  *
  * With each packet it transfers, the IPA hardware can perform certain
  * transformations of its packet data.  One of these is adding pad bytes
  * to the end of the packet data so the result ends on a power-of-2 boundary.
  *
  * It is also able to aggregate multiple packets into a single receive buffer.
  * Aggregation is "open" while a buffer is being filled, and "closes" when
  * certain criteria are met.  One of those criteria is the sender indicating
  * a "frame" consisting of several transfers has ended.
  */
 struct ipa_endpoint_rx_data {
 	u32 pad_align;
 	bool aggr_close_eof;
 };

 /**
  * struct ipa_endpoint_config_data - IPA endpoint hardware configuration
  * @resource_group:	resource group to assign endpoint to
  * @checksum:		whether checksum offload is enabled
  * @qmap:		whether endpoint uses QMAP protocol
  * @aggregation:	whether endpoint supports aggregation
  * @status_enable:	whether endpoint uses status elements
  * @dma_mode:		whether endpoint operates in DMA mode
  * @dma_endpoint:	peer endpoint, if operating in DMA mode
  * @tx:			TX-specific endpoint information (see above)
  * @rx:			RX-specific endpoint information (see above)
  */
 struct ipa_endpoint_config_data {
 	u32 resource_group;
 	bool checksum;
 	bool qmap;
 	bool aggregation;
 	bool status_enable;
 	bool dma_mode;
 	enum ipa_endpoint_name dma_endpoint;
 	union {
 		struct ipa_endpoint_tx_data tx;
 		struct ipa_endpoint_rx_data rx;
 	};
 };

 /**
  * struct ipa_endpoint_data - IPA endpoint configuration data
  * @filter_support:	whether endpoint supports filtering
  * @seq_type:		hardware sequencer type used for endpoint
  * @config:		hardware configuration (see above)
  *
  * Not all endpoints support the IPA filtering capability.  A filter table
  * defines the filters to apply for those endpoints that support it.  The
  * AP is responsible for initializing this table, and it must include entries
  * for non-AP endpoints.  For this reason we define *all* endpoints used
  * in the system, and indicate whether they support filtering.
  *
  * The remaining endpoint configuration data applies only to AP endpoints.
  * The IPA hardware is implemented by sequencers, and the AP must program
  * the type(s) of these sequencers at initialization time.  The remaining
  * endpoint configuration data is defined above.
  */
 struct ipa_endpoint_data {
 	bool filter_support;
 	/* The next two are specified only for AP endpoints */
 	enum ipa_seq_type seq_type;
 	struct ipa_endpoint_config_data config;
 };

 /**
  * struct ipa_gsi_endpoint_data - GSI channel/IPA endpoint data
  * ee:		GSI execution environment ID
  * channel_id:	GSI channel ID
  * endpoint_id:	IPA endpoint ID
  * toward_ipa:	direction of data transfer
  * gsi:		GSI channel configuration data (see above)
  * ipa:		IPA endpoint configuration data (see above)
  */
 struct ipa_gsi_endpoint_data {
 	u8 ee_id;		/* enum gsi_ee_id */
 	u8 channel_id;
 	u8 endpoint_id;
 	bool toward_ipa;

 	struct gsi_channel_data channel;
 	struct ipa_endpoint_data endpoint;
 };

 /** enum ipa_resource_type_src - source resource types */
 enum ipa_resource_type_src {
 	IPA_RESOURCE_TYPE_SRC_PKT_CONTEXTS,
 	IPA_RESOURCE_TYPE_SRC_DESCRIPTOR_LISTS,
 	IPA_RESOURCE_TYPE_SRC_DESCRIPTOR_BUFF,
 	IPA_RESOURCE_TYPE_SRC_HPS_DMARS,
 	IPA_RESOURCE_TYPE_SRC_ACK_ENTRIES,
 };

 /** enum ipa_resource_type_dst - destination resource types */
 enum ipa_resource_type_dst {
 	IPA_RESOURCE_TYPE_DST_DATA_SECTORS,
 	IPA_RESOURCE_TYPE_DST_DPS_DMARS,
 };

