2 * Intel Wireless Multicomm 3200 WiFi driver
4 * Copyright (C) 2009 Intel Corporation. All rights reserved.
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7 * modification, are permitted provided that the following conditions
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13 * notice, this list of conditions and the following disclaimer in
14 * the documentation and/or other materials provided with the
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17 * contributors may be used to endorse or promote products derived
18 * from this software without specific prior written permission.
20 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
21 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
22 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
23 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
24 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
25 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
26 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
27 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
28 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
29 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
30 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
33 * Intel Corporation <ilw@linux.intel.com>
34 * Samuel Ortiz <samuel.ortiz@intel.com>
35 * Zhu Yi <yi.zhu@intel.com>
40 * Hardware Abstraction Layer for iwm.
42 * This file mostly defines an abstraction API for
43 * sending various commands to the target.
45 * We have 2 types of commands: wifi and non-wifi ones.
48 * They are used for sending LMAC and UMAC commands,
49 * and thus are the most commonly used ones.
50 * There are 2 different wifi command types, the regular
51 * one and the LMAC one. The former is used to send
52 * UMAC commands (see UMAC_CMD_OPCODE_* from umac.h)
53 * while the latter is used for sending commands to the
54 * LMAC. If you look at LMAC commands you'll se that they
55 * are actually regular iwlwifi target commands encapsulated
56 * into a special UMAC command called UMAC passthrough.
57 * This is due to the fact the host talks exclusively
58 * to the UMAC and so there needs to be a special UMAC
59 * command for talking to the LMAC.
60 * This is how a wifi command is laid out:
61 * ------------------------
62 * | iwm_udma_out_wifi_hdr |
63 * ------------------------
64 * | SW meta_data (32 bits) |
65 * ------------------------
67 * ------------------------
71 * - non-wifi, or general commands:
72 * Those commands are handled by the device's bootrom,
73 * and are typically sent when the UMAC and the LMAC
74 * are not yet available.
75 * * This is how a non-wifi command is laid out:
76 * ---------------------------
77 * | iwm_udma_out_nonwifi_hdr |
78 * ---------------------------
83 * All the commands start with a UDMA header, which is
84 * basically a 32 bits field. The 4 LSB there define
85 * an opcode that allows the target to differentiate
86 * between wifi (opcode is 0xf) and non-wifi commands
87 * (opcode is [0..0xe]).
89 * When a command (wifi or non-wifi) is supposed to receive
90 * an answer, we queue the command buffer. When we do receive
91 * a command response from the UMAC, we go through the list
92 * of pending command, and pass both the command and the answer
93 * to the rx handler. Each command is sent with a unique
94 * sequence id, and the answer is sent with the same one. This
95 * is how we're supposed to match an answer with its command.
96 * See rx.c:iwm_rx_handle_[non]wifi() and iwm_get_pending_[non]wifi()
97 * for the implementation details.
