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/*- * Copyright (c) 2002-2007 Neterion, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: release/9.1.0/sys/dev/nxge/xgehal/xgehal-device-fp.c 173139 2007-10-29 14:19:32Z rwatson $ */ #ifdef XGE_DEBUG_FP #include <dev/nxge/include/xgehal-device.h> #endif #include <dev/nxge/include/xgehal-ring.h> #include <dev/nxge/include/xgehal-fifo.h> /** * xge_hal_device_bar0 - Get BAR0 mapped address. * @hldev: HAL device handle. * * Returns: BAR0 address of the specified device. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_bar0(xge_hal_device_t *hldev) { return hldev->bar0; } /** * xge_hal_device_isrbar0 - Get BAR0 mapped address. * @hldev: HAL device handle. * * Returns: BAR0 address of the specified device. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_isrbar0(xge_hal_device_t *hldev) { return hldev->isrbar0; } /** * xge_hal_device_bar1 - Get BAR1 mapped address. * @hldev: HAL device handle. * * Returns: BAR1 address of the specified device. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_bar1(xge_hal_device_t *hldev) { return hldev->bar1; } /** * xge_hal_device_bar0_set - Set BAR0 mapped address. * @hldev: HAL device handle. * @bar0: BAR0 mapped address. * * Set BAR0 address in the HAL device object. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_bar0_set(xge_hal_device_t *hldev, char *bar0) { xge_assert(bar0); hldev->bar0 = bar0; } /** * xge_hal_device_isrbar0_set - Set BAR0 mapped address. * @hldev: HAL device handle. * @isrbar0: BAR0 mapped address. * * Set BAR0 address in the HAL device object. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_isrbar0_set(xge_hal_device_t *hldev, char *isrbar0) { xge_assert(isrbar0); hldev->isrbar0 = isrbar0; } /** * xge_hal_device_bar1_set - Set BAR1 mapped address. * @hldev: HAL device handle. * @channelh: Channel handle. * @bar1: BAR1 mapped address. * * Set BAR1 address for the given channel. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_bar1_set(xge_hal_device_t *hldev, xge_hal_channel_h channelh, char *bar1) { xge_hal_fifo_t *fifo = (xge_hal_fifo_t *)channelh; xge_assert(bar1); xge_assert(fifo); /* Initializing the BAR1 address as the start of * the FIFO queue pointer and as a location of FIFO control * word. */ fifo->hw_pair = (xge_hal_fifo_hw_pair_t *) (bar1 + (fifo->channel.post_qid * XGE_HAL_FIFO_HW_PAIR_OFFSET)); hldev->bar1 = bar1; } /** * xge_hal_device_rev - Get Device revision number. * @hldev: HAL device handle. * * Returns: Device revision number */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE int xge_hal_device_rev(xge_hal_device_t *hldev) { return hldev->revision; } /** * xge_hal_device_begin_irq - Begin IRQ processing. * @hldev: HAL device handle. * @reason: "Reason" for the interrupt, the value of Xframe's * general_int_status register. * * The function performs two actions, It first checks whether (shared IRQ) the * interrupt was raised by the device. Next, it masks the device interrupts. * * Note: * xge_hal_device_begin_irq() does not flush MMIO writes through the * bridge. Therefore, two back-to-back interrupts are potentially possible. * It is the responsibility of the ULD to make sure that only one * xge_hal_device_continue_irq() runs at a time. * * Returns: 0, if the interrupt is not "ours" (note that in this case the * device remain enabled). * Otherwise, xge_hal_device_begin_irq() returns 64bit general adapter * status. * See also: xge_hal_device_handle_irq() */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_begin_irq(xge_hal_device_t *hldev, u64 *reason) { u64 val64; xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; hldev->stats.sw_dev_info_stats.total_intr_cnt++; val64 = xge_os_pio_mem_read64(hldev->pdev, hldev->regh0, &isrbar0->general_int_status); if (xge_os_unlikely(!val64)) { /* not Xframe interrupt */ hldev->stats.sw_dev_info_stats.not_xge_intr_cnt++; *reason = 0; return XGE_HAL_ERR_WRONG_IRQ; } if (xge_os_unlikely(val64 == XGE_HAL_ALL_FOXES)) { u64 adapter_status = xge_os_pio_mem_read64(hldev->pdev, hldev->regh0, &isrbar0->adapter_status); if (adapter_status == XGE_HAL_ALL_FOXES) { (void) xge_queue_produce(hldev->queueh, XGE_HAL_EVENT_SLOT_FREEZE, hldev, 1, /* critical: slot freeze */ sizeof(u64), (void*)&adapter_status); *reason = 0; return XGE_HAL_ERR_CRITICAL; } } *reason = val64; /* separate fast path, i.e. no errors */ if (val64 & XGE_HAL_GEN_INTR_RXTRAFFIC) { hldev->stats.sw_dev_info_stats.rx_traffic_intr_cnt++; return XGE_HAL_OK; } if (val64 & XGE_HAL_GEN_INTR_TXTRAFFIC) { hldev->stats.sw_dev_info_stats.tx_traffic_intr_cnt++; return XGE_HAL_OK; } hldev->stats.sw_dev_info_stats.not_traffic_intr_cnt++; if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_TXPIC)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.txpic_intr_cnt++; status = __hal_device_handle_txpic(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_TXDMA)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.txdma_intr_cnt++; status = __hal_device_handle_txdma(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_TXMAC)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.txmac_intr_cnt++; status = __hal_device_handle_txmac(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_TXXGXS)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.txxgxs_intr_cnt++; status = __hal_device_handle_txxgxs(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_RXPIC)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.rxpic_intr_cnt++; status = __hal_device_handle_rxpic(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_RXDMA)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.rxdma_intr_cnt++; status = __hal_device_handle_rxdma(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_RXMAC)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.rxmac_intr_cnt++; status = __hal_device_handle_rxmac(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_RXXGXS)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.rxxgxs_intr_cnt++; status = __hal_device_handle_rxxgxs(hldev, val64); if (status != XGE_HAL_OK) { return status; } } if (xge_os_unlikely(val64 & XGE_HAL_GEN_INTR_MC)) { xge_hal_status_e status; hldev->stats.sw_dev_info_stats.mc_intr_cnt++; status = __hal_device_handle_mc(hldev, val64); if (status != XGE_HAL_OK) { return status; } } return XGE_HAL_OK; } /** * xge_hal_device_clear_rx - Acknowledge (that is, clear) the * condition that has caused the RX interrupt. * @hldev: HAL device handle. * * Acknowledge (that is, clear) the condition that has caused * the Rx interrupt. * See also: xge_hal_device_begin_irq(), xge_hal_device_continue_irq(), * xge_hal_device_clear_tx(), xge_hal_device_mask_rx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_clear_rx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0xFFFFFFFFFFFFFFFFULL, &isrbar0->rx_traffic_int); } /** * xge_hal_device_clear_tx - Acknowledge (that is, clear) the * condition that has caused the TX interrupt. * @hldev: HAL device handle. * * Acknowledge (that is, clear) the condition that has caused * the Tx interrupt. * See also: xge_hal_device_begin_irq(), xge_hal_device_continue_irq(), * xge_hal_device_clear_rx(), xge_hal_device_mask_tx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_clear_tx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0xFFFFFFFFFFFFFFFFULL, &isrbar0->tx_traffic_int); } /** * xge_hal_device_poll_rx_channel - Poll Rx channel for completed * descriptors and process the same. * @channel: HAL channel. * @got_rx: Buffer to return the flag set if receive interrupt is occured * * The function polls the Rx channel for the completed descriptors and calls * the upper-layer driver (ULD) via supplied completion callback. * * Returns: XGE_HAL_OK, if the polling is completed successful. * XGE_HAL_COMPLETIONS_REMAIN: There are still more completed * descriptors available which are yet to be processed. * * See also: xge_hal_device_poll_tx_channel() */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_rx_channel(xge_hal_channel_t *channel, int *got_rx) { xge_hal_status_e ret = XGE_HAL_OK; xge_hal_dtr_h first_dtrh; xge_hal_device_t *hldev = (xge_hal_device_t *)channel->devh; u8 t_code; int got_bytes; /* for each opened rx channel */ got_bytes = *got_rx = 0; ((xge_hal_ring_t *)channel)->cmpl_cnt = 0; channel->poll_bytes = 0; if ((ret = xge_hal_ring_dtr_next_completed (channel, &first_dtrh, &t_code)) == XGE_HAL_OK) { if (channel->callback(channel, first_dtrh, t_code, channel->userdata) != XGE_HAL_OK) { (*got_rx) += ((xge_hal_ring_t *)channel)->cmpl_cnt + 