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https://github.com/brain-hackers/u-boot-brain
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9ea9021ac4
The keystone_nav driver is general driver intended to be used for working with queue manager and pktdma for different IPs like NETCP, AIF, FFTC, etc. So the it's API shouldn't be named like it works only with one of them, it should be general names. The names with prefix like netcp_* rather do for drivers/net/keystone_net.c driver. So it's good to generalize this driver to be used for different IP's and delete confusion with real NETCP driver. The current netcp_* functions of keystone navigator can be used for other settings of pktdma, not only for NETCP. The API of this driver is used by the keystone_net driver to work with NETCP, so net driver also should be corrected. For convenience collect pkdma configurations in drivers/dma/keystone_nav_cfg.c. Acked-by: Vitaly Andrianov <vitalya@ti.com> Signed-off-by: Ivan Khoronzhuk <ivan.khoronzhuk@ti.com>
333 lines
7.7 KiB
C
333 lines
7.7 KiB
C
/*
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* Multicore Navigator driver for TI Keystone 2 devices.
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*
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* (C) Copyright 2012-2014
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* Texas Instruments Incorporated, <www.ti.com>
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*
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* SPDX-License-Identifier: GPL-2.0+
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*/
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#include <common.h>
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#include <asm/io.h>
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#include <asm/ti-common/keystone_nav.h>
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struct qm_config qm_memmap = {
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.stat_cfg = CONFIG_KSNAV_QM_QUEUE_STATUS_BASE,
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.queue = (void *)CONFIG_KSNAV_QM_MANAGER_QUEUES_BASE,
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.mngr_vbusm = CONFIG_KSNAV_QM_BASE_ADDRESS,
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.i_lram = CONFIG_KSNAV_QM_LINK_RAM_BASE,
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.proxy = (void *)CONFIG_KSNAV_QM_MANAGER_Q_PROXY_BASE,
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.status_ram = CONFIG_KSNAV_QM_STATUS_RAM_BASE,
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.mngr_cfg = (void *)CONFIG_KSNAV_QM_CONF_BASE,
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.intd_cfg = CONFIG_KSNAV_QM_INTD_CONF_BASE,
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.desc_mem = (void *)CONFIG_KSNAV_QM_DESC_SETUP_BASE,
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.region_num = CONFIG_KSNAV_QM_REGION_NUM,
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.pdsp_cmd = CONFIG_KSNAV_QM_PDSP1_CMD_BASE,
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.pdsp_ctl = CONFIG_KSNAV_QM_PDSP1_CTRL_BASE,
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.pdsp_iram = CONFIG_KSNAV_QM_PDSP1_IRAM_BASE,
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.qpool_num = CONFIG_KSNAV_QM_QPOOL_NUM,
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};
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/*
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* We are going to use only one type of descriptors - host packet
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* descriptors. We staticaly allocate memory for them here
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*/
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struct qm_host_desc desc_pool[HDESC_NUM] __aligned(sizeof(struct qm_host_desc));
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static struct qm_config *qm_cfg;
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inline int num_of_desc_to_reg(int num_descr)
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{
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int j, num;
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for (j = 0, num = 32; j < 15; j++, num *= 2) {
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if (num_descr <= num)
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return j;
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}
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return 15;
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}
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int _qm_init(struct qm_config *cfg)
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{
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u32 j;
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qm_cfg = cfg;
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qm_cfg->mngr_cfg->link_ram_base0 = qm_cfg->i_lram;
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qm_cfg->mngr_cfg->link_ram_size0 = HDESC_NUM * 8;
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qm_cfg->mngr_cfg->link_ram_base1 = 0;
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qm_cfg->mngr_cfg->link_ram_size1 = 0;
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qm_cfg->mngr_cfg->link_ram_base2 = 0;
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qm_cfg->desc_mem[0].base_addr = (u32)desc_pool;
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qm_cfg->desc_mem[0].start_idx = 0;
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qm_cfg->desc_mem[0].desc_reg_size =
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(((sizeof(struct qm_host_desc) >> 4) - 1) << 16) |
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num_of_desc_to_reg(HDESC_NUM);
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memset(desc_pool, 0, sizeof(desc_pool));
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for (j = 0; j < HDESC_NUM; j++)
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qm_push(&desc_pool[j], qm_cfg->qpool_num);
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return QM_OK;
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}
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int qm_init(void)
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{
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return _qm_init(&qm_memmap);
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}
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void qm_close(void)
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{
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u32 j;
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if (qm_cfg == NULL)
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return;
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queue_close(qm_cfg->qpool_num);
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qm_cfg->mngr_cfg->link_ram_base0 = 0;
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qm_cfg->mngr_cfg->link_ram_size0 = 0;
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qm_cfg->mngr_cfg->link_ram_base1 = 0;
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qm_cfg->mngr_cfg->link_ram_size1 = 0;
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qm_cfg->mngr_cfg->link_ram_base2 = 0;
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for (j = 0; j < qm_cfg->region_num; j++) {