 /**
  * struct ipa_resource_limits - minimum and maximum resource counts
  * @min:	minimum number of resources of a given type
  * @max:	maximum number of resources of a given type
  */
 struct ipa_resource_limits {
 	u32 min;
 	u32 max;
 };

 /**
  * struct ipa_resource_src - source endpoint group resource usage
  * @type:	source group resource type
  * @limits:	array of limits to use for each resource group
  */
 struct ipa_resource_src {
 	enum ipa_resource_type_src type;
 	struct ipa_resource_limits limits[IPA_RESOURCE_GROUP_SRC_MAX];
 };

 /**
  * struct ipa_resource_dst - destination endpoint group resource usage
  * @type:	destination group resource type
  * @limits:	array of limits to use for each resource group
  */
 struct ipa_resource_dst {
 	enum ipa_resource_type_dst type;
 	struct ipa_resource_limits limits[IPA_RESOURCE_GROUP_DST_MAX];
 };

 /**
  * struct ipa_resource_data - IPA resource configuration data
  * @resource_src_count:	number of entries in the resource_src array
  * @resource_src:	source endpoint group resources
  * @resource_dst_count:	number of entries in the resource_dst array
  * @resource_dst:	destination endpoint group resources
  *
  * In order to manage quality of service between endpoints, certain resources
  * required for operation are allocated to groups of endpoints.  Generally
  * this information is invisible to the AP, but the AP is responsible for
  * programming it at initialization time, so we specify it here.
  */
 struct ipa_resource_data {
 	u32 resource_src_count;
 	const struct ipa_resource_src *resource_src;
 	u32 resource_dst_count;
 	const struct ipa_resource_dst *resource_dst;
 };

 /**
  * struct ipa_mem_data - description of IPA memory regions
  * @local_count:	number of regions defined in the local[] array
  * @local:		array of IPA-local memory region descriptors
  * @imem_addr:		physical address of IPA region within IMEM
  * @imem_size:		size in bytes of IPA IMEM region
  * @smem_id:		item identifier for IPA region within SMEM memory
  * @imem_size:		size in bytes of the IPA SMEM region
  */
 struct ipa_mem_data {
 	u32 local_count;
 	const struct ipa_mem *local;
 	u32 imem_addr;
 	u32 imem_size;
 	u32 smem_id;
 	u32 smem_size;
 };

 /**
  * struct ipa_interconnect_data - description of IPA interconnect bandwidths
  * @name:		Interconnect name (matches interconnect-name in DT)
  * @peak_bandwidth:	Peak interconnect bandwidth (in 1000 byte/sec units)
  * @average_bandwidth:	Average interconnect bandwidth (in 1000 byte/sec units)
  */
 struct ipa_interconnect_data {
 	const char *name;
 	u32 peak_bandwidth;
 	u32 average_bandwidth;
 };

 /**
  * struct ipa_clock_data - description of IPA clock and interconnect rates
  * @core_clock_rate:	Core clock rate (Hz)
  * @interconnect_count:	Number of entries in the interconnect_data array
  * @interconnect_data:	IPA interconnect configuration data
  */
 struct ipa_clock_data {
 	u32 core_clock_rate;
 	u32 interconnect_count;		/* # entries in interconnect_data[] */
 	const struct ipa_interconnect_data *interconnect_data;
 };

 /**
  * struct ipa_data - combined IPA/GSI configuration data
  * @version:		IPA hardware version
  * @endpoint_count:	number of entries in endpoint_data array
  * @endpoint_data:	IPA endpoint/GSI channel data
  * @resource_data:	IPA resource configuration data
  * @mem_count:		number of entries in mem_data array
  * @mem_data:		IPA-local shared memory region data
  */
 struct ipa_data {
 	enum ipa_version version;
 	u32 endpoint_count;	/* # entries in endpoint_data[] */
 	const struct ipa_gsi_endpoint_data *endpoint_data;
 	const struct ipa_resource_data *resource_data;
 	const struct ipa_mem_data *mem_data;
 	const struct ipa_clock_data *clock_data;
 };

 extern const struct ipa_data ipa_data_sdm845;
 extern const struct ipa_data ipa_data_sc7180;

