u-boot-brain/arch/arm/cpu/armv7/keystone/keystone_nav.c

/*
 * Multicore Navigator driver for TI Keystone 2 devices.
 *
 * (C) Copyright 2012-2014
 *     Texas Instruments Incorporated, <www.ti.com>
 *
 * SPDX-License-Identifier:     GPL-2.0+
 */
#include <common.h>
#include <asm/io.h>
#include <asm/arch/keystone_nav.h>

static int soc_type =
#ifdef CONFIG_SOC_K2HK
	k2hk;
#endif

struct qm_config k2hk_qm_memmap = {
	.stat_cfg	= 0x02a40000,
	.queue		= (struct qm_reg_queue *)0x02a80000,
	.mngr_vbusm	= 0x23a80000,
	.i_lram		= 0x00100000,
	.proxy		= (struct qm_reg_queue *)0x02ac0000,
	.status_ram	= 0x02a06000,
	.mngr_cfg	= (struct qm_cfg_reg *)0x02a02000,
	.intd_cfg	= 0x02a0c000,
	.desc_mem	= (struct descr_mem_setup_reg *)0x02a03000,
	.region_num	= 64,
	.pdsp_cmd	= 0x02a20000,
	.pdsp_ctl	= 0x02a0f000,
	.pdsp_iram	= 0x02a10000,
	.qpool_num	= 4000,
};

/*
 * We are going to use only one type of descriptors - host packet
 * descriptors. We staticaly allocate memory for them here
 */
struct qm_host_desc desc_pool[HDESC_NUM] __aligned(sizeof(struct qm_host_desc));

static struct qm_config *qm_cfg;

inline int num_of_desc_to_reg(int num_descr)
{
	int j, num;

	for (j = 0, num = 32; j < 15; j++, num *= 2) {
		if (num_descr <= num)
			return j;
	}

	return 15;
}

static int _qm_init(struct qm_config *cfg)
{
	u32	j;

	if (cfg == NULL)
		return QM_ERR;

	qm_cfg = cfg;

	qm_cfg->mngr_cfg->link_ram_base0	= qm_cfg->i_lram;
	qm_cfg->mngr_cfg->link_ram_size0	= HDESC_NUM * 8;
	qm_cfg->mngr_cfg->link_ram_base1	= 0;
	qm_cfg->mngr_cfg->link_ram_size1	= 0;
	qm_cfg->mngr_cfg->link_ram_base2	= 0;

	qm_cfg->desc_mem[0].base_addr = (u32)desc_pool;
	qm_cfg->desc_mem[0].start_idx = 0;
	qm_cfg->desc_mem[0].desc_reg_size =
		(((sizeof(struct qm_host_desc) >> 4) - 1) << 16) |
		num_of_desc_to_reg(HDESC_NUM);

	memset(desc_pool, 0, sizeof(desc_pool));
	for (j = 0; j < HDESC_NUM; j++)
		qm_push(&desc_pool[j], qm_cfg->qpool_num);

	return QM_OK;
}

int qm_init(void)
{
	switch (soc_type) {
	case k2hk:
		return _qm_init(&k2hk_qm_memmap);
	}

	return QM_ERR;
}

void qm_close(void)
{
	u32	j;

	if (qm_cfg == NULL)
		return;

	queue_close(qm_cfg->qpool_num);

	qm_cfg->mngr_cfg->link_ram_base0	= 0;
	qm_cfg->mngr_cfg->link_ram_size0	= 0;
	qm_cfg->mngr_cfg->link_ram_base1	= 0;
	qm_cfg->mngr_cfg->link_ram_size1	= 0;
	qm_cfg->mngr_cfg->link_ram_base2	= 0;

	for (j = 0; j < qm_cfg->region_num; j++) {
		qm_cfg->desc_mem[j].base_addr = 0;
		qm_cfg->desc_mem[j].start_idx = 0;
		qm_cfg->desc_mem[j].desc_reg_size = 0;
	}

