Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/s3/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/usie/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/aue/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/uhso/@/dev/nxge/xgehal/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/s3/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/usie/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/aue/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/uhso/@/dev/nxge/xgehal/xgehal-ring-fp.c |
/*- * 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-ring-fp.c 218909 2011-02-21 09:01:34Z brucec $ */ #ifdef XGE_DEBUG_FP #include <dev/nxge/include/xgehal-ring.h> #endif __HAL_STATIC_RING __HAL_INLINE_RING xge_hal_ring_rxd_priv_t* __hal_ring_rxd_priv(xge_hal_ring_t *ring, xge_hal_dtr_h dtrh) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; xge_hal_ring_rxd_priv_t *rxd_priv; xge_assert(rxdp); #if defined(XGE_HAL_USE_5B_MODE) xge_assert(ring); if (ring->buffer_mode == XGE_HAL_RING_QUEUE_BUFFER_MODE_5) { xge_hal_ring_rxd_5_t *rxdp_5 = (xge_hal_ring_rxd_5_t *)dtrh; #if defined (XGE_OS_PLATFORM_64BIT) int memblock_idx = rxdp_5->host_control >> 16; int i = rxdp_5->host_control & 0xFFFF; rxd_priv = (xge_hal_ring_rxd_priv_t *) ((char*)ring->mempool->memblocks_priv_arr[memblock_idx] + ring->rxd_priv_size * i); #else /* 32-bit case */ rxd_priv = (xge_hal_ring_rxd_priv_t *)rxdp_5->host_control; #endif } else #endif { rxd_priv = (xge_hal_ring_rxd_priv_t *) (ulong_t)rxdp->host_control; } xge_assert(rxd_priv); xge_assert(rxd_priv->dma_object); xge_assert(rxd_priv->dma_object->handle == rxd_priv->dma_handle); xge_assert(rxd_priv->dma_object->addr + rxd_priv->dma_offset == rxd_priv->dma_addr); return rxd_priv; } __HAL_STATIC_RING __HAL_INLINE_RING int __hal_ring_block_memblock_idx(xge_hal_ring_block_t *block) { return (int)*((u64 *)(void *)((char *)block + XGE_HAL_RING_MEMBLOCK_IDX_OFFSET)); } __HAL_STATIC_RING __HAL_INLINE_RING void __hal_ring_block_memblock_idx_set(xge_hal_ring_block_t*block, int memblock_idx) { *((u64 *)(void *)((char *)block + XGE_HAL_RING_MEMBLOCK_IDX_OFFSET)) = memblock_idx; } __HAL_STATIC_RING __HAL_INLINE_RING dma_addr_t __hal_ring_block_next_pointer(xge_hal_ring_block_t *block) { return (dma_addr_t)*((u64 *)(void *)((char *)block + XGE_HAL_RING_NEXT_BLOCK_POINTER_OFFSET)); } __HAL_STATIC_RING __HAL_INLINE_RING void __hal_ring_block_next_pointer_set(xge_hal_ring_block_t *block, dma_addr_t dma_next) { *((u64 *)(void *)((char *)block + XGE_HAL_RING_NEXT_BLOCK_POINTER_OFFSET)) = dma_next; } /** * xge_hal_ring_dtr_private - Get ULD private per-descriptor data. * @channelh: Channel handle. * @dtrh: Descriptor handle. * * Returns: private ULD info associated with the descriptor. * ULD requests per-descriptor space via xge_hal_channel_open(). * * See also: xge_hal_fifo_dtr_private(). * Usage: See ex_rx_compl{}. */ __HAL_STATIC_RING __HAL_INLINE_RING void* xge_hal_ring_dtr_private(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { return (char *)__hal_ring_rxd_priv((xge_hal_ring_t *) channelh, dtrh) + sizeof(xge_hal_ring_rxd_priv_t); } /** * xge_hal_ring_dtr_reserve - Reserve ring descriptor. * @channelh: Channel handle. * @dtrh: Reserved descriptor. On success HAL fills this "out" parameter * with a valid handle. * * Reserve Rx descriptor