1bd368728SMarko Zec /*-
24d846d26SWarner Losh * SPDX-License-Identifier: BSD-2-Clause
3bd368728SMarko Zec *
4bd368728SMarko Zec * Copyright (c) 2015 Bjoern A. Zeeb
5bd368728SMarko Zec * Copyright (c) 2020 Denis Salopek
6bd368728SMarko Zec *
7bd368728SMarko Zec * This software was developed by SRI International and the University of
8bd368728SMarko Zec * Cambridge Computer Laboratory under DARPA/AFRL contract FA8750-11-C-0249
9bd368728SMarko Zec * ("MRC2"), as part of the DARPA MRC research programme.
10bd368728SMarko Zec *
11bd368728SMarko Zec * Redistribution and use in source and binary forms, with or without
12bd368728SMarko Zec * modification, are permitted provided that the following conditions
13bd368728SMarko Zec * are met:
14bd368728SMarko Zec * 1. Redistributions of source code must retain the above copyright
15bd368728SMarko Zec * notice, this list of conditions and the following disclaimer.
16bd368728SMarko Zec * 2. Redistributions in binary form must reproduce the above copyright
17bd368728SMarko Zec * notice, this list of conditions and the following disclaimer in the
18bd368728SMarko Zec * documentation and/or other materials provided with the distribution.
19bd368728SMarko Zec *
20bd368728SMarko Zec * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
21bd368728SMarko Zec * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
22bd368728SMarko Zec * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
23bd368728SMarko Zec * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
24bd368728SMarko Zec * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
25bd368728SMarko Zec * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
26bd368728SMarko Zec * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
27bd368728SMarko Zec * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
28bd368728SMarko Zec * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
29bd368728SMarko Zec * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
30bd368728SMarko Zec * POSSIBILITY OF SUCH DAMAGE.
31bd368728SMarko Zec */
32bd368728SMarko Zec
33bd368728SMarko Zec #include <sys/param.h>
34bd368728SMarko Zec #include <sys/bus.h>
35bd368728SMarko Zec #include <sys/endian.h>
36bd368728SMarko Zec #include <sys/kernel.h>
37bd368728SMarko Zec #include <sys/limits.h>
38bd368728SMarko Zec #include <sys/module.h>
39bd368728SMarko Zec #include <sys/rman.h>
40bd368728SMarko Zec #include <sys/socket.h>
41bd368728SMarko Zec #include <sys/sockio.h>
42bd368728SMarko Zec #include <sys/sysctl.h>
43bd368728SMarko Zec #include <sys/taskqueue.h>
44bd368728SMarko Zec
45bd368728SMarko Zec #include <net/if.h>
46bd368728SMarko Zec #include <net/if_media.h>
47bd368728SMarko Zec #include <net/if_types.h>
48bd368728SMarko Zec #include <net/if_var.h>
49bd368728SMarko Zec
50bd368728SMarko Zec #include <netinet/in.h>
51bd368728SMarko Zec #include <netinet/if_ether.h>
52bd368728SMarko Zec
53bd368728SMarko Zec #include <dev/pci/pcivar.h>
54bd368728SMarko Zec #include <dev/pci/pcireg.h>
55bd368728SMarko Zec
56bd368728SMarko Zec #include <machine/bus.h>
57bd368728SMarko Zec
58bd368728SMarko Zec #include "adapter.h"
59bd368728SMarko Zec
60bd368728SMarko Zec #define PCI_VENDOR_ID_XILINX 0x10ee
61bd368728SMarko Zec #define PCI_DEVICE_ID_SUME 0x7028
62bd368728SMarko Zec
63bd368728SMarko Zec /* SUME bus driver interface */
64bd368728SMarko Zec static int sume_probe(device_t);
65bd368728SMarko Zec static int sume_attach(device_t);
66bd368728SMarko Zec static int sume_detach(device_t);
67bd368728SMarko Zec
68bd368728SMarko Zec static device_method_t sume_methods[] = {
69bd368728SMarko Zec DEVMETHOD(device_probe, sume_probe),
70bd368728SMarko Zec DEVMETHOD(device_attach, sume_attach),
71bd368728SMarko Zec DEVMETHOD(device_detach, sume_detach),
72bd368728SMarko Zec DEVMETHOD_END
73bd368728SMarko Zec };
74bd368728SMarko Zec
75bd368728SMarko Zec static driver_t sume_driver = {
76bd368728SMarko Zec "sume",
77bd368728SMarko Zec sume_methods,
78bd368728SMarko Zec sizeof(struct sume_adapter)
79bd368728SMarko Zec };
80bd368728SMarko Zec
81bd368728SMarko Zec /*
82bd368728SMarko Zec * The DMA engine for SUME generates interrupts for each RX/TX transaction.
83bd368728SMarko Zec * Depending on the channel (0 if packet transaction, 1 if register transaction)
84bd368728SMarko Zec * the used bits of the interrupt vector will be the lowest or the second lowest
85bd368728SMarko Zec * 5 bits.
86bd368728SMarko Zec *
87bd368728SMarko Zec * When receiving packets from SUME (RX):
88bd368728SMarko Zec * (1) SUME received a packet on one of the interfaces.
89bd368728SMarko Zec * (2) SUME generates an interrupt vector, bit 00001 is set (channel 0 - new RX
90bd368728SMarko Zec * transaction).
91bd368728SMarko Zec * (3) We read the length of the incoming packet and the offset along with the
92bd368728SMarko Zec * 'last' flag from the SUME registers.
93bd368728SMarko Zec * (4) We prepare for the DMA transaction by setting the bouncebuffer on the
94bd368728SMarko Zec * address buf_addr. For now, this is how it's done:
95bd368728SMarko Zec * - First 3*sizeof(uint32_t) bytes are: lower and upper 32 bits of physical
96bd368728SMarko Zec * address where we want the data to arrive (buf_addr[0] and buf_addr[1]),
97bd368728SMarko Zec * and length of incoming data (buf_addr[2]).
98bd368728SMarko Zec * - Data will start right after, at buf_addr+3*sizeof(uint32_t). The
99bd368728SMarko Zec * physical address buf_hw_addr is a block of contiguous memory mapped to
100bd368728SMarko Zec * buf_addr, so we can set the incoming data's physical address (buf_addr[0]
101bd368728SMarko Zec * and buf_addr[1]) to buf_hw_addr+3*sizeof(uint32_t).
102bd368728SMarko Zec * (5) We notify SUME that the bouncebuffer is ready for the transaction by
103bd368728SMarko Zec * writing the lower/upper physical address buf_hw_addr to the SUME
104bd368728SMarko Zec * registers RIFFA_TX_SG_ADDR_LO_REG_OFF and RIFFA_TX_SG_ADDR_HI_REG_OFF as
105bd368728SMarko Zec * well as the number of segments to the register RIFFA_TX_SG_LEN_REG_OFF.
106bd368728SMarko Zec * (6) SUME generates an interrupt vector, bit 00010 is set (channel 0 -
107bd368728SMarko Zec * bouncebuffer received).
108bd368728SMarko Zec * (7) SUME generates an interrupt vector, bit 00100 is set (channel 0 -
109bd368728SMarko Zec * transaction is done).
110bd368728SMarko Zec * (8) SUME can do both steps (6) and (7) using the same interrupt.
111bd368728SMarko Zec * (8) We read the first 16 bytes (metadata) of the received data and note the
112bd368728SMarko Zec * incoming interface so we can later forward it to the right one in the OS
113bd368728SMarko Zec * (sume0, sume1, sume2 or sume3).
114bd368728SMarko Zec * (10) We create an mbuf and copy the data from the bouncebuffer to the mbuf
115bd368728SMarko Zec * and set the mbuf rcvif to the incoming interface.
116bd368728SMarko Zec * (11) We forward the mbuf to the appropriate interface via ifp->if_input.
117bd368728SMarko Zec *
118bd368728SMarko Zec * When sending packets to SUME (TX):
119bd368728SMarko Zec * (1) The OS calls sume_if_start() function on TX.
120bd368728SMarko Zec * (2) We get the mbuf packet data and copy it to the
121bd368728SMarko Zec * buf_addr+3*sizeof(uint32_t) + metadata 16 bytes.
122bd368728SMarko Zec * (3) We create the metadata based on the output interface and copy it to the
123bd368728SMarko Zec * buf_addr+3*sizeof(uint32_t).
124bd368728SMarko Zec * (4) We write the offset/last and length of the packet to the SUME registers
125bd368728SMarko Zec * RIFFA_RX_OFFLAST_REG_OFF and RIFFA_RX_LEN_REG_OFF.
126bd368728SMarko Zec * (5) We fill the bouncebuffer by filling the first 3*sizeof(uint32_t) bytes
127bd368728SMarko Zec * with the physical address and length just as in RX step (4).
128bd368728SMarko Zec * (6) We notify SUME that the bouncebuffer is ready by writing to SUME
129bd368728SMarko Zec * registers RIFFA_RX_SG_ADDR_LO_REG_OFF, RIFFA_RX_SG_ADDR_HI_REG_OFF and
130bd368728SMarko Zec * RIFFA_RX_SG_LEN_REG_OFF just as in RX step (5).
131bd368728SMarko Zec * (7) SUME generates an interrupt vector, bit 01000 is set (channel 0 -
132bd368728SMarko Zec * bouncebuffer is read).
133bd368728SMarko Zec * (8) SUME generates an interrupt vector, bit 10000 is set (channel 0 -
134bd368728SMarko Zec * transaction is done).
135bd368728SMarko Zec * (9) SUME can do both steps (7) and (8) using the same interrupt.
136bd368728SMarko Zec *
137bd368728SMarko Zec * Internal registers
138bd368728SMarko Zec * Every module in the SUME hardware has its own set of internal registers
139bd368728SMarko Zec * (IDs, for debugging and statistic purposes, etc.). Their base addresses are
140bd368728SMarko Zec * defined in 'projects/reference_nic/hw/tcl/reference_nic_defines.tcl' and the
141bd368728SMarko Zec * offsets to different memory locations of every module are defined in their
142bd368728SMarko Zec * corresponding folder inside the library. These registers can be RO/RW and
143bd368728SMarko Zec * there is a special method to fetch/change this data over 1 or 2 DMA
144bd368728SMarko Zec * transactions. For writing, by calling the sume_module_reg_write(). For
145bd368728SMarko Zec * reading, by calling the sume_module_reg_write() and then
146bd368728SMarko Zec * sume_module_reg_read(). Check those functions for more information.
147bd368728SMarko Zec */
148bd368728SMarko Zec
149bd368728SMarko Zec MALLOC_DECLARE(M_SUME);
150bd368728SMarko Zec MALLOC_DEFINE(M_SUME, "sume", "NetFPGA SUME device driver");
151bd368728SMarko Zec
152bd368728SMarko Zec static void check_tx_queues(struct sume_adapter *);
153bd368728SMarko Zec static void sume_fill_bb_desc(struct sume_adapter *, struct riffa_chnl_dir *,
154bd368728SMarko Zec uint64_t);
155bd368728SMarko Zec
156bd368728SMarko Zec static struct unrhdr *unr;
157bd368728SMarko Zec
158bd368728SMarko Zec static struct {
159bd368728SMarko Zec uint16_t device;
160bd368728SMarko Zec char *desc;
161bd368728SMarko Zec } sume_pciids[] = {
162bd368728SMarko Zec {PCI_DEVICE_ID_SUME, "NetFPGA SUME reference NIC"},
163bd368728SMarko Zec };
164bd368728SMarko Zec
165bd368728SMarko Zec static inline uint32_t
read_reg(struct sume_adapter * adapter,int offset)166bd368728SMarko Zec read_reg(struct sume_adapter *adapter, int offset)
167bd368728SMarko Zec {
168bd368728SMarko Zec
169bd368728SMarko Zec return (bus_space_read_4(adapter->bt, adapter->bh, offset << 2));
170bd368728SMarko Zec }
171bd368728SMarko Zec
172bd368728SMarko Zec static inline void
write_reg(struct sume_adapter * adapter,int offset,uint32_t val)173bd368728SMarko Zec write_reg(struct sume_adapter *adapter, int offset, uint32_t val)
174bd368728SMarko Zec {
175bd368728SMarko Zec
176bd368728SMarko Zec bus_space_write_4(adapter->bt, adapter->bh, offset << 2, val);
177bd368728SMarko Zec }
178bd368728SMarko Zec
179bd368728SMarko Zec static int
sume_probe(device_t dev)180bd368728SMarko Zec sume_probe(device_t dev)
181bd368728SMarko Zec {
182bd368728SMarko Zec int i;
183bd368728SMarko Zec uint16_t v = pci_get_vendor(dev);
184bd368728SMarko Zec uint16_t d = pci_get_device(dev);
185bd368728SMarko Zec
186bd368728SMarko Zec if (v != PCI_VENDOR_ID_XILINX)
187bd368728SMarko Zec return (ENXIO);
188bd368728SMarko Zec
189bd368728SMarko Zec for (i = 0; i < nitems(sume_pciids); i++) {
190bd368728SMarko Zec if (d == sume_pciids[i].device) {
191bd368728SMarko Zec device_set_desc(dev, sume_pciids[i].desc);
192bd368728SMarko Zec return (BUS_PROBE_DEFAULT);
193bd368728SMarko Zec }
194bd368728SMarko Zec }
195bd368728SMarko Zec
196bd368728SMarko Zec return (ENXIO);
197bd368728SMarko Zec }
198bd368728SMarko Zec
199bd368728SMarko Zec /*
200bd368728SMarko Zec * Building mbuf for packet received from SUME. We expect to receive 'len'
201bd368728SMarko Zec * bytes of data (including metadata) written from the bouncebuffer address
202bd368728SMarko Zec * buf_addr+3*sizeof(uint32_t). Metadata will tell us which SUME interface
203bd368728SMarko Zec * received the packet (sport will be 1, 2, 4 or 8), the packet length (plen),
204bd368728SMarko Zec * and the magic word needs to be 0xcafe. When we have the packet data, we
205bd368728SMarko Zec * create an mbuf and copy the data to it using m_copyback() function, set the
206bd368728SMarko Zec * correct interface to rcvif and return the mbuf to be later sent to the OS
207bd368728SMarko Zec * with if_input.