	qm_cfg = NULL;
}

void qm_push(struct qm_host_desc *hd, u32 qnum)
{
	u32 regd;

	if (!qm_cfg)
		return;

	cpu_to_bus((u32 *)hd, sizeof(struct qm_host_desc)/4);
	regd = (u32)hd | ((sizeof(struct qm_host_desc) >> 4) - 1);
	writel(regd, &qm_cfg->queue[qnum].ptr_size_thresh);
}

void qm_buff_push(struct qm_host_desc *hd, u32 qnum,
		    void *buff_ptr, u32 buff_len)
{
	hd->orig_buff_len = buff_len;
	hd->buff_len = buff_len;
	hd->orig_buff_ptr = (u32)buff_ptr;
	hd->buff_ptr = (u32)buff_ptr;
	qm_push(hd, qnum);
}

struct qm_host_desc *qm_pop(u32 qnum)
{
	u32 uhd;

	if (!qm_cfg)
		return NULL;

	uhd = readl(&qm_cfg->queue[qnum].ptr_size_thresh) & ~0xf;
	if (uhd)
		cpu_to_bus((u32 *)uhd, sizeof(struct qm_host_desc)/4);

	return (struct qm_host_desc *)uhd;
}

struct qm_host_desc *qm_pop_from_free_pool(void)
{
	if (!qm_cfg)
		return NULL;

	return qm_pop(qm_cfg->qpool_num);
}

void queue_close(u32 qnum)
{
	struct qm_host_desc *hd;

	while ((hd = qm_pop(qnum)))
		;
}

/*
 * DMA API
 */

struct pktdma_cfg k2hk_netcp_pktdma = {
	.global		= (struct global_ctl_regs *)0x02004000,
	.tx_ch		= (struct tx_chan_regs *)0x02004400,
	.tx_ch_num	= 9,
	.rx_ch		= (struct rx_chan_regs *)0x02004800,
	.rx_ch_num	= 26,
	.tx_sched	= (u32 *)0x02004c00,
	.rx_flows	= (struct rx_flow_regs *)0x02005000,
	.rx_flow_num	= 32,
	.rx_free_q	= 4001,
	.rx_rcv_q	= 4002,
	.tx_snd_q	= 648,
};

struct pktdma_cfg *netcp;

static int netcp_rx_disable(void)
{
	u32 j, v, k;

	for (j = 0; j < netcp->rx_ch_num; j++) {
		v = readl(&netcp->rx_ch[j].cfg_a);
		if (!(v & CPDMA_CHAN_A_ENABLE))
			continue;

		writel(v | CPDMA_CHAN_A_TDOWN, &netcp->rx_ch[j].cfg_a);
		for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {
			udelay(100);
			v = readl(&netcp->rx_ch[j].cfg_a);
			if (!(v & CPDMA_CHAN_A_ENABLE))
				continue;
		}
		/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */
	}

	/* Clear all of the flow registers */
	for (j = 0; j < netcp->rx_flow_num; j++) {
		writel(0, &netcp->rx_flows[j].control);
		writel(0, &netcp->rx_flows[j].tags);
		writel(0, &netcp->rx_flows[j].tag_sel);
		writel(0, &netcp->rx_flows[j].fdq_sel[0]);
		writel(0, &netcp->rx_flows[j].fdq_sel[1]);
		writel(0, &netcp->rx_flows[j].thresh[0]);
		writel(0, &netcp->rx_flows[j].thresh[1]);
		writel(0, &netcp->rx_flows[j].thresh[2]);
	}

	return QM_OK;
}

static int netcp_tx_disable(void)
{
	u32 j, v, k;

	for (j = 0; j < netcp->tx_ch_num; j++) {
		v = readl(&netcp->tx_ch[j].cfg_a);
		if (!(v & CPDMA_CHAN_A_ENABLE))
			continue;

