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1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287 1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 | /* * Copyright (c) 2010 Broadcom Corporation * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* ****************** SDIO CARD Interface Functions **************************/ #include <linux/types.h> #include <linux/netdevice.h> #include <linux/pci.h> #include <linux/pci_ids.h> #include <linux/sched.h> #include <linux/completion.h> #include <linux/interrupt.h> #include <linux/scatterlist.h> #include <linux/mmc/sdio.h> #include <linux/mmc/core.h> #include <linux/mmc/sdio_func.h> #include <linux/mmc/card.h> #include <linux/mmc/host.h> #include <linux/pm_runtime.h> #include <linux/suspend.h> #include <linux/errno.h> #include <linux/module.h> #include <linux/acpi.h> #include <net/cfg80211.h> #include <defs.h> #include <brcm_hw_ids.h> #include <brcmu_utils.h> #include <brcmu_wifi.h> #include <chipcommon.h> #include <soc.h> #include "chip.h" #include "bus.h" #include "debug.h" #include "sdio.h" #include "core.h" #include "common.h" #define SDIOH_API_ACCESS_RETRY_LIMIT 2 #define DMA_ALIGN_MASK 0x03 #define SDIO_FUNC1_BLOCKSIZE 64 #define SDIO_FUNC2_BLOCKSIZE 512 /* Maximum milliseconds to wait for F2 to come up */ #define SDIO_WAIT_F2RDY 3000 #define BRCMF_DEFAULT_RXGLOM_SIZE 32 /* max rx frames in glom chain */ struct brcmf_sdiod_freezer { atomic_t freezing; atomic_t thread_count; u32 frozen_count; wait_queue_head_t thread_freeze; struct completion resumed; }; static irqreturn_t brcmf_sdiod_oob_irqhandler(int irq, void *dev_id) { struct brcmf_bus *bus_if = dev_get_drvdata(dev_id); struct brcmf_sdio_dev *sdiodev = bus_if->bus_priv.sdio; brcmf_dbg(INTR, "OOB intr triggered\n"); /* out-of-band interrupt is level-triggered which won't * be cleared until dpc */ if (sdiodev->irq_en) { disable_irq_nosync(irq); sdiodev->irq_en = false; } brcmf_sdio_isr(sdiodev->bus); return IRQ_HANDLED; } static void brcmf_sdiod_ib_irqhandler(struct sdio_func *func) { struct brcmf_bus *bus_if = dev_get_drvdata(&func->dev); struct brcmf_sdio_dev *sdiodev = bus_if->bus_priv.sdio; brcmf_dbg(INTR, "IB intr triggered\n"); brcmf_sdio_isr(sdiodev->bus); } /* dummy handler for SDIO function 2 interrupt */ static void brcmf_sdiod_dummy_irqhandler(struct sdio_func *func) { } int brcmf_sdiod_intr_register(struct brcmf_sdio_dev *sdiodev) { struct brcmfmac_sdio_pd *pdata; int ret = 0; u8 data; u32 addr, gpiocontrol; pdata = &sdiodev->settings->bus.sdio; if (pdata->oob_irq_supported) { brcmf_dbg(SDIO, "Enter, register OOB IRQ %d\n", pdata->oob_irq_nr); spin_lock_init(&sdiodev->irq_en_lock); sdiodev->irq_en = true; ret = request_irq(pdata->oob_irq_nr, brcmf_sdiod_oob_irqhandler, pdata->oob_irq_flags, "brcmf_oob_intr", &sdiodev->func[1]->dev); if (ret != 0) { brcmf_err("request_irq failed %d\n", ret); return ret; } sdiodev->oob_irq_requested = true; ret = enable_irq_wake(pdata->oob_irq_nr); if (ret != 0) { brcmf_err("enable_irq_wake failed %d\n", ret); return ret; } sdiodev->irq_wake = true; sdio_claim_host(sdiodev->func[1]); if (sdiodev->bus_if->chip == BRCM_CC_43362_CHIP_ID) { /* assign GPIO to SDIO core */ addr = CORE_CC_REG(SI_ENUM_BASE, gpiocontrol); gpiocontrol = brcmf_sdiod_regrl(sdiodev, addr, &ret); gpiocontrol |= 0x2; brcmf_sdiod_regwl(sdiodev, addr, gpiocontrol, &ret); brcmf_sdiod_regwb(sdiodev, SBSDIO_GPIO_SELECT, 0xf, &ret); brcmf_sdiod_regwb(sdiodev, SBSDIO_GPIO_OUT, 0, &ret); brcmf_sdiod_regwb(sdiodev, SBSDIO_GPIO_EN, 0x2, &ret); } /* must configure SDIO_CCCR_IENx to enable irq */ data = brcmf_sdiod_regrb(sdiodev, SDIO_CCCR_IENx, &ret); data |= 1 << SDIO_FUNC_1 | 1 << SDIO_FUNC_2 | 1; brcmf_sdiod_regwb(sdiodev, SDIO_CCCR_IENx, data, &ret); /* redirect, configure and enable io for interrupt signal */ data = SDIO_SEPINT_MASK | SDIO_SEPINT_OE; if (pdata->oob_irq_flags & IRQF_TRIGGER_HIGH) data |= SDIO_SEPINT_ACT_HI; brcmf_sdiod_regwb(sdiodev, SDIO_CCCR_BRCM_SEPINT, data, &ret); sdio_release_host(sdiodev->func[1]); } else { brcmf_dbg(SDIO, "Entering\n"); sdio_claim_host(sdiodev->func[1]); sdio_claim_irq(sdiodev->func[1], brcmf_sdiod_ib_irqhandler); sdio_claim_irq(sdiodev->func[2], brcmf_sdiod_dummy_irqhandler); sdio_release_host(sdiodev->func[1]); sdiodev->sd_irq_requested = true; } return 0; } void brcmf_sdiod_intr_unregister(struct brcmf_sdio_dev *sdiodev) { brcmf_dbg(SDIO, "Entering oob=%d sd=%d\n", sdiodev->oob_irq_requested, sdiodev->sd_irq_requested); if (sdiodev->oob_irq_requested) { struct brcmfmac_sdio_pd *pdata; pdata = &sdiodev->settings->bus.sdio; sdio_claim_host(sdiodev->func[1]); brcmf_sdiod_regwb(sdiodev, SDIO_CCCR_BRCM_SEPINT, 0, NULL); brcmf_sdiod_regwb(sdiodev, SDIO_CCCR_IENx, 0, NULL); sdio_release_host(sdiodev->func[1]); sdiodev->oob_irq_requested = false; if (sdiodev->irq_wake) { disable_irq_wake(pdata->oob_irq_nr); sdiodev->irq_wake = false; } free_irq(pdata->oob_irq_nr, &sdiodev->func[1]->dev); sdiodev->irq_en = false; sdiodev->oob_irq_requested = false; } if (sdiodev->sd_irq_requested) { sdio_claim_host(sdiodev->func[1]); sdio_release_irq(sdiodev->func[2]); sdio_release_irq(sdiodev->func[1]); sdio_release_host(sdiodev->func[1]); sdiodev->sd_irq_requested = false; } } void brcmf_sdiod_change_state(struct brcmf_sdio_dev *sdiodev, enum brcmf_sdiod_state state) { if (sdiodev->state == BRCMF_SDIOD_NOMEDIUM || state == sdiodev->state) return; brcmf_dbg(TRACE, "%d -> %d\n", sdiodev->state, state); switch (sdiodev->state) { case BRCMF_SDIOD_DATA: /* any other state means bus interface is down */ brcmf_bus_change_state(sdiodev->bus_if, BRCMF_BUS_DOWN); break; case BRCMF_SDIOD_DOWN: /* transition from DOWN to DATA means bus interface is up */ if (state == BRCMF_SDIOD_DATA) brcmf_bus_change_state(sdiodev->bus_if, BRCMF_BUS_UP); break; default: break; } sdiodev->state = state; } static inline int brcmf_sdiod_f0_writeb(struct sdio_func *func, uint regaddr, u8 byte) { int err_ret; /* * Can only directly write to some F0 registers. * Handle CCCR_IENx and CCCR_ABORT command * as a special case. */ if ((regaddr == SDIO_CCCR_ABORT) || (regaddr == SDIO_CCCR_IENx)) sdio_writeb(func, byte, regaddr, &err_ret); else sdio_f0_writeb(func, byte, regaddr, &err_ret); return err_ret; } static int brcmf_sdiod_request_data(struct brcmf_sdio_dev *sdiodev, u8 fn, u32 addr, u8 regsz, void *data, bool write) { struct sdio_func *func; int ret = -EINVAL; brcmf_dbg(SDIO, "rw=%d, func=%d, addr=0x%05x, nbytes=%d\n", write, fn, addr, regsz); /* only allow byte access on F0 */ if (WARN_ON(regsz > 1 && !fn)) return -EINVAL; func = sdiodev->func[fn]; switch (regsz) { case sizeof(u8): if (write) { if (fn) sdio_writeb(func, *(u8 *)data, addr, &ret); else ret = brcmf_sdiod_f0_writeb(func, addr, *(u8 *)data); } else { if (fn) *(u8 *)data = sdio_readb(func, addr, &ret); else *(u8 *)data = sdio_f0_readb(func, addr, &ret); } break; case sizeof(u16): if (write) sdio_writew(func, *(u16 *)data, addr, &ret); else *(u16 *)data = sdio_readw(func, addr, &ret); break; case sizeof(u32): if (write) sdio_writel(func, *(u32 *)data, addr, &ret); else *(u32 *)data = sdio_readl(func, addr, &ret); break; default: brcmf_err("invalid size: %d\n", regsz); break; } if (ret) brcmf_dbg(SDIO, "failed to %s data F%d@0x%05x, err: %d\n", write ? "write" : "read", fn, addr, ret); return ret; } static int brcmf_sdiod_regrw_helper(struct brcmf_sdio_dev *sdiodev, u32 addr, u8 regsz, void *data, bool write) { u8 func; s32 retry = 0; int ret; if (sdiodev->state == BRCMF_SDIOD_NOMEDIUM) return -ENOMEDIUM; /* * figure out how to read the register based on address range * 0x00 ~ 0x7FF: function 0 CCCR and FBR * 0x10000 ~ 0x1FFFF: function 1 miscellaneous registers * The rest: function 1 silicon backplane core registers */ if ((addr & ~REG_F0_REG_MASK) == 0) func = SDIO_FUNC_0; else func = SDIO_FUNC_1; do { if (!write) memset(data, 0, regsz); /* for retry wait for 1 ms till bus get settled down */ if (retry) usleep_range(1000, 