208bd368728SMarko Zec */
209bd368728SMarko Zec static struct mbuf *
sume_rx_build_mbuf(struct sume_adapter * adapter,uint32_t len)210bd368728SMarko Zec sume_rx_build_mbuf(struct sume_adapter *adapter, uint32_t len)
211bd368728SMarko Zec {
212bd368728SMarko Zec struct nf_priv *nf_priv;
213bd368728SMarko Zec struct mbuf *m;
214cc970676SJustin Hibbits if_t ifp = NULL;
215bd368728SMarko Zec int np;
216bd368728SMarko Zec uint16_t dport, plen, magic;
217bd368728SMarko Zec device_t dev = adapter->dev;
218bd368728SMarko Zec uint8_t *indata = (uint8_t *)
219bd368728SMarko Zec adapter->recv[SUME_RIFFA_CHANNEL_DATA]->buf_addr +
220bd368728SMarko Zec sizeof(struct nf_bb_desc);
221bd368728SMarko Zec struct nf_metadata *mdata = (struct nf_metadata *) indata;
222bd368728SMarko Zec
223bd368728SMarko Zec /* The metadata header is 16 bytes. */
224bd368728SMarko Zec if (len < sizeof(struct nf_metadata)) {
225bd368728SMarko Zec device_printf(dev, "short frame (%d)\n", len);
226bd368728SMarko Zec adapter->packets_err++;
227bd368728SMarko Zec adapter->bytes_err += len;
228bd368728SMarko Zec return (NULL);
229bd368728SMarko Zec }
230bd368728SMarko Zec
231bd368728SMarko Zec dport = le16toh(mdata->dport);
232bd368728SMarko Zec plen = le16toh(mdata->plen);
233bd368728SMarko Zec magic = le16toh(mdata->magic);
234bd368728SMarko Zec
235bd368728SMarko Zec if (sizeof(struct nf_metadata) + plen > len ||
236bd368728SMarko Zec magic != SUME_RIFFA_MAGIC) {
237bd368728SMarko Zec device_printf(dev, "corrupted packet (%zd + %d > %d || magic "
238bd368728SMarko Zec "0x%04x != 0x%04x)\n", sizeof(struct nf_metadata), plen,
239bd368728SMarko Zec len, magic, SUME_RIFFA_MAGIC);
240bd368728SMarko Zec return (NULL);
241bd368728SMarko Zec }
242bd368728SMarko Zec
243bd368728SMarko Zec /* We got the packet from one of the even bits */
244bd368728SMarko Zec np = (ffs(dport & SUME_DPORT_MASK) >> 1) - 1;
245bd368728SMarko Zec if (np > SUME_NPORTS) {
246bd368728SMarko Zec device_printf(dev, "invalid destination port 0x%04x (%d)\n",
247bd368728SMarko Zec dport, np);
248bd368728SMarko Zec adapter->packets_err++;
249bd368728SMarko Zec adapter->bytes_err += plen;
250bd368728SMarko Zec return (NULL);
251bd368728SMarko Zec }
252bd368728SMarko Zec ifp = adapter->ifp[np];
253cc970676SJustin Hibbits nf_priv = if_getsoftc(ifp);
254bd368728SMarko Zec nf_priv->stats.rx_packets++;
255bd368728SMarko Zec nf_priv->stats.rx_bytes += plen;
256bd368728SMarko Zec
257bd368728SMarko Zec /* If the interface is down, well, we are done. */
258cc970676SJustin Hibbits if (!(if_getflags(ifp) & IFF_UP)) {
259bd368728SMarko Zec nf_priv->stats.ifc_down_packets++;
260bd368728SMarko Zec nf_priv->stats.ifc_down_bytes += plen;
261bd368728SMarko Zec return (NULL);
262bd368728SMarko Zec }
263bd368728SMarko Zec
264bd368728SMarko Zec if (adapter->sume_debug)
265bd368728SMarko Zec printf("Building mbuf with length: %d\n", plen);
266bd368728SMarko Zec
267bd368728SMarko Zec m = m_getm(NULL, plen, M_NOWAIT, MT_DATA);
268bd368728SMarko Zec if (m == NULL) {
269bd368728SMarko Zec adapter->packets_err++;
270bd368728SMarko Zec adapter->bytes_err += plen;
271bd368728SMarko Zec return (NULL);
272bd368728SMarko Zec }
273bd368728SMarko Zec
274bd368728SMarko Zec /* Copy the data in at the right offset. */
275bd368728SMarko Zec m_copyback(m, 0, plen, (void *) (indata + sizeof(struct nf_metadata)));
276bd368728SMarko Zec m->m_pkthdr.rcvif = ifp;
277bd368728SMarko Zec
278bd368728SMarko Zec return (m);
279bd368728SMarko Zec }
280bd368728SMarko Zec
281bd368728SMarko Zec /*
282bd368728SMarko Zec * SUME interrupt handler for when we get a valid interrupt from the board.
283bd368728SMarko Zec * Theoretically, we can receive interrupt for any of the available channels,
284bd368728SMarko Zec * but RIFFA DMA uses only 2: 0 and 1, so we use only vect0. The vector is a 32
285bd368728SMarko Zec * bit number, using 5 bits for every channel, the least significant bits
286bd368728SMarko Zec * correspond to channel 0 and the next 5 bits correspond to channel 1. Vector
287bd368728SMarko Zec * bits for RX/TX are:
288bd368728SMarko Zec * RX
289bd368728SMarko Zec * bit 0 - new transaction from SUME
290bd368728SMarko Zec * bit 1 - SUME received our bouncebuffer address
291bd368728SMarko Zec * bit 2 - SUME copied the received data to our bouncebuffer, transaction done
292bd368728SMarko Zec * TX
293bd368728SMarko Zec * bit 3 - SUME received our bouncebuffer address
294bd368728SMarko Zec * bit 4 - SUME copied the data from our bouncebuffer, transaction done
295bd368728SMarko Zec *
296bd368728SMarko Zec * There are two finite state machines (one for TX, one for RX). We loop
297bd368728SMarko Zec * through channels 0 and 1 to check and our current state and which interrupt
298bd368728SMarko Zec * bit is set.
299bd368728SMarko Zec * TX
300bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_IDLE: waiting for the first TX transaction.
301bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_READY: we prepared (filled with data) the bouncebuffer
302bd368728SMarko Zec * and triggered the SUME for the TX transaction. Waiting for interrupt bit 3
303bd368728SMarko Zec * to go to the next state.
304bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_READ: waiting for interrupt bit 4 (for SUME to send
305bd368728SMarko Zec * our packet). Then we get the length of the sent data and go back to the
306bd368728SMarko Zec * IDLE state.
307bd368728SMarko Zec * RX
308bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_IDLE: waiting for the interrupt bit 0 (new RX
309bd368728SMarko Zec * transaction). When we get it, we prepare our bouncebuffer for reading and
310bd368728SMarko Zec * trigger the SUME to start the transaction. Go to the next state.
311bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_READY: waiting for the interrupt bit 1 (SUME got our
312bd368728SMarko Zec * bouncebuffer). Go to the next state.
313bd368728SMarko Zec * SUME_RIFFA_CHAN_STATE_READ: SUME copied data and our bouncebuffer is ready,
314bd368728SMarko Zec * we can build the mbuf and go back to the IDLE state.
315bd368728SMarko Zec */
316bd368728SMarko Zec static void
sume_intr_handler(void * arg)317bd368728SMarko Zec sume_intr_handler(void *arg)
318bd368728SMarko Zec {
319bd368728SMarko Zec struct sume_adapter *adapter = arg;
320bd368728SMarko Zec uint32_t vect, vect0, len;
321bd368728SMarko Zec int ch, loops;
322bd368728SMarko Zec device_t dev = adapter->dev;
323bd368728SMarko Zec struct mbuf *m = NULL;
324cc970676SJustin Hibbits if_t ifp = NULL;
325bd368728SMarko Zec struct riffa_chnl_dir *send, *recv;
326bd368728SMarko Zec
327bd368728SMarko Zec SUME_LOCK(adapter);
328bd368728SMarko Zec
329bd368728SMarko Zec vect0 = read_reg(adapter, RIFFA_IRQ_REG0_OFF);
330bd368728SMarko Zec if ((vect0 & SUME_INVALID_VECT) != 0) {
331bd368728SMarko Zec SUME_UNLOCK(adapter);
332bd368728SMarko Zec return;
333bd368728SMarko Zec }
334bd368728SMarko Zec
335bd368728SMarko Zec /*
336bd368728SMarko Zec * We only have one interrupt for all channels and no way
337bd368728SMarko Zec * to quickly lookup for which channel(s) we got an interrupt?
