Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Ivo van Doorn | 804 | 82.55% | 36 | 49.32% |
Helmut Schaa | 44 | 4.52% | 10 | 13.70% |
Johannes Berg | 37 | 3.80% | 6 | 8.22% |
Gertjan van Wingerde | 34 | 3.49% | 7 | 9.59% |
Stanislaw Gruszka | 19 | 1.95% | 4 | 5.48% |
Johannes Stezenbach | 11 | 1.13% | 1 | 1.37% |
Arnd Bergmann | 10 | 1.03% | 1 | 1.37% |
Stanislaw W. Gruszka | 5 | 0.51% | 1 | 1.37% |
John W. Linville | 2 | 0.21% | 2 | 2.74% |
Benoit Papillault | 2 | 0.21% | 1 | 1.37% |
Lucas De Marchi | 2 | 0.21% | 1 | 1.37% |
Thomas Gleixner | 2 | 0.21% | 1 | 1.37% |
Joe Perches | 1 | 0.10% | 1 | 1.37% |
Luis Correia | 1 | 0.10% | 1 | 1.37% |
Total | 974 | 73 |
/* SPDX-License-Identifier: GPL-2.0-or-later */ /* Copyright (C) 2004 - 2010 Ivo van Doorn <IvDoorn@gmail.com> <http://rt2x00.serialmonkey.com> */ /* Module: rt2x00 Abstract: rt2x00 queue datastructures and routines */ #ifndef RT2X00QUEUE_H #define RT2X00QUEUE_H #include <linux/prefetch.h> /** * DOC: Entry frame size * * Ralink PCI devices demand the Frame size to be a multiple of 128 bytes, * for USB devices this restriction does not apply, but the value of * 2432 makes sense since it is big enough to contain the maximum fragment * size according to the ieee802.11 specs. * The aggregation size depends on support from the driver, but should * be something around 3840 bytes. */ #define DATA_FRAME_SIZE 2432 #define MGMT_FRAME_SIZE 256 #define AGGREGATION_SIZE 3840 /** * enum data_queue_qid: Queue identification * * @QID_AC_VO: AC VO queue * @QID_AC_VI: AC VI queue * @QID_AC_BE: AC BE queue * @QID_AC_BK: AC BK queue * @QID_HCCA: HCCA queue * @QID_MGMT: MGMT queue (prio queue) * @QID_RX: RX queue * @QID_OTHER: None of the above (don't use, only present for completeness) * @QID_BEACON: Beacon queue (value unspecified, don't send it to device) * @QID_ATIM: Atim queue (value unspecified, don't send it to device) */ enum data_queue_qid { QID_AC_VO = 0, QID_AC_VI = 1, QID_AC_BE = 2, QID_AC_BK = 3, QID_HCCA = 4, QID_MGMT = 13, QID_RX = 14, QID_OTHER = 15, QID_BEACON, QID_ATIM, }; /** * enum skb_frame_desc_flags: Flags for &struct skb_frame_desc * * @SKBDESC_DMA_MAPPED_RX: &skb_dma field has been mapped for RX * @SKBDESC_DMA_MAPPED_TX: &skb_dma field has been mapped for TX * @SKBDESC_IV_STRIPPED: Frame contained a IV/EIV provided by * mac80211 but was stripped for processing by the driver. * @SKBDESC_NOT_MAC80211: Frame didn't originate from mac80211, * don't try to pass it back. * @SKBDESC_DESC_IN_SKB: The descriptor is at the start of the * skb, instead of in the desc field. */ enum skb_frame_desc_flags { SKBDESC_DMA_MAPPED_RX = 1 << 0, SKBDESC_DMA_MAPPED_TX = 1 << 1, SKBDESC_IV_STRIPPED = 1 << 2, SKBDESC_NOT_MAC80211 = 1 << 3, SKBDESC_DESC_IN_SKB = 1 << 4, }; /** * struct skb_frame_desc: Descriptor information for the skb buffer * * This structure is placed over the driver_data array, this means that * this structure should not exceed the size of that array (40 bytes). * * @flags: Frame flags, see &enum skb_frame_desc_flags. * @desc_len: Length of the frame descriptor. * @tx_rate_idx: the index of the TX rate, used for TX status reporting * @tx_rate_flags: the TX rate flags, used for TX status reporting * @desc: Pointer to descriptor part of the frame. * Note that this pointer could point to something outside * of the scope of the skb->data pointer. * @iv: IV/EIV data used during encryption/decryption. * @skb_dma: (PCI-only) the DMA address associated with the sk buffer. * @sta: The station where sk buffer was sent. */ struct skb_frame_desc { u8 flags; u8 desc_len; u8 tx_rate_idx; u8 tx_rate_flags; void *desc; __le32 iv[2]; dma_addr_t skb_dma; struct ieee80211_sta *sta; }; /** * get_skb_frame_desc - Obtain the rt2x00 frame descriptor from a sk_buff. * @skb: &struct sk_buff from where we obtain the &struct skb_frame_desc */ static inline struct skb_frame_desc* get_skb_frame_desc(struct sk_buff *skb) { BUILD_BUG_ON(sizeof(struct skb_frame_desc) > IEEE80211_TX_INFO_DRIVER_DATA_SIZE); return (struct skb_frame_desc *)&IEEE80211_SKB_CB(skb)->driver_data; } /** * enum rxdone_entry_desc_flags: Flags for &struct rxdone_entry_desc * * @RXDONE_SIGNAL_PLCP: Signal field contains the plcp value. * @RXDONE_SIGNAL_BITRATE: Signal field contains the bitrate value. * @RXDONE_SIGNAL_MCS: Signal field contains the mcs value. * @RXDONE_MY_BSS: Does this frame originate from device's BSS. * @RXDONE_CRYPTO_IV: Driver provided IV/EIV data. * @RXDONE_CRYPTO_ICV: Driver provided ICV data. * @RXDONE_L2PAD: 802.11 payload has been padded to 4-byte boundary. */ enum rxdone_entry_desc_flags { RXDONE_SIGNAL_PLCP = BIT(0), RXDONE_SIGNAL_BITRATE = BIT(1), RXDONE_SIGNAL_MCS = BIT(2), RXDONE_MY_BSS = BIT(3), RXDONE_CRYPTO_IV = BIT(4), RXDONE_CRYPTO_ICV = BIT(5), RXDONE_L2PAD = BIT(6), }; /** * RXDONE_SIGNAL_MASK - Define to mask off all &rxdone_entry_desc_flags flags * except for the RXDONE_SIGNAL_* flags. This is useful to convert the dev_flags * from &rxdone_entry_desc to a signal value type. */ #define RXDONE_SIGNAL_MASK \ ( RXDONE_SIGNAL_PLCP | RXDONE_SIGNAL_BITRATE | RXDONE_SIGNAL_MCS ) /** * struct rxdone_entry_desc: RX Entry descriptor * * Summary of information that has been read from the RX frame descriptor. * * @timestamp: RX Timestamp * @signal: Signal of the received frame. * @rssi: RSSI of the received frame. * @size: Data size of the received frame. * @flags: MAC80211 receive flags (See &enum mac80211_rx_flags). * @dev_flags: Ralink receive flags (See &enum rxdone_entry_desc_flags). * @rate_mode: Rate mode (See @enum rate_modulation). * @cipher: Cipher type used during decryption. * @cipher_status: Decryption status. * @iv: IV/EIV data used during decryption. * @icv: ICV data used during decryption. */ struct rxdone_entry_desc { u64 timestamp; int signal; int rssi; int size; int flags; int dev_flags; u16 rate_mode; u16 enc_flags; enum mac80211_rx_encoding encoding; enum rate_info_bw bw; u8 cipher; u8 cipher_status; __le32 iv[2]; __le32 icv; }; /** * enum txdone_entry_desc_flags: Flags for &struct txdone_entry_desc * * Every txdone report has to contain the basic result of the * transmission, either &TXDONE_UNKNOWN, &TXDONE_SUCCESS or * &TXDONE_FAILURE. The flag &TXDONE_FALLBACK can be used in * conjunction with all of these flags but should only be set * if retires > 0. The flag &TXDONE_EXCESSIVE_RETRY can only be used * in conjunction with &TXDONE_FAILURE. * * @TXDONE_UNKNOWN: Hardware could not determine success of transmission. * @TXDONE_SUCCESS: Frame was successfully send * @TXDONE_FALLBACK: Hardware used fallback rates for retries * @TXDONE_FAILURE: Frame was not successfully send * @TXDONE_EXCESSIVE_RETRY: In addition to &TXDONE_FAILURE, the * frame transmission failed due to excessive retries. */ enum txdone_entry_desc_flags { TXDONE_UNKNOWN, TXDONE_SUCCESS, TXDONE_FALLBACK, TXDONE_FAILURE, TXDONE_EXCESSIVE_RETRY, TXDONE_AMPDU, TXDONE_NO_ACK_REQ, }; /** * struct txdone_entry_desc: TX done entry descriptor * * Summary of information that has been read from the TX frame descriptor * after the device is done with transmission. * * @flags: TX done