99 #include <linux/kernel.h>
100 #include <linux/netdevice.h>
101 #include <linux/slab.h>
110 static int iwm_nonwifi_cmd_init(struct iwm_priv
*iwm
,
111 struct iwm_nonwifi_cmd
*cmd
,
112 struct iwm_udma_nonwifi_cmd
*udma_cmd
)
114 INIT_LIST_HEAD(&cmd
->pending
);
116 spin_lock(&iwm
->cmd_lock
);
118 cmd
->resp_received
= 0;
120 cmd
->seq_num
= iwm
->nonwifi_seq_num
;
121 udma_cmd
->seq_num
= cpu_to_le16(cmd
->seq_num
);
123 iwm
->nonwifi_seq_num
++;
124 iwm
->nonwifi_seq_num
%= UMAC_NONWIFI_SEQ_NUM_MAX
;
127 list_add_tail(&cmd
->pending
, &iwm
->nonwifi_pending_cmd
);
129 spin_unlock(&iwm
->cmd_lock
);
131 cmd
->buf
.start
= cmd
->buf
.payload
;
134 memcpy(&cmd
->udma_cmd
, udma_cmd
, sizeof(*udma_cmd
));
139 u16
iwm_alloc_wifi_cmd_seq(struct iwm_priv
*iwm
)
141 u16 seq_num
= iwm
->wifi_seq_num
;
144 iwm
->wifi_seq_num
%= UMAC_WIFI_SEQ_NUM_MAX
;
149 static void iwm_wifi_cmd_init(struct iwm_priv
*iwm
,
150 struct iwm_wifi_cmd
*cmd
,
151 struct iwm_udma_wifi_cmd
*udma_cmd
,
152 struct iwm_umac_cmd
*umac_cmd
,
153 struct iwm_lmac_cmd
*lmac_cmd
,
156 INIT_LIST_HEAD(&cmd
->pending
);
158 spin_lock(&iwm
->cmd_lock
);
160 cmd
->seq_num
= iwm_alloc_wifi_cmd_seq(iwm
);
161 umac_cmd
->seq_num
= cpu_to_le16(cmd
->seq_num
);
164 list_add_tail(&cmd
->pending
, &iwm
->wifi_pending_cmd
);
166 spin_unlock(&iwm
->cmd_lock
);
168 cmd
->buf
.start
= cmd
->buf
.payload
;
172 cmd
->buf
.start
-= sizeof(struct iwm_lmac_hdr
);
174 lmac_cmd
->seq_num
= cpu_to_le16(cmd
->seq_num
);
175 lmac_cmd
->count
= cpu_to_le16(payload_size
);
177 memcpy(&cmd
->lmac_cmd
, lmac_cmd
, sizeof(*lmac_cmd
));
179 umac_cmd
->count
= cpu_to_le16(sizeof(struct iwm_lmac_hdr
));
183 umac_cmd
->count
= cpu_to_le16(payload_size
+
184 le16_to_cpu(umac_cmd
->count
));
185 udma_cmd
->count
= cpu_to_le16(sizeof(struct iwm_umac_fw_cmd_hdr
) +
186 le16_to_cpu(umac_cmd
->count
));
188 memcpy(&cmd
->udma_cmd
, udma_cmd
, sizeof(*udma_cmd
));
189 memcpy(&cmd
->umac_cmd
, umac_cmd
, sizeof(*umac_cmd
));
192 void iwm_cmd_flush(struct iwm_priv
*iwm
)
194 struct iwm_wifi_cmd
*wcmd
, *wnext
;
195 struct iwm_nonwifi_cmd
*nwcmd
, *nwnext
;
197 list_for_each_entry_safe(wcmd
, wnext
, &iwm
->wifi_pending_cmd
, pending
) {
198 list_del(&wcmd
->pending
);
202 list_for_each_entry_safe(nwcmd
, nwnext
, &iwm
->nonwifi_pending_cmd
,
204 list_del(&nwcmd
->pending
);
209 struct iwm_wifi_cmd
*iwm_get_pending_wifi_cmd(struct iwm_priv
*iwm
, u16 seq_num