338bd368728SMarko Zec */
339bd368728SMarko Zec for (ch = 0; ch < SUME_RIFFA_CHANNELS; ch++) {
340bd368728SMarko Zec vect = vect0 >> (5 * ch);
341bd368728SMarko Zec send = adapter->send[ch];
342bd368728SMarko Zec recv = adapter->recv[ch];
343bd368728SMarko Zec
344bd368728SMarko Zec loops = 0;
345bd368728SMarko Zec while ((vect & (SUME_MSI_TXBUF | SUME_MSI_TXDONE)) &&
346bd368728SMarko Zec loops <= 5) {
347bd368728SMarko Zec if (adapter->sume_debug)
348bd368728SMarko Zec device_printf(dev, "TX ch %d state %u vect = "
349bd368728SMarko Zec "0x%08x\n", ch, send->state, vect);
350bd368728SMarko Zec switch (send->state) {
351bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_IDLE:
352bd368728SMarko Zec break;
353bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_READY:
354bd368728SMarko Zec if (!(vect & SUME_MSI_TXBUF)) {
355bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
356bd368728SMarko Zec "interrupt in send+3 state %u: "
357bd368728SMarko Zec "vect = 0x%08x\n", ch, send->state,
358bd368728SMarko Zec vect);
359bd368728SMarko Zec send->recovery = 1;
360bd368728SMarko Zec break;
361bd368728SMarko Zec }
362bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_READ;
363bd368728SMarko Zec vect &= ~SUME_MSI_TXBUF;
364bd368728SMarko Zec break;
365bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_READ:
366bd368728SMarko Zec if (!(vect & SUME_MSI_TXDONE)) {
367bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
368bd368728SMarko Zec "interrupt in send+4 state %u: "
369bd368728SMarko Zec "vect = 0x%08x\n", ch, send->state,
370bd368728SMarko Zec vect);
371bd368728SMarko Zec send->recovery = 1;
372bd368728SMarko Zec break;
373bd368728SMarko Zec }
374bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_LEN;
375bd368728SMarko Zec
376bd368728SMarko Zec len = read_reg(adapter, RIFFA_CHNL_REG(ch,
377bd368728SMarko Zec RIFFA_RX_TNFR_LEN_REG_OFF));
378bd368728SMarko Zec if (ch == SUME_RIFFA_CHANNEL_DATA) {
379bd368728SMarko Zec send->state =
380bd368728SMarko Zec SUME_RIFFA_CHAN_STATE_IDLE;
381bd368728SMarko Zec check_tx_queues(adapter);
382bd368728SMarko Zec } else if (ch == SUME_RIFFA_CHANNEL_REG)
383bd368728SMarko Zec wakeup(&send->event);
384bd368728SMarko Zec else {
385bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
386bd368728SMarko Zec "interrupt in send+4 state %u: "
387bd368728SMarko Zec "vect = 0x%08x\n", ch, send->state,
388bd368728SMarko Zec vect);
389bd368728SMarko Zec send->recovery = 1;
390bd368728SMarko Zec }
391bd368728SMarko Zec vect &= ~SUME_MSI_TXDONE;
392bd368728SMarko Zec break;
393bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_LEN:
394bd368728SMarko Zec break;
395bd368728SMarko Zec default:
396bd368728SMarko Zec device_printf(dev, "unknown TX state!\n");
397bd368728SMarko Zec }
398bd368728SMarko Zec loops++;
399bd368728SMarko Zec }
400bd368728SMarko Zec
401bd368728SMarko Zec if ((vect & (SUME_MSI_TXBUF | SUME_MSI_TXDONE)) &&
402bd368728SMarko Zec send->recovery)
403bd368728SMarko Zec device_printf(dev, "ch %d ignoring vect = 0x%08x "
404bd368728SMarko Zec "during TX; not in recovery; state = %d loops = "
405bd368728SMarko Zec "%d\n", ch, vect, send->state, loops);
406bd368728SMarko Zec
407bd368728SMarko Zec loops = 0;
408bd368728SMarko Zec while ((vect & (SUME_MSI_RXQUE | SUME_MSI_RXBUF |
409bd368728SMarko Zec SUME_MSI_RXDONE)) && loops < 5) {
410bd368728SMarko Zec if (adapter->sume_debug)
411bd368728SMarko Zec device_printf(dev, "RX ch %d state %u vect = "
412bd368728SMarko Zec "0x%08x\n", ch, recv->state, vect);
413bd368728SMarko Zec switch (recv->state) {
414bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_IDLE:
415bd368728SMarko Zec if (!(vect & SUME_MSI_RXQUE)) {
416bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
417bd368728SMarko Zec "interrupt in recv+0 state %u: "
418bd368728SMarko Zec "vect = 0x%08x\n", ch, recv->state,
419bd368728SMarko Zec vect);
420bd368728SMarko Zec recv->recovery = 1;
421bd368728SMarko Zec break;
422bd368728SMarko Zec }
423bd368728SMarko Zec uint32_t max_ptr;
424bd368728SMarko Zec
425bd368728SMarko Zec /* Clear recovery state. */
426bd368728SMarko Zec recv->recovery = 0;
427bd368728SMarko Zec
428bd368728SMarko Zec /* Get offset and length. */
429bd368728SMarko Zec recv->offlast = read_reg(adapter,
430bd368728SMarko Zec RIFFA_CHNL_REG(ch,
431bd368728SMarko Zec RIFFA_TX_OFFLAST_REG_OFF));
432bd368728SMarko Zec recv->len = read_reg(adapter, RIFFA_CHNL_REG(ch,
433bd368728SMarko Zec RIFFA_TX_LEN_REG_OFF));
434bd368728SMarko Zec
435bd368728SMarko Zec /* Boundary checks. */
436bd368728SMarko Zec max_ptr = (uint32_t)((uintptr_t)recv->buf_addr
437bd368728SMarko Zec + SUME_RIFFA_OFFSET(recv->offlast)
438bd368728SMarko Zec + SUME_RIFFA_LEN(recv->len) - 1);
439bd368728SMarko Zec if (max_ptr <
440bd368728SMarko Zec (uint32_t)((uintptr_t)recv->buf_addr))
441bd368728SMarko Zec device_printf(dev, "receive buffer "
442bd368728SMarko Zec "wrap-around overflow.\n");
443bd368728SMarko Zec if (SUME_RIFFA_OFFSET(recv->offlast) +
444bd368728SMarko Zec SUME_RIFFA_LEN(recv->len) >
445bd368728SMarko Zec adapter->sg_buf_size)
446bd368728SMarko Zec device_printf(dev, "receive buffer too"
447bd368728SMarko Zec " small.\n");
448bd368728SMarko Zec
449bd368728SMarko Zec /* Fill the bouncebuf "descriptor". */
450bd368728SMarko Zec sume_fill_bb_desc(adapter, recv,
451bd368728SMarko Zec SUME_RIFFA_LEN(recv->len));
452bd368728SMarko Zec
453bd368728SMarko Zec bus_dmamap_sync(recv->ch_tag, recv->ch_map,
454bd368728SMarko Zec BUS_DMASYNC_PREREAD |
455bd368728SMarko Zec BUS_DMASYNC_PREWRITE);
456bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(ch,
457bd368728SMarko Zec RIFFA_TX_SG_ADDR_LO_REG_OFF),
458bd368728SMarko Zec SUME_RIFFA_LO_ADDR(recv->buf_hw_addr));
459bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(ch,
460bd368728SMarko Zec RIFFA_TX_SG_ADDR_HI_REG_OFF),
461bd368728SMarko Zec SUME_RIFFA_HI_ADDR(recv->buf_hw_addr));
462bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(ch,
463bd368728SMarko Zec RIFFA_TX_SG_LEN_REG_OFF),
464bd368728SMarko Zec 4 * recv->num_sg);
465bd368728SMarko Zec bus_dmamap_sync(recv->ch_tag, recv->ch_map,
466bd368728SMarko Zec BUS_DMASYNC_POSTREAD |
467bd368728SMarko Zec BUS_DMASYNC_POSTWRITE);
468bd368728SMarko Zec
469bd368728SMarko Zec recv->state = SUME_RIFFA_CHAN_STATE_READY;
470bd368728SMarko Zec vect &= ~SUME_MSI_RXQUE;
471bd368728SMarko Zec break;
472bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_READY:
473bd368728SMarko Zec if (!(vect & SUME_MSI_RXBUF)) {
474bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
475bd368728SMarko Zec "interrupt in recv+1 state %u: "
476bd368728SMarko Zec "vect = 0x%08x\n", ch, recv->state,
477bd368728SMarko Zec vect);
478bd368728SMarko Zec recv->recovery = 1;
479bd368728SMarko Zec break;
480bd368728SMarko Zec }
481bd368728SMarko Zec recv->state = SUME_RIFFA_CHAN_STATE_READ;
482bd368728SMarko Zec vect &= ~SUME_MSI_RXBUF;
483bd368728SMarko Zec break;
484bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_READ:
485bd368728SMarko Zec if (!(vect & SUME_MSI_RXDONE)) {
486bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
487bd368728SMarko Zec "interrupt in recv+2 state %u: "
488bd368728SMarko Zec "vect = 0x%08x\n", ch, recv->state,
489bd368728SMarko Zec vect);
490bd368728SMarko Zec recv->recovery = 1;
491bd368728SMarko Zec break;
492bd368728SMarko Zec }
493bd368728SMarko Zec len = read_reg(adapter, RIFFA_CHNL_REG(ch,
494bd368728SMarko Zec RIFFA_TX_TNFR_LEN_REG_OFF));
495bd368728SMarko Zec
496bd368728SMarko Zec /* Remember, len and recv->len are words. */
497bd368728SMarko Zec if (ch == SUME_RIFFA_CHANNEL_DATA) {
498bd368728SMarko Zec m = sume_rx_build_mbuf(adapter,
499bd368728SMarko Zec len << 2);
500bd368728SMarko Zec recv->state =
501bd368728SMarko Zec SUME_RIFFA_CHAN_STATE_IDLE;
502bd368728SMarko Zec } else if (ch == SUME_RIFFA_CHANNEL_REG)
503bd368728SMarko Zec wakeup(&recv->event);
504bd368728SMarko Zec else {
505bd368728SMarko Zec device_printf(dev, "ch %d unexpected "
506bd368728SMarko Zec "interrupt in recv+2 state %u: "
507bd368728SMarko Zec "vect = 0x%08x\n", ch, recv->state,
508bd368728SMarko Zec vect);
509bd368728SMarko Zec recv->recovery = 1;
510bd368728SMarko Zec }
511bd368728SMarko Zec vect &= ~SUME_MSI_RXDONE;
512bd368728SMarko Zec break;
513bd368728SMarko Zec case SUME_RIFFA_CHAN_STATE_LEN:
514bd368728SMarko Zec break;
515bd368728SMarko Zec default:
516bd368728SMarko Zec device_printf(dev, "unknown RX state!\n");
517bd368728SMarko Zec }
518bd368728SMarko Zec loops++;
519bd368728SMarko Zec }
520bd368728SMarko Zec
521bd368728SMarko Zec if ((vect & (SUME_MSI_RXQUE | SUME_MSI_RXBUF |
522bd368728SMarko Zec SUME_MSI_RXDONE)) && recv->recovery) {
523bd368728SMarko Zec device_printf(dev, "ch %d ignoring vect = 0x%08x "
524bd368728SMarko Zec "during RX; not in recovery; state = %d, loops = "
525bd368728SMarko Zec "%d\n", ch, vect, recv->state, loops);
526bd368728SMarko Zec
527bd368728SMarko Zec /* Clean the unfinished transaction. */
528bd368728SMarko Zec if (ch == SUME_RIFFA_CHANNEL_REG &&
529bd368728SMarko Zec vect & SUME_MSI_RXDONE) {
530bd368728SMarko Zec read_reg(adapter, RIFFA_CHNL_REG(ch,
531bd368728SMarko Zec RIFFA_TX_TNFR_LEN_REG_OFF));
532bd368728SMarko Zec recv->recovery = 0;
533bd368728SMarko Zec }
534bd368728SMarko Zec }
535bd368728SMarko Zec }
536bd368728SMarko Zec SUME_UNLOCK(adapter);
537bd368728SMarko Zec
538bd368728SMarko Zec if (m != NULL) {
539bd368728SMarko Zec ifp = m->m_pkthdr.rcvif;
540cc970676SJustin Hibbits if_input(ifp, m);
541bd368728SMarko Zec }
542bd368728SMarko Zec }
543bd368728SMarko Zec
544bd368728SMarko Zec /*
545bd368728SMarko Zec * As we cannot disable interrupt generation, ignore early interrupts by waiting
546bd368728SMarko Zec * for the adapter to go into the 'running' state.
