Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Alex Elder | 314 | 100.00% | 5 | 100.00% |
Total | 314 | 5 |
/* 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_count() */ #define IPA_RESOURCE_GROUP_COUNT 4 /** enum ipa_resource_type_src - source resource types */ /** * 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 * @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 { 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_COUNT]; }; /** * 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_COUNT]; }; /** * 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 - 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_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; }; extern const struct ipa_data ipa_data_sdm845; extern const struct ipa_data ipa_data_sc7180; #endif /* _IPA_DATA_H_ */
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