		writel(v | CPDMA_CHAN_A_TDOWN, &netcp->tx_ch[j].cfg_a);
		for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {
			udelay(100);
			v = readl(&netcp->tx_ch[j].cfg_a);
			if (!(v & CPDMA_CHAN_A_ENABLE))
				continue;
		}
		/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */
	}

	return QM_OK;
}

static int _netcp_init(struct pktdma_cfg *netcp_cfg,
		       struct rx_buff_desc *rx_buffers)
{
	u32 j, v;
	struct qm_host_desc *hd;
	u8 *rx_ptr;

	if (netcp_cfg == NULL || rx_buffers == NULL ||
	    rx_buffers->buff_ptr == NULL || qm_cfg == NULL)
		return QM_ERR;

	netcp = netcp_cfg;
	netcp->rx_flow = rx_buffers->rx_flow;

	/* init rx queue */
	rx_ptr = rx_buffers->buff_ptr;

	for (j = 0; j < rx_buffers->num_buffs; j++) {
		hd = qm_pop(qm_cfg->qpool_num);
		if (hd == NULL)
			return QM_ERR;

		qm_buff_push(hd, netcp->rx_free_q,
			     rx_ptr, rx_buffers->buff_len);

		rx_ptr += rx_buffers->buff_len;
	}

	netcp_rx_disable();

	/* configure rx channels */
	v = CPDMA_REG_VAL_MAKE_RX_FLOW_A(1, 1, 0, 0, 0, 0, 0, netcp->rx_rcv_q);
	writel(v, &netcp->rx_flows[netcp->rx_flow].control);
	writel(0, &netcp->rx_flows[netcp->rx_flow].tags);
	writel(0, &netcp->rx_flows[netcp->rx_flow].tag_sel);

	v = CPDMA_REG_VAL_MAKE_RX_FLOW_D(0, netcp->rx_free_q, 0,
					 netcp->rx_free_q);

	writel(v, &netcp->rx_flows[netcp->rx_flow].fdq_sel[0]);
	writel(v, &netcp->rx_flows[netcp->rx_flow].fdq_sel[1]);
	writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[0]);
	writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[1]);
	writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[2]);

	for (j = 0; j < netcp->rx_ch_num; j++)
		writel(CPDMA_CHAN_A_ENABLE, &netcp->rx_ch[j].cfg_a);

	/* configure tx channels */
	/* Disable loopback in the tx direction */
	writel(0, &netcp->global->emulation_control);

/* TODO: make it dependend on a soc type variable */
#ifdef CONFIG_SOC_K2HK
	/* Set QM base address, only for K2x devices */
	writel(0x23a80000, &netcp->global->qm_base_addr[0]);
#endif

	/* Enable all channels. The current state isn't important */
	for (j = 0; j < netcp->tx_ch_num; j++)  {
		writel(0, &netcp->tx_ch[j].cfg_b);
		writel(CPDMA_CHAN_A_ENABLE, &netcp->tx_ch[j].cfg_a);
	}

	return QM_OK;
}

int netcp_init(struct rx_buff_desc *rx_buffers)
{
	switch (soc_type) {
	case k2hk:
		_netcp_init(&k2hk_netcp_pktdma, rx_buffers);
		return QM_OK;
	}
	return QM_ERR;
}

int netcp_close(void)
{
	if (!netcp)
		return QM_ERR;

	netcp_tx_disable();
	netcp_rx_disable();

	queue_close(netcp->rx_free_q);
	queue_close(netcp->rx_rcv_q);
	queue_close(netcp->tx_snd_q);

	return QM_OK;
}

int netcp_send(u32 *pkt, int num_bytes, u32 swinfo2)
{
	struct qm_host_desc *hd;

	hd = qm_pop(qm_cfg->qpool_num);
	if (hd == NULL)
		return QM_ERR;

	hd->desc_info	= num_bytes;
	hd->swinfo[2]	= swinfo2;
	hd->packet_info = qm_cfg->qpool_num;

	qm_buff_push(hd, netcp->tx_snd_q, pkt, num_bytes);

	return QM_OK;
}

void *netcp_recv(u32 **pkt, int *num_bytes)
{
	struct qm_host_desc *hd;

	hd = qm_pop(netcp->rx_rcv_q);
	if (!hd)
		return NULL;