for the subsequent filling-in (by upper layer * driver (ULD)) and posting on the corresponding channel (@channelh) * via xge_hal_ring_dtr_post(). * * Returns: XGE_HAL_OK - success. * XGE_HAL_INF_OUT_OF_DESCRIPTORS - Currently no descriptors available. * * See also: xge_hal_fifo_dtr_reserve(), xge_hal_ring_dtr_free(), * xge_hal_fifo_dtr_reserve_sp(), xge_hal_status_e{}. * Usage: See ex_post_all_rx{}. */ __HAL_STATIC_RING __HAL_INLINE_RING xge_hal_status_e xge_hal_ring_dtr_reserve(xge_hal_channel_h channelh, xge_hal_dtr_h *dtrh) { xge_hal_status_e status; #if defined(XGE_HAL_RX_MULTI_RESERVE_IRQ) unsigned long flags; #endif #if defined(XGE_HAL_RX_MULTI_RESERVE) xge_os_spin_lock(&((xge_hal_channel_t*)channelh)->reserve_lock); #elif defined(XGE_HAL_RX_MULTI_RESERVE_IRQ) xge_os_spin_lock_irq(&((xge_hal_channel_t*)channelh)->reserve_lock, flags); #endif status = __hal_channel_dtr_alloc(channelh, dtrh); #if defined(XGE_HAL_RX_MULTI_RESERVE) xge_os_spin_unlock(&((xge_hal_channel_t*)channelh)->reserve_lock); #elif defined(XGE_HAL_RX_MULTI_RESERVE_IRQ) xge_os_spin_unlock_irq(&((xge_hal_channel_t*)channelh)->reserve_lock, flags); #endif if (status == XGE_HAL_OK) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)*dtrh; /* instead of memset: reset this RxD */ rxdp->control_1 = rxdp->control_2 = 0; #if defined(XGE_OS_MEMORY_CHECK) __hal_ring_rxd_priv((xge_hal_ring_t *) channelh, rxdp)->allocated = 1; #endif } return status; } /** * xge_hal_ring_dtr_info_get - Get extended information associated with * a completed receive descriptor for 1b mode. * @channelh: Channel handle. * @dtrh: Descriptor handle. * @ext_info: See xge_hal_dtr_info_t{}. Returned by HAL. * * Retrieve extended information associated with a completed receive descriptor. * * See also: xge_hal_dtr_info_t{}, xge_hal_ring_dtr_1b_get(), * xge_hal_ring_dtr_5b_get(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_info_get(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, xge_hal_dtr_info_t *ext_info) { /* cast to 1-buffer mode RxD: the code below relies on the fact * that control_1 and control_2 are formatted the same way.. */ xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; ext_info->l3_cksum = XGE_HAL_RXD_GET_L3_CKSUM(rxdp->control_1); ext_info->l4_cksum = XGE_HAL_RXD_GET_L4_CKSUM(rxdp->control_1); ext_info->frame = XGE_HAL_RXD_GET_FRAME_TYPE(rxdp->control_1); ext_info->proto = XGE_HAL_RXD_GET_FRAME_PROTO(rxdp->control_1); ext_info->vlan = XGE_HAL_RXD_GET_VLAN_TAG(rxdp->control_2); /* Herc only, a few extra cycles imposed on Xena and/or * when RTH is not enabled. * Alternatively, could check * xge_hal_device_check_id(), hldev->config.rth_en, queue->rth_en */ ext_info->rth_it_hit = XGE_HAL_RXD_GET_RTH_IT_HIT(rxdp->control_1); ext_info->rth_spdm_hit = XGE_HAL_RXD_GET_RTH_SPDM_HIT(rxdp->control_1); ext_info->rth_hash_type = XGE_HAL_RXD_GET_RTH_HASH_TYPE(rxdp->control_1); ext_info->rth_value = XGE_HAL_RXD_1_GET_RTH_VALUE(rxdp->control_2); } /** * xge_hal_ring_dtr_info_nb_get - Get extended information associated * with a completed receive descriptor for 3b or 5b * modes. * @channelh: Channel handle. * @dtrh: Descriptor handle. * @ext_info: See xge_hal_dtr_info_t{}. Returned by HAL. * * Retrieve extended information associated with a completed receive descriptor. * * See also: xge_hal_dtr_info_t{}, xge_hal_ring_dtr_1b_get(), * xge_hal_ring_dtr_5b_get(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_info_nb_get(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, xge_hal_dtr_info_t *ext_info) { /* cast to 1-buffer mode RxD: the code below relies on the fact * that control_1 and control_2 are formatted the same way.. */ xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; ext_info->l3_cksum = XGE_HAL_RXD_GET_L3_CKSUM(rxdp->control_1); ext_info->l4_cksum = XGE_HAL_RXD_GET_L4_CKSUM(rxdp->control_1); ext_info->frame = XGE_HAL_RXD_GET_FRAME_TYPE(rxdp->control_1); ext_info->proto = XGE_HAL_RXD_GET_FRAME_PROTO(rxdp->control_1); ext_info->vlan = XGE_HAL_RXD_GET_VLAN_TAG(rxdp->control_2); /* Herc only, a few extra cycles imposed on Xena and/or * when RTH is not enabled. Same comment as above. */ ext_info->rth_it_hit = XGE_HAL_RXD_GET_RTH_IT_HIT(rxdp->control_1); ext_info->rth_spdm_hit = XGE_HAL_RXD_GET_RTH_SPDM_HIT(rxdp->control_1); ext_info->rth_hash_type = XGE_HAL_RXD_GET_RTH_HASH_TYPE(rxdp->control_1); ext_info->rth_value = (u32)rxdp->buffer0_ptr; } /** * xge_hal_ring_dtr_1b_set - Prepare 1-buffer-mode descriptor. * @dtrh: Descriptor handle. * @dma_pointer: DMA address of a single receive buffer this descriptor * should carry. Note that by the time * xge_hal_ring_dtr_1b_set * is called, the receive buffer should be already mapped * to the corresponding Xframe device. * @size: Size of the receive @dma_pointer buffer. * * Prepare 1-buffer-mode Rx descriptor for posting * (via xge_hal_ring_dtr_post()). * * This inline helper-function does not return any parameters and always * succeeds. * * See also: xge_hal_ring_dtr_3b_set(), xge_hal_ring_dtr_5b_set(). * Usage: See ex_post_all_rx{}. */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_1b_set(xge_hal_dtr_h dtrh, dma_addr_t dma_pointer, int size) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; rxdp->buffer0_ptr = dma_pointer; rxdp->control_2 &= (~XGE_HAL_RXD_1_MASK_BUFFER0_SIZE); rxdp->control_2 |= XGE_HAL_RXD_1_SET_BUFFER0_SIZE(size); xge_debug_ring(XGE_TRACE, "xge_hal_ring_dtr_1b_set: rxdp %p control_2 %p buffer0_ptr %p", (xge_hal_ring_rxd_1_t *)dtrh, rxdp->control_2, rxdp->buffer0_ptr); } /** * xge_hal_ring_dtr_1b_get - Get data from the completed 1-buf * descriptor. * @channelh: Channel handle. * @dtrh: Descriptor handle. * @dma_pointer: DMA address of a single receive buffer _this_ descriptor * carries. Returned by HAL. * @pkt_length: Length (in bytes) of the data in the buffer pointed by * @dma_pointer. Returned by HAL. * * Retrieve protocol data from the completed 1-buffer-mode Rx descriptor. * This inline helper-function uses completed descriptor to populate receive * buffer pointer and other "out" parameters. The function always succeeds. * * See also: xge_hal_ring_dtr_3b_get(), xge_hal_ring_dtr_5b_get(). * Usage: See ex_rx_compl{}. */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_1b_get(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, dma_addr_t *dma_pointer, int *pkt_length) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; *pkt_length = XGE_HAL_RXD_1_GET_BUFFER0_SIZE(rxdp->control_2); *dma_pointer = rxdp->buffer0_ptr; ((xge_hal_channel_t *)channelh)->poll_bytes += *pkt_length; } /** * xge_hal_ring_dtr_3b_set - Prepare 3-buffer-mode descriptor. * @dtrh: Descriptor handle. * @dma_pointers: Array of DMA addresses. Contains exactly 3 receive buffers * _this_ descriptor should carry. * Note that by the time xge_hal_ring_dtr_3b_set * is called, the receive buffers should be mapped * to the corresponding Xframe device. * @sizes: Array of receive buffer sizes. Contains 3 sizes: one size per * buffer from @dma_pointers. * * Prepare 3-buffer-mode Rx descriptor for posting (via * xge_hal_ring_dtr_post()). * This inline helper-function does not return any parameters and always * succeeds. * * See also: xge_hal_ring_dtr_1b_set(), xge_hal_ring_dtr_5b_set(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_3b_set(xge_hal_dtr_h dtrh, dma_addr_t dma_pointers[], int sizes[]) { xge_hal_ring_rxd_3_t *rxdp = (xge_hal_ring_rxd_3_t *)dtrh; rxdp->buffer0_ptr = dma_pointers[0]; rxdp->control_2 &= (~XGE_HAL_RXD_3_MASK_BUFFER0_SIZE); rxdp->control_2 |= XGE_HAL_RXD_3_SET_BUFFER0_SIZE(sizes[0]); rxdp->buffer1_ptr = dma_pointers[1]; rxdp->control_2 &= (~XGE_HAL_RXD_3_MASK_BUFFER1_SIZE); rxdp->control_2 |= XGE_HAL_RXD_3_SET_BUFFER1_SIZE(sizes[1]); rxdp->buffer2_ptr = dma_pointers[2]; rxdp->control_2 &= (~XGE_HAL_RXD_3_MASK_BUFFER2_SIZE); rxdp->control_2 |= XGE_HAL_RXD_3_SET_BUFFER2_SIZE(sizes[2]); } /** * xge_hal_ring_dtr_3b_get - Get data from the completed 3-buf * descriptor. * @channelh: Channel handle. * @dtrh: Descriptor handle. * @dma_pointers: DMA addresses of the 3 receive buffers _this_ descriptor * carries. The first two buffers contain ethernet and * (IP + transport) headers. The 3rd buffer contains packet * data. * Returned by HAL. * @sizes: Array of receive buffer sizes. Contains 3 sizes: one size per * buffer from @dma_pointers. Returned by HAL. * * Retrieve protocol data from the completed 3-buffer-mode Rx descriptor. * This inline helper-function uses completed descriptor to populate receive * buffer pointer and other "out" parameters. The function always succeeds. * * See also: xge_hal_ring_dtr_3b_get(), xge_hal_ring_dtr_5b_get(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_3b_get(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, dma_addr_t dma_pointers[], int sizes[]) { xge_hal_ring_rxd_3_t *rxdp = (xge_hal_ring_rxd_3_t *)dtrh; dma_pointers[0] = rxdp->buffer0_ptr; sizes[0] = XGE_HAL_RXD_3_GET_BUFFER0_SIZE(rxdp->control_2); dma_pointers[1] = rxdp->buffer1_ptr; sizes[1] = XGE_HAL_RXD_3_GET_BUFFER1_SIZE(rxdp->control_2); dma_pointers[2] = rxdp->buffer2_ptr; sizes[2] = XGE_HAL_RXD_3_GET_BUFFER2_SIZE(rxdp->control_2); ((xge_hal_channel_t *)channelh)->poll_bytes += sizes[0] + sizes[1] + sizes[2]; } /** * xge_hal_ring_dtr_5b_set - Prepare 5-buffer-mode descriptor. * @dtrh: Descriptor handle. * @dma_pointers: Array of DMA addresses. Contains exactly 5 receive buffers * _this_ descriptor should carry. * Note that by the time xge_hal_ring_dtr_5b_set * is called, the receive buffers should be mapped * to the corresponding Xframe device. * @sizes: Array of receive buffer sizes. Contains 5 sizes: one size per * buffer from @dma_pointers. * * Prepare 3-buffer-mode Rx descriptor for posting (via * xge_hal_ring_dtr_post()). * This inline helper-function does not return any parameters and always * succeeds. * * See also: xge_hal_ring_dtr_1b_set(), xge_hal_ring_dtr_3b_set(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_5b_set(xge_hal_dtr_h dtrh, dma_addr_t