Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Zhao Qiang | 5462 | 86.71% | 4 | 8.70% |
Mathias Thore | 200 | 3.18% | 2 | 4.35% |
Wen Yang | 187 | 2.97% | 1 | 2.17% |
David Gounaris | 114 | 1.81% | 6 | 13.04% |
Christophe Leroy | 82 | 1.30% | 1 | 2.17% |
Holger Brunck | 71 | 1.13% | 4 | 8.70% |
Rasmus Villemoes | 52 | 0.83% | 4 | 8.70% |
Alexandra Diupina | 23 | 0.37% | 1 | 2.17% |
Rob Herring | 14 | 0.22% | 2 | 4.35% |
Jia-Ju Bai | 14 | 0.22% | 1 | 2.17% |
Dan Carpenter | 13 | 0.21% | 1 | 2.17% |
Arnd Bergmann | 9 | 0.14% | 1 | 2.17% |
Esina Ekaterina | 8 | 0.13% | 1 | 2.17% |
Heinrich Schuchardt | 6 | 0.10% | 1 | 2.17% |
Vaishali Thakkar | 6 | 0.10% | 1 | 2.17% |
Li Yang | 5 | 0.08% | 1 | 2.17% |
Valentin Longchamp | 5 | 0.08% | 1 | 2.17% |
Yue haibing | 5 | 0.08% | 1 | 2.17% |
Michael S. Tsirkin | 4 | 0.06% | 1 | 2.17% |
Kees Cook | 4 | 0.06% | 1 | 2.17% |
Eric Dumazet | 3 | 0.05% | 1 | 2.17% |
Colin Ian King | 2 | 0.03% | 2 | 4.35% |
Thomas Gleixner | 2 | 0.03% | 1 | 2.17% |
Tejun Heo | 2 | 0.03% | 1 | 2.17% |
Wei Yongjun | 2 | 0.03% | 1 | 2.17% |
Wei Yang | 1 | 0.02% | 1 | 2.17% |
Andy Fleming | 1 | 0.02% | 1 | 2.17% |
Jakub Kiciński | 1 | 0.02% | 1 | 2.17% |
Luis R. Rodriguez | 1 | 0.02% | 1 | 2.17% |
Total | 6299 | 46 |
// SPDX-License-Identifier: GPL-2.0-or-later /* Freescale QUICC Engine HDLC Device Driver * * Copyright 2016 Freescale Semiconductor Inc. */ #include <linux/delay.h> #include <linux/dma-mapping.h> #include <linux/hdlc.h> #include <linux/init.h> #include <linux/interrupt.h> #include <linux/io.h> #include <linux/irq.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/netdevice.h> #include <linux/of_address.h> #include <linux/of_irq.h> #include <linux/of_platform.h> #include <linux/platform_device.h> #include <linux/sched.h> #include <linux/skbuff.h> #include <linux/slab.h> #include <linux/spinlock.h> #include <linux/stddef.h> #include <soc/fsl/qe/qe_tdm.h> #include <uapi/linux/if_arp.h> #include "fsl_ucc_hdlc.h" #define DRV_DESC "Freescale QE UCC HDLC Driver" #define DRV_NAME "ucc_hdlc" #define TDM_PPPOHT_SLIC_MAXIN #define RX_BD_ERRORS (R_CD_S | R_OV_S | R_CR_S | R_AB_S | R_NO_S | R_LG_S) static int uhdlc_close(struct net_device *dev); static struct ucc_tdm_info utdm_primary_info = { .uf_info = { .tsa = 0, .cdp = 0, .cds = 1, .ctsp = 1, .ctss = 1, .revd = 0, .urfs = 256, .utfs = 256, .urfet = 128, .urfset = 192, .utfet = 128, .utftt = 0x40, .ufpt = 256, .mode = UCC_FAST_PROTOCOL_MODE_HDLC, .ttx_trx = UCC_FAST_GUMR_TRANSPARENT_TTX_TRX_NORMAL, .tenc = UCC_FAST_TX_ENCODING_NRZ, .renc = UCC_FAST_RX_ENCODING_NRZ, .tcrc = UCC_FAST_16_BIT_CRC, .synl = UCC_FAST_SYNC_LEN_NOT_USED, }, .si_info = { #ifdef TDM_PPPOHT_SLIC_MAXIN .simr_rfsd = 1, .simr_tfsd = 2, #else .simr_rfsd = 0, .simr_tfsd = 0, #endif .simr_crt = 0, .simr_sl = 0, .simr_ce = 1, .simr_fe = 1, .simr_gm = 0, }, }; static struct ucc_tdm_info utdm_info[UCC_MAX_NUM]; static int uhdlc_init(struct ucc_hdlc_private *priv) { struct ucc_tdm_info *ut_info; struct ucc_fast_info *uf_info; u32 cecr_subblock; u16 bd_status; int ret, i; void *bd_buffer; dma_addr_t bd_dma_addr; s32 riptr; s32 tiptr; u32 gumr; ut_info = priv->ut_info; uf_info = &ut_info->uf_info; if (priv->tsa) { uf_info->tsa = 1; uf_info->ctsp = 1; uf_info->cds = 1; uf_info->ctss = 1; } else { uf_info->cds = 0; uf_info->ctsp = 0; uf_info->ctss = 0; } /* This sets HPM register in CMXUCR register which configures a * open drain connected HDLC bus */ if (priv->hdlc_bus) uf_info->brkpt_support = 1; uf_info->uccm_mask = ((UCC_HDLC_UCCE_RXB | UCC_HDLC_UCCE_RXF | UCC_HDLC_UCCE_TXB) << 16); ret = ucc_fast_init(uf_info, &priv->uccf); if (ret) { dev_err(priv->dev, "Failed to init uccf."); return ret; } priv->uf_regs = priv->uccf->uf_regs; ucc_fast_disable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); /* Loopback mode */ if (priv->loopback) { dev_info(priv->dev, "Loopback Mode\n"); /* use