1; got_bytes += channel->poll_bytes + 1; ret = XGE_HAL_COMPLETIONS_REMAIN; } else { (*got_rx) += ((xge_hal_ring_t *)channel)->cmpl_cnt + 1; got_bytes += channel->poll_bytes + 1; } } if (*got_rx) { hldev->irq_workload_rxd[channel->post_qid] += *got_rx; hldev->irq_workload_rxcnt[channel->post_qid] ++; } hldev->irq_workload_rxlen[channel->post_qid] += got_bytes; return ret; } /** * xge_hal_device_poll_tx_channel - Poll Tx channel for completed * descriptors and process the same. * @channel: HAL channel. * @got_tx: Buffer to return the flag set if transmit interrupt is occured * * The function polls the Tx channel for the completed descriptors and calls * the upper-layer driver (ULD) via supplied completion callback. * * Returns: XGE_HAL_OK, if the polling is completed successful. * XGE_HAL_COMPLETIONS_REMAIN: There are still more completed * descriptors available which are yet to be processed. * * See also: xge_hal_device_poll_rx_channel(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_tx_channel(xge_hal_channel_t *channel, int *got_tx) { xge_hal_dtr_h first_dtrh; xge_hal_device_t *hldev = (xge_hal_device_t *)channel->devh; u8 t_code; int got_bytes; /* for each opened tx channel */ got_bytes = *got_tx = 0; channel->poll_bytes = 0; if (xge_hal_fifo_dtr_next_completed (channel, &first_dtrh, &t_code) == XGE_HAL_OK) { if (channel->callback(channel, first_dtrh, t_code, channel->userdata) != XGE_HAL_OK) { (*got_tx)++; got_bytes += channel->poll_bytes + 1; return XGE_HAL_COMPLETIONS_REMAIN; } (*got_tx)++; got_bytes += channel->poll_bytes + 1; } if (*got_tx) { hldev->irq_workload_txd[channel->post_qid] += *got_tx; hldev->irq_workload_txcnt[channel->post_qid] ++; } hldev->irq_workload_txlen[channel->post_qid] += got_bytes; return XGE_HAL_OK; } /** * xge_hal_device_poll_rx_channels - Poll Rx channels for completed * descriptors and process the same. * @hldev: HAL device handle. * @got_rx: Buffer to return flag set if receive is ready * * The function polls the Rx channels for the completed descriptors and calls * the upper-layer driver (ULD) via supplied completion callback. * * Returns: XGE_HAL_OK, if the polling is completed successful. * XGE_HAL_COMPLETIONS_REMAIN: There are still more completed * descriptors available which are yet to be processed. * * See also: xge_hal_device_poll_tx_channels(), xge_hal_device_continue_irq(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_rx_channels(xge_hal_device_t *hldev, int *got_rx) { xge_list_t *item; xge_hal_channel_t *channel; /* for each opened rx channel */ xge_list_for_each(item, &hldev->ring_channels) { if (hldev->terminating) return XGE_HAL_OK; channel = xge_container_of(item, xge_hal_channel_t, item); (void) xge_hal_device_poll_rx_channel(channel, got_rx); } return XGE_HAL_OK; } /** * xge_hal_device_poll_tx_channels - Poll Tx channels for completed * descriptors and process the same. * @hldev: HAL device handle. * @got_tx: Buffer to return flag set if transmit is ready * * The function polls the Tx channels for the completed descriptors and calls * the upper-layer driver (ULD) via supplied completion callback. * * Returns: XGE_HAL_OK, if the polling is completed successful. * XGE_HAL_COMPLETIONS_REMAIN: There are still more completed * descriptors available which are yet to be processed. * * See also: xge_hal_device_poll_rx_channels(), xge_hal_device_continue_irq(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_tx_channels(xge_hal_device_t *hldev, int *got_tx) { xge_list_t *item; xge_hal_channel_t *channel; /* for each opened tx channel */ xge_list_for_each(item, &hldev->fifo_channels) { if (hldev->terminating) return XGE_HAL_OK; channel = xge_container_of(item, xge_hal_channel_t, item); (void) xge_hal_device_poll_tx_channel(channel, got_tx); } return XGE_HAL_OK; } /** * xge_hal_device_mask_tx - Mask Tx interrupts. * @hldev: HAL device handle. * * Mask Tx device interrupts. * * See also: xge_hal_device_unmask_tx(), xge_hal_device_mask_rx(), * xge_hal_device_clear_tx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_tx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0xFFFFFFFFFFFFFFFFULL, &isrbar0->tx_traffic_mask); } /** * xge_hal_device_mask_rx - Mask Rx interrupts. * @hldev: HAL device handle. * * Mask Rx device interrupts. * * See