dma_pointers[], int sizes[]) { xge_hal_ring_rxd_5_t *rxdp = (xge_hal_ring_rxd_5_t *)dtrh; rxdp->buffer0_ptr = dma_pointers[0]; rxdp->control_2 &= (~XGE_HAL_RXD_5_MASK_BUFFER0_SIZE); rxdp->control_2 |= XGE_HAL_RXD_5_SET_BUFFER0_SIZE(sizes[0]); rxdp->buffer1_ptr = dma_pointers[1]; rxdp->control_2 &= (~XGE_HAL_RXD_5_MASK_BUFFER1_SIZE); rxdp->control_2 |= XGE_HAL_RXD_5_SET_BUFFER1_SIZE(sizes[1]); rxdp->buffer2_ptr = dma_pointers[2]; rxdp->control_2 &= (~XGE_HAL_RXD_5_MASK_BUFFER2_SIZE); rxdp->control_2 |= XGE_HAL_RXD_5_SET_BUFFER2_SIZE(sizes[2]); rxdp->buffer3_ptr = dma_pointers[3]; rxdp->control_3 &= (~XGE_HAL_RXD_5_MASK_BUFFER3_SIZE); rxdp->control_3 |= XGE_HAL_RXD_5_SET_BUFFER3_SIZE(sizes[3]); rxdp->buffer4_ptr = dma_pointers[4]; rxdp->control_3 &= (~XGE_HAL_RXD_5_MASK_BUFFER4_SIZE); rxdp->control_3 |= XGE_HAL_RXD_5_SET_BUFFER4_SIZE(sizes[4]); } /** * xge_hal_ring_dtr_5b_get - Get data from the completed 5-buf * descriptor. * @channelh: Channel handle. * @dtrh: Descriptor handle. * @dma_pointers: DMA addresses of the 5 receive buffers _this_ descriptor * carries. The first 4 buffers contains L2 (ethernet) through * L5 headers. The 5th buffer contain received (applicaion) * data. Returned by HAL. * @sizes: Array of receive buffer sizes. Contains 5 sizes: one size per * buffer from @dma_pointers. Returned by HAL. * * Retrieve protocol data from the completed 5-buffer-mode Rx descriptor. * This inline helper-function uses completed descriptor to populate receive * buffer pointer and other "out" parameters. The function always succeeds. * * See also: xge_hal_ring_dtr_3b_get(), xge_hal_ring_dtr_5b_get(). */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_5b_get(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, dma_addr_t dma_pointers[], int sizes[]) { xge_hal_ring_rxd_5_t *rxdp = (xge_hal_ring_rxd_5_t *)dtrh; dma_pointers[0] = rxdp->buffer0_ptr; sizes[0] = XGE_HAL_RXD_5_GET_BUFFER0_SIZE(rxdp->control_2); dma_pointers[1] = rxdp->buffer1_ptr; sizes[1] = XGE_HAL_RXD_5_GET_BUFFER1_SIZE(rxdp->control_2); dma_pointers[2] = rxdp->buffer2_ptr; sizes[2] = XGE_HAL_RXD_5_GET_BUFFER2_SIZE(rxdp->control_2); dma_pointers[3] = rxdp->buffer3_ptr; sizes[3] = XGE_HAL_RXD_5_GET_BUFFER3_SIZE(rxdp->control_3); dma_pointers[4] = rxdp->buffer4_ptr; sizes[4] = XGE_HAL_RXD_5_GET_BUFFER4_SIZE(rxdp->control_3); ((xge_hal_channel_t *)channelh)->poll_bytes += sizes[0] + sizes[1] + sizes[2] + sizes[3] + sizes[4]; } /** * xge_hal_ring_dtr_pre_post - FIXME. * @channelh: Channel handle. * @dtrh: Descriptor handle. * * TBD */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_pre_post(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) xge_hal_ring_rxd_priv_t *priv; xge_hal_ring_t *ring = (xge_hal_ring_t *)channelh; #endif #if defined(XGE_HAL_RX_MULTI_POST_IRQ) unsigned long flags; #endif rxdp->control_2 |= XGE_HAL_RXD_NOT_COMPLETED; #ifdef XGE_DEBUG_ASSERT /* make sure Xena overwrites the (illegal) t_code on completion */ XGE_HAL_RXD_SET_T_CODE(rxdp->control_1, XGE_HAL_RXD_T_CODE_UNUSED_C); #endif xge_debug_ring(XGE_TRACE, "xge_hal_ring_dtr_pre_post: rxd 0x"XGE_OS_LLXFMT" posted %d post_qid %d", (unsigned long long)(ulong_t)dtrh, ((xge_hal_ring_t *)channelh)->channel.post_index, ((xge_hal_ring_t *)channelh)->channel.post_qid); #if defined(XGE_HAL_RX_MULTI_POST) xge_os_spin_lock(&((xge_hal_channel_t*)channelh)->post_lock); #elif