547bd368728SMarko Zec */
548bd368728SMarko Zec static int
sume_intr_filter(void * arg)549bd368728SMarko Zec sume_intr_filter(void *arg)
550bd368728SMarko Zec {
551bd368728SMarko Zec struct sume_adapter *adapter = arg;
552bd368728SMarko Zec
553bd368728SMarko Zec if (adapter->running == 0)
554bd368728SMarko Zec return (FILTER_STRAY);
555bd368728SMarko Zec
556bd368728SMarko Zec return (FILTER_SCHEDULE_THREAD);
557bd368728SMarko Zec }
558bd368728SMarko Zec
559bd368728SMarko Zec static int
sume_probe_riffa_pci(struct sume_adapter * adapter)560bd368728SMarko Zec sume_probe_riffa_pci(struct sume_adapter *adapter)
561bd368728SMarko Zec {
562bd368728SMarko Zec device_t dev = adapter->dev;
563bd368728SMarko Zec int error, count, capmem;
564bd368728SMarko Zec uint32_t reg, devctl, linkctl;
565bd368728SMarko Zec
566bd368728SMarko Zec pci_enable_busmaster(dev);
567bd368728SMarko Zec
568bd368728SMarko Zec adapter->rid = PCIR_BAR(0);
569bd368728SMarko Zec adapter->bar0_addr = bus_alloc_resource_any(dev, SYS_RES_MEMORY,
570bd368728SMarko Zec &adapter->rid, RF_ACTIVE);
571bd368728SMarko Zec if (adapter->bar0_addr == NULL) {
572bd368728SMarko Zec device_printf(dev, "unable to allocate bus resource: "
573bd368728SMarko Zec "BAR0 address\n");
574bd368728SMarko Zec return (ENXIO);
575bd368728SMarko Zec }
576bd368728SMarko Zec adapter->bt = rman_get_bustag(adapter->bar0_addr);
577bd368728SMarko Zec adapter->bh = rman_get_bushandle(adapter->bar0_addr);
578bd368728SMarko Zec adapter->bar0_len = rman_get_size(adapter->bar0_addr);
579bd368728SMarko Zec if (adapter->bar0_len != 1024) {
580bd368728SMarko Zec device_printf(dev, "BAR0 resource length %lu != 1024\n",
581bd368728SMarko Zec adapter->bar0_len);
582bd368728SMarko Zec return (ENXIO);
583bd368728SMarko Zec }
584bd368728SMarko Zec
585bd368728SMarko Zec count = pci_msi_count(dev);
586bd368728SMarko Zec error = pci_alloc_msi(dev, &count);
587bd368728SMarko Zec if (error) {
588bd368728SMarko Zec device_printf(dev, "unable to allocate bus resource: PCI "
589bd368728SMarko Zec "MSI\n");
590bd368728SMarko Zec return (error);
591bd368728SMarko Zec }
592bd368728SMarko Zec
593bd368728SMarko Zec adapter->irq.rid = 1; /* Should be 1, thus says pci_alloc_msi() */
594bd368728SMarko Zec adapter->irq.res = bus_alloc_resource_any(dev, SYS_RES_IRQ,
595bd368728SMarko Zec &adapter->irq.rid, RF_SHAREABLE | RF_ACTIVE);
596bd368728SMarko Zec if (adapter->irq.res == NULL) {
597bd368728SMarko Zec device_printf(dev, "unable to allocate bus resource: IRQ "
598bd368728SMarko Zec "memory\n");
599bd368728SMarko Zec return (ENXIO);
600bd368728SMarko Zec }
601bd368728SMarko Zec
602bd368728SMarko Zec error = bus_setup_intr(dev, adapter->irq.res, INTR_MPSAFE |
603bd368728SMarko Zec INTR_TYPE_NET, sume_intr_filter, sume_intr_handler, adapter,
604bd368728SMarko Zec &adapter->irq.tag);
605bd368728SMarko Zec if (error) {
606bd368728SMarko Zec device_printf(dev, "failed to setup interrupt for rid %d, name"
607bd368728SMarko Zec " %s: %d\n", adapter->irq.rid, "SUME_INTR", error);
608bd368728SMarko Zec return (ENXIO);
609bd368728SMarko Zec }
610bd368728SMarko Zec
611bd368728SMarko Zec if (pci_find_cap(dev, PCIY_EXPRESS, &capmem) != 0) {
612bd368728SMarko Zec device_printf(dev, "PCI not PCIe capable\n");
613bd368728SMarko Zec return (ENXIO);
614bd368728SMarko Zec }
615bd368728SMarko Zec
616bd368728SMarko Zec devctl = pci_read_config(dev, capmem + PCIER_DEVICE_CTL, 2);
617bd368728SMarko Zec pci_write_config(dev, capmem + PCIER_DEVICE_CTL, (devctl |
618bd368728SMarko Zec PCIEM_CTL_EXT_TAG_FIELD), 2);
619bd368728SMarko Zec
620bd368728SMarko Zec devctl = pci_read_config(dev, capmem + PCIER_DEVICE_CTL2, 2);
621bd368728SMarko Zec pci_write_config(dev, capmem + PCIER_DEVICE_CTL2, (devctl |
622bd368728SMarko Zec PCIEM_CTL2_ID_ORDERED_REQ_EN), 2);
623bd368728SMarko Zec
624bd368728SMarko Zec linkctl = pci_read_config(dev, capmem + PCIER_LINK_CTL, 2);
625bd368728SMarko Zec pci_write_config(dev, capmem + PCIER_LINK_CTL, (linkctl |
626bd368728SMarko Zec PCIEM_LINK_CTL_RCB), 2);
627bd368728SMarko Zec
628bd368728SMarko Zec reg = read_reg(adapter, RIFFA_INFO_REG_OFF);
629bd368728SMarko Zec adapter->num_sg = RIFFA_SG_ELEMS * ((reg >> 19) & 0xf);
630bd368728SMarko Zec adapter->sg_buf_size = RIFFA_SG_BUF_SIZE * ((reg >> 19) & 0xf);
631bd368728SMarko Zec
632bd368728SMarko Zec error = ENODEV;
633bd368728SMarko Zec /* Check bus master is enabled. */
634bd368728SMarko Zec if (((reg >> 4) & 0x1) != 1) {
635bd368728SMarko Zec device_printf(dev, "bus master not enabled: %d\n",
636bd368728SMarko Zec (reg >> 4) & 0x1);
637bd368728SMarko Zec return (error);
638bd368728SMarko Zec }
639bd368728SMarko Zec /* Check link parameters are valid. */
640bd368728SMarko Zec if (((reg >> 5) & 0x3f) == 0 || ((reg >> 11) & 0x3) == 0) {
641bd368728SMarko Zec device_printf(dev, "link parameters not valid: %d %d\n",
642bd368728SMarko Zec (reg >> 5) & 0x3f, (reg >> 11) & 0x3);
643bd368728SMarko Zec return (error);
644bd368728SMarko Zec }
645bd368728SMarko Zec /* Check # of channels are within valid range. */
646bd368728SMarko Zec if ((reg & 0xf) == 0 || (reg & 0xf) > RIFFA_MAX_CHNLS) {
647bd368728SMarko Zec device_printf(dev, "number of channels out of range: %d\n",
648bd368728SMarko Zec reg & 0xf);
649bd368728SMarko Zec return (error);
650bd368728SMarko Zec }
651bd368728SMarko Zec /* Check bus width. */
652bd368728SMarko Zec if (((reg >> 19) & 0xf) == 0 ||
653bd368728SMarko Zec ((reg >> 19) & 0xf) > RIFFA_MAX_BUS_WIDTH_PARAM) {
654bd368728SMarko Zec device_printf(dev, "bus width out of range: %d\n",
655bd368728SMarko Zec (reg >> 19) & 0xf);
656bd368728SMarko Zec return (error);
657bd368728SMarko Zec }
658bd368728SMarko Zec
659bd368728SMarko Zec device_printf(dev, "[riffa] # of channels: %d\n",
660bd368728SMarko Zec reg & 0xf);
661bd368728SMarko Zec device_printf(dev, "[riffa] bus interface width: %d\n",
662bd368728SMarko Zec ((reg >> 19) & 0xf) << 5);
663bd368728SMarko Zec device_printf(dev, "[riffa] bus master enabled: %d\n",
664bd368728SMarko Zec (reg >> 4) & 0x1);
665bd368728SMarko Zec device_printf(dev, "[riffa] negotiated link width: %d\n",
666bd368728SMarko Zec (reg >> 5) & 0x3f);
667bd368728SMarko Zec device_printf(dev, "[riffa] negotiated rate width: %d MTs\n",
668bd368728SMarko Zec ((reg >> 11) & 0x3) * 2500);
669bd368728SMarko Zec device_printf(dev, "[riffa] max downstream payload: %d B\n",
670bd368728SMarko Zec 128 << ((reg >> 13) & 0x7));
671bd368728SMarko Zec device_printf(dev, "[riffa] max upstream payload: %d B\n",
672bd368728SMarko Zec 128 << ((reg >> 16) & 0x7));
673bd368728SMarko Zec
674bd368728SMarko Zec return (0);
675bd368728SMarko Zec }
676bd368728SMarko Zec
677bd368728SMarko Zec /* If there is no sume_if_init, the ether_ioctl panics. */
678bd368728SMarko Zec static void
sume_if_init(void * sc)679bd368728SMarko Zec sume_if_init(void *sc)
680bd368728SMarko Zec {
681bd368728SMarko Zec }
682bd368728SMarko Zec
683bd368728SMarko Zec /* Write the address and length for our incoming / outgoing transaction. */
684bd368728SMarko Zec static void
sume_fill_bb_desc(struct sume_adapter * adapter,struct riffa_chnl_dir * p,uint64_t len)685bd368728SMarko Zec sume_fill_bb_desc(struct sume_adapter *adapter, struct riffa_chnl_dir *p,
686bd368728SMarko Zec uint64_t len)
687bd368728SMarko Zec {
688bd368728SMarko Zec struct nf_bb_desc *bouncebuf = (struct nf_bb_desc *) p->buf_addr;
689bd368728SMarko Zec
690bd368728SMarko Zec bouncebuf->lower = (p->buf_hw_addr + sizeof(struct nf_bb_desc));
691bd368728SMarko Zec bouncebuf->upper = (p->buf_hw_addr + sizeof(struct nf_bb_desc)) >> 32;
692bd368728SMarko Zec bouncebuf->len = len >> 2;
693bd368728SMarko Zec }
694bd368728SMarko Zec
695bd368728SMarko Zec /* Module register locked write. */
696bd368728SMarko Zec static int
sume_modreg_write_locked(struct sume_adapter * adapter)697bd368728SMarko Zec sume_modreg_write_locked(struct sume_adapter *adapter)
698bd368728SMarko Zec {
699bd368728SMarko Zec struct riffa_chnl_dir *send = adapter->send[SUME_RIFFA_CHANNEL_REG];
700bd368728SMarko Zec
701bd368728SMarko Zec /* Let the FPGA know about the transfer. */
702bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_REG,
703bd368728SMarko Zec RIFFA_RX_OFFLAST_REG_OFF), SUME_OFFLAST);
704bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_REG,
705bd368728SMarko Zec RIFFA_RX_LEN_REG_OFF), send->len); /* words */
706bd368728SMarko Zec
707bd368728SMarko Zec /* Fill the bouncebuf "descriptor". */
708bd368728SMarko Zec sume_fill_bb_desc(adapter, send, SUME_RIFFA_LEN(send->len));
709bd368728SMarko Zec
710bd368728SMarko Zec /* Update the state before intiating the DMA to avoid races. */
711bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_READY;
712bd368728SMarko Zec
713bd368728SMarko Zec bus_dmamap_sync(send->ch_tag, send->ch_map,
714bd368728SMarko Zec BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
715bd368728SMarko Zec /* DMA. */
716bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_REG,
717bd368728SMarko Zec RIFFA_RX_SG_ADDR_LO_REG_OFF),
718bd368728SMarko Zec SUME_RIFFA_LO_ADDR(send->buf_hw_addr));
719bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_REG,
720bd368728SMarko Zec RIFFA_RX_SG_ADDR_HI_REG_OFF),
721bd368728SMarko Zec SUME_RIFFA_HI_ADDR(send->buf_hw_addr));
722bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_REG,
723bd368728SMarko Zec RIFFA_RX_SG_LEN_REG_OFF), 4 * send->num_sg);
724bd368728SMarko Zec bus_dmamap_sync(send->ch_tag, send->ch_map,
725bd368728SMarko Zec BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
726bd368728SMarko Zec
727bd368728SMarko Zec return (0);
728bd368728SMarko Zec }
729bd368728SMarko Zec
730bd368728SMarko Zec /*
731bd368728SMarko Zec * Request a register read or write (depending on optype).
732bd368728SMarko Zec * If optype is set (0x1f) this will result in a register write,
733bd368728SMarko Zec * otherwise this will result in a register read request at the given
734bd368728SMarko Zec * address and the result will need to be DMAed back.
735bd368728SMarko Zec */
736bd368728SMarko Zec static int
sume_module_reg_write(struct nf_priv * nf_priv,struct sume_ifreq * sifr,uint32_t optype)737bd368728SMarko Zec sume_module_reg_write(struct nf_priv *nf_priv, struct sume_ifreq *sifr,
738bd368728SMarko Zec uint32_t optype)
739bd368728SMarko Zec {
740bd368728SMarko Zec struct sume_adapter *adapter = nf_priv->adapter;
741bd368728SMarko Zec struct riffa_chnl_dir *send = adapter->send[SUME_RIFFA_CHANNEL_REG];
742bd368728SMarko Zec struct nf_regop_data *data;
743bd368728SMarko Zec int error;
744bd368728SMarko Zec
745bd368728SMarko Zec /*
746bd368728SMarko Zec * 1. Make sure the channel is free; otherwise return EBUSY.
747bd368728SMarko Zec * 2. Prepare the memory in the bounce buffer (which we always
748bd368728SMarko Zec * use for regs).
749bd368728SMarko Zec * 3. Start the DMA process.
750bd368728SMarko Zec * 4. Sleep and wait for result and return success or error.
751bd368728SMarko Zec */
752bd368728SMarko Zec SUME_LOCK(adapter);
753bd368728SMarko Zec
754bd368728SMarko Zec if (send->state != SUME_RIFFA_CHAN_STATE_IDLE) {
755bd368728SMarko Zec SUME_UNLOCK(adapter);
756bd368728SMarko Zec return (EBUSY);
757bd368728SMarko Zec }
758bd368728SMarko Zec
759bd368728SMarko Zec data = (struct nf_regop_data *) (send->buf_addr +
760bd368728SMarko Zec sizeof(struct nf_bb_desc));
761bd368728SMarko Zec data->addr = htole32(sifr->addr);
762bd368728SMarko Zec data->val = htole32(sifr->val);
763bd368728SMarko Zec /* Tag to indentify request. */
764bd368728SMarko Zec data->rtag = htole32(++send->rtag);
765bd368728SMarko Zec data->optype = htole32(optype);
766bd368728SMarko Zec send->len = sizeof(struct nf_regop_data) / 4; /* words */
767bd368728SMarko Zec
768bd368728SMarko Zec error = sume_modreg_write_locked(adapter);
769bd368728SMarko Zec if (error) {
770bd368728SMarko Zec SUME_UNLOCK(adapter);
771bd368728SMarko Zec return (EFAULT);
772bd368728SMarko Zec }
773bd368728SMarko Zec
774bd368728SMarko Zec /* Timeout after 1s. */
775bd368728SMarko Zec if (send->state != SUME_RIFFA_CHAN_STATE_LEN)
776bd368728SMarko Zec error = msleep(&send->event, &adapter->lock, 0,
777bd368728SMarko Zec "Waiting recv finish", 1 * hz);
778bd368728SMarko Zec
779bd368728SMarko Zec /* This was a write so we are done; were interrupted, or timed out. */
780bd368728SMarko Zec if (optype != SUME_MR_READ || error != 0 || error == EWOULDBLOCK) {
781bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_IDLE;
782bd368728SMarko Zec if (optype == SUME_MR_READ)
783bd368728SMarko Zec error = EWOULDBLOCK;
784bd368728SMarko Zec else
785bd368728SMarko Zec error = 0;
786bd368728SMarko Zec } else
787bd368728SMarko Zec error = 0;
788bd368728SMarko Zec
789bd368728SMarko Zec /*
790bd368728SMarko Zec * For read requests we will update state once we are done
791bd368728SMarko Zec * having read the result to avoid any two outstanding
792bd368728SMarko Zec * transactions, or we need a queue and validate tags,
793bd368728SMarko Zec * which is a lot of work for a low priority, infrequent
794bd368728SMarko Zec * event.