2000); ret = brcmf_sdiod_request_data(sdiodev, func, addr, regsz, data, write); } while (ret != 0 && ret != -ENOMEDIUM && retry++ < SDIOH_API_ACCESS_RETRY_LIMIT); if (ret == -ENOMEDIUM) brcmf_sdiod_change_state(sdiodev, BRCMF_SDIOD_NOMEDIUM); else if (ret != 0) { /* * SleepCSR register access can fail when * waking up the device so reduce this noise * in the logs. */ if (addr != SBSDIO_FUNC1_SLEEPCSR) brcmf_err("failed to %s data F%d@0x%05x, err: %d\n", write ? "write" : "read", func, addr, ret); else brcmf_dbg(SDIO, "failed to %s data F%d@0x%05x, err: %d\n", write ? "write" : "read", func, addr, ret); } return ret; } static int brcmf_sdiod_set_sbaddr_window(struct brcmf_sdio_dev *sdiodev, u32 address) { int err = 0, i; u8 addr[3]; if (sdiodev->state == BRCMF_SDIOD_NOMEDIUM) return -ENOMEDIUM; addr[0] = (address >> 8) & SBSDIO_SBADDRLOW_MASK; addr[1] = (address >> 16) & SBSDIO_SBADDRMID_MASK; addr[2] = (address >> 24) & SBSDIO_SBADDRHIGH_MASK; for (i = 0; i < 3; i++) { err = brcmf_sdiod_regrw_helper(sdiodev, SBSDIO_FUNC1_SBADDRLOW + i, sizeof(u8), &addr[i], true); if (err) { brcmf_err("failed at addr: 0x%0x\n", SBSDIO_FUNC1_SBADDRLOW + i); break; } } return err; } static int brcmf_sdiod_addrprep(struct brcmf_sdio_dev *sdiodev, uint width, u32 *addr) { uint bar0 = *addr & ~SBSDIO_SB_OFT_ADDR_MASK; int err = 0; if (bar0 != sdiodev->sbwad) { err = brcmf_sdiod_set_sbaddr_window(sdiodev, bar0); if (err) return err; sdiodev->sbwad = bar0; } *addr &= SBSDIO_SB_OFT_ADDR_MASK; if (width == 4) *addr |= SBSDIO_SB_ACCESS_2_4B_FLAG; return 0; } u8 brcmf_sdiod_regrb(struct brcmf_sdio_dev *sdiodev, u32 addr, int *ret) { u8 data; int retval; brcmf_dbg(SDIO, "addr:0x%08x\n", addr); retval = brcmf_sdiod_regrw_helper(sdiodev, addr, sizeof(data), &data, false); brcmf_dbg(SDIO, "data:0x%02x\n", data); if (ret) *ret = retval; return data; } u32 brcmf_sdiod_regrl(struct brcmf_sdio_dev *sdiodev, u32 addr, int *ret) { u32 data = 0; int retval; brcmf_dbg(SDIO, "addr:0x%08x\n", addr); retval = brcmf_sdiod_addrprep(sdiodev, sizeof(data), &addr); if (retval) goto done; retval = brcmf_sdiod_regrw_helper(sdiodev, addr, sizeof(data), &data, false); brcmf_dbg(SDIO, "data:0x%08x\n", data); done: if (ret) *ret = retval; return data; } void brcmf_sdiod_regwb(struct brcmf_sdio_dev *sdiodev, u32 addr, u8 data, int *ret) { int retval; brcmf_dbg(SDIO, "addr:0x%08x, data:0x%02x\n", addr, data); retval = brcmf_sdiod_regrw_helper(sdiodev, addr, sizeof(data), &data, true); if (ret) *ret = retval; } void brcmf_sdiod_regwl(struct brcmf_sdio_dev *sdiodev, u32 addr, u32 data, int *ret) { int retval; brcmf_dbg(SDIO, "addr:0x%08x, data:0x%08x\n", addr, data); retval = brcmf_sdiod_addrprep(sdiodev, sizeof(data), &addr); if (retval) goto done; retval = brcmf_sdiod_regrw_helper(sdiodev, addr, sizeof(data), &data, true); done: if (ret) *ret = retval; } static int brcmf_sdiod_buffrw(struct brcmf_sdio_dev *sdiodev, uint fn, bool write, u32 addr, struct sk_buff *pkt) { unsigned int req_sz; int err; /* Single skb use the standard mmc interface */ req_sz = pkt->len + 3; req_sz &= (uint)~3; if (write) err = sdio_memcpy_toio(sdiodev->func[fn], addr, ((u8 *)(pkt->data)), req_sz); else if (fn == 1) err = sdio_memcpy_fromio(sdiodev->func[fn], ((u8 *)(pkt->data)), addr, req_sz); else /* function 2 read is FIFO operation */ err = sdio_readsb(sdiodev->func[fn], ((u8 *)(pkt->data)), addr, req_sz); if (err == -ENOMEDIUM) brcmf_sdiod_change_state(sdiodev, BRCMF_SDIOD_NOMEDIUM); return err; } /** * brcmf_sdiod_sglist_rw - SDIO interface function for block data access * @sdiodev: brcmfmac sdio device * @fn: SDIO function number * @write: direction flag * @addr: dongle memory address as source/destination * @pkt: skb pointer * * This function takes the respbonsibility as the interface function to MMC * stack for block data access. It assumes that the skb passed down by the * caller has already been padded and aligned. */ static int brcmf_sdiod_sglist_rw(struct