the same clock when work in loopback */ qe_setbrg(ut_info->uf_info.rx_clock, 20000000, 1); gumr = ioread32be(&priv->uf_regs->gumr); gumr |= (UCC_FAST_GUMR_LOOPBACK | UCC_FAST_GUMR_CDS | UCC_FAST_GUMR_TCI); gumr &= ~(UCC_FAST_GUMR_CTSP | UCC_FAST_GUMR_RSYN); iowrite32be(gumr, &priv->uf_regs->gumr); } /* Initialize SI */ if (priv->tsa) ucc_tdm_init(priv->utdm, priv->ut_info); /* Write to QE CECR, UCCx channel to Stop Transmission */ cecr_subblock = ucc_fast_get_qe_cr_subblock(uf_info->ucc_num); ret = qe_issue_cmd(QE_STOP_TX, cecr_subblock, QE_CR_PROTOCOL_UNSPECIFIED, 0); /* Set UPSMR normal mode (need fixed)*/ iowrite32be(0, &priv->uf_regs->upsmr); /* hdlc_bus mode */ if (priv->hdlc_bus) { u32 upsmr; dev_info(priv->dev, "HDLC bus Mode\n"); upsmr = ioread32be(&priv->uf_regs->upsmr); /* bus mode and retransmit enable, with collision window * set to 8 bytes */ upsmr |= UCC_HDLC_UPSMR_RTE | UCC_HDLC_UPSMR_BUS | UCC_HDLC_UPSMR_CW8; iowrite32be(upsmr, &priv->uf_regs->upsmr); /* explicitly disable CDS & CTSP */ gumr = ioread32be(&priv->uf_regs->gumr); gumr &= ~(UCC_FAST_GUMR_CDS | UCC_FAST_GUMR_CTSP); /* set automatic sync to explicitly ignore CD signal */ gumr |= UCC_FAST_GUMR_SYNL_AUTO; iowrite32be(gumr, &priv->uf_regs->gumr); } priv->rx_ring_size = RX_BD_RING_LEN; priv->tx_ring_size = TX_BD_RING_LEN; /* Alloc Rx BD */ priv->rx_bd_base = dma_alloc_coherent(priv->dev, RX_BD_RING_LEN * sizeof(struct qe_bd), &priv->dma_rx_bd, GFP_KERNEL); if (!priv->rx_bd_base) { dev_err(priv->dev, "Cannot allocate MURAM memory for RxBDs\n"); ret = -ENOMEM; goto free_uccf; } /* Alloc Tx BD */ priv->tx_bd_base = dma_alloc_coherent(priv->dev, TX_BD_RING_LEN * sizeof(struct qe_bd), &priv->dma_tx_bd, GFP_KERNEL); if (!priv->tx_bd_base) { dev_err(priv->dev, "Cannot allocate MURAM memory for TxBDs\n"); ret = -ENOMEM; goto free_rx_bd; } /* Alloc parameter ram for ucc hdlc */ priv->ucc_pram_offset = qe_muram_alloc(sizeof(struct ucc_hdlc_param), ALIGNMENT_OF_UCC_HDLC_PRAM); if (priv->ucc_pram_offset < 0) { dev_err(priv->dev, "Can not allocate MURAM for hdlc parameter.\n"); ret = -ENOMEM; goto free_tx_bd; } priv->rx_skbuff = kcalloc(priv->rx_ring_size, sizeof(*priv->rx_skbuff), GFP_KERNEL); if (!priv->rx_skbuff) { ret = -ENOMEM; goto free_ucc_pram; } priv->tx_skbuff = kcalloc(priv->tx_ring_size, sizeof(*priv->tx_skbuff), GFP_KERNEL); if (!priv->tx_skbuff) { ret = -ENOMEM; goto free_rx_skbuff; } priv->skb_curtx = 0; priv->skb_dirtytx = 0; priv->curtx_bd = priv->tx_bd_base; priv->dirty_tx = priv->tx_bd_base; priv->currx_bd = priv->rx_bd_base; priv->currx_bdnum = 0; /* init parameter base */ cecr_subblock = ucc_fast_get_qe_cr_subblock(uf_info->ucc_num); ret = qe_issue_cmd(QE_ASSIGN_PAGE_TO_DEVICE, cecr_subblock, QE_CR_PROTOCOL_UNSPECIFIED, priv->ucc_pram_offset); priv->ucc_pram = (struct ucc_hdlc_param __iomem *) qe_muram_addr(priv->ucc_pram_offset); /* Zero out parameter ram */ memset_io(priv->ucc_pram, 0, sizeof(struct ucc_hdlc_param)); /* Alloc riptr, tiptr */ riptr = qe_muram_alloc(32, 32); if (riptr < 0) { dev_err(priv->dev, "Cannot allocate MURAM mem for Receive internal temp data pointer\n"); ret = -ENOMEM; goto free_tx_skbuff; } tiptr = qe_muram_alloc(32, 32); if (tiptr < 0) { dev_err(priv->dev, "Cannot allocate MURAM mem for Transmit internal temp data pointer\n"); ret = -ENOMEM; goto free_riptr; } if (riptr != (u16)riptr || tiptr != (u16)tiptr) { dev_err(priv->dev, "MURAM allocation out of addressable range\n"); ret = -ENOMEM; goto free_tiptr; } /* Set RIPTR, TIPTR */ iowrite16be(riptr, &priv->ucc_pram->riptr); iowrite16be(tiptr, &priv->ucc_pram->tiptr); /* Set MRBLR */ iowrite16be(MAX_RX_BUF_LENGTH, &priv->ucc_pram->mrblr); /* Set RBASE, TBASE */ iowrite32be(priv->dma_rx_bd, &priv->ucc_pram->rbase); iowrite32be(priv->dma_tx_bd, &priv->ucc_pram->tbase); /* Set RSTATE, TSTATE */ iowrite32be(BMR_GBL | BMR_BIG_ENDIAN, &priv->ucc_pram->rstate); iowrite32be(BMR_GBL | BMR_BIG_ENDIAN, &priv->ucc_pram->tstate); /* Set C_MASK, C_PRES for 16bit CRC */ iowrite32be(CRC_16BIT_MASK, &priv->ucc_pram->c_mask); iowrite32be(CRC_16BIT_PRES, &priv->ucc_pram->c_pres); iowrite16be(MAX_FRAME_LENGTH, &priv->ucc_pram->mflr); iowrite16be(DEFAULT_RFTHR, &priv->ucc_pram->rfthr); iowrite16be(DEFAULT_RFTHR, &priv->ucc_pram->rfcnt); iowrite16be(priv->hmask, &priv->ucc_pram->hmask); iowrite16be(DEFAULT_HDLC_ADDR, &priv->ucc_pram->haddr1); iowrite16be(DEFAULT_HDLC_ADDR, &priv->ucc_pram->haddr2); iowrite16be(DEFAULT_HDLC_ADDR, &priv->ucc_pram->haddr3); iowrite16be(DEFAULT_HDLC_ADDR, &priv->ucc_pram->haddr4); /* Get BD buffer */ bd_buffer = dma_alloc_coherent(priv->dev, (RX_BD_RING_LEN + TX_BD_RING_LEN) * MAX_RX_BUF_LENGTH, &bd_dma_addr, GFP_KERNEL); if (!bd_buffer) { dev_err(priv->dev, "Could not allocate buffer descriptors\n"); ret = -ENOMEM; goto free_tiptr; } priv->rx_buffer = bd_buffer; priv->tx_buffer = bd_buffer + RX_BD_RING_LEN * MAX_RX_BUF_LENGTH; priv->dma_rx_addr = bd_dma_addr; priv->dma_tx_addr = bd_dma_addr + RX_BD_RING_LEN * MAX_RX_BUF_LENGTH; for (i = 0; i < RX_BD_RING_LEN; i++) { if (i < (RX_BD_RING_LEN - 1)) bd_status = R_E_S | R_I_S; else bd_status = R_E_S | R_I_S | R_W_S; priv->rx_bd_base[i].status = cpu_to_be16(bd_status); priv->rx_bd_base[i].buf = cpu_to_be32(priv->dma_rx_addr + i * MAX_RX_BUF_LENGTH); } for (i = 0; i < TX_BD_RING_LEN; i++) { if (i < (TX_BD_RING_LEN - 1)) bd_status = T_I_S | T_TC_S; else bd_status = T_I_S | T_TC_S | T_W_S; priv->tx_bd_base[i].status = cpu_to_be16(bd_status); priv->tx_bd_base[i].buf = cpu_to_be32(priv->dma_tx_addr + i * MAX_RX_BUF_LENGTH); } dma_wmb(); return 0; free_tiptr: qe_muram_free(tiptr); free_riptr: qe_muram_free(riptr); free_tx_skbuff: kfree(priv->tx_skbuff); free_rx_skbuff: kfree(priv->rx_skbuff); free_ucc_pram: qe_muram_free(priv->ucc_pram_offset); free_tx_bd: dma_free_coherent(priv->dev, TX_BD_RING_LEN * sizeof(struct qe_bd), priv->tx_bd_base, priv->dma_tx_bd); free_rx_bd: dma_free_coherent(priv->dev, RX_BD_RING_LEN * sizeof(struct qe_bd), priv->rx_bd_base, priv->dma_rx_bd); free_uccf: ucc_fast_free(priv->uccf); return ret; } static netdev_tx_t ucc_hdlc_tx(struct sk_buff *skb, struct net_device *dev) { hdlc_device *hdlc = dev_to_hdlc(dev); struct ucc_hdlc_private *priv = (struct ucc_hdlc_private *)hdlc->priv; struct qe_bd *bd; u16 bd_status; unsigned long flags; __be16 *proto_head; switch (dev->type) { case ARPHRD_RAWHDLC: if (skb_headroom(skb) < HDLC_HEAD_LEN) { dev->stats.tx_dropped++; dev_kfree_skb(skb); netdev_err(dev, "No enough space for hdlc head\n"); return -ENOMEM; } skb_push(skb, HDLC_HEAD_LEN); proto_head = (__be16 *)skb->data; *proto_head = htons(DEFAULT_HDLC_HEAD); dev->stats.tx_bytes += skb->len; break; case ARPHRD_PPP: proto_head = (__be16 *)skb->data; if (*proto_head != htons(DEFAULT_PPP_HEAD)) { dev->stats.tx_dropped++; dev_kfree_skb(skb); netdev_err(dev, "Wrong ppp header\n"); return -ENOMEM; } dev->stats.tx_bytes += skb->len; break; case ARPHRD_ETHER: dev->stats.tx_bytes += skb->len; break; default: dev->stats.tx_dropped++; dev_kfree_skb(skb); return -ENOMEM; } netdev_sent_queue(dev, skb->len); spin_lock_irqsave(&priv->lock, flags); dma_rmb(); /* Start from the next BD that should be filled */ bd = priv->curtx_bd; bd_status = be16_to_cpu(bd->status); /* Save the skb pointer so we can free it later */ priv->tx_skbuff[priv->skb_curtx] = skb; /* Update the current skb pointer (wrapping if this was the last) */ priv->skb_curtx = (priv->skb_curtx + 1) & TX_RING_MOD_MASK(TX_BD_RING_LEN); /* copy skb data to tx buffer for sdma processing */ memcpy(priv->tx_buffer + (be32_to_cpu(bd->buf) - priv->dma_tx_addr), skb->data, skb->len); /* set bd status and length */ bd_status = (bd_status & T_W_S) | T_R_S | T_I_S | T_L_S | T_TC_S; bd->length = cpu_to_be16(skb->len); bd->status = cpu_to_be16(bd_status); /* Move to next BD in the ring */ if (!