flags (See &enum txdone_entry_desc_flags). * @retry: Retry count. */ struct txdone_entry_desc { unsigned long flags; int retry; }; /** * enum txentry_desc_flags: Status flags for TX entry descriptor * * @ENTRY_TXD_RTS_FRAME: This frame is a RTS frame. * @ENTRY_TXD_CTS_FRAME: This frame is a CTS-to-self frame. * @ENTRY_TXD_GENERATE_SEQ: This frame requires sequence counter. * @ENTRY_TXD_FIRST_FRAGMENT: This is the first frame. * @ENTRY_TXD_MORE_FRAG: This frame is followed by another fragment. * @ENTRY_TXD_REQ_TIMESTAMP: Require timestamp to be inserted. * @ENTRY_TXD_BURST: This frame belongs to the same burst event. * @ENTRY_TXD_ACK: An ACK is required for this frame. * @ENTRY_TXD_RETRY_MODE: When set, the long retry count is used. * @ENTRY_TXD_ENCRYPT: This frame should be encrypted. * @ENTRY_TXD_ENCRYPT_PAIRWISE: Use pairwise key table (instead of shared). * @ENTRY_TXD_ENCRYPT_IV: Generate IV/EIV in hardware. * @ENTRY_TXD_ENCRYPT_MMIC: Generate MIC in hardware. * @ENTRY_TXD_HT_AMPDU: This frame is part of an AMPDU. * @ENTRY_TXD_HT_BW_40: Use 40MHz Bandwidth. * @ENTRY_TXD_HT_SHORT_GI: Use short GI. * @ENTRY_TXD_HT_MIMO_PS: The receiving STA is in dynamic SM PS mode. */ enum txentry_desc_flags { ENTRY_TXD_RTS_FRAME, ENTRY_TXD_CTS_FRAME, ENTRY_TXD_GENERATE_SEQ, ENTRY_TXD_FIRST_FRAGMENT, ENTRY_TXD_MORE_FRAG, ENTRY_TXD_REQ_TIMESTAMP, ENTRY_TXD_BURST, ENTRY_TXD_ACK, ENTRY_TXD_RETRY_MODE, ENTRY_TXD_ENCRYPT, ENTRY_TXD_ENCRYPT_PAIRWISE, ENTRY_TXD_ENCRYPT_IV, ENTRY_TXD_ENCRYPT_MMIC, ENTRY_TXD_HT_AMPDU, ENTRY_TXD_HT_BW_40, ENTRY_TXD_HT_SHORT_GI, ENTRY_TXD_HT_MIMO_PS, }; /** * struct txentry_desc: TX Entry descriptor * * Summary of information for the frame descriptor before sending a TX frame. * * @flags: Descriptor flags (See &enum queue_entry_flags). * @length: Length of the entire frame. * @header_length: Length of 802.11 header. * @length_high: PLCP length high word. * @length_low: PLCP length low word. * @signal: PLCP signal. * @service: PLCP service. * @msc: MCS. * @stbc: Use Space Time Block Coding (only available for MCS rates < 8). * @ba_size: Size of the recepients RX reorder buffer - 1. * @rate_mode: Rate mode (See @enum rate_modulation). * @mpdu_density: MDPU density. * @retry_limit: Max number of retries. * @ifs: IFS value. * @txop: IFS value for 11n capable chips. * @cipher: Cipher type used for encryption. * @key_idx: Key index used for encryption. * @iv_offset: Position where IV should be inserted by hardware. * @iv_len: Length of IV data. */ struct txentry_desc { unsigned long flags; u16 length; u16 header_length; union { struct { u16 length_high; u16 length_low; u16 signal; u16 service; enum ifs ifs; } plcp; struct { u16 mcs; u8 stbc; u8 ba_size; u8 mpdu_density; enum txop txop; int wcid; } ht; } u; enum rate_modulation rate_mode; short retry_limit; enum cipher cipher; u16 key_idx; u16 iv_offset; u16 iv_len; }; /** * enum queue_entry_flags: Status flags for queue entry * * @ENTRY_BCN_ASSIGNED: This entry has been assigned to an interface. * As long as this bit is set, this entry may only be touched * through the interface structure. * @ENTRY_OWNER_DEVICE_DATA: This entry is owned by the device for data * transfer (either TX or RX depending on the queue). The entry should * only be touched after the device has signaled it is done with it. * @ENTRY_DATA_PENDING: This entry contains a valid frame and is waiting * for the signal to start sending. * @ENTRY_DATA_IO_FAILED: Hardware indicated that an IO error occurred * while transferring the data to the hardware. No TX status report will * be