defined(XGE_HAL_RX_MULTI_POST_IRQ) xge_os_spin_lock_irq(&((xge_hal_channel_t*)channelh)->post_lock, flags); #endif #if defined(XGE_DEBUG_ASSERT) && defined(XGE_HAL_RING_ENFORCE_ORDER) { xge_hal_channel_t *channel = (xge_hal_channel_t *)channelh; if (channel->post_index != 0) { xge_hal_dtr_h prev_dtrh; xge_hal_ring_rxd_priv_t *rxdp_priv; rxdp_priv = __hal_ring_rxd_priv((xge_hal_ring_t*)channel, rxdp); prev_dtrh = channel->work_arr[channel->post_index - 1]; if (prev_dtrh != NULL && (rxdp_priv->dma_offset & (~0xFFF)) != rxdp_priv->dma_offset) { xge_assert((char *)prev_dtrh + ((xge_hal_ring_t*)channel)->rxd_size == dtrh); } } } #endif __hal_channel_dtr_post(channelh, dtrh); #if defined(XGE_HAL_RX_MULTI_POST) xge_os_spin_unlock(&((xge_hal_channel_t*)channelh)->post_lock); #elif defined(XGE_HAL_RX_MULTI_POST_IRQ) xge_os_spin_unlock_irq(&((xge_hal_channel_t*)channelh)->post_lock, flags); #endif } /** * xge_hal_ring_dtr_post_post - FIXME. * @channelh: Channel handle. * @dtrh: Descriptor handle. * * TBD */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_post_post(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; xge_hal_ring_t *ring = (xge_hal_ring_t *)channelh; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) xge_hal_ring_rxd_priv_t *priv; #endif /* do POST */ rxdp->control_1 |= XGE_HAL_RXD_POSTED_4_XFRAME; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) priv = __hal_ring_rxd_priv(ring, rxdp); xge_os_dma_sync(ring->channel.pdev, priv->dma_handle, priv->dma_addr, priv->dma_offset, ring->rxd_size, XGE_OS_DMA_DIR_TODEVICE); #endif xge_debug_ring(XGE_TRACE, "xge_hal_ring_dtr_post_post: rxdp %p control_1 %p", (xge_hal_ring_rxd_1_t *)dtrh, rxdp->control_1); if (ring->channel.usage_cnt > 0) ring->channel.usage_cnt--; } /** * xge_hal_ring_dtr_post_post_wmb. * @channelh: Channel handle. * @dtrh: Descriptor handle. * * Similar as xge_hal_ring_dtr_post_post, but in addition it does memory barrier. */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_post_post_wmb(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { xge_hal_ring_rxd_1_t *rxdp = (xge_hal_ring_rxd_1_t *)dtrh; xge_hal_ring_t *ring = (xge_hal_ring_t *)channelh; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) xge_hal_ring_rxd_priv_t *priv; #endif /* Do memory barrier before changing the ownership */ xge_os_wmb(); /* do POST */ rxdp->control_1 |= XGE_HAL_RXD_POSTED_4_XFRAME; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) priv = __hal_ring_rxd_priv(ring, rxdp); xge_os_dma_sync(ring->channel.pdev, priv->dma_handle, priv->dma_addr, priv->dma_offset, ring->rxd_size, XGE_OS_DMA_DIR_TODEVICE); #endif if (ring->channel.usage_cnt > 0) ring->channel.usage_cnt--; xge_debug_ring(XGE_TRACE, "xge_hal_ring_dtr_post_post_wmb: rxdp %p control_1 %p rxds_with_host %d", (xge_hal_ring_rxd_1_t *)dtrh, rxdp->control_1, ring->channel.usage_cnt); } /** * xge_hal_ring_dtr_post - Post descriptor on the ring channel. * @channelh: Channel handle. * @dtrh: Descriptor obtained via xge_hal_ring_dtr_reserve(). * * Post descriptor on the 'ring' type channel. * Prior to posting the descriptor should be filled in accordance with * Host/Xframe interface specification for a given service (LL, etc.). * * See also: xge_hal_fifo_dtr_post_many(), xge_hal_fifo_dtr_post(). * Usage: See