)
211 struct iwm_wifi_cmd
*cmd
;
213 list_for_each_entry(cmd
, &iwm
->wifi_pending_cmd
, pending
)
214 if (cmd
->seq_num
== seq_num
) {
215 list_del(&cmd
->pending
);
222 struct iwm_nonwifi_cmd
*iwm_get_pending_nonwifi_cmd(struct iwm_priv
*iwm
,
223 u8 seq_num
, u8 cmd_opcode
)
225 struct iwm_nonwifi_cmd
*cmd
;
227 list_for_each_entry(cmd
, &iwm
->nonwifi_pending_cmd
, pending
)
228 if ((cmd
->seq_num
== seq_num
) &&
229 (cmd
->udma_cmd
.opcode
== cmd_opcode
) &&
230 (cmd
->resp_received
)) {
231 list_del(&cmd
->pending
);
238 static void iwm_build_udma_nonwifi_hdr(struct iwm_priv
*iwm
,
239 struct iwm_udma_out_nonwifi_hdr
*hdr
,
240 struct iwm_udma_nonwifi_cmd
*cmd
)
242 memset(hdr
, 0, sizeof(*hdr
));
244 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_OPCODE
, cmd
->opcode
);
245 SET_VAL32(hdr
->cmd
, UDMA_HDI_OUT_NW_CMD_RESP
, cmd
->resp
);
246 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_EOT
, 1);
247 SET_VAL32(hdr
->cmd
, UDMA_HDI_OUT_NW_CMD_HANDLE_BY_HW
,
249 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_SIGNATURE
, UMAC_HDI_OUT_SIGNATURE
);
250 SET_VAL32(hdr
->cmd
, UDMA_HDI_OUT_CMD_NON_WIFI_HW_SEQ_NUM
,
251 le16_to_cpu(cmd
->seq_num
));
253 hdr
->addr
= cmd
->addr
;
254 hdr
->op1_sz
= cmd
->op1_sz
;
258 static int iwm_send_udma_nonwifi_cmd(struct iwm_priv
*iwm
,
259 struct iwm_nonwifi_cmd
*cmd
)
261 struct iwm_udma_out_nonwifi_hdr
*udma_hdr
;
262 struct iwm_nonwifi_cmd_buff
*buf
;
263 struct iwm_udma_nonwifi_cmd
*udma_cmd
= &cmd
->udma_cmd
;
267 buf
->start
-= sizeof(struct iwm_umac_nonwifi_out_hdr
);
268 buf
->len
+= sizeof(struct iwm_umac_nonwifi_out_hdr
);
270 udma_hdr
= (struct iwm_udma_out_nonwifi_hdr
*)(buf
->start
);
272 iwm_build_udma_nonwifi_hdr(iwm
, udma_hdr
, udma_cmd
);
274 IWM_DBG_CMD(iwm
, DBG
,
275 "Send UDMA nonwifi cmd: opcode = 0x%x, resp = 0x%x, "
276 "hw = 0x%x, seqnum = %d, addr = 0x%x, op1_sz = 0x%x, "
277 "op2 = 0x%x\n", udma_cmd
->opcode
, udma_cmd
->resp
,
278 udma_cmd
->handle_by_hw
, cmd
->seq_num
, udma_cmd
->addr
,
279 udma_cmd
->op1_sz
, udma_cmd
->op2
);
281 trace_iwm_tx_nonwifi_cmd(iwm
, udma_hdr
);
282 return iwm_bus_send_chunk(iwm
, buf
->start
, buf
->len
);
285 void iwm_udma_wifi_hdr_set_eop(struct iwm_priv
*iwm
, u8
*buf
, u8 eop
)
287 struct iwm_udma_out_wifi_hdr
*hdr
= (struct iwm_udma_out_wifi_hdr
*)buf
;
289 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_EOT
, eop
);