brcmf_sdio_dev *sdiodev, uint fn, bool write, u32 addr, struct sk_buff_head *pktlist) { unsigned int req_sz, func_blk_sz, sg_cnt, sg_data_sz, pkt_offset; unsigned int max_req_sz, orig_offset, dst_offset; unsigned short max_seg_cnt, seg_sz; unsigned char *pkt_data, *orig_data, *dst_data; struct sk_buff *pkt_next = NULL, *local_pkt_next; struct sk_buff_head local_list, *target_list; struct mmc_request mmc_req; struct mmc_command mmc_cmd; struct mmc_data mmc_dat; struct scatterlist *sgl; int ret = 0; if (!pktlist->qlen) return -EINVAL; target_list = pktlist; /* for host with broken sg support, prepare a page aligned list */ __skb_queue_head_init(&local_list); if (!write && sdiodev->settings->bus.sdio.broken_sg_support) { req_sz = 0; skb_queue_walk(pktlist, pkt_next) req_sz += pkt_next->len; req_sz = ALIGN(req_sz, sdiodev->func[fn]->cur_blksize); while (req_sz > PAGE_SIZE) { pkt_next = brcmu_pkt_buf_get_skb(PAGE_SIZE); if (pkt_next == NULL) { ret = -ENOMEM; goto exit; } __skb_queue_tail(&local_list, pkt_next); req_sz -= PAGE_SIZE; } pkt_next = brcmu_pkt_buf_get_skb(req_sz); if (pkt_next == NULL) { ret = -ENOMEM; goto exit; } __skb_queue_tail(&local_list, pkt_next); target_list = &local_list; } func_blk_sz = sdiodev->func[fn]->cur_blksize; max_req_sz = sdiodev->max_request_size; max_seg_cnt = min_t(unsigned short, sdiodev->max_segment_count, target_list->qlen); seg_sz = target_list->qlen; pkt_offset = 0; pkt_next = target_list->next; memset(&mmc_req, 0, sizeof(struct mmc_request)); memset(&mmc_cmd, 0, sizeof(struct mmc_command)); memset(&mmc_dat, 0, sizeof(struct mmc_data)); mmc_dat.sg = sdiodev->sgtable.sgl; mmc_dat.blksz = func_blk_sz; mmc_dat.flags = write ? MMC_DATA_WRITE : MMC_DATA_READ; mmc_cmd.opcode = SD_IO_RW_EXTENDED; mmc_cmd.arg = write ? 1<<31 : 0; /* write flag */ mmc_cmd.arg |= (fn & 0x7) << 28; /* SDIO func num */ mmc_cmd.arg |= 1<<27; /* block mode */ /* for function 1 the addr will be incremented */ mmc_cmd.arg |= (fn == 1) ? 1<<26 : 0; mmc_cmd.flags = MMC_RSP_SPI_R5 | MMC_RSP_R5 | MMC_CMD_ADTC; mmc_req.cmd = &mmc_cmd; mmc_req.data = &mmc_dat; while (seg_sz) { req_sz = 0; sg_cnt = 0; sgl = sdiodev->sgtable.sgl; /* prep sg table */ while (pkt_next != (struct sk_buff *)target_list) { pkt_data = pkt_next->data + pkt_offset; sg_data_sz = pkt_next->len - pkt_offset; if (sg_data_sz > sdiodev->max_segment_size) sg_data_sz = sdiodev->max_segment_size; if (sg_data_sz > max_req_sz - req_sz) sg_data_sz = max_req_sz - req_sz; sg_set_buf(sgl, pkt_data, sg_data_sz); sg_cnt++; sgl = sg_next(sgl); req_sz += sg_data_sz; pkt_offset += sg_data_sz; if (pkt_offset == pkt_next->len) { pkt_offset = 0; pkt_next = pkt_next->next; } if (req_sz >= max_req_sz || sg_cnt >= max_seg_cnt) break; } seg_sz -= sg_cnt; if (req_sz % func_blk_sz != 0) { brcmf_err("sg request length %u is not %u aligned\n", req_sz, func_blk_sz); ret = -ENOTBLK; goto exit; } mmc_dat.sg_len = sg_cnt; mmc_dat.blocks = req_sz / func_blk_sz; mmc_cmd.arg |= (addr & 0x1FFFF) << 9; /* address */ mmc_cmd.arg |= mmc_dat.blocks & 0x1FF; /* block count */ /* incrementing addr for function 1 */ if (fn == 1) addr += req_sz; mmc_set_data_timeout(&mmc_dat, sdiodev->func[fn]->card); mmc_wait_for_req(sdiodev->func[fn]->card->host, &mmc_req); ret = mmc_cmd.error ? mmc_cmd.error : mmc_dat.error; if (ret == -ENOMEDIUM) { brcmf_sdiod_change_state(sdiodev, BRCMF_SDIOD_NOMEDIUM); break; } else if (ret != 0) { brcmf_err("CMD53 sg block %s failed %d\n", write ? "write" : "read", ret); ret = -EIO; break; } } if (!write && sdiodev->settings->bus.sdio.broken_sg_support) { local_pkt_next = local_list.next; orig_offset = 0; skb_queue_walk(pktlist, pkt_next) { dst_offset = 0; do { req_sz = local_pkt_next->len - orig_offset; req_sz = min_t(uint, pkt_next->len - dst_offset, req_sz); orig_data = local_pkt_next->data + orig_offset; dst_data = pkt_next->data + dst_offset; memcpy(dst_data, orig_data, req_sz); orig_offset += req_sz; dst_offset += req_sz; if (orig_offset == local_pkt_next->len) { orig_offset = 0; local_pkt_next = local_pkt_next->next; } if (dst_offset == pkt_next->len) break; } while (!skb_queue_empty(&local_list)); } } exit: sg_init_table(sdiodev->sgtable.sgl, sdiodev->sgtable.orig_nents); while ((pkt_next = __skb_dequeue(&local_list)) != NULL) brcmu_pkt_buf_free_skb(pkt_next); return ret; } int brcmf_sdiod_recv_buf(struct brcmf_sdio_dev *sdiodev, u8 *buf, uint nbytes) { struct sk_buff *mypkt; int err; mypkt = brcmu_pkt_buf_get_skb(nbytes); if (!mypkt) { brcmf_err("brcmu_pkt_buf_get_skb failed: len %d\n", nbytes); return -EIO; } err = brcmf_sdiod_recv_pkt(sdiodev, mypkt); if (!err) memcpy(buf, mypkt->data, nbytes); brcmu_pkt_buf_free_skb(mypkt); return err; } int brcmf_sdiod_recv_pkt(struct brcmf_sdio_dev *sdiodev, struct sk_buff *pkt) { u32 addr = sdiodev->sbwad; int err = 0; brcmf_dbg(SDIO, "addr = 0x%x, size = %d\n", addr, pkt->len); err = brcmf_sdiod_addrprep(sdiodev, 4, &addr); if (err) goto done; err = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_2, false, addr, pkt); done: return err; } int brcmf_sdiod_recv_chain(struct brcmf_sdio_dev *sdiodev, struct sk_buff_head *pktq, uint totlen) { struct sk_buff *glom_skb = NULL; struct sk_buff *skb; u32 addr = sdiodev->sbwad; int err = 0; brcmf_dbg(SDIO, "addr = 0x%x, size = %d\n", addr, pktq->qlen); err = brcmf_sdiod_addrprep(sdiodev, 4, &addr); if (err) goto done; if (pktq->qlen == 1) err = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_2, false, addr, pktq->next); else if (!sdiodev->sg_support) { glom_skb = brcmu_pkt_buf_get_skb(totlen); if (!glom_skb) return -ENOMEM; err = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_2, false, addr, glom_skb); if (err) goto done; skb_queue_walk(pktq, skb) { memcpy(skb->data, glom_skb->data, skb->len); skb_pull(glom_skb, skb->len); } } else err = brcmf_sdiod_sglist_rw(sdiodev, SDIO_FUNC_2, false, addr, pktq); done: brcmu_pkt_buf_free_skb(glom_skb); return err; } int brcmf_sdiod_send_buf(struct brcmf_sdio_dev *sdiodev, u8 *buf, uint nbytes) { struct sk_buff *mypkt; u32 addr = sdiodev->sbwad; int err; mypkt = brcmu_pkt_buf_get_skb(nbytes); if (!mypkt) { brcmf_err("brcmu_pkt_buf_get_skb failed: len %d\n", nbytes); return -EIO; } memcpy(mypkt->data, buf, nbytes); err = brcmf_sdiod_addrprep(sdiodev, 4, &addr); if (!err) err = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_2, true, addr, mypkt); brcmu_pkt_buf_free_skb(mypkt); return err; } int brcmf_sdiod_send_pkt(struct brcmf_sdio_dev *sdiodev, struct sk_buff_head *pktq) { struct sk_buff *skb; u32 addr = sdiodev->sbwad; int err; brcmf_dbg(SDIO, "addr = 0x%x, size = %d\n", addr, pktq->qlen); err = brcmf_sdiod_addrprep(sdiodev, 4, &addr); if (err) return err; if (pktq->qlen == 1 || !sdiodev->sg_support) skb_queue_walk(pktq, skb) { err = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_2, true, addr, skb); if (err) break; } else err = brcmf_sdiod_sglist_rw(sdiodev, SDIO_FUNC_2, true, addr, pktq); return err; } int brcmf_sdiod_ramrw(struct brcmf_sdio_dev *sdiodev, bool write, u32 address, u8 *data, uint size) { int bcmerror = 0; struct sk_buff *pkt; u32 sdaddr; uint dsize; dsize = min_t(uint, SBSDIO_SB_OFT_ADDR_LIMIT, size); pkt = dev_alloc_skb(dsize); if (!pkt) { brcmf_err("dev_alloc_skb failed: len %d\n", dsize); return -EIO; } pkt->priority = 0; /* Determine initial transfer parameters */ sdaddr = address & SBSDIO_SB_OFT_ADDR_MASK; if ((sdaddr + size) & SBSDIO_SBWINDOW_MASK) dsize = (SBSDIO_SB_OFT_ADDR_LIMIT - sdaddr); else dsize = size; sdio_claim_host(sdiodev->func[1]); /* Do the transfer(s) */ while (size) { /* Set the backplane window to include the start address */ bcmerror = brcmf_sdiod_set_sbaddr_window(sdiodev, address); if (bcmerror) break; brcmf_dbg(SDIO, "%s %d bytes at offset 0x%08x in window 0x%08x\n", write ? "write" : "read", dsize, sdaddr, address & SBSDIO_SBWINDOW_MASK); sdaddr &= SBSDIO_SB_OFT_ADDR_MASK; sdaddr |= SBSDIO_SB_ACCESS_2_4B_FLAG; skb_put(pkt, dsize); if (write) memcpy(pkt->data, data, dsize); bcmerror = brcmf_sdiod_buffrw(sdiodev, SDIO_FUNC_1, write, sdaddr, pkt); if (bcmerror) { brcmf_err("membytes transfer failed\n"); break; } if (!write) memcpy(data, pkt->data, dsize); skb_trim(pkt, 0); /* Adjust for next transfer (if any) */ size -= dsize; if (size) { data += dsize; address += dsize; sdaddr = 0; dsize = min_t(uint, SBSDIO_SB_OFT_ADDR_LIMIT, size); } } dev_kfree_skb(pkt); /* Return the window to backplane enumeration space for core access */ if (brcmf_sdiod_set_sbaddr_window(sdiodev, sdiodev->sbwad)) brcmf_err("FAILED to set window back to 0x%x\n", sdiodev->sbwad); sdio_release_host(sdiodev->func[1]); return bcmerror; } int brcmf_sdiod_abort(struct brcmf_sdio_dev *sdiodev, uint fn) { char t_func = (char)fn; brcmf_dbg(SDIO, "Enter\n"); /* issue abort cmd52 command through F0 */ brcmf_sdiod_request_data(sdiodev, SDIO_FUNC_0, SDIO_CCCR_ABORT, sizeof(t_func), &t_func, true); brcmf_dbg(SDIO, "Exit\n"); return 0; } void brcmf_sdiod_sgtable_alloc(struct brcmf_sdio_dev *sdiodev) { struct sdio_func *func; struct mmc_host *host; uint max_blocks; uint nents; int err; func = sdiodev->func[2]; host = func->card->host; sdiodev->sg_support = host->max_segs > 1; max_blocks = min_t(uint, host->max_blk_count, 511u); sdiodev->max_request_size = min_t(uint, host->max_req_size, max_blocks * func->cur_blksize); sdiodev->max_segment_count = min_t(uint, host->max_segs, SG_MAX_SINGLE_ALLOC); sdiodev->max_segment_size = host->max_seg_size; if (!sdiodev->sg_support) return; nents = max_t(uint, BRCMF_DEFAULT_RXGLOM_SIZE, sdiodev->settings->bus.sdio.txglomsz); nents += (nents >> 4) + 1; WARN_ON(nents > sdiodev->max_segment_count); brcmf_dbg(TRACE, "nents=%d\n", nents); err = sg_alloc_table(&sdiodev->sgtable, nents, GFP_KERNEL); if (err < 0) { brcmf_err("allocation failed: disable scatter-gather"); sdiodev->sg_support = false; } sdiodev->txglomsz = sdiodev->settings->bus.sdio.txglomsz; } #ifdef CONFIG_PM_SLEEP static int brcmf_sdiod_freezer_attach(struct brcmf_sdio_dev *sdiodev) { sdiodev->freezer = kzalloc(sizeof(*sdiodev->freezer), GFP_KERNEL); if (!sdiodev->freezer) return -ENOMEM; atomic_set(&sdiodev->freezer->thread_count, 0); atomic_set(&sdiodev->freezer->freezing, 0); init_waitqueue_head(&sdiodev->freezer->thread_freeze); init_completion(&sdiodev->freezer->resumed); return 0; } static void brcmf_sdiod_freezer_detach(struct brcmf_sdio_dev *sdiodev) { if (sdiodev->freezer) { WARN_ON(atomic_read(&sdiodev->freezer->freezing)); kfree(sdiodev->freezer); } } static int brcmf_sdiod_freezer_on(struct brcmf_sdio_dev *sdiodev) { atomic_t *expect = &sdiodev->freezer->thread_count; int res = 0; sdiodev->freezer->frozen_count = 0; reinit_completion(&sdiodev->freezer->resumed); atomic_set(&sdiodev->freezer->freezing, 1); brcmf_sdio_trigger_dpc(sdiodev->bus); wait_event(sdiodev->freezer->thread_freeze, atomic_read(expect) == sdiodev->freezer->frozen_count); sdio_claim_host(sdiodev->func[1]); res = brcmf_sdio_sleep(sdiodev->bus, true); sdio_release_host(sdiodev->func[1]); return res; } static void brcmf_sdiod_freezer_off(struct brcmf_sdio_dev *sdiodev) { sdio_claim_host(sdiodev->func[1]); brcmf_sdio_sleep(sdiodev->bus, false); sdio_release_host(sdiodev->func[1]); atomic_set(&sdiodev->freezer->freezing, 0); complete_all(&sdiodev->freezer->resumed); } bool brcmf_sdiod_freezing(struct brcmf_sdio_dev *sdiodev) { return atomic_read(&sdiodev->freezer->freezing); } void brcmf_sdiod_try_freeze(struct brcmf_sdio_dev *sdiodev) { if (!brcmf_sdiod_freezing(sdiodev)) return; sdiodev->freezer->frozen_count++; wake_up(&sdiodev->freezer->thread_freeze); wait_for_completion(&sdiodev->freezer->resumed); } void brcmf_sdiod_freezer_count(struct brcmf_sdio_dev *sdiodev) { atomic_inc(&sdiodev->freezer->thread_count); } void brcmf_sdiod_freezer_uncount(struct brcmf_sdio_dev *sdiodev) { atomic_dec(&sdiodev->freezer->thread_count); } #else static int brcmf_sdiod_freezer_attach(struct brcmf_sdio_dev *sdiodev) { return 0; } static void