ex_post_all_rx{}. */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_post(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { xge_hal_ring_dtr_pre_post(channelh, dtrh); xge_hal_ring_dtr_post_post(channelh, dtrh); } /** * xge_hal_ring_dtr_next_completed - Get the _next_ completed * descriptor. * @channelh: Channel handle. * @dtrh: Descriptor handle. Returned by HAL. * @t_code: Transfer code, as per Xframe User Guide, * Receive Descriptor Format. Returned by HAL. * * Retrieve the _next_ completed descriptor. * HAL uses channel callback (*xge_hal_channel_callback_f) to notifiy * upper-layer driver (ULD) of new completed descriptors. After that * the ULD can use xge_hal_ring_dtr_next_completed to retrieve the rest * completions (the very first completion is passed by HAL via * xge_hal_channel_callback_f). * * Implementation-wise, the upper-layer driver is free to call * xge_hal_ring_dtr_next_completed either immediately from inside the * channel callback, or in a deferred fashion and separate (from HAL) * context. * * Non-zero @t_code means failure to fill-in receive buffer(s) * of the descriptor. * For instance, parity error detected during the data transfer. * In this case Xframe will complete the descriptor and indicate * for the host that the received data is not to be used. * For details please refer to Xframe User Guide. * * Returns: XGE_HAL_OK - success. * XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS - No completed descriptors * are currently available for processing. * * See also: xge_hal_channel_callback_f{}, * xge_hal_fifo_dtr_next_completed(), xge_hal_status_e{}. * Usage: See ex_rx_compl{}. */ __HAL_STATIC_RING __HAL_INLINE_RING xge_hal_status_e xge_hal_ring_dtr_next_completed(xge_hal_channel_h channelh, xge_hal_dtr_h *dtrh, u8 *t_code) { xge_hal_ring_rxd_1_t *rxdp; /* doesn't matter 1, 3 or 5... */ xge_hal_ring_t *ring = (xge_hal_ring_t *)channelh; #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) xge_hal_ring_rxd_priv_t *priv; #endif __hal_channel_dtr_try_complete(ring, dtrh); rxdp = (xge_hal_ring_rxd_1_t *)*dtrh; if (rxdp == NULL) { return XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS; } #if defined(XGE_OS_DMA_REQUIRES_SYNC) && defined(XGE_HAL_DMA_DTR_STREAMING) /* Note: 24 bytes at most means: * - Control_3 in case of 5-buffer mode * - Control_1 and Control_2 * * This is the only length needs to be invalidated * type of channels.*/ priv = __hal_ring_rxd_priv(ring, rxdp); xge_os_dma_sync(ring->channel.pdev, priv->dma_handle, priv->dma_addr, priv->dma_offset, 24, XGE_OS_DMA_DIR_FROMDEVICE); #endif /* check whether it is not the end */ if (!(rxdp->control_2 & XGE_HAL_RXD_NOT_COMPLETED) && !(rxdp->control_1 & XGE_HAL_RXD_POSTED_4_XFRAME)) { #ifndef XGE_HAL_IRQ_POLLING if (++ring->cmpl_cnt > ring->indicate_max_pkts) { /* reset it. since we don't want to return * garbage to the ULD */ *dtrh = 0; return XGE_HAL_COMPLETIONS_REMAIN; } #endif #ifdef XGE_DEBUG_ASSERT #if defined(XGE_HAL_USE_5B_MODE) #if !defined(XGE_OS_PLATFORM_64BIT) if (ring->buffer_mode == XGE_HAL_RING_QUEUE_BUFFER_MODE_5) { xge_assert(((xge_hal_ring_rxd_5_t *) rxdp)->host_control!=0); } #endif #else xge_assert(rxdp->host_control!