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qm_cfg->desc_mem[j].base_addr = 0;
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qm_cfg->desc_mem[j].start_idx = 0;
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qm_cfg->desc_mem[j].desc_reg_size = 0;
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}
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qm_cfg = NULL;
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}
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void qm_push(struct qm_host_desc *hd, u32 qnum)
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{
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u32 regd;
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if (!qm_cfg)
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return;
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cpu_to_bus((u32 *)hd, sizeof(struct qm_host_desc)/4);
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regd = (u32)hd | ((sizeof(struct qm_host_desc) >> 4) - 1);
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writel(regd, &qm_cfg->queue[qnum].ptr_size_thresh);
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}
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void qm_buff_push(struct qm_host_desc *hd, u32 qnum,
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void *buff_ptr, u32 buff_len)
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{
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hd->orig_buff_len = buff_len;
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hd->buff_len = buff_len;
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hd->orig_buff_ptr = (u32)buff_ptr;
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hd->buff_ptr = (u32)buff_ptr;
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qm_push(hd, qnum);
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}
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struct qm_host_desc *qm_pop(u32 qnum)
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{
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u32 uhd;
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if (!qm_cfg)
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return NULL;
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uhd = readl(&qm_cfg->queue[qnum].ptr_size_thresh) & ~0xf;
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if (uhd)
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cpu_to_bus((u32 *)uhd, sizeof(struct qm_host_desc)/4);
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return (struct qm_host_desc *)uhd;
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}
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struct qm_host_desc *qm_pop_from_free_pool(void)
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{
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if (!qm_cfg)
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return NULL;
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return qm_pop(qm_cfg->qpool_num);
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}
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void queue_close(u32 qnum)
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{
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struct qm_host_desc *hd;
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while ((hd = qm_pop(qnum)))
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;
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}
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/**
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* DMA API
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*/
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static int ksnav_rx_disable(struct pktdma_cfg *pktdma)
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{
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u32 j, v, k;
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for (j = 0; j < pktdma->rx_ch_num; j++) {
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v = readl(&pktdma->rx_ch[j].cfg_a);
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if (!(v & CPDMA_CHAN_A_ENABLE))
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continue;
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writel(v | CPDMA_CHAN_A_TDOWN, &pktdma->rx_ch[j].cfg_a);
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for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {
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udelay(100);
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v = readl(&pktdma->rx_ch[j].cfg_a);
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if (!(v & CPDMA_CHAN_A_ENABLE))
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continue;
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}
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/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */
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}
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/* Clear all of the flow registers */
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for (j = 0; j < pktdma->rx_flow_num; j++) {
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writel(0, &pktdma->rx_flows[j].control);
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writel(0, &pktdma->rx_flows[j].tags);
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writel(0, &pktdma->rx_flows[j].tag_sel);
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writel(0, &pktdma->rx_flows[j].fdq_sel[0]);
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writel(0, &pktdma->rx_flows[j].fdq_sel[1]);
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writel(0, &pktdma->rx_flows[j].thresh[0]);
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writel(0, &pktdma->rx_flows[j].thresh[1]);
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writel(0, &pktdma->rx_flows[j].thresh[2]);
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}
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return QM_OK;
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}
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static int ksnav_tx_disable(struct pktdma_cfg *pktdma)
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{
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u32 j, v, k;
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for (j = 0; j < pktdma->tx_ch_num; j++) {
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v = readl(&pktdma->tx_ch[j].cfg_a);
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if (!(v & CPDMA_CHAN_A_ENABLE))
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continue;
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writel(v | CPDMA_CHAN_A_TDOWN, &pktdma->tx_ch[j].cfg_a);
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for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {
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udelay(100);
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v = readl(&pktdma->tx_ch[j].cfg_a);
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if (!(v & CPDMA_CHAN_A_ENABLE))
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continue;
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}
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/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */
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}
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return QM_OK;