brcmf_sdiod_freezer_detach(struct brcmf_sdio_dev *sdiodev) { } #endif /* CONFIG_PM_SLEEP */ static int brcmf_sdiod_remove(struct brcmf_sdio_dev *sdiodev) { sdiodev->state = BRCMF_SDIOD_DOWN; if (sdiodev->bus) { brcmf_sdio_remove(sdiodev->bus); sdiodev->bus = NULL; } brcmf_sdiod_freezer_detach(sdiodev); /* Disable Function 2 */ sdio_claim_host(sdiodev->func[2]); sdio_disable_func(sdiodev->func[2]); sdio_release_host(sdiodev->func[2]); /* Disable Function 1 */ sdio_claim_host(sdiodev->func[1]); sdio_disable_func(sdiodev->func[1]); sdio_release_host(sdiodev->func[1]); sg_free_table(&sdiodev->sgtable); sdiodev->sbwad = 0; pm_runtime_allow(sdiodev->func[1]->card->host->parent); return 0; } static void brcmf_sdiod_host_fixup(struct mmc_host *host) { /* runtime-pm powers off the device */ pm_runtime_forbid(host->parent); /* avoid removal detection upon resume */ host->caps |= MMC_CAP_NONREMOVABLE; } static int brcmf_sdiod_probe(struct brcmf_sdio_dev *sdiodev) { int ret = 0; sdiodev->num_funcs = 2; sdio_claim_host(sdiodev->func[1]); ret = sdio_set_block_size(sdiodev->func[1], SDIO_FUNC1_BLOCKSIZE); if (ret) { brcmf_err("Failed to set F1 blocksize\n"); sdio_release_host(sdiodev->func[1]); goto out; } ret = sdio_set_block_size(sdiodev->func[2], SDIO_FUNC2_BLOCKSIZE); if (ret) { brcmf_err("Failed to set F2 blocksize\n"); sdio_release_host(sdiodev->func[1]); goto out; } /* increase F2 timeout */ sdiodev->func[2]->enable_timeout = SDIO_WAIT_F2RDY; /* Enable Function 1 */ ret = sdio_enable_func(sdiodev->func[1]); sdio_release_host(sdiodev->func[1]); if (ret) { brcmf_err("Failed to enable F1: err=%d\n", ret); goto out; } ret = brcmf_sdiod_freezer_attach(sdiodev); if (ret) goto out; /* try to attach to the target device */ sdiodev->bus = brcmf_sdio_probe(sdiodev); if (!sdiodev->bus) { ret = -ENODEV; goto out; } brcmf_sdiod_host_fixup(sdiodev->func[2]->card->host); out: if (ret) brcmf_sdiod_remove(sdiodev); return ret; } #define BRCMF_SDIO_DEVICE(dev_id) \ {SDIO_DEVICE(SDIO_VENDOR_ID_BROADCOM, dev_id)} /* devices we support, null terminated */ static const struct sdio_device_id brcmf_sdmmc_ids[] = { BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43143), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43241), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4329), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4330), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4334), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43340), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43341), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43362), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4335_4339), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4339), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43430), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4345), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_43455), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4354), BRCMF_SDIO_DEVICE(SDIO_DEVICE_ID_BROADCOM_4356), { /* end: all zeroes */ } }; MODULE_DEVICE_TABLE(sdio, brcmf_sdmmc_ids); static void brcmf_sdiod_acpi_set_power_manageable(struct device *dev, int val) { #if IS_ENABLED(CONFIG_ACPI) struct acpi_device *adev; adev = ACPI_COMPANION(dev); if (adev) adev->flags.power_manageable = 0; #endif } static int brcmf_ops_sdio_probe(struct sdio_func *func, const struct sdio_device_id *id) { int err; struct brcmf_sdio_dev *sdiodev; struct brcmf_bus *bus_if; struct device *dev; brcmf_dbg(SDIO, "Enter\n"); brcmf_dbg(SDIO, "Class=%x\n", func->class); brcmf_dbg(SDIO, "sdio vendor ID: 0x%04x\n", func->vendor); brcmf_dbg(SDIO, "sdio device ID: 0x%04x\n", func->device); brcmf_dbg(SDIO, "Function#: %d\n", func->num); dev = &func->dev; /* prohibit ACPI power management for this device */ brcmf_sdiod_acpi_set_power_manageable(dev, 0); /* Consume func num 1 but dont do anything with it. */ if (func->num == 1) return 0; /* Ignore anything but func 2 */ if (func->num != 