/********************************************************************** * Author: Cavium, Inc. * * Contact: support@cavium.com * Please include "LiquidIO" in the subject. * * Copyright (c) 2003-2016 Cavium, Inc. * * This file is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License, Version 2, as * published by the Free Software Foundation. * * This file is distributed in the hope that it will be useful, but * AS-IS and WITHOUT ANY WARRANTY; without even the implied warranty * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE, TITLE, or * NONINFRINGEMENT. See the GNU General Public License for more details. ***********************************************************************/ /*! \file octeon_droq.h * \brief Implementation of Octeon Output queues. "Output" is with * respect to the Octeon device on the NIC. From this driver's point of * view they are ingress queues. */ #ifndef __OCTEON_DROQ_H__ #define __OCTEON_DROQ_H__ /* Default number of packets that will be processed in one iteration. */ #define MAX_PACKET_BUDGET 0xFFFFFFFF /** Octeon descriptor format. * The descriptor ring is made of descriptors which have 2 64-bit values: * -# Physical (bus) address of the data buffer. * -# Physical (bus) address of a octeon_droq_info structure. * The Octeon device DMA's incoming packets and its information at the address * given by these descriptor fields. */ struct octeon_droq_desc { /** The buffer pointer */ u64 buffer_ptr; /** The Info pointer */ u64 info_ptr; }; #define OCT_DROQ_DESC_SIZE (sizeof(struct octeon_droq_desc)) /** Information about packet DMA'ed by Octeon. * The format of the information available at Info Pointer after Octeon * has posted a packet. Not all descriptors have valid information. Only * the Info field of the first descriptor for a packet has information * about the packet. */ struct octeon_droq_info { /** The Length of the packet. */ u64 length; /** The Output Receive Header. */ union octeon_rh rh; }; #define OCT_DROQ_INFO_SIZE (sizeof(struct octeon_droq_info)) struct octeon_skb_page_info { /* DMA address for the page */ dma_addr_t dma; /* Page for the rx dma **/ struct page *page; /** which offset into page */ unsigned int page_offset; }; /** Pointer to data buffer. * Driver keeps a pointer to the data buffer that it made available to * the Octeon device. Since the descriptor ring keeps physical (bus) * addresses, this field is required for the driver to keep track of * the virtual address pointers. */ struct octeon_recv_buffer { /** Packet buffer, including metadata. */ void *buffer; /** Data in the packet buffer. */ u8 *data; /** pg_info **/ struct octeon_skb_page_info pg_info; }; #define OCT_DROQ_RECVBUF_SIZE (sizeof(struct octeon_recv_buffer)) /** Output Queue statistics. Each output queue has four stats fields. */ struct oct_droq_stats { /** Number of packets received in this queue. */ u64 pkts_received; /** Bytes received by this queue. */ u64 bytes_received; /** Packets dropped due to no dispatch function. */ u64 dropped_nodispatch; /** Packets dropped due to no memory available. */ u64 dropped_nomem; /** Packets dropped due to large number of pkts to process. */ u64 dropped_toomany; /** Number of packets sent to stack from this queue. */ u64 rx_pkts_received; /** Number of Bytes sent to stack from this queue. */ u64 rx_bytes_received; /** Num of Packets dropped due to receive path failures. */ u64 rx_dropped; u64 rx_vxlan; /** Num of failures of recv_buffer_alloc() */ u64 rx_alloc_failure; }; /* The maximum number of buffers that can be dispatched from the * output/dma queue. Set to 64 assuming 1K buffers in DROQ and the fact that * max packet size from DROQ is 64K. */ #define MAX_RECV_BUFS 64 /** Receive Packet format used when dispatching output queue packets * with non-raw opcodes. * The received packet will be sent to the upper layers using this * structure which is passed as a parameter to the dispatch function */ struct octeon_recv_pkt { /** Number of buffers in