	*pkt = (u32 *)hd->buff_ptr;
	*num_bytes = hd->desc_info & 0x3fffff;

	return hd;
}

void netcp_release_rxhd(void *hd)
{
	struct qm_host_desc *_hd = (struct qm_host_desc *)hd;

	_hd->buff_len = _hd->orig_buff_len;
	_hd->buff_ptr = _hd->orig_buff_ptr;

	qm_push(_hd, netcp->rx_free_q);
}
keystone2: add keystone multicore navigator driver Multicore navigator consists of Network Coprocessor (NetCP) and Queue Manager sub system. More details on the hardware can be obtained from the following links:- Network Coprocessor: http://www.ti.com/lit/pdf/sprugz6 Multicore Navigator: http://www.ti.com/lit/pdf/sprugr9 Multicore navigator driver implements APIs to configure the Queue Manager and NetCP Pkt DMA. Signed-off-by: Vitaly Andrianov <vitalya@ti.com> Signed-off-by: Murali Karicheri <m-karicheri2@ti.com> Signed-off-by: WingMan Kwok <w-kwok2@ti.com> Acked-by: Tom Rini <trini@ti.com> 2014-04-02 04:01:12 +09:00			`/*`
			`* Multicore Navigator driver for TI Keystone 2 devices.`
			`*`
			`* (C) Copyright 2012-2014`
			`* Texas Instruments Incorporated, <www.ti.com>`
			`*`
			`* SPDX-License-Identifier: GPL-2.0+`
			`*/`
			`#include <common.h>`
			`#include <asm/io.h>`
			`#include <asm/arch/keystone_nav.h>`

			`static int soc_type =`
			`#ifdef CONFIG_SOC_K2HK`
			`k2hk;`
			`#endif`

			`struct qm_config k2hk_qm_memmap = {`
			`.stat_cfg = 0x02a40000,`
			`.queue = (struct qm_reg_queue *)0x02a80000,`
			`.mngr_vbusm = 0x23a80000,`
			`.i_lram = 0x00100000,`
			`.proxy = (struct qm_reg_queue *)0x02ac0000,`
			`.status_ram = 0x02a06000,`
			`.mngr_cfg = (struct qm_cfg_reg *)0x02a02000,`
			`.intd_cfg = 0x02a0c000,`
			`.desc_mem = (struct descr_mem_setup_reg *)0x02a03000,`
			`.region_num = 64,`
			`.pdsp_cmd = 0x02a20000,`
			`.pdsp_ctl = 0x02a0f000,`
			`.pdsp_iram = 0x02a10000,`
			`.qpool_num = 4000,`
			`};`

			`/*`
			`* We are going to use only one type of descriptors - host packet`
			`* descriptors. We staticaly allocate memory for them here`
			`*/`
			`struct qm_host_desc desc_pool[HDESC_NUM] __aligned(sizeof(struct qm_host_desc));`

			`static struct qm_config *qm_cfg;`

			`inline int num_of_desc_to_reg(int num_descr)`
			`{`
			`int j, num;`

			`for (j = 0, num = 32; j < 15; j++, num *= 2) {`
			`if (num_descr <= num)`
			`return j;`
			`}`

			`return 15;`
			`}`

			`static int _qm_init(struct qm_config *cfg)`
			`{`
			`u32 j;`

			`if (cfg == NULL)`
			`return QM_ERR;`

			`qm_cfg = cfg;`

			`qm_cfg->mngr_cfg->link_ram_base0 = qm_cfg->i_lram;`
			`qm_cfg->mngr_cfg->link_ram_size0 = HDESC_NUM * 8;`
			`qm_cfg->mngr_cfg->link_ram_base1 = 0;`
			`qm_cfg->mngr_cfg->link_ram_size1 = 0;`
			`qm_cfg->mngr_cfg->link_ram_base2 = 0;`