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}
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int ksnav_init(struct pktdma_cfg *pktdma, struct rx_buff_desc *rx_buffers)
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{
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u32 j, v;
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struct qm_host_desc *hd;
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u8 *rx_ptr;
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if (pktdma == NULL || rx_buffers == NULL ||
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rx_buffers->buff_ptr == NULL || qm_cfg == NULL)
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return QM_ERR;
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pktdma->rx_flow = rx_buffers->rx_flow;
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/* init rx queue */
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rx_ptr = rx_buffers->buff_ptr;
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for (j = 0; j < rx_buffers->num_buffs; j++) {
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hd = qm_pop(qm_cfg->qpool_num);
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if (hd == NULL)
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return QM_ERR;
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qm_buff_push(hd, pktdma->rx_free_q,
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rx_ptr, rx_buffers->buff_len);
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rx_ptr += rx_buffers->buff_len;
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}
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ksnav_rx_disable(pktdma);
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/* configure rx channels */
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v = CPDMA_REG_VAL_MAKE_RX_FLOW_A(1, 1, 0, 0, 0, 0, 0, pktdma->rx_rcv_q);
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writel(v, &pktdma->rx_flows[pktdma->rx_flow].control);
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writel(0, &pktdma->rx_flows[pktdma->rx_flow].tags);
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writel(0, &pktdma->rx_flows[pktdma->rx_flow].tag_sel);
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v = CPDMA_REG_VAL_MAKE_RX_FLOW_D(0, pktdma->rx_free_q, 0,
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pktdma->rx_free_q);
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writel(v, &pktdma->rx_flows[pktdma->rx_flow].fdq_sel[0]);
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writel(v, &pktdma->rx_flows[pktdma->rx_flow].fdq_sel[1]);
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writel(0, &pktdma->rx_flows[pktdma->rx_flow].thresh[0]);
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writel(0, &pktdma->rx_flows[pktdma->rx_flow].thresh[1]);
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writel(0, &pktdma->rx_flows[pktdma->rx_flow].thresh[2]);
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for (j = 0; j < pktdma->rx_ch_num; j++)
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writel(CPDMA_CHAN_A_ENABLE, &pktdma->rx_ch[j].cfg_a);
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/* configure tx channels */
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/* Disable loopback in the tx direction */
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writel(0, &pktdma->global->emulation_control);
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/* Set QM base address, only for K2x devices */
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writel(CONFIG_KSNAV_QM_BASE_ADDRESS, &pktdma->global->qm_base_addr[0]);
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/* Enable all channels. The current state isn't important */
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for (j = 0; j < pktdma->tx_ch_num; j++) {
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writel(0, &pktdma->tx_ch[j].cfg_b);
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writel(CPDMA_CHAN_A_ENABLE, &pktdma->tx_ch[j].cfg_a);
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}
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return QM_OK;
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}
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int ksnav_close(struct pktdma_cfg *pktdma)
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{
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if (!pktdma)
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return QM_ERR;
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ksnav_tx_disable(pktdma);
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ksnav_rx_disable(pktdma);
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queue_close(pktdma->rx_free_q);
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queue_close(pktdma->rx_rcv_q);
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queue_close(pktdma->tx_snd_q);
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return QM_OK;
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}
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int ksnav_send(struct pktdma_cfg *pktdma, u32 *pkt, int num_bytes, u32 swinfo2)
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{
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struct qm_host_desc *hd;
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hd = qm_pop(qm_cfg->qpool_num);
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if (hd == NULL)
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return QM_ERR;
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hd->desc_info = num_bytes;
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hd->swinfo[2] = swinfo2;
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hd->packet_info = qm_cfg->qpool_num;
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qm_buff_push(hd, pktdma->tx_snd_q, pkt, num_bytes);
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return QM_OK;
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}
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void *ksnav_recv(struct pktdma_cfg *pktdma, u32 **pkt, int *num_bytes)
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{
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struct qm_host_desc *hd;
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hd = qm_pop(pktdma->rx_rcv_q);
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if (!hd)
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return NULL;
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*pkt = (u32 *)hd->buff_ptr;
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*num_bytes = hd->desc_info & 0x3fffff;
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return hd;
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}
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void ksnav_release_rxhd(struct pktdma_cfg *pktdma, void *hd)
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{
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struct qm_host_desc *_hd = (struct qm_host_desc *)hd;
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_hd->buff_len = _hd->orig_buff_len;
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_hd->buff_ptr = _hd->orig_buff_ptr;
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qm_push(_hd, pktdma->rx_free_q);
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}
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