 #endif /* _IPA_DATA_H_ */
	/* SPDX-License-Identifier: GPL-2.0 */

	/* Copyright (c) 2012-2018, The Linux Foundation. All rights reserved.
	* Copyright (C) 2019-2020 Linaro Ltd.
	*/
	#ifndef _IPA_DATA_H_
	#define _IPA_DATA_H_

	#include <linux/types.h>

	#include "ipa_version.h"
	#include "ipa_endpoint.h"
	#include "ipa_mem.h"

	/**
	* DOC: IPA/GSI Configuration Data
	*
	* Boot-time configuration data is used to define the configuration of the
	* IPA and GSI resources to use for a given platform. This data is supplied
	* via the Device Tree match table, associated with a particular compatible
	* string. The data defines information about resources, endpoints, and
	* channels.
	*
	* Resources are data structures used internally by the IPA hardware. The
	* configuration data defines the number (or limits of the number) of various
	* types of these resources.
	*
	* Endpoint configuration data defines properties of both IPA endpoints and
	* GSI channels. A channel is a GSI construct, and represents a single
	* communication path between the IPA and a particular execution environment
	* (EE), such as the AP or Modem. Each EE has a set of channels associated
	* with it, and each channel has an ID unique for that EE. For the most part
	* the only GSI channels of concern to this driver belong to the AP
	*
	* An endpoint is an IPA construct representing a single channel anywhere
	* in the system. An IPA endpoint ID maps directly to an (EE, channel_id)
	* pair. Generally, this driver is concerned with only endpoints associated
	* with the AP, however this will change when support for routing (etc.) is
	* added. IPA endpoint and GSI channel configuration data are defined
	* together, establishing the endpoint_id->(EE, channel_id) mapping.
	*
	* Endpoint configuration data consists of three parts: properties that
	* are common to IPA and GSI (EE ID, channel ID, endpoint ID, and direction);
	* properties associated with the GSI channel; and properties associated with
	* the IPA endpoint.
	*/

	/* The maximum value returned by ipa_resource_group_{src,dst}_count() */
	#define IPA_RESOURCE_GROUP_SRC_MAX 5
	#define IPA_RESOURCE_GROUP_DST_MAX 5

	/**
	* struct gsi_channel_data - GSI channel configuration data
	* @tre_count: number of TREs in the channel ring
	* @event_count: number of slots in the associated event ring
	* @tlv_count: number of entries in channel's TLV FIFO
	*
	* A GSI channel is a unidirectional means of transferring data to or
	* from (and through) the IPA. A GSI channel has a ring buffer made
	* up of "transfer elements" (TREs) that specify individual data transfers
	* or IPA immediate commands. TREs are filled by the AP, and control
	* is passed to IPA hardware by writing the last written element
	* into a doorbell register.
	*
	* When data transfer commands have completed the GSI generates an
	* event (a structure of data) and optionally signals the AP with
	* an interrupt. Event structures are implemented by another ring
	* buffer, directed toward the AP from the IPA.
	*
	* The input to a GSI channel is a FIFO of type/length/value (TLV)
	* elements, and the size of this FIFO limits the number of TREs
	* that can be included in a single transaction.
	*/
	struct gsi_channel_data {
	u16 tre_count;
	u16 event_count;
	u8 tlv_count;
	};

	/**
	* struct ipa_endpoint_tx_data - configuration data for TX endpoints
	* @status_endpoint: endpoint to which status elements are sent
	*
	* The @status_endpoint is only valid if the endpoint's @status_enable
	* flag is set.
	*/
	struct ipa_endpoint_tx_data {
	enum ipa_endpoint_name status_endpoint;
	};