			`qm_cfg->desc_mem[0].base_addr = (u32)desc_pool;`
			`qm_cfg->desc_mem[0].start_idx = 0;`
			`qm_cfg->desc_mem[0].desc_reg_size =`
			`(((sizeof(struct qm_host_desc) >> 4) - 1) << 16) \|`
			`num_of_desc_to_reg(HDESC_NUM);`

			`memset(desc_pool, 0, sizeof(desc_pool));`
			`for (j = 0; j < HDESC_NUM; j++)`
			`qm_push(&desc_pool[j], qm_cfg->qpool_num);`

			`return QM_OK;`
			`}`

			`int qm_init(void)`
			`{`
			`switch (soc_type) {`
			`case k2hk:`
			`return _qm_init(&k2hk_qm_memmap);`
			`}`

			`return QM_ERR;`
			`}`

			`void qm_close(void)`
			`{`
			`u32 j;`

			`if (qm_cfg == NULL)`
			`return;`

			`queue_close(qm_cfg->qpool_num);`

			`qm_cfg->mngr_cfg->link_ram_base0 = 0;`
			`qm_cfg->mngr_cfg->link_ram_size0 = 0;`
			`qm_cfg->mngr_cfg->link_ram_base1 = 0;`
			`qm_cfg->mngr_cfg->link_ram_size1 = 0;`
			`qm_cfg->mngr_cfg->link_ram_base2 = 0;`

			`for (j = 0; j < qm_cfg->region_num; j++) {`
			`qm_cfg->desc_mem[j].base_addr = 0;`
			`qm_cfg->desc_mem[j].start_idx = 0;`
			`qm_cfg->desc_mem[j].desc_reg_size = 0;`
			`}`

			`qm_cfg = NULL;`
			`}`

			`void qm_push(struct qm_host_desc *hd, u32 qnum)`
			`{`
			`u32 regd;`

			`if (!qm_cfg)`
			`return;`

			`cpu_to_bus((u32 *)hd, sizeof(struct qm_host_desc)/4);`
			`regd = (u32)hd \| ((sizeof(struct qm_host_desc) >> 4) - 1);`
			`writel(regd, &qm_cfg->queue[qnum].ptr_size_thresh);`
			`}`

			`void qm_buff_push(struct qm_host_desc *hd, u32 qnum,`
			`void *buff_ptr, u32 buff_len)`
			`{`
			`hd->orig_buff_len = buff_len;`
			`hd->buff_len = buff_len;`
			`hd->orig_buff_ptr = (u32)buff_ptr;`
			`hd->buff_ptr = (u32)buff_ptr;`
			`qm_push(hd, qnum);`
			`}`

			`struct qm_host_desc *qm_pop(u32 qnum)`
			`{`
			`u32 uhd;`

			`if (!qm_cfg)`
			`return NULL;`

			`uhd = readl(&qm_cfg->queue[qnum].ptr_size_thresh) & ~0xf;`
			`if (uhd)`
			`cpu_to_bus((u32 *)uhd, sizeof(struct qm_host_desc)/4);`

			`return (struct qm_host_desc *)uhd;`
			`}`

			`struct qm_host_desc *qm_pop_from_free_pool(void)`
			`{`
			`if (!qm_cfg)`
			`return NULL;`

			`return qm_pop(qm_cfg->qpool_num);`
			`}`

			`void queue_close(u32 qnum)`
			`{`
			`struct qm_host_desc *hd;`

			`while ((hd = qm_pop(qnum)))`
			`;`
			`}`

			`/*`
			`* DMA API`
			`*/`

			`struct pktdma_cfg k2hk_netcp_pktdma = {`
			`.global = (struct global_ctl_regs *)0x02004000,`
			`.tx_ch = (struct tx_chan_regs *)0x02004400,`
			`.tx_ch_num = 9,`
			`.rx_ch = (struct rx_chan_regs *)0x02004800,`
			`.rx_ch_num = 26,`
			`.tx_sched = (u32 *)0x02004c00,`
			`.rx_flows = (struct rx_flow_regs *)0x02005000,`
			`.rx_flow_num = 32,`
			`.rx_free_q = 4001,`
			`.rx_rcv_q = 4002,`
			`.tx_snd_q = 648,`
			`};`