795bd368728SMarko Zec */
796bd368728SMarko Zec
797bd368728SMarko Zec SUME_UNLOCK(adapter);
798bd368728SMarko Zec
799bd368728SMarko Zec return (error);
800bd368728SMarko Zec }
801bd368728SMarko Zec
802bd368728SMarko Zec /* Module register read. */
803bd368728SMarko Zec static int
sume_module_reg_read(struct nf_priv * nf_priv,struct sume_ifreq * sifr)804bd368728SMarko Zec sume_module_reg_read(struct nf_priv *nf_priv, struct sume_ifreq *sifr)
805bd368728SMarko Zec {
806bd368728SMarko Zec struct sume_adapter *adapter = nf_priv->adapter;
807bd368728SMarko Zec struct riffa_chnl_dir *recv = adapter->recv[SUME_RIFFA_CHANNEL_REG];
808bd368728SMarko Zec struct riffa_chnl_dir *send = adapter->send[SUME_RIFFA_CHANNEL_REG];
809bd368728SMarko Zec struct nf_regop_data *data;
810bd368728SMarko Zec int error = 0;
811bd368728SMarko Zec
812bd368728SMarko Zec /*
813bd368728SMarko Zec * 0. Sleep waiting for result if needed (unless condition is
814bd368728SMarko Zec * true already).
815bd368728SMarko Zec * 1. Read DMA results.
816bd368728SMarko Zec * 2. Update state on *TX* to IDLE to allow next read to start.
817bd368728SMarko Zec */
818bd368728SMarko Zec SUME_LOCK(adapter);
819bd368728SMarko Zec
820bd368728SMarko Zec bus_dmamap_sync(recv->ch_tag, recv->ch_map,
821bd368728SMarko Zec BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
822bd368728SMarko Zec /*
823bd368728SMarko Zec * We only need to be woken up at the end of the transaction.
824bd368728SMarko Zec * Timeout after 1s.
825bd368728SMarko Zec */
826bd368728SMarko Zec if (recv->state != SUME_RIFFA_CHAN_STATE_READ)
827bd368728SMarko Zec error = msleep(&recv->event, &adapter->lock, 0,
828bd368728SMarko Zec "Waiting transaction finish", 1 * hz);
829bd368728SMarko Zec
830bd368728SMarko Zec if (recv->state != SUME_RIFFA_CHAN_STATE_READ || error == EWOULDBLOCK) {
831bd368728SMarko Zec SUME_UNLOCK(adapter);
832bd368728SMarko Zec device_printf(adapter->dev, "wait error: %d\n", error);
833bd368728SMarko Zec return (EWOULDBLOCK);
834bd368728SMarko Zec }
835bd368728SMarko Zec
836bd368728SMarko Zec bus_dmamap_sync(recv->ch_tag, recv->ch_map,
837bd368728SMarko Zec BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
838bd368728SMarko Zec
839bd368728SMarko Zec /*
840bd368728SMarko Zec * Read reply data and validate address and tag.
841bd368728SMarko Zec * Note: we do access the send side without lock but the state
842bd368728SMarko Zec * machine does prevent the data from changing.
843bd368728SMarko Zec */
844bd368728SMarko Zec data = (struct nf_regop_data *) (recv->buf_addr +
845bd368728SMarko Zec sizeof(struct nf_bb_desc));
846bd368728SMarko Zec
847bd368728SMarko Zec if (le32toh(data->rtag) != send->rtag)
848bd368728SMarko Zec device_printf(adapter->dev, "rtag error: 0x%08x 0x%08x\n",
849bd368728SMarko Zec le32toh(data->rtag), send->rtag);
850bd368728SMarko Zec
851bd368728SMarko Zec sifr->val = le32toh(data->val);
852bd368728SMarko Zec recv->state = SUME_RIFFA_CHAN_STATE_IDLE;
853bd368728SMarko Zec
854bd368728SMarko Zec /* We are done. */
855bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_IDLE;
856bd368728SMarko Zec
857bd368728SMarko Zec SUME_UNLOCK(adapter);
858bd368728SMarko Zec
859bd368728SMarko Zec return (0);
860bd368728SMarko Zec }
861bd368728SMarko Zec
862bd368728SMarko Zec /* Read value from a module register and return it to a sume_ifreq. */
863bd368728SMarko Zec static int
get_modreg_value(struct nf_priv * nf_priv,struct sume_ifreq * sifr)864bd368728SMarko Zec get_modreg_value(struct nf_priv *nf_priv, struct sume_ifreq *sifr)
865bd368728SMarko Zec {
866bd368728SMarko Zec int error;
867bd368728SMarko Zec
868bd368728SMarko Zec error = sume_module_reg_write(nf_priv, sifr, SUME_MR_READ);
869bd368728SMarko Zec if (!error)
870bd368728SMarko Zec error = sume_module_reg_read(nf_priv, sifr);
871bd368728SMarko Zec
872bd368728SMarko Zec return (error);
873bd368728SMarko Zec }
874bd368728SMarko Zec
875bd368728SMarko Zec static int
sume_if_ioctl(if_t ifp,unsigned long cmd,caddr_t data)876cc970676SJustin Hibbits sume_if_ioctl(if_t ifp, unsigned long cmd, caddr_t data)
877bd368728SMarko Zec {
878bd368728SMarko Zec struct ifreq *ifr = (struct ifreq *) data;
879cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
880bd368728SMarko Zec struct sume_ifreq sifr;
881bd368728SMarko Zec int error = 0;
882bd368728SMarko Zec
883bd368728SMarko Zec switch (cmd) {
884bd368728SMarko Zec case SIOCGIFMEDIA:
885bd368728SMarko Zec case SIOCGIFXMEDIA:
886bd368728SMarko Zec error = ifmedia_ioctl(ifp, ifr, &nf_priv->media, cmd);
887bd368728SMarko Zec break;
888bd368728SMarko Zec
889bd368728SMarko Zec case SUME_IOCTL_CMD_WRITE_REG:
890bd368728SMarko Zec error = copyin(ifr_data_get_ptr(ifr), &sifr, sizeof(sifr));
891bd368728SMarko Zec if (error) {
892bd368728SMarko Zec error = EINVAL;
893bd368728SMarko Zec break;
894bd368728SMarko Zec }
895bd368728SMarko Zec error = sume_module_reg_write(nf_priv, &sifr, SUME_MR_WRITE);
896bd368728SMarko Zec break;
897bd368728SMarko Zec
898bd368728SMarko Zec case SUME_IOCTL_CMD_READ_REG:
899bd368728SMarko Zec error = copyin(ifr_data_get_ptr(ifr), &sifr, sizeof(sifr));
900bd368728SMarko Zec if (error) {
901bd368728SMarko Zec error = EINVAL;
902bd368728SMarko Zec break;
903bd368728SMarko Zec }
904bd368728SMarko Zec
905bd368728SMarko Zec error = get_modreg_value(nf_priv, &sifr);
906bd368728SMarko Zec if (error)
907bd368728SMarko Zec break;
908bd368728SMarko Zec
909bd368728SMarko Zec error = copyout(&sifr, ifr_data_get_ptr(ifr), sizeof(sifr));
910bd368728SMarko Zec if (error)
911bd368728SMarko Zec error = EINVAL;
912bd368728SMarko Zec
913bd368728SMarko Zec break;
914bd368728SMarko Zec
915bd368728SMarko Zec case SIOCSIFFLAGS:
916bd368728SMarko Zec /* Silence tcpdump 'promisc mode not supported' warning. */
917cc970676SJustin Hibbits if (if_getflags(ifp) & IFF_PROMISC)
918bd368728SMarko Zec break;
919bd368728SMarko Zec
920bd368728SMarko Zec default:
921bd368728SMarko Zec error = ether_ioctl(ifp, cmd, data);
922bd368728SMarko Zec break;
923bd368728SMarko Zec }
924bd368728SMarko Zec
925bd368728SMarko Zec return (error);
926bd368728SMarko Zec }
927bd368728SMarko Zec
928bd368728SMarko Zec static int
sume_media_change(if_t ifp)929cc970676SJustin Hibbits sume_media_change(if_t ifp)
930bd368728SMarko Zec {
931cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
932bd368728SMarko Zec struct ifmedia *ifm = &nf_priv->media;
933bd368728SMarko Zec
934bd368728SMarko Zec if (IFM_TYPE(ifm->ifm_media) != IFM_ETHER)
935bd368728SMarko Zec return (EINVAL);
936bd368728SMarko Zec
937bd368728SMarko Zec if (IFM_SUBTYPE(ifm->ifm_media) == IFM_10G_SR)
938cc970676SJustin Hibbits if_setbaudrate(ifp, ifmedia_baudrate(IFM_ETHER | IFM_10G_SR));
939bd368728SMarko Zec else
940cc970676SJustin Hibbits if_setbaudrate(ifp, ifmedia_baudrate(ifm->ifm_media));
941bd368728SMarko Zec
942bd368728SMarko Zec return (0);
943bd368728SMarko Zec }
944bd368728SMarko Zec
945bd368728SMarko Zec static void
sume_update_link_status(if_t ifp)946cc970676SJustin Hibbits sume_update_link_status(if_t ifp)
947bd368728SMarko Zec {
948cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
949bd368728SMarko Zec struct sume_adapter *adapter = nf_priv->adapter;
950bd368728SMarko Zec struct sume_ifreq sifr;
951bd368728SMarko Zec int link_status;
952bd368728SMarko Zec
953bd368728SMarko Zec sifr.addr = SUME_STATUS_ADDR(nf_priv->port);
954bd368728SMarko Zec sifr.val = 0;
955bd368728SMarko Zec
956bd368728SMarko Zec if (get_modreg_value(nf_priv, &sifr))
957bd368728SMarko Zec return;
958bd368728SMarko Zec
959bd368728SMarko Zec link_status = SUME_LINK_STATUS(sifr.val);
960bd368728SMarko Zec
961bd368728SMarko Zec if (!link_status && nf_priv->link_up) {
962bd368728SMarko Zec if_link_state_change(ifp, LINK_STATE_DOWN);
963bd368728SMarko Zec nf_priv->link_up = 0;
964bd368728SMarko Zec if (adapter->sume_debug)
965bd368728SMarko Zec device_printf(adapter->dev, "port %d link state "
966bd368728SMarko Zec "changed to DOWN\n", nf_priv->unit);
967bd368728SMarko Zec } else if (link_status && !nf_priv->link_up) {
968bd368728SMarko Zec nf_priv->link_up = 1;
969bd368728SMarko Zec if_link_state_change(ifp, LINK_STATE_UP);
970bd368728SMarko Zec if (adapter->sume_debug)
971bd368728SMarko Zec device_printf(adapter->dev, "port %d link state "
972bd368728SMarko Zec "changed to UP\n", nf_priv->unit);
973bd368728SMarko Zec }
974bd368728SMarko Zec }
975bd368728SMarko Zec
976bd368728SMarko Zec static void
sume_media_status(if_t ifp,struct ifmediareq * ifmr)977cc970676SJustin Hibbits sume_media_status(if_t ifp, struct ifmediareq *ifmr)
978bd368728SMarko Zec {
979cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
980bd368728SMarko Zec struct ifmedia *ifm = &nf_priv->media;
981bd368728SMarko Zec
982bd368728SMarko Zec if (ifm->ifm_cur->ifm_media == (IFM_ETHER | IFM_10G_SR) &&
983cc970676SJustin Hibbits (if_getflags(ifp) & IFF_UP))
984bd368728SMarko Zec ifmr->ifm_active = IFM_ETHER | IFM_10G_SR;
985bd368728SMarko Zec else
986bd368728SMarko Zec ifmr->ifm_active = ifm->ifm_cur->ifm_media;
987bd368728SMarko Zec
988bd368728SMarko Zec ifmr->ifm_status |= IFM_AVALID;
989bd368728SMarko Zec
990bd368728SMarko Zec sume_update_link_status(ifp);
991bd368728SMarko Zec
992bd368728SMarko Zec if (nf_priv->link_up)
993bd368728SMarko Zec ifmr->ifm_status |= IFM_ACTIVE;
994bd368728SMarko Zec }
995bd368728SMarko Zec
996bd368728SMarko Zec /*
997bd368728SMarko Zec * Packet to transmit. We take the packet data from the mbuf and copy it to the
998bd368728SMarko Zec * bouncebuffer address buf_addr+3*sizeof(uint32_t)+16. The 16 bytes before the
999bd368728SMarko Zec * packet data are for metadata: sport/dport (depending on our source
1000bd368728SMarko Zec * interface), packet length and magic 0xcafe. We tell the SUME about the
1001bd368728SMarko Zec * transfer, fill the first 3*sizeof(uint32_t) bytes of the bouncebuffer with
1002bd368728SMarko Zec * the information about the start and length of the packet and trigger the
1003bd368728SMarko Zec * transaction.