	/**
	* struct ipa_endpoint_rx_data - configuration data for RX endpoints
	* @pad_align: power-of-2 boundary to which packet payload is aligned
	* @aggr_close_eof: whether aggregation closes on end-of-frame
	*
	* With each packet it transfers, the IPA hardware can perform certain
	* transformations of its packet data. One of these is adding pad bytes
	* to the end of the packet data so the result ends on a power-of-2 boundary.
	*
	* It is also able to aggregate multiple packets into a single receive buffer.
	* Aggregation is "open" while a buffer is being filled, and "closes" when
	* certain criteria are met. One of those criteria is the sender indicating
	* a "frame" consisting of several transfers has ended.
	*/
	struct ipa_endpoint_rx_data {
	u32 pad_align;
	bool aggr_close_eof;
	};

	/**
	* struct ipa_endpoint_config_data - IPA endpoint hardware configuration
	* @resource_group: resource group to assign endpoint to
	* @checksum: whether checksum offload is enabled
	* @qmap: whether endpoint uses QMAP protocol
	* @aggregation: whether endpoint supports aggregation
	* @status_enable: whether endpoint uses status elements
	* @dma_mode: whether endpoint operates in DMA mode
	* @dma_endpoint: peer endpoint, if operating in DMA mode
	* @tx: TX-specific endpoint information (see above)
	* @rx: RX-specific endpoint information (see above)
	*/
	struct ipa_endpoint_config_data {
	u32 resource_group;
	bool checksum;
	bool qmap;
	bool aggregation;
	bool status_enable;
	bool dma_mode;
	enum ipa_endpoint_name dma_endpoint;
	union {
	struct ipa_endpoint_tx_data tx;
	struct ipa_endpoint_rx_data rx;
	};
	};

	/**
	* struct ipa_endpoint_data - IPA endpoint configuration data
	* @filter_support: whether endpoint supports filtering
	* @seq_type: hardware sequencer type used for endpoint
	* @config: hardware configuration (see above)
	*
	* Not all endpoints support the IPA filtering capability. A filter table
	* defines the filters to apply for those endpoints that support it. The
	* AP is responsible for initializing this table, and it must include entries
	* for non-AP endpoints. For this reason we define all endpoints used
	* in the system, and indicate whether they support filtering.
	*
	* The remaining endpoint configuration data applies only to AP endpoints.
	* The IPA hardware is implemented by sequencers, and the AP must program
	* the type(s) of these sequencers at initialization time. The remaining
	* endpoint configuration data is defined above.
	*/
	struct ipa_endpoint_data {
	bool filter_support;
	/* The next two are specified only for AP endpoints */
	enum ipa_seq_type seq_type;
	struct ipa_endpoint_config_data config;
	};

	/**
	* struct ipa_gsi_endpoint_data - GSI channel/IPA endpoint data
	* ee: GSI execution environment ID
	* channel_id: GSI channel ID
	* endpoint_id: IPA endpoint ID
	* toward_ipa: direction of data transfer
	* gsi: GSI channel configuration data (see above)
	* ipa: IPA endpoint configuration data (see above)
	*/
	struct ipa_gsi_endpoint_data {
	u8 ee_id; /* enum gsi_ee_id */
	u8 channel_id;
	u8 endpoint_id;
	bool toward_ipa;

	struct gsi_channel_data channel;
	struct ipa_endpoint_data endpoint;
	};

	/** enum ipa_resource_type_src - source resource types */
	enum ipa_resource_type_src {
	IPA_RESOURCE_TYPE_SRC_PKT_CONTEXTS,
	IPA_RESOURCE_TYPE_SRC_DESCRIPTOR_LISTS,
	IPA_RESOURCE_TYPE_SRC_DESCRIPTOR_BUFF,
	IPA_RESOURCE_TYPE_SRC_HPS_DMARS,
	IPA_RESOURCE_TYPE_SRC_ACK_ENTRIES,
	};

	/** enum ipa_resource_type_dst - destination resource types */
	enum ipa_resource_type_dst {
	IPA_RESOURCE_TYPE_DST_DATA_SECTORS,
	IPA_RESOURCE_TYPE_DST_DPS_DMARS,
	};