			`struct pktdma_cfg *netcp;`

			`static int netcp_rx_disable(void)`
			`{`
			`u32 j, v, k;`

			`for (j = 0; j < netcp->rx_ch_num; j++) {`
			`v = readl(&netcp->rx_ch[j].cfg_a);`
			`if (!(v & CPDMA_CHAN_A_ENABLE))`
			`continue;`

			`writel(v \| CPDMA_CHAN_A_TDOWN, &netcp->rx_ch[j].cfg_a);`
			`for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {`
			`udelay(100);`
			`v = readl(&netcp->rx_ch[j].cfg_a);`
			`if (!(v & CPDMA_CHAN_A_ENABLE))`
			`continue;`
			`}`
			`/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */`
			`}`

			`/* Clear all of the flow registers */`
			`for (j = 0; j < netcp->rx_flow_num; j++) {`
			`writel(0, &netcp->rx_flows[j].control);`
			`writel(0, &netcp->rx_flows[j].tags);`
			`writel(0, &netcp->rx_flows[j].tag_sel);`
			`writel(0, &netcp->rx_flows[j].fdq_sel[0]);`
			`writel(0, &netcp->rx_flows[j].fdq_sel[1]);`
			`writel(0, &netcp->rx_flows[j].thresh[0]);`
			`writel(0, &netcp->rx_flows[j].thresh[1]);`
			`writel(0, &netcp->rx_flows[j].thresh[2]);`
			`}`

			`return QM_OK;`
			`}`

			`static int netcp_tx_disable(void)`
			`{`
			`u32 j, v, k;`

			`for (j = 0; j < netcp->tx_ch_num; j++) {`
			`v = readl(&netcp->tx_ch[j].cfg_a);`
			`if (!(v & CPDMA_CHAN_A_ENABLE))`
			`continue;`

			`writel(v \| CPDMA_CHAN_A_TDOWN, &netcp->tx_ch[j].cfg_a);`
			`for (k = 0; k < TDOWN_TIMEOUT_COUNT; k++) {`
			`udelay(100);`
			`v = readl(&netcp->tx_ch[j].cfg_a);`
			`if (!(v & CPDMA_CHAN_A_ENABLE))`
			`continue;`
			`}`
			`/* TODO: teardown error on if TDOWN_TIMEOUT_COUNT is reached */`
			`}`

			`return QM_OK;`
			`}`

			`static int _netcp_init(struct pktdma_cfg *netcp_cfg,`
			`struct rx_buff_desc *rx_buffers)`
			`{`
			`u32 j, v;`
			`struct qm_host_desc *hd;`
			`u8 *rx_ptr;`

			`if (netcp_cfg == NULL \|\| rx_buffers == NULL \|\|`
			`rx_buffers->buff_ptr == NULL \|\| qm_cfg == NULL)`
			`return QM_ERR;`

			`netcp = netcp_cfg;`
			`netcp->rx_flow = rx_buffers->rx_flow;`

			`/* init rx queue */`
			`rx_ptr = rx_buffers->buff_ptr;`

			`for (j = 0; j < rx_buffers->num_buffs; j++) {`
			`hd = qm_pop(qm_cfg->qpool_num);`
			`if (hd == NULL)`
			`return QM_ERR;`