1004bd368728SMarko Zec */
1005bd368728SMarko Zec static int
sume_if_start_locked(if_t ifp)1006cc970676SJustin Hibbits sume_if_start_locked(if_t ifp)
1007bd368728SMarko Zec {
1008bd368728SMarko Zec struct mbuf *m;
1009cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
1010bd368728SMarko Zec struct sume_adapter *adapter = nf_priv->adapter;
1011bd368728SMarko Zec struct riffa_chnl_dir *send = adapter->send[SUME_RIFFA_CHANNEL_DATA];
1012bd368728SMarko Zec uint8_t *outbuf;
1013bd368728SMarko Zec struct nf_metadata *mdata;
1014bd368728SMarko Zec int plen = SUME_MIN_PKT_SIZE;
1015bd368728SMarko Zec
1016bd368728SMarko Zec KASSERT(mtx_owned(&adapter->lock), ("SUME lock not owned"));
1017bd368728SMarko Zec KASSERT(send->state == SUME_RIFFA_CHAN_STATE_IDLE,
1018bd368728SMarko Zec ("SUME not in IDLE state"));
1019bd368728SMarko Zec
1020cc970676SJustin Hibbits m = if_dequeue(ifp);
1021bd368728SMarko Zec if (m == NULL)
1022bd368728SMarko Zec return (EINVAL);
1023bd368728SMarko Zec
1024bd368728SMarko Zec /* Packets large enough do not need to be padded */
1025bd368728SMarko Zec if (m->m_pkthdr.len > SUME_MIN_PKT_SIZE)
1026bd368728SMarko Zec plen = m->m_pkthdr.len;
1027bd368728SMarko Zec
1028bd368728SMarko Zec if (adapter->sume_debug)
1029bd368728SMarko Zec device_printf(adapter->dev, "sending %d bytes to %s%d\n", plen,
1030bd368728SMarko Zec SUME_ETH_DEVICE_NAME, nf_priv->unit);
1031bd368728SMarko Zec
1032bd368728SMarko Zec outbuf = (uint8_t *) send->buf_addr + sizeof(struct nf_bb_desc);
1033bd368728SMarko Zec mdata = (struct nf_metadata *) outbuf;
1034bd368728SMarko Zec
1035bd368728SMarko Zec /* Clear the recovery flag. */
1036bd368728SMarko Zec send->recovery = 0;
1037bd368728SMarko Zec
1038bd368728SMarko Zec /* Make sure we fit with the 16 bytes nf_metadata. */
1039bd368728SMarko Zec if (m->m_pkthdr.len + sizeof(struct nf_metadata) >
1040bd368728SMarko Zec adapter->sg_buf_size) {
1041bd368728SMarko Zec device_printf(adapter->dev, "packet too big for bounce buffer "
1042bd368728SMarko Zec "(%d)\n", m->m_pkthdr.len);
1043bd368728SMarko Zec m_freem(m);
1044bd368728SMarko Zec nf_priv->stats.tx_dropped++;
1045bd368728SMarko Zec return (ENOMEM);
1046bd368728SMarko Zec }
1047bd368728SMarko Zec
1048bd368728SMarko Zec bus_dmamap_sync(send->ch_tag, send->ch_map,
1049bd368728SMarko Zec BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
1050bd368728SMarko Zec
1051bd368728SMarko Zec /* Zero out the padded data */
1052bd368728SMarko Zec if (m->m_pkthdr.len < SUME_MIN_PKT_SIZE)
1053bd368728SMarko Zec bzero(outbuf + sizeof(struct nf_metadata), SUME_MIN_PKT_SIZE);
1054bd368728SMarko Zec /* Skip the first 16 bytes for the metadata. */
1055bd368728SMarko Zec m_copydata(m, 0, m->m_pkthdr.len, outbuf + sizeof(struct nf_metadata));
1056bd368728SMarko Zec send->len = (sizeof(struct nf_metadata) + plen + 3) / 4;
1057bd368728SMarko Zec
1058bd368728SMarko Zec /* Fill in the metadata: CPU(DMA) ports are odd, MAC ports are even. */
1059bd368728SMarko Zec mdata->sport = htole16(1 << (nf_priv->port * 2 + 1));
1060bd368728SMarko Zec mdata->dport = htole16(1 << (nf_priv->port * 2));
1061bd368728SMarko Zec mdata->plen = htole16(plen);
1062bd368728SMarko Zec mdata->magic = htole16(SUME_RIFFA_MAGIC);
1063bd368728SMarko Zec mdata->t1 = htole32(0);
1064bd368728SMarko Zec mdata->t2 = htole32(0);
1065bd368728SMarko Zec
1066bd368728SMarko Zec /* Let the FPGA know about the transfer. */
1067bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_DATA,
1068bd368728SMarko Zec RIFFA_RX_OFFLAST_REG_OFF), SUME_OFFLAST);
1069bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_DATA,
1070bd368728SMarko Zec RIFFA_RX_LEN_REG_OFF), send->len);
1071bd368728SMarko Zec
1072bd368728SMarko Zec /* Fill the bouncebuf "descriptor". */
1073bd368728SMarko Zec sume_fill_bb_desc(adapter, send, SUME_RIFFA_LEN(send->len));
1074bd368728SMarko Zec
1075bd368728SMarko Zec /* Update the state before intiating the DMA to avoid races. */
1076bd368728SMarko Zec send->state = SUME_RIFFA_CHAN_STATE_READY;
1077bd368728SMarko Zec
1078bd368728SMarko Zec /* DMA. */
1079bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_DATA,
1080bd368728SMarko Zec RIFFA_RX_SG_ADDR_LO_REG_OFF),
1081bd368728SMarko Zec SUME_RIFFA_LO_ADDR(send->buf_hw_addr));
1082bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_DATA,
1083bd368728SMarko Zec RIFFA_RX_SG_ADDR_HI_REG_OFF),
1084bd368728SMarko Zec SUME_RIFFA_HI_ADDR(send->buf_hw_addr));
1085bd368728SMarko Zec write_reg(adapter, RIFFA_CHNL_REG(SUME_RIFFA_CHANNEL_DATA,
1086bd368728SMarko Zec RIFFA_RX_SG_LEN_REG_OFF), 4 * send->num_sg);
1087bd368728SMarko Zec
1088bd368728SMarko Zec bus_dmamap_sync(send->ch_tag, send->ch_map,
1089bd368728SMarko Zec BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
1090bd368728SMarko Zec
1091bd368728SMarko Zec nf_priv->stats.tx_packets++;
1092bd368728SMarko Zec nf_priv->stats.tx_bytes += plen;
1093bd368728SMarko Zec
1094bd368728SMarko Zec /* We can free as long as we use the bounce buffer. */
1095bd368728SMarko Zec m_freem(m);
1096bd368728SMarko Zec
1097bd368728SMarko Zec adapter->last_ifc = nf_priv->port;
1098bd368728SMarko Zec
1099bd368728SMarko Zec /* Reset watchdog counter. */
1100bd368728SMarko Zec adapter->wd_counter = 0;
1101bd368728SMarko Zec
1102bd368728SMarko Zec return (0);
1103bd368728SMarko Zec }
1104bd368728SMarko Zec
1105bd368728SMarko Zec static void
sume_if_start(if_t ifp)1106cc970676SJustin Hibbits sume_if_start(if_t ifp)
1107bd368728SMarko Zec {
1108cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
1109bd368728SMarko Zec struct sume_adapter *adapter = nf_priv->adapter;
1110bd368728SMarko Zec
1111cc970676SJustin Hibbits if (!adapter->running || !(if_getflags(ifp) & IFF_UP))
1112bd368728SMarko Zec return;
1113bd368728SMarko Zec
1114bd368728SMarko Zec SUME_LOCK(adapter);
1115bd368728SMarko Zec if (adapter->send[SUME_RIFFA_CHANNEL_DATA]->state ==
1116bd368728SMarko Zec SUME_RIFFA_CHAN_STATE_IDLE)
1117bd368728SMarko Zec sume_if_start_locked(ifp);
1118bd368728SMarko Zec SUME_UNLOCK(adapter);
1119bd368728SMarko Zec }
1120bd368728SMarko Zec
1121bd368728SMarko Zec /*
1122bd368728SMarko Zec * We call this function at the end of every TX transaction to check for
1123bd368728SMarko Zec * remaining packets in the TX queues for every UP interface.
1124bd368728SMarko Zec */
1125bd368728SMarko Zec static void
check_tx_queues(struct sume_adapter * adapter)1126bd368728SMarko Zec check_tx_queues(struct sume_adapter *adapter)
1127bd368728SMarko Zec {
1128bd368728SMarko Zec int i, last_ifc;
1129bd368728SMarko Zec
1130bd368728SMarko Zec KASSERT(mtx_owned(&adapter->lock), ("SUME lock not owned"));
1131bd368728SMarko Zec
1132bd368728SMarko Zec last_ifc = adapter->last_ifc;
1133bd368728SMarko Zec
1134bd368728SMarko Zec /* Check all interfaces */
1135bd368728SMarko Zec for (i = last_ifc + 1; i < last_ifc + SUME_NPORTS + 1; i++) {
1136cc970676SJustin Hibbits if_t ifp = adapter->ifp[i % SUME_NPORTS];
1137bd368728SMarko Zec
1138cc970676SJustin Hibbits if (!(if_getflags(ifp) & IFF_UP))
1139bd368728SMarko Zec continue;
1140bd368728SMarko Zec
1141bd368728SMarko Zec if (!sume_if_start_locked(ifp))
1142bd368728SMarko Zec break;
1143bd368728SMarko Zec }
1144bd368728SMarko Zec }
1145bd368728SMarko Zec
1146aa386085SZhenlei Huang static void
sume_ifp_alloc(struct sume_adapter * adapter,uint32_t port)1147bd368728SMarko Zec sume_ifp_alloc(struct sume_adapter *adapter, uint32_t port)
1148bd368728SMarko Zec {
1149cc970676SJustin Hibbits if_t ifp;
1150bd368728SMarko Zec struct nf_priv *nf_priv = malloc(sizeof(struct nf_priv), M_SUME,
1151bd368728SMarko Zec M_ZERO | M_WAITOK);
1152bd368728SMarko Zec
1153bd368728SMarko Zec ifp = if_alloc(IFT_ETHER);
1154bd368728SMarko Zec adapter->ifp[port] = ifp;
1155cc970676SJustin Hibbits if_setsoftc(ifp, nf_priv);
1156bd368728SMarko Zec
1157bd368728SMarko Zec nf_priv->adapter = adapter;
1158bd368728SMarko Zec nf_priv->unit = alloc_unr(unr);
1159bd368728SMarko Zec nf_priv->port = port;
1160bd368728SMarko Zec nf_priv->link_up = 0;
1161bd368728SMarko Zec
1162bd368728SMarko Zec if_initname(ifp, SUME_ETH_DEVICE_NAME, nf_priv->unit);
1163cc970676SJustin Hibbits if_setflags(ifp, IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST);
1164bd368728SMarko Zec
1165cc970676SJustin Hibbits if_setinitfn(ifp, sume_if_init);
1166cc970676SJustin Hibbits if_setstartfn(ifp, sume_if_start);
1167cc970676SJustin Hibbits if_setioctlfn(ifp, sume_if_ioctl);
1168bd368728SMarko Zec
1169bd368728SMarko Zec uint8_t hw_addr[ETHER_ADDR_LEN] = DEFAULT_ETHER_ADDRESS;
1170bd368728SMarko Zec hw_addr[ETHER_ADDR_LEN-1] = nf_priv->unit;
1171bd368728SMarko Zec ether_ifattach(ifp, hw_addr);
1172bd368728SMarko Zec
1173bd368728SMarko Zec ifmedia_init(&nf_priv->media, IFM_IMASK, sume_media_change,
1174bd368728SMarko Zec sume_media_status);
1175bd368728SMarko Zec ifmedia_add(&nf_priv->media, IFM_ETHER | IFM_10G_SR, 0, NULL);
1176bd368728SMarko Zec ifmedia_set(&nf_priv->media, IFM_ETHER | IFM_10G_SR);
1177bd368728SMarko Zec
1178cc970676SJustin Hibbits if_setdrvflagbits(ifp, IFF_DRV_RUNNING, 0);
1179bd368728SMarko Zec }
1180bd368728SMarko Zec
1181bd368728SMarko Zec static void
callback_dma(void * arg,bus_dma_segment_t * segs,int nseg,int err)1182bd368728SMarko Zec callback_dma(void *arg, bus_dma_segment_t *segs, int nseg, int err)