expected from the hardware. * @ENTRY_DATA_STATUS_PENDING: The entry has been send to the device and * returned. It is now waiting for the status reporting before the * entry can be reused again. */ enum queue_entry_flags { ENTRY_BCN_ASSIGNED, ENTRY_BCN_ENABLED, ENTRY_OWNER_DEVICE_DATA, ENTRY_DATA_PENDING, ENTRY_DATA_IO_FAILED, ENTRY_DATA_STATUS_PENDING, }; /** * struct queue_entry: Entry inside the &struct data_queue * * @flags: Entry flags, see &enum queue_entry_flags. * @last_action: Timestamp of last change. * @queue: The data queue (&struct data_queue) to which this entry belongs. * @skb: The buffer which is currently being transmitted (for TX queue), * or used to directly receive data in (for RX queue). * @entry_idx: The entry index number. * @priv_data: Private data belonging to this queue entry. The pointer * points to data specific to a particular driver and queue type. * @status: Device specific status */ struct queue_entry { unsigned long flags; unsigned long last_action; struct data_queue *queue; struct sk_buff *skb; unsigned int entry_idx; void *priv_data; }; /** * enum queue_index: Queue index type * * @Q_INDEX: Index pointer to the current entry in the queue, if this entry is * owned by the hardware then the queue is considered to be full. * @Q_INDEX_DMA_DONE: Index pointer for the next entry which will have been * transferred to the hardware. * @Q_INDEX_DONE: Index pointer to the next entry which will be completed by * the hardware and for which we need to run the txdone handler. If this * entry is not owned by the hardware the queue is considered to be empty. * @Q_INDEX_MAX: Keep last, used in &struct data_queue to determine the size * of the index array. */ enum queue_index { Q_INDEX, Q_INDEX_DMA_DONE, Q_INDEX_DONE, Q_INDEX_MAX, }; /** * enum data_queue_flags: Status flags for data queues * * @QUEUE_STARTED: The queue has been started. Fox RX queues this means the * device might be DMA'ing skbuffers. TX queues will accept skbuffers to * be transmitted and beacon queues will start beaconing the configured * beacons. * @QUEUE_PAUSED: The queue has been started but is currently paused. * When this bit is set, the queue has been stopped in mac80211, * preventing new frames to be enqueued. However, a few frames * might still appear shortly after the pausing... */ enum data_queue_flags { QUEUE_STARTED, QUEUE_PAUSED, }; /** * struct data_queue: Data queue * * @rt2x00dev: Pointer to main &struct rt2x00dev where this queue belongs to. * @entries: Base address of the &struct queue_entry which are * part of this queue. * @qid: The queue identification, see &enum data_queue_qid. * @flags: Entry flags, see &enum queue_entry_flags. * @status_lock: The mutex for protecting the start/stop/flush * handling on this queue. * @tx_lock: Spinlock to serialize tx operations on this queue. * @index_lock: Spinlock to protect index handling. Whenever @index, @index_done or * @index_crypt needs to be changed this lock should be grabbed to prevent * index corruption due to concurrency. * @count: Number of frames handled in the queue. * @limit: Maximum number of entries in the queue. * @threshold: Minimum number of free entries before queue is kicked by force. * @length: Number of frames in queue. * @index: Index pointers to entry positions in the queue, * use &enum queue_index to get a specific index field. * @wd_count: watchdog counter number of times entry does change * in the queue * @wd_idx: index of queue entry saved by watchdog * @txop: maximum burst time. * @aifs: The aifs value for outgoing frames (field ignored in RX queue). * @cw_min: The cw min value for outgoing frames (field ignored in RX queue). * @cw_max: The cw max value for outgoing frames (field ignored in RX queue). * @data_size: Maximum data size for the frames in this queue. * @desc_size: Hardware descriptor size for the data in this queue. * @priv_size: Size of per-queue_entry private data. * @usb_endpoint: Device endpoint used for communication (USB only) * @usb_maxpacket: Max packet size for given endpoint (USB only) */ struct data_queue { struct rt2x00_dev *rt2x00dev; struct queue_entry *entries; enum data_queue_qid qid; unsigned long flags; struct mutex status_lock; spinlock_t tx_lock; spinlock_t index_lock; unsigned int count; unsigned short limit; unsigned short threshold; unsigned short length; unsigned short index[Q_INDEX_MAX]; unsigned short wd_count; unsigned int wd_idx; unsigned short txop; unsigned short aifs; unsigned short cw_min; unsigned short cw_max; unsigned short data_size; unsigned char desc_size; unsigned char winfo_size; unsigned short priv_size; unsigned short usb_endpoint; unsigned short usb_maxpacket; }; /** * queue_end - Return pointer to the last queue (HELPER MACRO). * @__dev: Pointer to &struct rt2x00_dev * * Using the base rx pointer and the maximum number of available queues, * this macro will return the address of 1 position beyond the end of the * queues array. */ #define queue_end(__dev) \ &(__dev)->rx[(__dev)->data_queues] /** * tx_queue_end - Return pointer to the last TX queue (HELPER MACRO). * @__dev: Pointer to &struct rt2x00_dev * * Using the base tx pointer and the maximum number of available TX * queues, this macro will return the address of 1 position beyond * the end of the TX queue array. */ #define tx_queue_end(__dev) \ &(__dev)->tx[(__dev)->ops->tx_queues] /** * queue_next - Return pointer to next queue in list (HELPER MACRO). * @__queue: Current queue for which we need the next queue * * Using the current queue address we take the address directly * after the queue to take the next queue. Note that this macro * should be used carefully since it does not protect against * moving past the end of the list. (See macros &queue_end and * &tx_queue_end for determining the end of the queue). */ #define queue_next(__queue) \ &(__queue)[1] /** * queue_loop - Loop through the queues within a specific range (HELPER MACRO). * @__entry: Pointer where the current queue entry will be stored in. * @__start: Start queue pointer. * @__end: End queue pointer. * * This macro will loop through all queues between &__start and &__end. */ #define queue_loop(__entry, __start, __end) \ for ((__entry) = (__start); \ prefetch(queue_next(__entry)), (__entry) != (__end);\ (__entry) = queue_next(__entry)) /** * queue_for_each - Loop through all queues * @__dev: Pointer to &struct rt2x00_dev * @__entry: Pointer where the current queue entry will be stored in. * * This macro will loop through all available queues. */ #define queue_for_each(__dev, __entry) \ queue_loop(__entry, (__dev)->rx, queue_end(__dev)) /** * tx_queue_for_each - Loop through the TX queues * @__dev: Pointer to &struct rt2x00_dev * @__entry: Pointer where the current queue entry will be stored in. * * This macro will loop through all TX related queues excluding * the Beacon and Atim queues. */ #define tx_queue_for_each(__dev, __entry) \ queue_loop(__entry, (__dev)->tx, tx_queue_end(__dev)) /** * txall_queue_for_each - Loop through all TX related queues * @__dev: Pointer to &struct rt2x00_dev * @__entry: Pointer where the current queue entry will