this received packet */ u16 buffer_count; /** Id of the device that is sending the packet up */ u16 octeon_id; /** Length of data in the packet buffer */ u32 length; /** The receive header */ union octeon_rh rh; /** Pointer to the OS-specific packet buffer */ void *buffer_ptr[MAX_RECV_BUFS]; /** Size of the buffers pointed to by ptr's in buffer_ptr */ u32 buffer_size[MAX_RECV_BUFS]; }; #define OCT_RECV_PKT_SIZE (sizeof(struct octeon_recv_pkt)) /** The first parameter of a dispatch function. * For a raw mode opcode, the driver dispatches with the device * pointer in this structure. * For non-raw mode opcode, the driver dispatches the recv_pkt * created to contain the buffers with data received from Octeon. * --------------------- * | *recv_pkt ----|--- * |-------------------| | * | 0 or more bytes | | * | reserved by driver| | * |-------------------|<-/ * | octeon_recv_pkt | * | | * |___________________| */ struct octeon_recv_info { void *rsvd; struct octeon_recv_pkt *recv_pkt; }; #define OCT_RECV_INFO_SIZE (sizeof(struct octeon_recv_info)) /** Allocate a recv_info structure. The recv_pkt pointer in the recv_info * structure is filled in before this call returns. * @param extra_bytes - extra bytes to be allocated at the end of the recv info * structure. * @return - pointer to a newly allocated recv_info structure. */ static inline struct octeon_recv_info *octeon_alloc_recv_info(int extra_bytes) { struct octeon_recv_info *recv_info; u8 *buf; buf = kmalloc(OCT_RECV_PKT_SIZE + OCT_RECV_INFO_SIZE + extra_bytes, GFP_ATOMIC); if (!buf) return NULL; recv_info = (struct octeon_recv_info *)buf; recv_info->recv_pkt = (struct octeon_recv_pkt *)(buf + OCT_RECV_INFO_SIZE); recv_info->rsvd = NULL; if (extra_bytes) recv_info->rsvd = buf + OCT_RECV_INFO_SIZE + OCT_RECV_PKT_SIZE; return recv_info; } /** Free a recv_info structure. * @param recv_info - Pointer to receive_info to be freed */ static inline void octeon_free_recv_info(struct octeon_recv_info *recv_info) { kfree(recv_info); } typedef int (*octeon_dispatch_fn_t)(struct octeon_recv_info *, void *); /** Used by NIC module to register packet handler and to get device * information for each octeon device. */ struct octeon_droq_ops { /** This registered function will be called by the driver with * the octeon id, pointer to buffer from droq and length of * data in the buffer. The receive header gives the port * number to the caller. Function pointer is set by caller. */ void (*fptr)(u32, void *, u32, union octeon_rh *, void *, void *); void *farg; /* This function will be called by the driver for all NAPI related * events. The first param is the octeon id. The second param is the * output queue number. The third is the NAPI event that occurred. */ void (*napi_fn)(void *); u32 poll_mode; /** Flag indicating if the DROQ handler should drop packets that * it cannot handle in one iteration. Set by caller. */ u32 drop_on_max; }; /** The Descriptor Ring Output Queue structure. * This structure has all the information required to implement a * Octeon DROQ. */ struct octeon_droq { u32 q_no; u32 pkt_count; struct octeon_droq_ops ops; struct octeon_device *oct_dev; /** The 8B aligned descriptor ring starts at this address. */ struct octeon_droq_desc *desc_ring; /** Index in the ring where the driver should read the next packet */ u32 read_idx; /** Index in the ring where Octeon will write the next packet */ u32 write_idx; /** Index in the ring where the driver will refill the descriptor's * buffer */ u32 refill_idx; /** Packets pending to be processed */ atomic_t pkts_pending; /** Number of descriptors in this ring. */ u32 max_count; /** The number of descriptors pending refill. */ u32 refill_count; u32 pkts_per_intr; u32 refill_threshold; /** The max number of descriptors in DROQ without a buffer. * This field is used to keep track of empty space threshold. If the * refill_count reaches this value, the DROQ cannot accept a max-sized * (64K) packet. */ u32 max_empty_descs; /** The