1183bd368728SMarko Zec {
1184bd368728SMarko Zec if (err)
1185bd368728SMarko Zec return;
1186bd368728SMarko Zec
1187bd368728SMarko Zec KASSERT(nseg == 1, ("%d segments returned!", nseg));
1188bd368728SMarko Zec
1189bd368728SMarko Zec *(bus_addr_t *) arg = segs[0].ds_addr;
1190bd368728SMarko Zec }
1191bd368728SMarko Zec
1192bd368728SMarko Zec static int
sume_probe_riffa_buffer(const struct sume_adapter * adapter,struct riffa_chnl_dir *** p,const char * dir)1193bd368728SMarko Zec sume_probe_riffa_buffer(const struct sume_adapter *adapter,
1194bd368728SMarko Zec struct riffa_chnl_dir ***p, const char *dir)
1195bd368728SMarko Zec {
1196bd368728SMarko Zec struct riffa_chnl_dir **rp;
1197bd368728SMarko Zec bus_addr_t hw_addr;
1198*761339c5SZhenlei Huang int ch;
1199bd368728SMarko Zec device_t dev = adapter->dev;
1200bd368728SMarko Zec
1201bd368728SMarko Zec *p = malloc(SUME_RIFFA_CHANNELS * sizeof(struct riffa_chnl_dir *),
1202bd368728SMarko Zec M_SUME, M_ZERO | M_WAITOK);
1203bd368728SMarko Zec
1204bd368728SMarko Zec rp = *p;
1205bd368728SMarko Zec /* Allocate the chnl_dir structs themselves. */
1206bd368728SMarko Zec for (ch = 0; ch < SUME_RIFFA_CHANNELS; ch++) {
1207bd368728SMarko Zec /* One direction. */
1208bd368728SMarko Zec rp[ch] = malloc(sizeof(struct riffa_chnl_dir), M_SUME,
1209bd368728SMarko Zec M_ZERO | M_WAITOK);
1210bd368728SMarko Zec
1211bd368728SMarko Zec int err = bus_dma_tag_create(bus_get_dma_tag(dev),
1212bd368728SMarko Zec 4, 0,
1213bd368728SMarko Zec BUS_SPACE_MAXADDR,
1214bd368728SMarko Zec BUS_SPACE_MAXADDR,
1215bd368728SMarko Zec NULL, NULL,
1216bd368728SMarko Zec adapter->sg_buf_size,
1217bd368728SMarko Zec 1,
1218bd368728SMarko Zec adapter->sg_buf_size,
1219bd368728SMarko Zec 0,
1220bd368728SMarko Zec NULL,
1221bd368728SMarko Zec NULL,
1222bd368728SMarko Zec &rp[ch]->ch_tag);
1223bd368728SMarko Zec
1224bd368728SMarko Zec if (err) {
1225bd368728SMarko Zec device_printf(dev, "bus_dma_tag_create(%s[%d]) "
1226bd368728SMarko Zec "failed.\n", dir, ch);
1227bd368728SMarko Zec return (err);
1228bd368728SMarko Zec }
1229bd368728SMarko Zec
1230bd368728SMarko Zec err = bus_dmamem_alloc(rp[ch]->ch_tag, (void **)
1231bd368728SMarko Zec &rp[ch]->buf_addr, BUS_DMA_WAITOK | BUS_DMA_COHERENT |
1232bd368728SMarko Zec BUS_DMA_ZERO, &rp[ch]->ch_map);
1233bd368728SMarko Zec if (err) {
1234bd368728SMarko Zec device_printf(dev, "bus_dmamem_alloc(%s[%d]) failed.\n",
1235bd368728SMarko Zec dir, ch);
1236bd368728SMarko Zec return (err);
1237bd368728SMarko Zec }
1238bd368728SMarko Zec
1239bd368728SMarko Zec bzero(rp[ch]->buf_addr, adapter->sg_buf_size);
1240bd368728SMarko Zec
1241bd368728SMarko Zec err = bus_dmamap_load(rp[ch]->ch_tag, rp[ch]->ch_map,
1242bd368728SMarko Zec rp[ch]->buf_addr, adapter->sg_buf_size, callback_dma,
1243bd368728SMarko Zec &hw_addr, BUS_DMA_NOWAIT);
1244bd368728SMarko Zec if (err) {
1245bd368728SMarko Zec device_printf(dev, "bus_dmamap_load(%s[%d]) failed.\n",
1246bd368728SMarko Zec dir, ch);
1247bd368728SMarko Zec return (err);
1248bd368728SMarko Zec }
1249bd368728SMarko Zec rp[ch]->buf_hw_addr = hw_addr;
1250bd368728SMarko Zec rp[ch]->num_sg = 1;
1251bd368728SMarko Zec rp[ch]->state = SUME_RIFFA_CHAN_STATE_IDLE;
1252bd368728SMarko Zec
1253bd368728SMarko Zec rp[ch]->rtag = SUME_INIT_RTAG;
1254bd368728SMarko Zec }
1255bd368728SMarko Zec
1256bd368728SMarko Zec return (0);
1257bd368728SMarko Zec }
1258bd368728SMarko Zec
1259bd368728SMarko Zec static int
sume_probe_riffa_buffers(struct sume_adapter * adapter)1260bd368728SMarko Zec sume_probe_riffa_buffers(struct sume_adapter *adapter)
1261bd368728SMarko Zec {
1262bd368728SMarko Zec int error;
1263bd368728SMarko Zec
1264bd368728SMarko Zec error = sume_probe_riffa_buffer(adapter, &adapter->recv, "recv");
1265bd368728SMarko Zec if (error)
1266bd368728SMarko Zec return (error);
1267bd368728SMarko Zec
1268bd368728SMarko Zec error = sume_probe_riffa_buffer(adapter, &adapter->send, "send");
1269bd368728SMarko Zec
1270bd368728SMarko Zec return (error);
1271bd368728SMarko Zec }
1272bd368728SMarko Zec
1273bd368728SMarko Zec static void
sume_sysctl_init(struct sume_adapter * adapter)1274bd368728SMarko Zec sume_sysctl_init(struct sume_adapter *adapter)
1275bd368728SMarko Zec {
1276bd368728SMarko Zec device_t dev = adapter->dev;
1277bd368728SMarko Zec struct sysctl_ctx_list *ctx = device_get_sysctl_ctx(dev);
1278bd368728SMarko Zec struct sysctl_oid *tree = device_get_sysctl_tree(dev);
1279bd368728SMarko Zec struct sysctl_oid_list *child = SYSCTL_CHILDREN(tree);
1280bd368728SMarko Zec struct sysctl_oid *tmp_tree;
1281bd368728SMarko Zec char namebuf[MAX_IFC_NAME_LEN];
1282bd368728SMarko Zec int i;
1283bd368728SMarko Zec
1284bd368728SMarko Zec tree = SYSCTL_ADD_NODE(ctx, child, OID_AUTO, "sume", CTLFLAG_RW,
1285bd368728SMarko Zec 0, "SUME top-level tree");
1286bd368728SMarko Zec if (tree == NULL) {
1287bd368728SMarko Zec device_printf(dev, "SYSCTL_ADD_NODE failed.\n");
1288bd368728SMarko Zec return;
1289bd368728SMarko Zec }
1290bd368728SMarko Zec SYSCTL_ADD_INT(ctx, child, OID_AUTO, "debug", CTLFLAG_RW,
1291bd368728SMarko Zec &adapter->sume_debug, 0, "debug int leaf");
1292bd368728SMarko Zec
1293bd368728SMarko Zec /* total RX error stats */
1294bd368728SMarko Zec SYSCTL_ADD_U64(ctx, child, OID_AUTO, "rx_epkts",
1295bd368728SMarko Zec CTLFLAG_RD, &adapter->packets_err, 0, "rx errors");
1296bd368728SMarko Zec SYSCTL_ADD_U64(ctx, child, OID_AUTO, "rx_ebytes",
1297bd368728SMarko Zec CTLFLAG_RD, &adapter->bytes_err, 0, "rx error bytes");
1298bd368728SMarko Zec
1299bd368728SMarko Zec for (i = SUME_NPORTS - 1; i >= 0; i--) {
1300cc970676SJustin Hibbits if_t ifp = adapter->ifp[i];
1301bd368728SMarko Zec if (ifp == NULL)
1302bd368728SMarko Zec continue;
1303bd368728SMarko Zec
1304cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
1305bd368728SMarko Zec
1306bd368728SMarko Zec snprintf(namebuf, MAX_IFC_NAME_LEN, "%s%d",
1307bd368728SMarko Zec SUME_ETH_DEVICE_NAME, nf_priv->unit);
1308bd368728SMarko Zec tmp_tree = SYSCTL_ADD_NODE(ctx, child, OID_AUTO, namebuf,
1309bd368728SMarko Zec CTLFLAG_RW, 0, "SUME ifc tree");
1310bd368728SMarko Zec if (tmp_tree == NULL) {
1311bd368728SMarko Zec device_printf(dev, "SYSCTL_ADD_NODE failed.\n");
1312bd368728SMarko Zec return;
1313bd368728SMarko Zec }
1314bd368728SMarko Zec
1315bd368728SMarko Zec /* Packets dropped by down interface. */
1316bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1317bd368728SMarko Zec "ifc_down_bytes", CTLFLAG_RD,
1318bd368728SMarko Zec &nf_priv->stats.ifc_down_bytes, 0, "ifc_down bytes");
1319bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1320bd368728SMarko Zec "ifc_down_packets", CTLFLAG_RD,
1321bd368728SMarko Zec &nf_priv->stats.ifc_down_packets, 0, "ifc_down packets");
1322bd368728SMarko Zec
1323bd368728SMarko Zec /* HW RX stats */
1324bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1325bd368728SMarko Zec "hw_rx_packets", CTLFLAG_RD, &nf_priv->stats.hw_rx_packets,
1326bd368728SMarko Zec 0, "hw_rx packets");
1327bd368728SMarko Zec
1328bd368728SMarko Zec /* HW TX stats */
1329bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1330bd368728SMarko Zec "hw_tx_packets", CTLFLAG_RD, &nf_priv->stats.hw_tx_packets,
1331bd368728SMarko Zec 0, "hw_tx packets");
1332bd368728SMarko Zec
1333bd368728SMarko Zec /* RX stats */
1334bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1335bd368728SMarko Zec "rx_bytes", CTLFLAG_RD, &nf_priv->stats.rx_bytes, 0,
1336bd368728SMarko Zec "rx bytes");
1337bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1338bd368728SMarko Zec "rx_dropped", CTLFLAG_RD, &nf_priv->stats.rx_dropped, 0,
1339bd368728SMarko Zec "rx dropped");
1340bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1341bd368728SMarko Zec "rx_packets", CTLFLAG_RD, &nf_priv->stats.rx_packets, 0,
1342bd368728SMarko Zec "rx packets");
1343bd368728SMarko Zec
1344bd368728SMarko Zec /* TX stats */
1345bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1346bd368728SMarko Zec "tx_bytes", CTLFLAG_RD, &nf_priv->stats.tx_bytes, 0,
1347bd368728SMarko Zec "tx bytes");
1348bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1349bd368728SMarko Zec "tx_dropped", CTLFLAG_RD, &nf_priv->stats.tx_dropped, 0,
1350bd368728SMarko Zec "tx dropped");
1351bd368728SMarko Zec SYSCTL_ADD_U64(ctx, SYSCTL_CHILDREN(tmp_tree), OID_AUTO,
1352bd368728SMarko Zec "tx_packets", CTLFLAG_RD, &nf_priv->stats.tx_packets, 0,
1353bd368728SMarko Zec "tx packets");
1354bd368728SMarko Zec }
1355bd368728SMarko Zec }
1356bd368728SMarko Zec
1357bd368728SMarko Zec static void
sume_local_timer(void * arg)1358bd368728SMarko Zec sume_local_timer(void *arg)
1359bd368728SMarko Zec {
1360bd368728SMarko Zec struct sume_adapter *adapter = arg;
1361bd368728SMarko Zec
1362bd368728SMarko Zec if (!adapter->running)
1363bd368728SMarko Zec return;
1364bd368728SMarko Zec
1365bd368728SMarko Zec taskqueue_enqueue(adapter->tq, &adapter->stat_task);
1366bd368728SMarko Zec
1367bd368728SMarko Zec SUME_LOCK(adapter);
1368bd368728SMarko Zec if (adapter->send[SUME_RIFFA_CHANNEL_DATA]->state !=
1369bd368728SMarko Zec SUME_RIFFA_CHAN_STATE_IDLE && ++adapter->wd_counter >= 3) {
1370bd368728SMarko Zec /* Resetting interfaces if stuck for 3 seconds. */