			`qm_buff_push(hd, netcp->rx_free_q,`
			`rx_ptr, rx_buffers->buff_len);`

			`rx_ptr += rx_buffers->buff_len;`
			`}`

			`netcp_rx_disable();`

			`/* configure rx channels */`
			`v = CPDMA_REG_VAL_MAKE_RX_FLOW_A(1, 1, 0, 0, 0, 0, 0, netcp->rx_rcv_q);`
			`writel(v, &netcp->rx_flows[netcp->rx_flow].control);`
			`writel(0, &netcp->rx_flows[netcp->rx_flow].tags);`
			`writel(0, &netcp->rx_flows[netcp->rx_flow].tag_sel);`

			`v = CPDMA_REG_VAL_MAKE_RX_FLOW_D(0, netcp->rx_free_q, 0,`
			`netcp->rx_free_q);`

			`writel(v, &netcp->rx_flows[netcp->rx_flow].fdq_sel[0]);`
			`writel(v, &netcp->rx_flows[netcp->rx_flow].fdq_sel[1]);`
			`writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[0]);`
			`writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[1]);`
			`writel(0, &netcp->rx_flows[netcp->rx_flow].thresh[2]);`

			`for (j = 0; j < netcp->rx_ch_num; j++)`
			`writel(CPDMA_CHAN_A_ENABLE, &netcp->rx_ch[j].cfg_a);`

			`/* configure tx channels */`
			`/* Disable loopback in the tx direction */`
			`writel(0, &netcp->global->emulation_control);`

			`/* TODO: make it dependend on a soc type variable */`
			`#ifdef CONFIG_SOC_K2HK`
			`/* Set QM base address, only for K2x devices */`
			`writel(0x23a80000, &netcp->global->qm_base_addr[0]);`
			`#endif`

			`/* Enable all channels. The current state isn't important */`
			`for (j = 0; j < netcp->tx_ch_num; j++) {`
			`writel(0, &netcp->tx_ch[j].cfg_b);`
			`writel(CPDMA_CHAN_A_ENABLE, &netcp->tx_ch[j].cfg_a);`
			`}`

			`return QM_OK;`
			`}`

			`int netcp_init(struct rx_buff_desc *rx_buffers)`
			`{`
			`switch (soc_type) {`
			`case k2hk:`
			`_netcp_init(&k2hk_netcp_pktdma, rx_buffers);`
			`return QM_OK;`
			`}`
			`return QM_ERR;`
			`}`

			`int netcp_close(void)`
			`{`
			`if (!netcp)`
			`return QM_ERR;`

			`netcp_tx_disable();`
			`netcp_rx_disable();`

			`queue_close(netcp->rx_free_q);`
			`queue_close(netcp->rx_rcv_q);`
			`queue_close(netcp->tx_snd_q);`

			`return QM_OK;`
			`}`

			`int netcp_send(u32 *pkt, int num_bytes, u32 swinfo2)`
			`{`
			`struct qm_host_desc *hd;`

			`hd = qm_pop(qm_cfg->qpool_num);`
			`if (hd == NULL)`
			`return QM_ERR;`

			`hd->desc_info = num_bytes;`
			`hd->swinfo[2] = swinfo2;`
			`hd->packet_info = qm_cfg->qpool_num;`

			`qm_buff_push(hd, netcp->tx_snd_q, pkt, num_bytes);`

			`return QM_OK;`
			`}`

			`void netcp_recv(u32 pkt, int num_bytes)`
			`{`
			`struct qm_host_desc *hd;`

			`hd = qm_pop(netcp->rx_rcv_q);`
			`if (!hd)`
			`return NULL;`

			`pkt = (u32 )hd->buff_ptr;`
			`*num_bytes = hd->desc_info & 0x3fffff;`

			`return hd;`
			`}`

			`void netcp_release_rxhd(void *hd)`
			`{`
			`struct qm_host_desc _hd = (struct qm_host_desc )hd;`

			`_hd->buff_len = _hd->orig_buff_len;`
			`_hd->buff_ptr = _hd->orig_buff_ptr;`

			`qm_push(_hd, netcp->rx_free_q);`
			`}`