1 /* SPDX-License-Identifier: GPL-2.0-only */
2 /*
3 * This file is part of wl1251
4 *
5 * Copyright (c) 1998-2007 Texas Instruments Incorporated
6 * Copyright (C) 2008 Nokia Corporation
7 */
8
9 #ifndef __WL1251_TX_H__
10 #define __WL1251_TX_H__
11
12 #include <linux/bitops.h>
13 #include "acx.h"
14
15 /*
16 *
17 * TX PATH
18 *
19 * The Tx path uses a double buffer and a tx_control structure, each located
20 * at a fixed address in the device's memory. On startup, the host retrieves
21 * the pointers to these addresses. A double buffer allows for continuous data
22 * flow towards the device. The host keeps track of which buffer is available
23 * and alternates between these two buffers on a per packet basis.
24 *
25 * The size of each of the two buffers is large enough to hold the longest
26 * 802.3 packet - maximum size Ethernet packet + header + descriptor.
27 * TX complete indication will be received a-synchronously in a TX done cyclic
28 * buffer which is composed of 16 tx_result descriptors structures and is used
29 * in a cyclic manner.
30 *
31 * The TX (HOST) procedure is as follows:
32 * 1. Read the Tx path status, that will give the data_out_count.
33 * 2. goto 1, if not possible.
34 * i.e. if data_in_count - data_out_count >= HwBuffer size (2 for double
35 * buffer).
36 * 3. Copy the packet (preceded by double_buffer_desc), if possible.
37 * i.e. if data_in_count - data_out_count < HwBuffer size (2 for double
38 * buffer).
39 * 4. increment data_in_count.
40 * 5. Inform the firmware by generating a firmware internal interrupt.
41 * 6. FW will increment data_out_count after it reads the buffer.
42 *
43 * The TX Complete procedure:
44 * 1. To get a TX complete indication the host enables the tx_complete flag in
45 * the TX descriptor Structure.
46 * 2. For each packet with a Tx Complete field set, the firmware adds the
47 * transmit results to the cyclic buffer (txDoneRing) and sets both done_1
48 * and done_2 to 1 to indicate driver ownership.
49 * 3. The firmware sends a Tx Complete interrupt to the host to trigger the
50 * host to process the new data. Note: interrupt will be send per packet if
51 * TX complete indication was requested in tx_control or per crossing
52 * aggregation threshold.
53 * 4. After receiving the Tx Complete interrupt, the host reads the
54 * TxDescriptorDone information in a cyclic manner and clears both done_1
55 * and done_2 fields.
56 *
57 */
58
59 #define TX_COMPLETE_REQUIRED_BIT 0x80
60 #define TX_STATUS_DATA_OUT_COUNT_MASK 0xf
61
62 #define WL1251_TX_ALIGN_TO 4
63 #define WL1251_TX_ALIGN(len) (((len) + WL1251_TX_ALIGN_TO - 1) & \
64 ~(WL1251_TX_ALIGN_TO - 1))
65 #define WL1251_TKIP_IV_SPACE 4
66
67 struct tx_control {
68 /* Rate Policy (class) index */
69 unsigned rate_policy:3;
70
71 /* When set, no ack policy is expected */
72 unsigned ack_policy:1;
73
74 /*
75 * Packet type:
76 * 0 -> 802.11
77 * 1 -> 802.3
78 * 2 -> IP
79 * 3 -> raw codec
80 */
81 unsigned packet_type:2;
82
83 /* If set, this is a QoS-Null or QoS-Data frame */
84 unsigned qos:1;
85
86 /*
87 * If set, the target triggers the tx complete INT
88 * upon frame sending completion.
89 */
90 unsigned tx_complete:1;
91
92 /* 2 bytes padding before packet header */
93 unsigned xfer_pad:1;
94
95 unsigned reserved:7;
96 } __packed;
97
98
99 struct tx_double_buffer_desc {
100 /* Length of payload, including headers. */
101 __le16 length;
102
103 /*
104 * A bit mask that specifies the initial rate to be used
105 * Possible values are:
106 * 0x0001 - 1Mbits
107 * 0x0002 - 2Mbits
108 * 0x0004 - 5.5Mbits
109 * 0x0008 - 6Mbits
110 * 0x0010 - 9Mbits
111 * 0x0020 - 11Mbits
112 * 0x0040 - 12Mbits
113 * 0x0080 - 18Mbits
114 * 0x0100 - 22Mbits
115 * 0x0200 - 24Mbits
116 * 0x0400 - 36Mbits
117 * 0x0800 - 48Mbits
118 * 0x1000 - 54Mbits
119 */
120 __le16 rate;
121
122 /* Time in us that a packet can spend in the target */
123 __le32 expiry_time;
124
125 /* index of the TX queue used for this packet */
126 u8 xmit_queue;
127
128 /* Used to identify a packet */
129 u8 id;
130
131 struct tx_control control;
132
133 /*
134 * The FW should cut the packet into fragments
135 * of this size.
136 */
137 __le16 frag_threshold;
138
139 /* Numbers of HW queue blocks to be allocated */
140 u8 num_mem_blocks;
141
142 u8 reserved;
143 } __packed;
144
145 enum {
146 TX_SUCCESS = 0,
147 TX_DMA_ERROR = BIT(7),
148 TX_DISABLED = BIT(6),
149 TX_RETRY_EXCEEDED = BIT(5),
150 TX_TIMEOUT = BIT(4),
151 TX_KEY_NOT_FOUND = BIT(3),
152 TX_ENCRYPT_FAIL = BIT(2),
153 TX_UNAVAILABLE_PRIORITY = BIT(1),
154 };
155
156 struct tx_result {
157 /*
158 * Ownership synchronization between the host and
159 * the firmware. If done_1 and done_2 are cleared,
160 * owned by the FW (no info ready).
161 */
162 u8 done_1;
163
164 /* same as double_buffer_desc->id */
165 u8 id;
166
167 /*
168 * Total air access duration consumed by this
169 * packet, including all retries and overheads.
170 */
171 u16 medium_usage;
172
173 /* Total media delay (from 1st EDCA AIFS counter until TX Complete). */
174 u32 medium_delay;
175
176 /* Time between host xfer and tx complete */
177 u32 fw_hnadling_time;
178
179 /* The LS-byte of the last TKIP sequence number. */
180 u8 lsb_seq_num;
181
182 /* Retry count */
183 u8 ack_failures;
184
185 /* At which rate we got a ACK */
186 u16 rate;
187
188 u16 reserved;
189
190 /* TX_* */
191 u8 status;
192
193 /* See done_1 */
194 u8 done_2;
195 } __packed;
196
wl1251_tx_get_queue(int queue)197 static inline int wl1251_tx_get_queue(int queue)
198 {
199 switch (queue) {
200 case 0:
201 return QOS_AC_VO;
202 case 1:
203 return QOS_AC_VI;
204 case 2:
205 return QOS_AC_BE;
206 case 3:
207 return QOS_AC_BK;
208 default:
209 return QOS_AC_BE;
210 }
211 }
212
213 void wl1251_tx_work(struct work_struct *work);
214 void wl1251_tx_complete(struct wl1251 *wl);
215 void wl1251_tx_flush(struct wl1251 *wl);
216
217 #endif
218