receive buffer list. This list has the virtual addresses of the * buffers. */ struct octeon_recv_buffer *recv_buf_list; /** The size of each buffer pointed by the buffer pointer. */ u32 buffer_size; /** Pointer to the mapped packet credit register. * Host writes number of info/buffer ptrs available to this register */ void __iomem *pkts_credit_reg; /** Pointer to the mapped packet sent register. * Octeon writes the number of packets DMA'ed to host memory * in this register. */ void __iomem *pkts_sent_reg; struct list_head dispatch_list; /** Statistics for this DROQ. */ struct oct_droq_stats stats; /** DMA mapped address of the DROQ descriptor ring. */ size_t desc_ring_dma; /** application context */ void *app_ctx; struct napi_struct napi; u32 cpu_id; call_single_data_t csd; }; #define OCT_DROQ_SIZE (sizeof(struct octeon_droq)) /** * Allocates space for the descriptor ring for the droq and sets the * base addr, num desc etc in Octeon registers. * * @param oct_dev - pointer to the octeon device structure * @param q_no - droq no. ranges from 0 - 3. * @param app_ctx - pointer to application context * @return Success: 0 Failure: 1 */ int octeon_init_droq(struct octeon_device *oct_dev, u32 q_no, u32 num_descs, u32 desc_size, void *app_ctx); /** * Frees the space for descriptor ring for the droq. * * @param oct_dev - pointer to the octeon device structure * @param q_no - droq no. ranges from 0 - 3. * @return: Success: 0 Failure: 1 */ int octeon_delete_droq(struct octeon_device *oct_dev, u32 q_no); /** Register a change in droq operations. The ops field has a pointer to a * function which will called by the DROQ handler for all packets arriving * on output queues given by q_no irrespective of the type of packet. * The ops field also has a flag which if set tells the DROQ handler to * drop packets if it receives more than what it can process in one * invocation of the handler. * @param oct - octeon device * @param q_no - octeon output queue number (0 <= q_no <= MAX_OCTEON_DROQ-1 * @param ops - the droq_ops settings for this queue * @return - 0 on success, -ENODEV or -EINVAL on error. */ int octeon_register_droq_ops(struct octeon_device *oct, u32 q_no, struct octeon_droq_ops *ops); /** Resets the function pointer and flag settings made by * octeon_register_droq_ops(). After this routine is called, the DROQ handler * will lookup dispatch function for each arriving packet on the output queue * given by q_no. * @param oct - octeon device * @param q_no - octeon output queue number (0 <= q_no <= MAX_OCTEON_DROQ-1 * @return - 0 on success, -ENODEV or -EINVAL on error. */ int octeon_unregister_droq_ops(struct octeon_device *oct, u32 q_no); /** Register a dispatch function for a opcode/subcode. The driver will call * this dispatch function when it receives a packet with the given * opcode/subcode in its output queues along with the user specified * argument. * @param oct - the octeon device to register with. * @param opcode - the opcode for which the dispatch will be registered. * @param subcode - the subcode for which the dispatch will be registered * @param fn - the dispatch function. * @param fn_arg - user specified that will be passed along with the * dispatch function by the driver. * @return Success: 0; Failure: 1 */ int octeon_register_dispatch_fn(struct octeon_device *oct, u16 opcode, u16 subcode, octeon_dispatch_fn_t fn, void *fn_arg); void *octeon_get_dispatch_arg(struct octeon_device *oct, u16 opcode, u16 subcode); u32 octeon_droq_check_hw_for_pkts(struct octeon_droq *droq); int octeon_create_droq(struct octeon_device *oct, u32 q_no, u32 num_descs, u32 desc_size, void *app_ctx); int octeon_droq_process_packets(struct octeon_device *oct, struct octeon_droq *droq, u32 budget); int octeon_droq_process_poll_pkts(struct octeon_device *oct, struct octeon_droq *droq, u32 budget); int octeon_enable_irq(struct octeon_device *oct, u32 q_no); int octeon_retry_droq_refill(struct octeon_droq *droq); #endif /*__OCTEON_DROQ_H__ */