=0); #endif #endif __hal_channel_dtr_complete(ring); *t_code = (u8)XGE_HAL_RXD_GET_T_CODE(rxdp->control_1); /* see XGE_HAL_SET_RXD_T_CODE() above.. */ xge_assert(*t_code != XGE_HAL_RXD_T_CODE_UNUSED_C); xge_debug_ring(XGE_TRACE, "compl_index %d post_qid %d t_code %d rxd 0x"XGE_OS_LLXFMT, ((xge_hal_channel_t*)ring)->compl_index, ((xge_hal_channel_t*)ring)->post_qid, *t_code, (unsigned long long)(ulong_t)rxdp); ring->channel.usage_cnt++; if (ring->channel.stats.usage_max < ring->channel.usage_cnt) ring->channel.stats.usage_max = ring->channel.usage_cnt; return XGE_HAL_OK; } /* reset it. since we don't want to return * garbage to the ULD */ *dtrh = 0; return XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS; } /** * xge_hal_ring_dtr_free - Free descriptor. * @channelh: Channel handle. * @dtrh: Descriptor handle. * * Free the reserved descriptor. This operation is "symmetrical" to * xge_hal_ring_dtr_reserve. The "free-ing" completes the descriptor's * lifecycle. * * After free-ing (see xge_hal_ring_dtr_free()) the descriptor again can * be: * * - reserved (xge_hal_ring_dtr_reserve); * * - posted (xge_hal_ring_dtr_post); * * - completed (xge_hal_ring_dtr_next_completed); * * - and recycled again (xge_hal_ring_dtr_free). * * For alternative state transitions and more details please refer to * the design doc. * * See also: xge_hal_ring_dtr_reserve(), xge_hal_fifo_dtr_free(). * Usage: See ex_rx_compl{}. */ __HAL_STATIC_RING __HAL_INLINE_RING void xge_hal_ring_dtr_free(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh) { #if defined(XGE_HAL_RX_MULTI_FREE_IRQ) unsigned long flags; #endif #if defined(XGE_HAL_RX_MULTI_FREE) xge_os_spin_lock(&((xge_hal_channel_t*)channelh)->free_lock); #elif defined(XGE_HAL_RX_MULTI_FREE_IRQ) xge_os_spin_lock_irq(&((xge_hal_channel_t*)channelh)->free_lock, flags); #endif __hal_channel_dtr_free(channelh, dtrh); #if defined(XGE_OS_MEMORY_CHECK) __hal_ring_rxd_priv((xge_hal_ring_t * ) channelh, dtrh)->allocated = 0; #endif #if defined(XGE_HAL_RX_MULTI_FREE) xge_os_spin_unlock(&((xge_hal_channel_t*)channelh)->free_lock); #elif defined(XGE_HAL_RX_MULTI_FREE_IRQ) xge_os_spin_unlock_irq(&((xge_hal_channel_t*)channelh)->free_lock, flags); #endif } /** * xge_hal_ring_is_next_dtr_completed - Check if the next dtr is completed * @channelh: Channel handle. * * Checks if the _next_ completed descriptor is in host memory * * Returns: XGE_HAL_OK - success. * XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS - No completed descriptors * are currently available for processing. */ __HAL_STATIC_RING __HAL_INLINE_RING xge_hal_status_e xge_hal_ring_is_next_dtr_completed(xge_hal_channel_h channelh) { xge_hal_ring_rxd_1_t *rxdp; /* doesn't matter 1, 3 or 5... */ xge_hal_ring_t *ring = (xge_hal_ring_t *)channelh; xge_hal_dtr_h dtrh; __hal_channel_dtr_try_complete(ring, &dtrh); rxdp = (xge_hal_ring_rxd_1_t *)dtrh; if (rxdp == NULL) { return XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS; } /* check whether it is not the end */ if (!(rxdp->control_2 & XGE_HAL_RXD_NOT_COMPLETED) && !(rxdp->control_1 & XGE_HAL_RXD_POSTED_4_XFRAME)) { #ifdef XGE_DEBUG_ASSERT #if defined(XGE_HAL_USE_5B_MODE) #if !defined(XGE_OS_PLATFORM_64BIT) if (ring->buffer_mode == XGE_HAL_RING_QUEUE_BUFFER_MODE_5) { xge_assert(((xge_hal_ring_rxd_5_t *) rxdp)->host_control!=0); } #endif #else xge_assert(rxdp->host_control!=0); #endif #endif return XGE_HAL_OK; } return XGE_HAL_INF_NO_MORE_COMPLETED_DESCRIPTORS; }