292 void iwm_build_udma_wifi_hdr(struct iwm_priv
*iwm
,
293 struct iwm_udma_out_wifi_hdr
*hdr
,
294 struct iwm_udma_wifi_cmd
*cmd
)
296 memset(hdr
, 0, sizeof(*hdr
));
298 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_OPCODE
, UMAC_HDI_OUT_OPCODE_WIFI
);
299 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_EOT
, cmd
->eop
);
300 SET_VAL32(hdr
->cmd
, UMAC_HDI_OUT_CMD_SIGNATURE
, UMAC_HDI_OUT_SIGNATURE
);
302 SET_VAL32(hdr
->meta_data
, UMAC_HDI_OUT_BYTE_COUNT
,
303 le16_to_cpu(cmd
->count
));
304 SET_VAL32(hdr
->meta_data
, UMAC_HDI_OUT_CREDIT_GRP
, cmd
->credit_group
);
305 SET_VAL32(hdr
->meta_data
, UMAC_HDI_OUT_RATID
, cmd
->ra_tid
);
306 SET_VAL32(hdr
->meta_data
, UMAC_HDI_OUT_LMAC_OFFSET
, cmd
->lmac_offset
);
309 void iwm_build_umac_hdr(struct iwm_priv
*iwm
,
310 struct iwm_umac_fw_cmd_hdr
*hdr
,
311 struct iwm_umac_cmd
*cmd
)
313 memset(hdr
, 0, sizeof(*hdr
));
315 SET_VAL32(hdr
->meta_data
, UMAC_FW_CMD_BYTE_COUNT
,
316 le16_to_cpu(cmd
->count
));
317 SET_VAL32(hdr
->meta_data
, UMAC_FW_CMD_TX_STA_COLOR
, cmd
->color
);
318 SET_VAL8(hdr
->cmd
.flags
, UMAC_DEV_CMD_FLAGS_RESP_REQ
, cmd
->resp
);
320 hdr
->cmd
.cmd
= cmd
->id
;
321 hdr
->cmd
.seq_num
= cmd
->seq_num
;
324 static int iwm_send_udma_wifi_cmd(struct iwm_priv
*iwm
,
325 struct iwm_wifi_cmd
*cmd
)
327 struct iwm_umac_wifi_out_hdr
*umac_hdr
;
328 struct iwm_wifi_cmd_buff
*buf
;
329 struct iwm_udma_wifi_cmd
*udma_cmd
= &cmd
->udma_cmd
;
330 struct iwm_umac_cmd
*umac_cmd
= &cmd
->umac_cmd
;
335 buf
->start
-= sizeof(struct iwm_umac_wifi_out_hdr
);
336 buf
->len
+= sizeof(struct iwm_umac_wifi_out_hdr
);
338 umac_hdr
= (struct iwm_umac_wifi_out_hdr
*)(buf
->start
);
340 iwm_build_udma_wifi_hdr(iwm
, &umac_hdr
->hw_hdr
, udma_cmd
);
341 iwm_build_umac_hdr(iwm
, &umac_hdr
->sw_hdr
, umac_cmd
);
343 IWM_DBG_CMD(iwm
, DBG
,
344 "Send UDMA wifi cmd: opcode = 0x%x, UMAC opcode = 0x%x, "
345 "eop = 0x%x, count = 0x%x, credit_group = 0x%x, "
346 "ra_tid = 0x%x, lmac_offset = 0x%x, seqnum = %d\n",
347 UMAC_HDI_OUT_OPCODE_WIFI
, umac_cmd
->id
,
348 udma_cmd
->eop
, udma_cmd
->count
, udma_cmd
->credit_group
,
349 udma_cmd
->ra_tid
, udma_cmd
->lmac_offset
, cmd
->seq_num
);
351 if (umac_cmd
->id
== UMAC_CMD_OPCODE_WIFI_PASS_THROUGH
)
352 IWM_DBG_CMD(iwm
, DBG
, "\tLMAC opcode: 0x%x\n",
355 ret
= iwm_tx_credit_alloc(iwm
, udma_cmd
->credit_group
, buf
->len
);
357 /* We keep sending UMAC reset regardless of the command credits.