be stored in. * * This macro will loop through all TX related queues including * the Beacon and Atim queues. */ #define txall_queue_for_each(__dev, __entry) \ queue_loop(__entry, (__dev)->tx, queue_end(__dev)) /** * rt2x00queue_for_each_entry - Loop through all entries in the queue * @queue: Pointer to @data_queue * @start: &enum queue_index Pointer to start index * @end: &enum queue_index Pointer to end index * @data: Data to pass to the callback function * @fn: The function to call for each &struct queue_entry * * This will walk through all entries in the queue, in chronological * order. This means it will start at the current @start pointer * and will walk through the queue until it reaches the @end pointer. * * If fn returns true for an entry rt2x00queue_for_each_entry will stop * processing and return true as well. */ bool rt2x00queue_for_each_entry(struct data_queue *queue, enum queue_index start, enum queue_index end, void *data, bool (*fn)(struct queue_entry *entry, void *data)); /** * rt2x00queue_empty - Check if the queue is empty. * @queue: Queue to check if empty. */ static inline int rt2x00queue_empty(struct data_queue *queue) { return queue->length == 0; } /** * rt2x00queue_full - Check if the queue is full. * @queue: Queue to check if full. */ static inline int rt2x00queue_full(struct data_queue *queue) { return queue->length == queue->limit; } /** * rt2x00queue_free - Check the number of available entries in queue. * @queue: Queue to check. */ static inline int rt2x00queue_available(struct data_queue *queue) { return queue->limit - queue->length; } /** * rt2x00queue_threshold - Check if the queue is below threshold * @queue: Queue to check. */ static inline int rt2x00queue_threshold(struct data_queue *queue) { return rt2x00queue_available(queue) < queue->threshold; } /** * rt2x00queue_dma_timeout - Check if a timeout occurred for DMA transfers * @entry: Queue entry to check. */ static inline int rt2x00queue_dma_timeout(struct queue_entry *entry) { if (!test_bit(ENTRY_OWNER_DEVICE_DATA, &entry->flags)) return false; return time_after(jiffies, entry->last_action + msecs_to_jiffies(100)); } /** * _rt2x00_desc_read - Read a word from the hardware descriptor. * @desc: Base descriptor address * @word: Word index from where the descriptor should be read. */ static inline __le32 _rt2x00_desc_read(__le32 *desc, const u8 word) { return desc[word]; } /** * rt2x00_desc_read - Read a word from the hardware descriptor, this * function will take care of the byte ordering. * @desc: Base descriptor address * @word: Word index from where the descriptor should be read. */ static inline u32 rt2x00_desc_read(__le32 *desc, const u8 word) { return le32_to_cpu(_rt2x00_desc_read(desc, word)); } /** * rt2x00_desc_write - write a word to the hardware descriptor, this * function will take care of the byte ordering. * @desc: Base descriptor address * @word: Word index from where the descriptor should be written. * @value: Value that should be written into the descriptor. */ static inline void _rt2x00_desc_write(__le32 *desc, const u8 word, __le32 value) { desc[word] = value; } /** * rt2x00_desc_write - write a word to the hardware descriptor. * @desc: Base descriptor address * @word: Word index from where the descriptor should be written. * @value: Value that should be written into the descriptor. */ static inline void rt2x00_desc_write(__le32 *desc, const u8 word, u32 value) { _rt2x00_desc_write(desc, word, cpu_to_le32(value)); } #endif /* RT2X00QUEUE_H */
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