2) return -ENODEV; bus_if = kzalloc(sizeof(struct brcmf_bus), GFP_KERNEL); if (!bus_if) return -ENOMEM; sdiodev = kzalloc(sizeof(struct brcmf_sdio_dev), GFP_KERNEL); if (!sdiodev) { kfree(bus_if); return -ENOMEM; } /* store refs to functions used. mmc_card does * not hold the F0 function pointer. */ sdiodev->func[0] = kmemdup(func, sizeof(*func), GFP_KERNEL); sdiodev->func[0]->num = 0; sdiodev->func[1] = func->card->sdio_func[0]; sdiodev->func[2] = func; sdiodev->bus_if = bus_if; bus_if->bus_priv.sdio = sdiodev; bus_if->proto_type = BRCMF_PROTO_BCDC; dev_set_drvdata(&func->dev, bus_if); dev_set_drvdata(&sdiodev->func[1]->dev, bus_if); sdiodev->dev = &sdiodev->func[1]->dev; brcmf_sdiod_change_state(sdiodev, BRCMF_SDIOD_DOWN); brcmf_dbg(SDIO, "F2 found, calling brcmf_sdiod_probe...\n"); err = brcmf_sdiod_probe(sdiodev); if (err) { brcmf_err("F2 error, probe failed %d...\n", err); goto fail; } brcmf_dbg(SDIO, "F2 init completed...\n"); return 0; fail: dev_set_drvdata(&func->dev, NULL); dev_set_drvdata(&sdiodev->func[1]->dev, NULL); kfree(sdiodev->func[0]); kfree(sdiodev); kfree(bus_if); return err; } static void brcmf_ops_sdio_remove(struct sdio_func *func) { struct brcmf_bus *bus_if; struct brcmf_sdio_dev *sdiodev; brcmf_dbg(SDIO, "Enter\n"); brcmf_dbg(SDIO, "sdio vendor ID: 0x%04x\n", func->vendor); brcmf_dbg(SDIO, "sdio device ID: 0x%04x\n", func->device); brcmf_dbg(SDIO, "Function: %d\n", func->num); bus_if = dev_get_drvdata(&func->dev); if (bus_if) { sdiodev = bus_if->bus_priv.sdio; /* start by unregistering irqs */ brcmf_sdiod_intr_unregister(sdiodev); if (func->num != 1) return; /* only proceed with rest of cleanup if func 1 */ brcmf_sdiod_remove(sdiodev); dev_set_drvdata(&sdiodev->func[1]->dev, NULL); dev_set_drvdata(&sdiodev->func[2]->dev, NULL); kfree(bus_if); kfree(sdiodev->func[0]); kfree(sdiodev); } brcmf_dbg(SDIO, "Exit\n"); } void brcmf_sdio_wowl_config(struct device *dev, bool enabled) { struct brcmf_bus *bus_if = dev_get_drvdata(dev); struct brcmf_sdio_dev *sdiodev = bus_if->bus_priv.sdio; brcmf_dbg(SDIO, "Configuring WOWL, enabled=%d\n", enabled); sdiodev->wowl_enabled = enabled; } #ifdef CONFIG_PM_SLEEP static int brcmf_ops_sdio_suspend(struct device *dev) { struct sdio_func *func; struct brcmf_bus *bus_if; struct brcmf_sdio_dev *sdiodev; mmc_pm_flag_t sdio_flags; func = container_of(dev, struct sdio_func, dev); brcmf_dbg(SDIO, "Enter: F%d\n", func->num); if (func->num != SDIO_FUNC_1) return 0; bus_if = dev_get_drvdata(dev); sdiodev = bus_if->bus_priv.sdio; brcmf_sdiod_freezer_on(sdiodev); brcmf_sdio_wd_timer(sdiodev->bus, 0); sdio_flags = MMC_PM_KEEP_POWER; if (sdiodev->wowl_enabled) { if (sdiodev->settings->bus.sdio.oob_irq_supported) enable_irq_wake(sdiodev->settings->bus.sdio.oob_irq_nr); else sdio_flags |= MMC_PM_WAKE_SDIO_IRQ; } if (sdio_set_host_pm_flags(sdiodev->func[1], sdio_flags)) brcmf_err("Failed to set pm_flags %x\n", sdio_flags); return 0; } static int brcmf_ops_sdio_resume(struct device *dev) { struct brcmf_bus *bus_if = dev_get_drvdata(dev); struct brcmf_sdio_dev *sdiodev = bus_if->bus_priv.sdio; struct sdio_func *func = container_of(dev, struct sdio_func, dev); brcmf_dbg(SDIO, "Enter: F%d\n", func->num); if (func->num != SDIO_FUNC_2) return 0; brcmf_sdiod_freezer_off(sdiodev); return 0; } static const struct dev_pm_ops brcmf_sdio_pm_ops = { .suspend = brcmf_ops_sdio_suspend, .resume = brcmf_ops_sdio_resume, }; #endif /* CONFIG_PM_SLEEP */ static struct sdio_driver brcmf_sdmmc_driver = { .probe = brcmf_ops_sdio_probe, .remove = brcmf_ops_sdio_remove, .name = KBUILD_MODNAME, .id_table = brcmf_sdmmc_ids, .drv = { .owner = THIS_MODULE, #ifdef CONFIG_PM_SLEEP .pm = &brcmf_sdio_pm_ops, #endif /* CONFIG_PM_SLEEP */ }, }; void brcmf_sdio_register(void) { int ret; ret = sdio_register_driver(&brcmf_sdmmc_driver); if (ret) brcmf_err("sdio_register_driver failed: %d\n", ret); } void brcmf_sdio_exit(void) { brcmf_dbg(SDIO, "Enter\n"); sdio_unregister_driver(&brcmf_sdmmc_driver); } |