	/**
	* struct ipa_resource_limits - minimum and maximum resource counts
	* @min: minimum number of resources of a given type
	* @max: maximum number of resources of a given type
	*/
	struct ipa_resource_limits {
	u32 min;
	u32 max;
	};

	/**
	* struct ipa_resource_src - source endpoint group resource usage
	* @type: source group resource type
	* @limits: array of limits to use for each resource group
	*/
	struct ipa_resource_src {
	enum ipa_resource_type_src type;
	struct ipa_resource_limits limits[IPA_RESOURCE_GROUP_SRC_MAX];
	};

	/**
	* struct ipa_resource_dst - destination endpoint group resource usage
	* @type: destination group resource type
	* @limits: array of limits to use for each resource group
	*/
	struct ipa_resource_dst {
	enum ipa_resource_type_dst type;
	struct ipa_resource_limits limits[IPA_RESOURCE_GROUP_DST_MAX];
	};

	/**
	* struct ipa_resource_data - IPA resource configuration data
	* @resource_src_count: number of entries in the resource_src array
	* @resource_src: source endpoint group resources
	* @resource_dst_count: number of entries in the resource_dst array
	* @resource_dst: destination endpoint group resources
	*
	* In order to manage quality of service between endpoints, certain resources
	* required for operation are allocated to groups of endpoints. Generally
	* this information is invisible to the AP, but the AP is responsible for
	* programming it at initialization time, so we specify it here.
	*/
	struct ipa_resource_data {
	u32 resource_src_count;
	const struct ipa_resource_src *resource_src;
	u32 resource_dst_count;
	const struct ipa_resource_dst *resource_dst;
	};

	/**
	* struct ipa_mem_data - description of IPA memory regions
	* @local_count: number of regions defined in the local[] array
	* @local: array of IPA-local memory region descriptors
	* @imem_addr: physical address of IPA region within IMEM
	* @imem_size: size in bytes of IPA IMEM region
	* @smem_id: item identifier for IPA region within SMEM memory
	* @imem_size: size in bytes of the IPA SMEM region
	*/
	struct ipa_mem_data {
	u32 local_count;
	const struct ipa_mem *local;
	u32 imem_addr;
	u32 imem_size;
	u32 smem_id;
	u32 smem_size;
	};

	/**
	* struct ipa_interconnect_data - description of IPA interconnect bandwidths
	* @name: Interconnect name (matches interconnect-name in DT)
	* @peak_bandwidth: Peak interconnect bandwidth (in 1000 byte/sec units)
	* @average_bandwidth: Average interconnect bandwidth (in 1000 byte/sec units)
	*/
	struct ipa_interconnect_data {
	const char *name;
	u32 peak_bandwidth;
	u32 average_bandwidth;
	};

	/**
	* struct ipa_clock_data - description of IPA clock and interconnect rates
	* @core_clock_rate: Core clock rate (Hz)
	* @interconnect_count: Number of entries in the interconnect_data array
	* @interconnect_data: IPA interconnect configuration data
	*/
	struct ipa_clock_data {
	u32 core_clock_rate;
	u32 interconnect_count; /* # entries in interconnect_data[] */
	const struct ipa_interconnect_data *interconnect_data;
	};

	/**
	* struct ipa_data - combined IPA/GSI configuration data
	* @version: IPA hardware version
	* @endpoint_count: number of entries in endpoint_data array
	* @endpoint_data: IPA endpoint/GSI channel data
	* @resource_data: IPA resource configuration data
	* @mem_count: number of entries in mem_data array
	* @mem_data: IPA-local shared memory region data
	*/
	struct ipa_data {
	enum ipa_version version;
	u32 endpoint_count; /* # entries in endpoint_data[] */
	const struct ipa_gsi_endpoint_data *endpoint_data;
	const struct ipa_resource_data *resource_data;
	const struct ipa_mem_data *mem_data;
	const struct ipa_clock_data *clock_data;
	};

	extern const struct ipa_data ipa_data_sdm845;
	extern const struct ipa_data ipa_data_sc7180;

	#endif /* _IPA_DATA_H_ */