(bd_status & T_W_S)) bd += 1; else bd = priv->tx_bd_base; if (bd == priv->dirty_tx) { if (!netif_queue_stopped(dev)) netif_stop_queue(dev); } priv->curtx_bd = bd; spin_unlock_irqrestore(&priv->lock, flags); return NETDEV_TX_OK; } static int hdlc_tx_restart(struct ucc_hdlc_private *priv) { u32 cecr_subblock; cecr_subblock = ucc_fast_get_qe_cr_subblock(priv->ut_info->uf_info.ucc_num); qe_issue_cmd(QE_RESTART_TX, cecr_subblock, QE_CR_PROTOCOL_UNSPECIFIED, 0); return 0; } static int hdlc_tx_done(struct ucc_hdlc_private *priv) { /* Start from the next BD that should be filled */ struct net_device *dev = priv->ndev; unsigned int bytes_sent = 0; int howmany = 0; struct qe_bd *bd; /* BD pointer */ u16 bd_status; int tx_restart = 0; dma_rmb(); bd = priv->dirty_tx; bd_status = be16_to_cpu(bd->status); /* Normal processing. */ while ((bd_status & T_R_S) == 0) { struct sk_buff *skb; if (bd_status & T_UN_S) { /* Underrun */ dev->stats.tx_fifo_errors++; tx_restart = 1; } if (bd_status & T_CT_S) { /* Carrier lost */ dev->stats.tx_carrier_errors++; tx_restart = 1; } /* BD contains already transmitted buffer. */ /* Handle the transmitted buffer and release */ /* the BD to be used with the current frame */ skb = priv->tx_skbuff[priv->skb_dirtytx]; if (!skb) break; howmany++; bytes_sent += skb->len; dev->stats.tx_packets++; memset(priv->tx_buffer + (be32_to_cpu(bd->buf) - priv->dma_tx_addr), 0, skb->len); dev_consume_skb_irq(skb); priv->tx_skbuff[priv->skb_dirtytx] = NULL; priv->skb_dirtytx = (priv->skb_dirtytx + 1) & TX_RING_MOD_MASK(TX_BD_RING_LEN); /* We freed a buffer, so now we can restart transmission */ if (netif_queue_stopped(dev)) netif_wake_queue(dev); /* Advance the confirmation BD pointer */ if (!(bd_status & T_W_S)) bd += 1; else bd = priv->tx_bd_base; bd_status = be16_to_cpu(bd->status); } priv->dirty_tx = bd; if (tx_restart) hdlc_tx_restart(priv); netdev_completed_queue(dev, howmany, bytes_sent); return 0; } static int hdlc_rx_done(struct ucc_hdlc_private *priv, int rx_work_limit) { struct net_device *dev = priv->ndev; struct sk_buff *skb = NULL; hdlc_device *hdlc = dev_to_hdlc(dev); struct qe_bd *bd; u16 bd_status; u16 length, howmany = 0; u8 *bdbuffer; dma_rmb(); bd = priv->currx_bd; bd_status = be16_to_cpu(bd->status); /* while there are received buffers and BD is full (~R_E) */ while (!((bd_status & (R_E_S)) || (--rx_work_limit < 0))) { if (bd_status & (RX_BD_ERRORS)) { dev->stats.rx_errors++; if (bd_status & R_CD_S) dev->stats.collisions++; if (bd_status & R_OV_S) dev->stats.rx_fifo_errors++; if (bd_status & R_CR_S) dev->stats.rx_crc_errors++; if (bd_status & R_AB_S) dev->stats.rx_over_errors++; if (bd_status & R_NO_S) dev->stats.rx_frame_errors++; if (bd_status & R_LG_S) dev->stats.rx_length_errors++; goto recycle; } bdbuffer = priv->rx_buffer + (priv->currx_bdnum * MAX_RX_BUF_LENGTH); length = be16_to_cpu(bd->length); switch (dev->type) { case ARPHRD_RAWHDLC: bdbuffer += HDLC_HEAD_LEN; length -= (HDLC_HEAD_LEN + HDLC_CRC_SIZE); skb = dev_alloc_skb(length); if (!skb) { dev->stats.rx_dropped++; return -ENOMEM; } skb_put(skb, length); skb->len = length; skb->dev = dev; memcpy(skb->data, bdbuffer, length); break; case ARPHRD_PPP: case ARPHRD_ETHER: length -= HDLC_CRC_SIZE; skb = dev_alloc_skb(length); if (!skb) { dev->stats.rx_dropped++; return -ENOMEM; } skb_put(skb, length); skb->len = length; skb->dev = dev; memcpy(skb->data, bdbuffer, length); break; } dev->stats.rx_packets++; dev->stats.rx_bytes += skb->len; howmany++; if (hdlc->proto) skb->protocol = hdlc_type_trans(skb, dev); netif_receive_skb(skb); recycle: bd->status = cpu_to_be16((bd_status & R_W_S) | R_E_S | R_I_S); /* update to point at the next bd */ if (bd_status & R_W_S) { priv->currx_bdnum = 0; bd = priv->rx_bd_base; } else { if (priv->currx_bdnum < (RX_BD_RING_LEN - 1)) priv->currx_bdnum += 1; else priv->currx_bdnum = RX_BD_RING_LEN - 1; bd += 1; } bd_status = be16_to_cpu(bd->status); } dma_rmb(); priv->currx_bd = bd; return howmany; } static int ucc_hdlc_poll(struct napi_struct *napi, int budget) { struct ucc_hdlc_private *priv = container_of(napi, struct ucc_hdlc_private, napi); int howmany; /* Tx event processing */ spin_lock(&priv->lock); hdlc_tx_done(priv); spin_unlock(&priv->lock); howmany = 0; howmany += hdlc_rx_done(priv, budget - howmany); if (howmany < budget) { napi_complete_done(napi, howmany); qe_setbits_be32(priv->uccf->p_uccm, (UCCE_HDLC_RX_EVENTS | UCCE_HDLC_TX_EVENTS) << 16); } return howmany; } static irqreturn_t ucc_hdlc_irq_handler(int irq, void *dev_id) { struct ucc_hdlc_private *priv = (struct ucc_hdlc_private *)dev_id; struct net_device *dev = priv->ndev; struct ucc_fast_private *uccf; u32 ucce; u32 uccm; uccf = priv->uccf; ucce = ioread32be(uccf->p_ucce); uccm = ioread32be(uccf->p_uccm); ucce &= uccm; iowrite32be(ucce, uccf->p_ucce); if (!ucce) return IRQ_NONE; if ((ucce >> 16) & (UCCE_HDLC_RX_EVENTS | UCCE_HDLC_TX_EVENTS)) { if (napi_schedule_prep(&priv->napi)) { uccm &= ~((UCCE_HDLC_RX_EVENTS | UCCE_HDLC_TX_EVENTS) << 16); iowrite32be(uccm, uccf->p_uccm); __napi_schedule(&priv->napi); } } /* Errors and other events */ if (ucce >> 16 & UCC_HDLC_UCCE_BSY) dev->stats.rx_missed_errors++; if (ucce >> 16 & UCC_HDLC_UCCE_TXE) dev->stats.tx_errors++; return IRQ_HANDLED; } static int uhdlc_ioctl(struct net_device *dev, struct if_settings *ifs) { const size_t size = sizeof(te1_settings); te1_settings line; struct ucc_hdlc_private *priv = netdev_priv(dev); switch (ifs->type) { case IF_GET_IFACE: ifs->type = IF_IFACE_E1; if (ifs->size < size) { ifs->size = size; /* data size wanted */ return -ENOBUFS; } memset(&line, 0, sizeof(line)); line.clock_type = priv->clocking; if (copy_to_user(ifs->ifs_ifsu.sync, &line, size)) return -EFAULT; return 0; default: return hdlc_ioctl(dev, ifs); } } static int uhdlc_open(struct net_device *dev) { u32 cecr_subblock; hdlc_device *hdlc = dev_to_hdlc(dev); struct ucc_hdlc_private *priv = hdlc->priv; struct ucc_tdm *utdm = priv->utdm; int rc = 0; if (priv->hdlc_busy != 1) { if (request_irq(priv->ut_info->uf_info.irq, ucc_hdlc_irq_handler, 0, "hdlc", priv)) return -ENODEV; cecr_subblock = ucc_fast_get_qe_cr_subblock( priv->ut_info->uf_info.ucc_num); qe_issue_cmd(QE_INIT_TX_RX, cecr_subblock, QE_CR_PROTOCOL_UNSPECIFIED, 0); ucc_fast_enable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); /* Enable the TDM port */ if (priv->tsa) qe_setbits_8(&utdm->si_regs->siglmr1_h, 0x1 << utdm->tdm_port); priv->hdlc_busy = 1; netif_device_attach(priv->ndev); napi_enable(&priv->napi); netdev_reset_queue(dev); netif_start_queue(dev); rc = hdlc_open(dev); if (rc) uhdlc_close(dev); } return rc; } static void uhdlc_memclean(struct ucc_hdlc_private *priv) { qe_muram_free(ioread16be(&priv->ucc_pram->riptr)); qe_muram_free(ioread16be(&priv->ucc_pram->tiptr)); if (priv->rx_bd_base) { dma_free_coherent(priv->dev, RX_BD_RING_LEN * sizeof(struct qe_bd), priv->rx_bd_base, priv->dma_rx_bd); priv->rx_bd_base = NULL; priv->dma_rx_bd = 0; } if (priv->tx_bd_base) { dma_free_coherent(priv->dev, TX_BD_RING_LEN * sizeof(struct qe_bd), priv->tx_bd_base, priv->dma_tx_bd); priv->tx_bd_base = NULL; priv->dma_tx_bd = 0; } if (priv->ucc_pram) { qe_muram_free(priv->ucc_pram_offset); priv->ucc_pram = NULL; priv->ucc_pram_offset = 0; } kfree(priv->rx_skbuff); priv->rx_skbuff = NULL; kfree(priv->tx_skbuff); priv->tx_skbuff = NULL; if (priv->uf_regs) { iounmap(priv->uf_regs); priv->uf_regs = NULL; } if (priv->uccf) { ucc_fast_free(priv->uccf); priv->uccf = NULL; } if (priv->rx_buffer) { dma_free_coherent(priv->dev, RX_BD_RING_LEN * MAX_RX_BUF_LENGTH, priv->rx_buffer, priv->dma_rx_addr); priv->rx_buffer = NULL; priv->dma_rx_addr = 0; } if (priv->tx_buffer) { dma_free_coherent(priv->dev, TX_BD_RING_LEN * MAX_RX_BUF_LENGTH, priv->tx_buffer, priv->dma_tx_addr); priv->tx_buffer = NULL; priv->dma_tx_addr = 0; } } static int uhdlc_close(struct net_device *dev) { struct ucc_hdlc_private *priv = dev_to_hdlc(dev)->priv; struct ucc_tdm *utdm = priv->utdm; u32 cecr_subblock; napi_disable(&priv->napi); cecr_subblock = ucc_fast_get_qe_cr_subblock( priv->ut_info->uf_info.ucc_num); qe_issue_cmd(QE_GRACEFUL_STOP_TX, cecr_subblock, (u8)QE_CR_PROTOCOL_UNSPECIFIED, 0); qe_issue_cmd(QE_CLOSE_RX_BD, cecr_subblock, (u8)QE_CR_PROTOCOL_UNSPECIFIED, 0); if (priv->tsa) qe_clrbits_8(&utdm->si_regs->siglmr1_h, 0x1 << utdm->tdm_port); ucc_fast_disable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); free_irq(priv->ut_info->uf_info.irq, priv); netif_stop_queue(dev); netdev_reset_queue(dev); priv->hdlc_busy = 0; hdlc_close(dev); return 0; } static int ucc_hdlc_attach(struct net_device *dev, unsigned short encoding, unsigned short parity) { struct ucc_hdlc_private *priv = dev_to_hdlc(dev)->priv; if (encoding != ENCODING_NRZ && encoding != ENCODING_NRZI) return -EINVAL; if (parity != PARITY_NONE && parity != PARITY_CRC32_PR1_CCITT && parity != PARITY_CRC16_PR0_CCITT && parity != PARITY_CRC16_PR1_CCITT) return -EINVAL; priv->encoding = encoding; priv->parity = parity; return 0; } #ifdef CONFIG_PM static void store_clk_config(struct ucc_hdlc_private *priv) { struct qe_mux __iomem *qe_mux_reg = &qe_immr->qmx; /* store si clk */ priv->cmxsi1cr_h = ioread32be(&qe_mux_reg->cmxsi1cr_h); priv->cmxsi1cr_l = ioread32be(&qe_mux_reg->cmxsi1cr_l); /* store si sync */ priv->cmxsi1syr = ioread32be(&qe_mux_reg->cmxsi1syr); /* store ucc clk */ memcpy_fromio(priv->cmxucr, qe_mux_reg->cmxucr, 4 * sizeof(u32)); } static void resume_clk_config(struct ucc_hdlc_private *priv) { struct qe_mux __iomem *qe_mux_reg = &qe_immr->qmx; memcpy_toio(qe_mux_reg->cmxucr, priv->cmxucr, 4 * sizeof(u32)); iowrite32be(priv->cmxsi1cr_h, &qe_mux_reg->cmxsi1cr_h); iowrite32be(priv->cmxsi1cr_l, &qe_mux_reg->cmxsi1cr_l); iowrite32be(priv->cmxsi1syr, &qe_mux_reg->cmxsi1syr); } static int uhdlc_suspend(struct device *dev) { struct ucc_hdlc_private *priv = dev_get_drvdata(dev); struct ucc_fast __iomem *uf_regs; if (!priv) return -EINVAL; if (!netif_running(priv->ndev)) return 0; netif_device_detach(priv->ndev); napi_disable(&priv->napi); uf_regs = priv->uf_regs; /* backup gumr guemr*/ priv->gumr = ioread32be(&uf_regs->gumr); priv->guemr = ioread8(&uf_regs->guemr); priv->ucc_pram_bak = kmalloc(sizeof(*priv->ucc_pram_bak), GFP_KERNEL); if (!priv->ucc_pram_bak) return -ENOMEM; /* backup HDLC parameter */ memcpy_fromio(priv->ucc_pram_bak, priv->ucc_pram, sizeof(struct ucc_hdlc_param)); /* store the clk configuration */ store_clk_config(priv); /* save power */ ucc_fast_disable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); return 0; } static int uhdlc_resume(struct device *dev) { struct ucc_hdlc_private *priv = dev_get_drvdata(dev); struct ucc_tdm *utdm; struct ucc_tdm_info *ut_info; struct ucc_fast __iomem *uf_regs; struct ucc_fast_private *uccf; struct ucc_fast_info *uf_info; int i; u32 cecr_subblock; u16 bd_status; if (!priv) return -EINVAL; if (!netif_running(priv->ndev)) return 0; utdm = priv->utdm; ut_info = priv->ut_info; uf_info = &ut_info->uf_info; uf_regs = priv->uf_regs; uccf = priv->uccf; /* restore gumr guemr */ iowrite8(priv->guemr, &uf_regs->guemr); iowrite32be(priv->gumr, &uf_regs->gumr); /* Set Virtual Fifo registers */ iowrite16be(uf_info->urfs, &uf_regs->urfs); iowrite16be(uf_info->urfet, &uf_regs->urfet); iowrite16be(uf_info->urfset, &uf_regs->urfset); iowrite16be(uf_info->utfs, &uf_regs->utfs); iowrite16be(uf_info->utfet, &uf_regs->utfet); iowrite16be(uf_info->utftt, &uf_regs->utftt); /* utfb, urfb are offsets from MURAM base */ iowrite32be(uccf->ucc_fast_tx_virtual_fifo_base_offset, &uf_regs->utfb); iowrite32be(uccf->ucc_fast_rx_virtual_fifo_base_offset, &uf_regs->urfb); /* Rx Tx and sync clock routing */ resume_clk_config(priv); iowrite32be(uf_info->uccm_mask, &uf_regs->uccm); iowrite32be(0xffffffff, &uf_regs->ucce); ucc_fast_disable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); /* rebuild SIRAM */ if (priv->tsa) ucc_tdm_init(priv->utdm, priv->ut_info); /* Write to QE CECR, UCCx channel to Stop Transmission */ cecr_subblock = ucc_fast_get_qe_cr_subblock(uf_info->ucc_num); qe_issue_cmd(QE_STOP_TX, cecr_subblock, (u8)QE_CR_PROTOCOL_UNSPECIFIED, 0); /* Set UPSMR normal mode */ iowrite32be(0, &uf_regs->upsmr); /* init parameter base */ cecr_subblock = ucc_fast_get_qe_cr_subblock(uf_info->ucc_num); qe_issue_cmd(QE_ASSIGN_PAGE_TO_DEVICE, cecr_subblock, QE_CR_PROTOCOL_UNSPECIFIED, priv->ucc_pram_offset); priv->ucc_pram = (struct ucc_hdlc_param __iomem *) qe_muram_addr(priv->ucc_pram_offset); /* restore ucc parameter */ memcpy_toio(priv->ucc_pram, priv->ucc_pram_bak, sizeof(struct ucc_hdlc_param)); kfree(priv->ucc_pram_bak); /* rebuild BD entry */ for (i = 0; i < RX_BD_RING_LEN; i++) { if (i < (RX_BD_RING_LEN - 1)) bd_status = R_E_S | R_I_S; else bd_status = R_E_S | R_I_S | R_W_S; priv->rx_bd_base[i].status = cpu_to_be16(bd_status); priv->rx_bd_base[i].buf = cpu_to_be32(priv->dma_rx_addr + i * MAX_RX_BUF_LENGTH); } for (i = 0; i < TX_BD_RING_LEN; i++) { if (i < (TX_BD_RING_LEN - 1)) bd_status = T_I_S | T_TC_S; else bd_status = T_I_S | T_TC_S | T_W_S; priv->tx_bd_base[i].status = cpu_to_be16(bd_status); priv->tx_bd_base[i].buf = cpu_to_be32(priv->dma_tx_addr + i * MAX_RX_BUF_LENGTH); } dma_wmb(); /* if hdlc is busy enable TX and RX */ if (priv->hdlc_busy == 1) { cecr_subblock = ucc_fast_get_qe_cr_subblock( priv->ut_info->uf_info.ucc_num); qe_issue_cmd(QE_INIT_TX_RX, cecr_subblock, (u8)QE_CR_PROTOCOL_UNSPECIFIED, 0); ucc_fast_enable(priv->uccf, COMM_DIR_RX | COMM_DIR_TX); /* Enable the TDM port */ if (priv->tsa) qe_setbits_8(&utdm->si_regs->siglmr1_h, 0x1 << utdm->tdm_port); } napi_enable(&priv->napi); netif_device_attach(priv->ndev); return 0; } static const struct dev_pm_ops uhdlc_pm_ops = { .suspend = uhdlc_suspend, .resume = uhdlc_resume, .freeze = uhdlc_suspend, .thaw = uhdlc_resume, }; #define HDLC_PM_OPS (&uhdlc_pm_ops) #else #define HDLC_PM_OPS NULL #endif static void uhdlc_tx_timeout(struct net_device *ndev, unsigned int txqueue) { netdev_err(ndev, "%s\n", __func__); } static const struct net_device_ops uhdlc_ops = { .ndo_open = uhdlc_open, .ndo_stop = uhdlc_close, .ndo_start_xmit = hdlc_start_xmit, .ndo_siocwandev = uhdlc_ioctl, .ndo_tx_timeout = uhdlc_tx_timeout, }; static int hdlc_map_iomem(char *name, int init_flag, void __iomem **ptr) { struct device_node *np; struct platform_device *pdev; struct resource *res; static int siram_init_flag; int ret = 0; np = of_find_compatible_node(NULL, NULL, name); if (!np) return -EINVAL; pdev = of_find_device_by_node(np); if (!pdev) { pr_err("%pOFn: failed to lookup pdev\n", np); of_node_put(np); return -EINVAL; } of_node_put(np); res = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!res) { ret = -EINVAL; goto error_put_device; } *ptr = ioremap(res->start, resource_size(res)); if (!*ptr) { ret = -ENOMEM; goto error_put_device; } /* We've remapped the addresses, and we don't need the device any * more, so we should release it. */ put_device(&pdev->dev); if (init_flag && siram_init_flag == 0) { memset_io(*ptr, 0, resource_size(res)); siram_init_flag = 1; } return 0; error_put_device: put_device(&pdev->dev); return ret; } static int ucc_hdlc_probe(struct platform_device *pdev) { struct device_node *np = pdev->dev.of_node; struct ucc_hdlc_private *uhdlc_priv = NULL; struct ucc_tdm_info *ut_info; struct ucc_tdm *utdm = NULL; struct resource res; struct net_device *dev; hdlc_device *hdlc; int ucc_num; const char *sprop; int ret; u32 val; ret = of_property_read_u32_index(np, "cell-index", 0, &val); if (ret) { dev_err(&pdev->dev, "Invalid ucc property\n"); return -ENODEV; } ucc_num = val - 1; if (ucc_num > (UCC_MAX_NUM - 1) || ucc_num < 0) { dev_err(&pdev->dev, ": Invalid UCC num\n"); return -EINVAL; } memcpy(&utdm_info[ucc_num], &utdm_primary_info, sizeof(utdm_primary_info)); ut_info = &utdm_info[ucc_num]; ut_info->uf_info.ucc_num = ucc_num; sprop = of_get_property(np, "rx-clock-name", NULL); if (sprop) { ut_info->uf_info.rx_clock = qe_clock_source(sprop); if ((ut_info->uf_info.rx_clock < QE_CLK_NONE) || (ut_info->uf_info.rx_clock > QE_CLK24)) { dev_err(&pdev->dev, "Invalid rx-clock-name property\n"); return -EINVAL; } } else { dev_err(&pdev->dev, "Invalid rx-clock-name property\n"); return -EINVAL; } sprop = of_get_property(np, "tx-clock-name", NULL); if (sprop) { ut_info->uf_info.tx_clock = qe_clock_source(sprop); if ((ut_info->uf_info.tx_clock < QE_CLK_NONE) || (ut_info->uf_info.tx_clock > QE_CLK24)) { dev_err(&pdev->dev, "Invalid tx-clock-name property\n"); return -EINVAL; } } else { dev_err(&pdev->dev, "Invalid tx-clock-name property\n"); return -EINVAL; } ret = of_address_to_resource(np, 0, &res); if (ret) return -EINVAL; ut_info->uf_info.regs = res.start; ut_info->uf_info.irq = irq_of_parse_and_map(np, 0); uhdlc_priv = kzalloc(sizeof(*uhdlc_priv), GFP_KERNEL); if (!uhdlc_priv) return -ENOMEM; dev_set_drvdata(&pdev->dev, uhdlc_priv); uhdlc_priv->dev = &pdev->dev; uhdlc_priv->ut_info = ut_info; uhdlc_priv->tsa = of_property_read_bool(np, "fsl,tdm-interface"); uhdlc_priv->loopback = of_property_read_bool(np, "fsl,ucc-internal-loopback"); uhdlc_priv->hdlc_bus = of_property_read_bool(np, "fsl,hdlc-bus"); if (uhdlc_priv->tsa == 1) { utdm = kzalloc(sizeof(*utdm), GFP_KERNEL); if (!utdm) { ret = -ENOMEM; dev_err(&pdev->dev, "No mem to alloc ucc tdm data\n"); goto free_uhdlc_priv; } uhdlc_priv->utdm = utdm; ret = ucc_of_parse_tdm(np, utdm, ut_info); if (ret) goto free_utdm; ret = hdlc_map_iomem("fsl,t1040-qe-si", 0, (void __iomem **)&utdm->si_regs); if (ret) goto free_utdm; ret = hdlc_map_iomem("fsl,t1040-qe-siram", 1, (void __iomem **)&utdm->siram); if (ret) goto unmap_si_regs; } if (of_property_read_u16(np, "fsl,hmask", &uhdlc_priv->hmask)) uhdlc_priv->hmask = DEFAULT_ADDR_MASK; ret = uhdlc_init(uhdlc_priv); if (ret) { dev_err(&pdev->dev, "Failed to init uhdlc\n"); goto undo_uhdlc_init; } dev = alloc_hdlcdev(uhdlc_priv); if (!dev) { ret = -ENOMEM; pr_err("ucc_hdlc: unable to allocate memory\n"); goto undo_uhdlc_init; } uhdlc_priv->ndev = dev; hdlc = dev_to_hdlc(dev); dev->tx_queue_len = 16; dev->netdev_ops = &uhdlc_ops; dev->watchdog_timeo = 2 * HZ; hdlc->attach = ucc_hdlc_attach; hdlc->xmit = ucc_hdlc_tx; netif_napi_add_weight(dev, &uhdlc_priv->napi, ucc_hdlc_poll, 32); if (register_hdlc_device(dev)) { ret = -ENOBUFS; pr_err("ucc_hdlc: unable to register hdlc device\n"); goto free_dev; } return 0; free_dev: free_netdev(dev); undo_uhdlc_init: if (utdm) iounmap(utdm->siram); unmap_si_regs: if (utdm) iounmap(utdm->si_regs); free_utdm: if (uhdlc_priv->tsa) kfree(utdm); free_uhdlc_priv: kfree(uhdlc_priv); return ret; } static int ucc_hdlc_remove(struct platform_device *pdev) { struct ucc_hdlc_private *priv = dev_get_drvdata(&pdev->dev); uhdlc_memclean(priv); if (priv->utdm->si_regs) { iounmap(priv->utdm->si_regs); priv->utdm->si_regs = NULL; } if (priv->utdm->siram) { iounmap(priv->utdm->siram); priv->utdm->siram = NULL; } kfree(priv); dev_info(&pdev->dev, "UCC based hdlc module removed\n"); return 0; } static const struct of_device_id fsl_ucc_hdlc_of_match[] = { { .compatible = "fsl,ucc-hdlc", }, {}, }; MODULE_DEVICE_TABLE(of, fsl_ucc_hdlc_of_match); static struct platform_driver ucc_hdlc_driver = { .probe = ucc_hdlc_probe, .remove = ucc_hdlc_remove, .driver = { .name = DRV_NAME, .pm = HDLC_PM_OPS, .of_match_table = fsl_ucc_hdlc_of_match, }, }; module_platform_driver(ucc_hdlc_driver); MODULE_LICENSE("GPL"); MODULE_DESCRIPTION(DRV_DESC);
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