also: xge_hal_device_unmask_rx(), xge_hal_device_mask_tx(), * xge_hal_device_clear_rx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_rx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0xFFFFFFFFFFFFFFFFULL, &isrbar0->rx_traffic_mask); } /** * xge_hal_device_mask_all - Mask all device interrupts. * @hldev: HAL device handle. * * Mask all device interrupts. * * See also: xge_hal_device_unmask_all() */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_all(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0xFFFFFFFFFFFFFFFFULL, &isrbar0->general_int_mask); } /** * xge_hal_device_unmask_tx - Unmask Tx interrupts. * @hldev: HAL device handle. * * Unmask Tx device interrupts. * * See also: xge_hal_device_mask_tx(), xge_hal_device_clear_tx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_tx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0x0ULL, &isrbar0->tx_traffic_mask); } /** * xge_hal_device_unmask_rx - Unmask Rx interrupts. * @hldev: HAL device handle. * * Unmask Rx device interrupts. * * See also: xge_hal_device_mask_rx(), xge_hal_device_clear_rx(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_rx(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0x0ULL, &isrbar0->rx_traffic_mask); } /** * xge_hal_device_unmask_all - Unmask all device interrupts. * @hldev: HAL device handle. * * Unmask all device interrupts. * * See also: xge_hal_device_mask_all() */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_all(xge_hal_device_t *hldev) { xge_hal_pci_bar0_t *isrbar0 = (xge_hal_pci_bar0_t *)hldev->isrbar0; xge_os_pio_mem_write64(hldev->pdev, hldev->regh0, 0x0ULL, &isrbar0->general_int_mask); } /** * xge_hal_device_continue_irq - Continue handling IRQ: process all * completed descriptors. * @hldev: HAL device handle. * * Process completed descriptors and unmask the device interrupts. * * The xge_hal_device_continue_irq() walks all open channels * and calls upper-layer driver (ULD) via supplied completion * callback. Note that the completion callback is specified at channel open * time, see xge_hal_channel_open(). * * Note that the xge_hal_device_continue_irq is part of the _fast_ path. * To optimize the processing, the function does _not_ check for * errors and alarms. * * The latter is done in a polling fashion, via xge_hal_device_poll(). * * Returns: XGE_HAL_OK. * * See also: xge_hal_device_handle_irq(), xge_hal_device_poll(), * xge_hal_ring_dtr_next_completed(), * xge_hal_fifo_dtr_next_completed(), xge_hal_channel_callback_f{}. */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_continue_irq(xge_hal_device_t *hldev) { int got_rx = 1, got_tx = 1; int isr_polling_cnt = hldev->config.isr_polling_cnt; int count = 0; do { if (got_rx) (void) xge_hal_device_poll_rx_channels(hldev, &got_rx); if (got_tx && hldev->tti_enabled) (void) xge_hal_device_poll_tx_channels(hldev, &got_tx); if (!got_rx && !got_tx) break; count += (got_rx + got_tx); }while (isr_polling_cnt--); if (!count) hldev->stats.sw_dev_info_stats.not_traffic_intr_cnt++; return XGE_HAL_OK; } /** * xge_hal_device_handle_irq - Handle device IRQ. * @hldev: HAL device handle. * * Perform the complete handling of the line interrupt. The function * performs two calls. * First it uses xge_hal_device_begin_irq() to check the reason for * the interrupt and mask the device interrupts. * Second, it calls xge_hal_device_continue_irq() to process all * completed descriptors and re-enable the interrupts. * * Returns: XGE_HAL_OK - success; * XGE_HAL_ERR_WRONG_IRQ - (shared) IRQ produced by other device. * * See also: xge_hal_device_begin_irq(), xge_hal_device_continue_irq(). */ __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_handle_irq(xge_hal_device_t *hldev) { u64 reason; xge_hal_status_e status; xge_hal_device_mask_all(hldev); status = xge_hal_device_begin_irq(hldev, &reason); if (status != XGE_HAL_OK) { xge_hal_device_unmask_all(hldev); return status; } if (reason & XGE_HAL_GEN_INTR_RXTRAFFIC) { xge_hal_device_clear_rx(hldev); } status = xge_hal_device_continue_irq(hldev); xge_hal_device_clear_tx(hldev); xge_hal_device_unmask_all(hldev); return status; } #if defined(XGE_HAL_CONFIG_LRO) __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL int __hal_lro_check_for_session_match(lro_t *lro, tcplro_t *tcp, iplro_t *ip) { /* Match Source address field */ if ((lro->ip_hdr->saddr != ip->saddr)) return XGE_HAL_FAIL; /* Match Destination address field */ if ((lro->ip_hdr->daddr != ip->daddr)) return XGE_HAL_FAIL; /* Match Source Port field */ if ((lro->tcp_hdr->source != tcp->source)) return XGE_HAL_FAIL; /* Match Destination Port field */ if ((lro->tcp_hdr->dest != tcp->dest)) return XGE_HAL_FAIL; return XGE_HAL_OK; } /* * __hal_tcp_seg_len: Find the tcp seg len. * @ip: ip header. * @tcp: tcp header. * returns: Tcp seg length. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL u16 __hal_tcp_seg_len(iplro_t *ip, tcplro_t *tcp) { u16 ret; ret = (xge_os_ntohs(ip->tot_len) - ((ip->version_ihl & 0x0F)<<2) - ((tcp->doff_res)>>2)); return (ret); } /* * __hal_ip_lro_capable: Finds whether ip is lro capable. * @ip: ip header. * @ext_info: descriptor info. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_ip_lro_capable(iplro_t *ip, xge_hal_dtr_info_t *ext_info) { #ifdef XGE_LL_DEBUG_DUMP_PKT { u16 i; u8 ch, *iph = (u8 *)ip; xge_debug_ring(XGE_TRACE, "Dump Ip:" ); for (i =0; i < 40; i++) { ch = ntohs(*((u8 *)(iph + i)) ); printf("i:%d %02x, ",i,ch); } } #endif if (ip->version_ihl != IP_FAST_PATH_HDR_MASK) { xge_debug_ring(XGE_ERR, "iphdr !=45 :%d",ip->version_ihl); return XGE_HAL_FAIL; } if (ext_info->proto & XGE_HAL_FRAME_PROTO_IP_FRAGMENTED) { xge_debug_ring(XGE_ERR, "IP fragmented"); return XGE_HAL_FAIL; } return XGE_HAL_OK; } /* * __hal_tcp_lro_capable: Finds whether tcp is lro capable. * @ip: ip header. * @tcp: tcp header. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_tcp_lro_capable(iplro_t *ip, tcplro_t *tcp, lro_t *lro, int *ts_off) { #ifdef XGE_LL_DEBUG_DUMP_PKT { u8 ch; u16 i; xge_debug_ring(XGE_TRACE, "Dump Tcp:" ); for (i =0; i < 20; i++) { ch = ntohs(*((u8 *)((u8 *)tcp + i)) ); xge_os_printf("i:%d %02x, ",i,ch); } } #endif if ((TCP_FAST_PATH_HDR_MASK2 != tcp->ctrl) && (TCP_FAST_PATH_HDR_MASK3 != tcp->ctrl)) goto _exit_fail; *ts_off = -1; if (TCP_FAST_PATH_HDR_MASK1 != tcp->doff_res) { u16 tcp_hdr_len = tcp->doff_res >> 2; /* TCP header len */ u16 off = 20; /* Start of tcp options */ int i, diff; /* Does Packet can contain time stamp */ if (tcp_hdr_len < 32) { /* * If the session is not opened, we can consider * this packet for LRO */ if (lro == NULL) return XGE_HAL_OK; goto _exit_fail; } /* Ignore No-operation 0x1 */ while (((u8 *)tcp)[off] == 0x1) off++; /* Next option == Timestamp */ if (((u8 *)tcp)[off] != 0x8) { /* * If the session ie not opened, we can consider * this packet for LRO */ if (lro == NULL) return XGE_HAL_OK; goto _exit_fail; } *ts_off = off; if (lro == NULL) return XGE_HAL_OK; /* * Now the session is opened. If the LRO frame doesn't * have time stamp, we cannot consider current packet for * LRO. */ if (lro->ts_off == -1) { xge_debug_ring(XGE_ERR, "Pkt received with time stamp after session opened with no time stamp : %02x %02x", tcp->doff_res, tcp->ctrl); return XGE_HAL_FAIL; } /* * If the difference is greater than three, then there are * more options possible. * else, there are two cases: * case 1: remaining are padding bytes. * case 2: remaining can contain options or padding */ off += ((u8 *)tcp)[off+1]; diff = tcp_hdr_len - off; if (diff > 3) { /* * Probably contains more options. */ xge_debug_ring(XGE_ERR, "tcphdr not fastpth : pkt received with tcp options in addition to time stamp after the session is opened %02x %02x ", tcp->doff_res, tcp->ctrl); return XGE_HAL_FAIL; } for (i = 0; i < diff; i++) { u8 byte = ((u8 *)tcp)[off+i]; /* Ignore No-operation 0x1 */ if ((byte == 0x0) || (byte == 0x1)) continue; xge_debug_ring(XGE_ERR, "tcphdr not fastpth : pkt received with tcp options in addition to time stamp after the session is opened %02x %02x ", tcp->doff_res, tcp->ctrl); return XGE_HAL_FAIL; } /* * Update the time stamp of LRO frame. */ xge_os_memcpy(((char *)lro->tcp_hdr + lro->ts_off + 2), (char *)((char *)tcp + (*ts_off) + 2), 8); } return XGE_HAL_OK; _exit_fail: xge_debug_ring(XGE_TRACE, "tcphdr not fastpth %02x %02x", tcp->doff_res, tcp->ctrl); return XGE_HAL_FAIL; } /* * __hal_lro_capable: Finds whether frame is lro capable. * @buffer: Ethernet frame. * @ip: ip frame. * @tcp: tcp frame. * @ext_info: Descriptor info. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_lro_capable( u8 *buffer, iplro_t **ip, tcplro_t **tcp, xge_hal_dtr_info_t *ext_info) { u8 ip_off, ip_length; if (!(ext_info->proto & XGE_HAL_FRAME_PROTO_TCP)) { xge_debug_ring(XGE_ERR, "Cant do lro %d", ext_info->proto); return XGE_HAL_FAIL; } if ( !*ip ) { #ifdef XGE_LL_DEBUG_DUMP_PKT { u8 ch; u16 i; xge_os_printf("Dump Eth:" ); for (i =0; i < 60; i++) { ch = ntohs(*((u8 *)(buffer + i)) ); xge_os_printf("i:%d %02x, ",i,ch); } } #endif switch (ext_info->frame) { case XGE_HAL_FRAME_TYPE_DIX: ip_off = XGE_HAL_HEADER_ETHERNET_II_802_3_SIZE; break; case XGE_HAL_FRAME_TYPE_LLC: ip_off = (XGE_HAL_HEADER_ETHERNET_II_802_3_SIZE + XGE_HAL_HEADER_802_2_SIZE); break; case XGE_HAL_FRAME_TYPE_SNAP: ip_off = (XGE_HAL_HEADER_ETHERNET_II_802_3_SIZE + XGE_HAL_HEADER_SNAP_SIZE); break; default: // XGE_HAL_FRAME_TYPE_IPX, etc. return XGE_HAL_FAIL; } if (ext_info->proto & XGE_HAL_FRAME_PROTO_VLAN_TAGGED) { ip_off += XGE_HAL_HEADER_VLAN_SIZE; } /* Grab ip, tcp headers */ *ip = (iplro_t *)((char*)buffer + ip_off); } /* !*ip */ ip_length = (u8)((*ip)->version_ihl & 0x0F); ip_length = ip_length <<2; *tcp = (tcplro_t *)((char *)*ip + ip_length); xge_debug_ring(XGE_TRACE, "ip_length:%d ip:"XGE_OS_LLXFMT " tcp:"XGE_OS_LLXFMT"", (int)ip_length, (unsigned long long)(ulong_t)*ip, (unsigned long long)(ulong_t)*tcp); return XGE_HAL_OK; } /* * __hal_open_lro_session: Open a new LRO session. * @buffer: Ethernet frame. * @ip: ip header. * @tcp: tcp header. * @lro: lro pointer * @ext_info: Descriptor info. * @hldev: Hal context. * @ring_lro: LRO descriptor per rx ring. * @slot: Bucket no. * @tcp_seg_len: Length of tcp segment. * @ts_off: time stamp offset in the packet. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void __hal_open_lro_session (u8 *buffer, iplro_t *ip, tcplro_t *tcp, lro_t **lro, xge_hal_device_t *hldev, xge_hal_lro_desc_t *ring_lro, int slot, u32 tcp_seg_len, int ts_off) { lro_t *lro_new = &ring_lro->lro_pool[slot]; lro_new->in_use = 1; lro_new->ll_hdr = buffer; lro_new->ip_hdr = ip; lro_new->tcp_hdr = tcp; lro_new->tcp_next_seq_num = tcp_seg_len + xge_os_ntohl( tcp->seq); lro_new->tcp_seq_num = tcp->seq; lro_new->tcp_ack_num = tcp->ack_seq; lro_new->sg_num = 1; lro_new->total_length = xge_os_ntohs(ip->tot_len); lro_new->frags_len = 0; lro_new->ts_off = ts_off; hldev->stats.sw_dev_info_stats.tot_frms_lroised++; hldev->stats.sw_dev_info_stats.tot_lro_sessions++; *lro = ring_lro->lro_recent = lro_new; return; } /* * __hal_lro_get_free_slot: Get a free LRO bucket. * @ring_lro: LRO descriptor per ring. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL int __hal_lro_get_free_slot (xge_hal_lro_desc_t *ring_lro) { int i; for (i = 0; i < XGE_HAL_LRO_MAX_BUCKETS; i++) { lro_t *lro_temp = &ring_lro->lro_pool[i]; if (!lro_temp->in_use) return i; } return -1; } /* * __hal_get_lro_session: Gets matching LRO session or creates one. * @eth_hdr: Ethernet header. * @ip: ip header. * @tcp: tcp header. * @lro: lro pointer * @ext_info: Descriptor info. * @hldev: Hal context. * @ring_lro: LRO descriptor per rx ring */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_get_lro_session (u8 *eth_hdr, iplro_t *ip, tcplro_t *tcp, lro_t **lro, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev, xge_hal_lro_desc_t *ring_lro, lro_t **lro_end3 /* Valid only when ret=END_3 */) { lro_t *lro_match; int i, free_slot = -1; u32 tcp_seg_len; int ts_off = -1; *lro = lro_match = NULL; /* * Compare the incoming frame with the lro session left from the * previous call. There is a good chance that this incoming frame * matches the lro session. */ if (ring_lro->lro_recent && ring_lro->lro_recent->in_use) { if (__hal_lro_check_for_session_match(ring_lro->lro_recent, tcp, ip) == XGE_HAL_OK) lro_match = ring_lro->lro_recent; } if (!lro_match) { /* * Search in the pool of LROs for the session that matches * the incoming frame. */ for (i = 0; i < XGE_HAL_LRO_MAX_BUCKETS; i++) { lro_t *lro_temp = &ring_lro->lro_pool[i]; if (!lro_temp->in_use) { if (free_slot == -1) free_slot = i; continue; } if (__hal_lro_check_for_session_match(lro_temp, tcp, ip) == XGE_HAL_OK) { lro_match = lro_temp; break; } } } if (lro_match) { /* * Matching LRO Session found */ *lro = lro_match; if (lro_match->tcp_next_seq_num != xge_os_ntohl(tcp->seq)) { xge_debug_ring(XGE_ERR, "**retransmit **" "found***"); hldev->stats.sw_dev_info_stats.lro_out_of_seq_pkt_cnt++; return XGE_HAL_INF_LRO_END_2; } if (XGE_HAL_OK != __hal_ip_lro_capable(ip, ext_info)) { return XGE_HAL_INF_LRO_END_2; } if (XGE_HAL_OK != __hal_tcp_lro_capable(ip, tcp, lro_match, &ts_off)) { /* * Close the current session and open a new * LRO session with this packet, * provided it has tcp payload */ tcp_seg_len = __hal_tcp_seg_len(ip, tcp); if (tcp_seg_len == 0) { return XGE_HAL_INF_LRO_END_2; } /* Get a free bucket */ free_slot = __hal_lro_get_free_slot(ring_lro); if (free_slot == -1) { return XGE_HAL_INF_LRO_END_2; } /* * Open a new LRO session */ __hal_open_lro_session (eth_hdr, ip, tcp, lro_end3, hldev, ring_lro, free_slot, tcp_seg_len, ts_off); return XGE_HAL_INF_LRO_END_3; } /* * The frame is good, in-sequence, can be LRO-ed; * take its (latest) ACK - unless it is a dupack. * Note: to be exact need to check window size as well.. */ if (lro_match->tcp_ack_num == tcp->ack_seq && lro_match->tcp_seq_num == tcp->seq) { hldev->stats.sw_dev_info_stats.lro_dup_pkt_cnt++; return XGE_HAL_INF_LRO_END_2; } lro_match->tcp_seq_num = tcp->seq; lro_match->tcp_ack_num = tcp->ack_seq; lro_match->frags_len += __hal_tcp_seg_len(ip, tcp); ring_lro->lro_recent = lro_match; return XGE_HAL_INF_LRO_CONT; } /* ********** New Session ***************/ if (free_slot == -1) return XGE_HAL_INF_LRO_UNCAPABLE; if (XGE_HAL_FAIL == __hal_ip_lro_capable(ip, ext_info)) return XGE_HAL_INF_LRO_UNCAPABLE; if (XGE_HAL_FAIL == __hal_tcp_lro_capable(ip, tcp, NULL, &ts_off)) return XGE_HAL_INF_LRO_UNCAPABLE; xge_debug_ring(XGE_TRACE, "Creating lro session."); /* * Open a LRO session, provided the packet contains payload. */ tcp_seg_len = __hal_tcp_seg_len(ip, tcp); if (tcp_seg_len == 0) return XGE_HAL_INF_LRO_UNCAPABLE; __hal_open_lro_session (eth_hdr, ip, tcp, lro, hldev, ring_lro, free_slot, tcp_seg_len, ts_off); return XGE_HAL_INF_LRO_BEGIN; } /* * __hal_lro_under_optimal_thresh: Finds whether combined session is optimal. * @ip: ip header. * @tcp: tcp header. * @lro: lro pointer * @hldev: Hal context. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_lro_under_optimal_thresh (iplro_t *ip, tcplro_t *tcp, lro_t *lro, xge_hal_device_t *hldev) { if (!lro) return XGE_HAL_FAIL; if ((lro->total_length + __hal_tcp_seg_len(ip, tcp) ) > hldev->config.lro_frm_len) { xge_debug_ring(XGE_TRACE, "Max LRO frame len exceeded:" "max length %d ", hldev->config.lro_frm_len); hldev->stats.sw_dev_info_stats.lro_frm_len_exceed_cnt++; return XGE_HAL_FAIL; } if (lro->sg_num == hldev->config.lro_sg_size) { xge_debug_ring(XGE_TRACE, "Max sg count exceeded:" "max sg %d ", hldev->config.lro_sg_size); hldev->stats.sw_dev_info_stats.lro_sg_exceed_cnt++; return XGE_HAL_FAIL; } return XGE_HAL_OK; } /* * __hal_collapse_ip_hdr: Collapses ip header. * @ip: ip header. * @tcp: tcp header. * @lro: lro pointer * @hldev: Hal context. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_collapse_ip_hdr ( iplro_t *ip, tcplro_t *tcp, lro_t *lro, xge_hal_device_t *hldev) { lro->total_length += __hal_tcp_seg_len(ip, tcp); /* May be we have to handle time stamps or more options */ return XGE_HAL_OK; } /* * __hal_collapse_tcp_hdr: Collapses tcp header. * @ip: ip header. * @tcp: tcp header. * @lro: lro pointer * @hldev: Hal context. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_collapse_tcp_hdr ( iplro_t *ip, tcplro_t *tcp, lro_t *lro, xge_hal_device_t *hldev) { lro->tcp_next_seq_num += __hal_tcp_seg_len(ip, tcp); return XGE_HAL_OK; } /* * __hal_append_lro: Appends new frame to existing LRO session. * @ip: ip header. * @tcp: IN tcp header, OUT tcp payload. * @seg_len: tcp payload length. * @lro: lro pointer * @hldev: Hal context. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_append_lro(iplro_t *ip, tcplro_t **tcp, u32 *seg_len, lro_t *lro, xge_hal_device_t *hldev) { (void) __hal_collapse_ip_hdr(ip, *tcp, lro, hldev); (void) __hal_collapse_tcp_hdr(ip, *tcp, lro, hldev); // Update mbuf chain will be done in ll driver. // xge_hal_accumulate_large_rx on success of appending new frame to // lro will return to ll driver tcpdata pointer, and tcp payload length. // along with return code lro frame appended. lro->sg_num++; *seg_len = __hal_tcp_seg_len(ip, *tcp); *tcp = (tcplro_t *)((char *)*tcp + (((*tcp)->doff_res)>>2)); return XGE_HAL_OK; } /** * __xge_hal_accumulate_large_rx: LRO a given frame * frames * @ring: rx ring number * @eth_hdr: ethernet header. * @ip_hdr: ip header (optional) * @tcp: tcp header. * @seglen: packet length. * @p_lro: lro pointer. * @ext_info: descriptor info, see xge_hal_dtr_info_t{}. * @hldev: HAL device. * @lro_end3: for lro_end3 output * * LRO the newly received frame, i.e. attach it (if possible) to the * already accumulated (i.e., already LRO-ed) received frames (if any), * to form one super-sized frame for the subsequent processing * by the stack. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e xge_hal_lro_process_rx(int ring, u8 *eth_hdr, u8 *ip_hdr, tcplro_t **tcp, u32 *seglen, lro_t **p_lro, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev, lro_t **lro_end3) { iplro_t *ip = (iplro_t *)ip_hdr; xge_hal_status_e ret; lro_t *lro; xge_debug_ring(XGE_TRACE, "Entered accumu lro. "); if (XGE_HAL_OK != __hal_lro_capable(eth_hdr, &ip, (tcplro_t **)tcp, ext_info)) return XGE_HAL_INF_LRO_UNCAPABLE; /* * This function shall get matching LRO or else * create one and return it */ ret = __hal_get_lro_session(eth_hdr, ip, (tcplro_t *)*tcp, p_lro, ext_info, hldev, &hldev->lro_desc[ring], lro_end3); xge_debug_ring(XGE_TRACE, "ret from get_lro:%d ",ret); lro = *p_lro; if (XGE_HAL_INF_LRO_CONT == ret) { if (XGE_HAL_OK == __hal_lro_under_optimal_thresh(ip, (tcplro_t *)*tcp, lro, hldev)) { (void) __hal_append_lro(ip,(tcplro_t **) tcp, seglen, lro, hldev); hldev->stats.sw_dev_info_stats.tot_frms_lroised++; if (lro->sg_num >= hldev->config.lro_sg_size) { hldev->stats.sw_dev_info_stats.lro_sg_exceed_cnt++; ret = XGE_HAL_INF_LRO_END_1; } } else ret = XGE_HAL_INF_LRO_END_2; } /* * Since its time to flush, * update ip header so that it can be sent up */ if ((ret == XGE_HAL_INF_LRO_END_1) || (ret == XGE_HAL_INF_LRO_END_2) || (ret == XGE_HAL_INF_LRO_END_3)) { lro->ip_hdr->tot_len = xge_os_htons((*p_lro)->total_length); lro->ip_hdr->check = xge_os_htons(0); lro->ip_hdr->check = XGE_LL_IP_FAST_CSUM(((u8 *)(lro->ip_hdr)), (lro->ip_hdr->version_ihl & 0x0F)); lro->tcp_hdr->ack_seq = lro->tcp_ack_num; } return (ret); } /** * xge_hal_accumulate_large_rx: LRO a given frame * frames * @buffer: Ethernet frame. * @tcp: tcp header. * @seglen: packet length. * @p_lro: lro pointer. * @ext_info: descriptor info, see xge_hal_dtr_info_t{}. * @hldev: HAL device. * @lro_end3: for lro_end3 output * * LRO the newly received frame, i.e. attach it (if possible) to the * already accumulated (i.e., already LRO-ed) received frames (if any), * to form one super-sized frame for the subsequent processing * by the stack. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e xge_hal_accumulate_large_rx(u8 *buffer, tcplro_t **tcp, u32 *seglen, lro_t **p_lro, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev, lro_t **lro_end3) { int ring = 0; return xge_hal_lro_process_rx(ring, buffer, NULL, tcp, seglen, p_lro, ext_info, hldev, lro_end3); } /** * xge_hal_lro_close_session: Close LRO session * @lro: LRO Session. * @hldev: HAL Context. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void xge_hal_lro_close_session (lro_t *lro) { lro->in_use = 0; } /** * xge_hal_lro_next_session: Returns next LRO session in the list or NULL * if none exists. * @hldev: HAL Context. * @ring: rx ring number. */ __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL lro_t * xge_hal_lro_next_session (xge_hal_device_t *hldev, int ring) { xge_hal_lro_desc_t *ring_lro = &hldev->lro_desc[ring]; int i; int start_idx = ring_lro->lro_next_idx; for(i = start_idx; i < XGE_HAL_LRO_MAX_BUCKETS; i++) { lro_t *lro = &ring_lro->lro_pool[i]; if (!lro->in_use) continue; lro->ip_hdr->tot_len = xge_os_htons(lro->total_length); lro->ip_hdr->check = xge_os_htons(0); lro->ip_hdr->check = XGE_LL_IP_FAST_CSUM(((u8 *)(lro->ip_hdr)), (lro->ip_hdr->version_ihl & 0x0F)); ring_lro->lro_next_idx = i + 1; return lro; } ring_lro->lro_next_idx = 0; return NULL; } __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL lro_t * xge_hal_lro_get_next_session(xge_hal_device_t *hldev) { int ring = 0; /* assume default ring=0 */ return xge_hal_lro_next_session(hldev, ring); } #endif