1371bd368728SMarko Zec device_printf(adapter->dev, "TX stuck, resetting adapter.\n");
1372bd368728SMarko Zec read_reg(adapter, RIFFA_INFO_REG_OFF);
1373bd368728SMarko Zec
1374bd368728SMarko Zec adapter->send[SUME_RIFFA_CHANNEL_DATA]->state =
1375bd368728SMarko Zec SUME_RIFFA_CHAN_STATE_IDLE;
1376bd368728SMarko Zec adapter->wd_counter = 0;
1377bd368728SMarko Zec
1378bd368728SMarko Zec check_tx_queues(adapter);
1379bd368728SMarko Zec }
1380bd368728SMarko Zec SUME_UNLOCK(adapter);
1381bd368728SMarko Zec
1382bd368728SMarko Zec callout_reset(&adapter->timer, 1 * hz, sume_local_timer, adapter);
1383bd368728SMarko Zec }
1384bd368728SMarko Zec
1385bd368728SMarko Zec static void
sume_get_stats(void * context,int pending)1386bd368728SMarko Zec sume_get_stats(void *context, int pending)
1387bd368728SMarko Zec {
1388bd368728SMarko Zec struct sume_adapter *adapter = context;
1389bd368728SMarko Zec int i;
1390bd368728SMarko Zec
1391bd368728SMarko Zec for (i = 0; i < SUME_NPORTS; i++) {
1392cc970676SJustin Hibbits if_t ifp = adapter->ifp[i];
1393bd368728SMarko Zec
1394cc970676SJustin Hibbits if (if_getflags(ifp) & IFF_UP) {
1395cc970676SJustin Hibbits struct nf_priv *nf_priv = if_getsoftc(ifp);
1396bd368728SMarko Zec struct sume_ifreq sifr;
1397bd368728SMarko Zec
1398bd368728SMarko Zec sume_update_link_status(ifp);
1399bd368728SMarko Zec
1400bd368728SMarko Zec /* Get RX counter. */
1401bd368728SMarko Zec sifr.addr = SUME_STAT_RX_ADDR(nf_priv->port);
1402bd368728SMarko Zec sifr.val = 0;
1403bd368728SMarko Zec
1404bd368728SMarko Zec if (!get_modreg_value(nf_priv, &sifr))
1405bd368728SMarko Zec nf_priv->stats.hw_rx_packets += sifr.val;
1406bd368728SMarko Zec
1407bd368728SMarko Zec /* Get TX counter. */
1408bd368728SMarko Zec sifr.addr = SUME_STAT_TX_ADDR(nf_priv->port);
1409bd368728SMarko Zec sifr.val = 0;
1410bd368728SMarko Zec
1411bd368728SMarko Zec if (!get_modreg_value(nf_priv, &sifr))
1412bd368728SMarko Zec nf_priv->stats.hw_tx_packets += sifr.val;
1413bd368728SMarko Zec }
1414bd368728SMarko Zec }
1415bd368728SMarko Zec }
1416bd368728SMarko Zec
1417bd368728SMarko Zec static int
sume_attach(device_t dev)1418bd368728SMarko Zec sume_attach(device_t dev)
1419bd368728SMarko Zec {
1420bd368728SMarko Zec struct sume_adapter *adapter = device_get_softc(dev);
1421bd368728SMarko Zec adapter->dev = dev;
1422bd368728SMarko Zec int error, i;
1423bd368728SMarko Zec
1424bd368728SMarko Zec mtx_init(&adapter->lock, "Global lock", NULL, MTX_DEF);
1425bd368728SMarko Zec
1426bd368728SMarko Zec adapter->running = 0;
1427bd368728SMarko Zec
1428bd368728SMarko Zec /* OK finish up RIFFA. */
1429bd368728SMarko Zec error = sume_probe_riffa_pci(adapter);
1430bd368728SMarko Zec if (error != 0)
1431bd368728SMarko Zec goto error;
1432bd368728SMarko Zec
1433bd368728SMarko Zec error = sume_probe_riffa_buffers(adapter);
1434bd368728SMarko Zec if (error != 0)
1435bd368728SMarko Zec goto error;
1436bd368728SMarko Zec
1437bd368728SMarko Zec /* Now do the network interfaces. */
1438aa386085SZhenlei Huang for (i = 0; i < SUME_NPORTS; i++)
1439aa386085SZhenlei Huang sume_ifp_alloc(adapter, i);
1440bd368728SMarko Zec
1441bd368728SMarko Zec /* Register stats and register sysctls. */
1442bd368728SMarko Zec sume_sysctl_init(adapter);
1443bd368728SMarko Zec
1444bd368728SMarko Zec /* Reset the HW. */
1445bd368728SMarko Zec read_reg(adapter, RIFFA_INFO_REG_OFF);
1446bd368728SMarko Zec
1447bd368728SMarko Zec /* Ready to go, "enable" IRQ. */
1448bd368728SMarko Zec adapter->running = 1;
1449bd368728SMarko Zec
1450bd368728SMarko Zec callout_init(&adapter->timer, 1);
1451bd368728SMarko Zec TASK_INIT(&adapter->stat_task, 0, sume_get_stats, adapter);
1452bd368728SMarko Zec
1453bd368728SMarko Zec adapter->tq = taskqueue_create("sume_stats", M_NOWAIT,
1454bd368728SMarko Zec taskqueue_thread_enqueue, &adapter->tq);
1455bd368728SMarko Zec taskqueue_start_threads(&adapter->tq, 1, PI_NET, "%s stattaskq",
1456bd368728SMarko Zec device_get_nameunit(adapter->dev));
1457bd368728SMarko Zec
1458bd368728SMarko Zec callout_reset(&adapter->timer, 1 * hz, sume_local_timer, adapter);
1459bd368728SMarko Zec
1460bd368728SMarko Zec return (0);
1461bd368728SMarko Zec
1462bd368728SMarko Zec error:
1463bd368728SMarko Zec sume_detach(dev);
1464bd368728SMarko Zec
1465bd368728SMarko Zec return (error);
1466bd368728SMarko Zec }
1467bd368728SMarko Zec
1468bd368728SMarko Zec static void
sume_remove_riffa_buffer(const struct sume_adapter * adapter,struct riffa_chnl_dir ** pp)1469bd368728SMarko Zec sume_remove_riffa_buffer(const struct sume_adapter *adapter,
1470bd368728SMarko Zec struct riffa_chnl_dir **pp)
1471bd368728SMarko Zec {
1472bd368728SMarko Zec int ch;
1473bd368728SMarko Zec
1474bd368728SMarko Zec for (ch = 0; ch < SUME_RIFFA_CHANNELS; ch++) {
1475bd368728SMarko Zec if (pp[ch] == NULL)
1476bd368728SMarko Zec continue;
1477bd368728SMarko Zec
1478bd368728SMarko Zec if (pp[ch]->buf_hw_addr != 0) {
1479bd368728SMarko Zec bus_dmamem_free(pp[ch]->ch_tag, pp[ch]->buf_addr,
1480bd368728SMarko Zec pp[ch]->ch_map);
1481bd368728SMarko Zec pp[ch]->buf_hw_addr = 0;
1482bd368728SMarko Zec }
1483bd368728SMarko Zec
1484bd368728SMarko Zec free(pp[ch], M_SUME);
1485bd368728SMarko Zec }
1486bd368728SMarko Zec }
1487bd368728SMarko Zec
1488bd368728SMarko Zec static void
sume_remove_riffa_buffers(struct sume_adapter * adapter)1489bd368728SMarko Zec sume_remove_riffa_buffers(struct sume_adapter *adapter)
1490bd368728SMarko Zec {
1491bd368728SMarko Zec if (adapter->send != NULL) {
1492bd368728SMarko Zec sume_remove_riffa_buffer(adapter, adapter->send);
1493bd368728SMarko Zec free(adapter->send, M_SUME);
1494bd368728SMarko Zec adapter->send = NULL;
1495bd368728SMarko Zec }
1496bd368728SMarko Zec if (adapter->recv != NULL) {
1497bd368728SMarko Zec sume_remove_riffa_buffer(adapter, adapter->recv);
1498bd368728SMarko Zec free(adapter->recv, M_SUME);
1499bd368728SMarko Zec adapter->recv = NULL;
1500bd368728SMarko Zec }
1501bd368728SMarko Zec }
1502bd368728SMarko Zec
1503bd368728SMarko Zec static int
sume_detach(device_t dev)1504bd368728SMarko Zec sume_detach(device_t dev)
1505bd368728SMarko Zec {
1506bd368728SMarko Zec struct sume_adapter *adapter = device_get_softc(dev);
1507bd368728SMarko Zec int i;
1508bd368728SMarko Zec struct nf_priv *nf_priv;
1509bd368728SMarko Zec
1510bd368728SMarko Zec KASSERT(mtx_initialized(&adapter->lock), ("SUME mutex not "
1511bd368728SMarko Zec "initialized"));
1512bd368728SMarko Zec adapter->running = 0;
1513bd368728SMarko Zec
1514bd368728SMarko Zec /* Drain the stats callout and task queue. */
1515bd368728SMarko Zec callout_drain(&adapter->timer);
1516bd368728SMarko Zec
1517bd368728SMarko Zec if (adapter->tq) {
1518bd368728SMarko Zec taskqueue_drain(adapter->tq, &adapter->stat_task);
1519bd368728SMarko Zec taskqueue_free(adapter->tq);
1520bd368728SMarko Zec }
1521bd368728SMarko Zec
1522bd368728SMarko Zec for (i = 0; i < SUME_NPORTS; i++) {
1523cc970676SJustin Hibbits if_t ifp = adapter->ifp[i];
1524bd368728SMarko Zec if (ifp == NULL)
1525bd368728SMarko Zec continue;
1526bd368728SMarko Zec
1527cc970676SJustin Hibbits if_setdrvflagbits(ifp, 0, IFF_DRV_RUNNING);
1528cc970676SJustin Hibbits nf_priv = if_getsoftc(ifp);
1529bd368728SMarko Zec
1530cc970676SJustin Hibbits if (if_getflags(ifp) & IFF_UP)
1531bd368728SMarko Zec if_down(ifp);
1532bd368728SMarko Zec ifmedia_removeall(&nf_priv->media);
1533bd368728SMarko Zec free_unr(unr, nf_priv->unit);
1534bd368728SMarko Zec
1535cc970676SJustin Hibbits if_setflagbits(ifp, 0, IFF_UP);
1536bd368728SMarko Zec ether_ifdetach(ifp);
1537bd368728SMarko Zec if_free(ifp);
1538bd368728SMarko Zec
1539bd368728SMarko Zec free(nf_priv, M_SUME);
1540bd368728SMarko Zec }
1541bd368728SMarko Zec
1542bd368728SMarko Zec sume_remove_riffa_buffers(adapter);
1543bd368728SMarko Zec
1544bd368728SMarko Zec if (adapter->irq.tag)
1545bd368728SMarko Zec bus_teardown_intr(dev, adapter->irq.res, adapter->irq.tag);
1546bd368728SMarko Zec if (adapter->irq.res)
1547bd368728SMarko Zec bus_release_resource(dev, SYS_RES_IRQ, adapter->irq.rid,
1548bd368728SMarko Zec adapter->irq.res);
1549bd368728SMarko Zec
1550bd368728SMarko Zec pci_release_msi(dev);
1551bd368728SMarko Zec
1552bd368728SMarko Zec if (adapter->bar0_addr)
1553bd368728SMarko Zec bus_release_resource(dev, SYS_RES_MEMORY, adapter->rid,
1554bd368728SMarko Zec adapter->bar0_addr);
1555bd368728SMarko Zec
1556bd368728SMarko Zec mtx_destroy(&adapter->lock);
1557bd368728SMarko Zec
1558bd368728SMarko Zec return (0);
1559bd368728SMarko Zec }
1560bd368728SMarko Zec
1561bd368728SMarko Zec static int
mod_event(module_t mod,int cmd,void * arg)1562bd368728SMarko Zec mod_event(module_t mod, int cmd, void *arg)
1563bd368728SMarko Zec {
1564bd368728SMarko Zec switch (cmd) {
1565bd368728SMarko Zec case MOD_LOAD:
1566bd368728SMarko Zec unr = new_unrhdr(0, INT_MAX, NULL);
1567bd368728SMarko Zec break;
1568bd368728SMarko Zec
1569bd368728SMarko Zec case MOD_UNLOAD:
1570bd368728SMarko Zec delete_unrhdr(unr);
1571bd368728SMarko Zec break;
1572bd368728SMarko Zec }
1573bd368728SMarko Zec
1574bd368728SMarko Zec return (0);
1575bd368728SMarko Zec }
1576bd368728SMarko Zec
157710155347SJohn Baldwin DRIVER_MODULE(sume, pci, sume_driver, mod_event, NULL);
1578bd368728SMarko Zec MODULE_VERSION(sume, 1);
1579