358 * The UMAC is supposed to be reset anyway and the Tx credits are
359 * reinitialized afterwards. If we are lucky, the reset could
360 * still be done even though we have run out of credits for the
361 * command pool at this moment.*/
362 if (ret
&& (umac_cmd
->id
!= UMAC_CMD_OPCODE_RESET
)) {
363 IWM_DBG_TX(iwm
, DBG
, "Failed to alloc tx credit for cmd %d\n",
368 trace_iwm_tx_wifi_cmd(iwm
, umac_hdr
);
369 return iwm_bus_send_chunk(iwm
, buf
->start
, buf
->len
);
372 /* target_cmd a.k.a udma_nonwifi_cmd can be sent when UMAC is not available */
373 int iwm_hal_send_target_cmd(struct iwm_priv
*iwm
,
374 struct iwm_udma_nonwifi_cmd
*udma_cmd
,
377 struct iwm_nonwifi_cmd
*cmd
;
380 cmd
= kzalloc(sizeof(struct iwm_nonwifi_cmd
), GFP_KERNEL
);
382 IWM_ERR(iwm
, "Couldn't alloc memory for hal cmd\n");
386 seq_num
= iwm_nonwifi_cmd_init(iwm
, cmd
, udma_cmd
);
388 if (cmd
->udma_cmd
.opcode
== UMAC_HDI_OUT_OPCODE_WRITE
||
389 cmd
->udma_cmd
.opcode
== UMAC_HDI_OUT_OPCODE_WRITE_PERSISTENT
) {
390 cmd
->buf
.len
= le32_to_cpu(cmd
->udma_cmd
.op1_sz
);
391 memcpy(&cmd
->buf
.payload
, payload
, cmd
->buf
.len
);
394 ret
= iwm_send_udma_nonwifi_cmd(iwm
, cmd
);
405 static void iwm_build_lmac_hdr(struct iwm_priv
*iwm
, struct iwm_lmac_hdr
*hdr
,
406 struct iwm_lmac_cmd
*cmd
)
408 memset(hdr
, 0, sizeof(*hdr
));
411 hdr
->flags
= 0; /* Is this ever used? */
412 hdr
->seq_num
= cmd
->seq_num
;
416 * iwm_hal_send_host_cmd(): sends commands to the UMAC or the LMAC.
417 * Sending command to the LMAC is equivalent to sending a
418 * regular UMAC command with the LMAC passthrough or the LMAC
419 * wrapper UMAC command IDs.
421 int iwm_hal_send_host_cmd(struct iwm_priv
*iwm
,
422 struct iwm_udma_wifi_cmd
*udma_cmd
,
423 struct iwm_umac_cmd
*umac_cmd
,
424 struct iwm_lmac_cmd
*lmac_cmd
,
425 const void *payload
, u16 payload_size
)
427 struct iwm_wifi_cmd
*cmd
;
428 struct iwm_lmac_hdr
*hdr
;
429 int lmac_hdr_len
= 0;
432 cmd
= kzalloc(sizeof(struct iwm_wifi_cmd
), GFP_KERNEL
);
434 IWM_ERR(iwm
, "Couldn't alloc memory for wifi hal cmd\n");
438 iwm_wifi_cmd_init(iwm
, cmd
, udma_cmd
, umac_cmd
, lmac_cmd
, payload_size
);
441 hdr
= (struct iwm_lmac_hdr
*)(cmd
->buf
.start
);
443 iwm_build_lmac_hdr(iwm
, hdr
, &cmd
->lmac_cmd
);
444 lmac_hdr_len
= sizeof(struct iwm_lmac_hdr
);
447 memcpy(cmd
->buf
.payload
, payload
, payload_size
);
448 cmd
->buf
.len
= le16_to_cpu(umac_cmd
->count
);
450 ret
= iwm_send_udma_wifi_cmd(iwm
, cmd
);
452 /* We free the cmd if we're not expecting any response */
459 * iwm_hal_send_umac_cmd(): This is a special case for
460 * iwm_hal_send_host_cmd() to send direct UMAC cmd (without
463 int iwm_hal_send_umac_cmd(struct iwm_priv
*iwm
,
464 struct iwm_udma_wifi_cmd
*udma_cmd
,
465 struct iwm_umac_cmd
*umac_cmd
,
466 const void *payload
, u16 payload_size
)
468 return iwm_hal_send_host_cmd(iwm
, udma_cmd
, umac_cmd
, NULL
,
469 payload
, payload_size
);