u-boot/arch/mips/mach-octeon/cvmx-pko3-queue.c

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// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2018-2022 Marvell International Ltd.
*/
#include <errno.h>
#include <log.h>
#include <time.h>
#include <linux/delay.h>
#include <mach/cvmx-regs.h>
#include <mach/cvmx-csr.h>
#include <mach/cvmx-bootmem.h>
#include <mach/octeon-model.h>
#include <mach/cvmx-fuse.h>
#include <mach/octeon-feature.h>
#include <mach/cvmx-qlm.h>
#include <mach/octeon_qlm.h>
#include <mach/cvmx-pcie.h>
#include <mach/cvmx-coremask.h>
#include <mach/cvmx-agl-defs.h>
#include <mach/cvmx-bgxx-defs.h>
#include <mach/cvmx-ciu-defs.h>
#include <mach/cvmx-gmxx-defs.h>
#include <mach/cvmx-gserx-defs.h>
#include <mach/cvmx-ilk-defs.h>
#include <mach/cvmx-ipd-defs.h>
#include <mach/cvmx-pcsx-defs.h>
#include <mach/cvmx-pcsxx-defs.h>
#include <mach/cvmx-pki-defs.h>
#include <mach/cvmx-pko-defs.h>
#include <mach/cvmx-xcv-defs.h>
#include <mach/cvmx-hwpko.h>
#include <mach/cvmx-ilk.h>
#include <mach/cvmx-pki.h>
#include <mach/cvmx-pko3.h>
#include <mach/cvmx-pko3-queue.h>
#include <mach/cvmx-pko3-resources.h>
#include <mach/cvmx-helper.h>
#include <mach/cvmx-helper-board.h>
#include <mach/cvmx-helper-cfg.h>
#include <mach/cvmx-helper-bgx.h>
#include <mach/cvmx-helper-cfg.h>
#include <mach/cvmx-helper-util.h>
#include <mach/cvmx-helper-pki.h>
/* Smalles Round-Robin quantum to use +1 */
#define CVMX_PKO3_RR_QUANTUM_MIN 0x10
static int debug; /* 1 for basic, 2 for detailed trace */
struct cvmx_pko3_dq {
unsigned dq_count : 6; /* Number of descriptor queues */
unsigned dq_base : 10; /* Descriptor queue start number */
#define CVMX_PKO3_SWIZZLE_IPD 0x0
};
/*
* @INTERNAL
* Descriptor Queue to IPD port mapping table.
*
* This pointer is per-core, contains the virtual address
* of a global named block which has 2^12 entries per each
* possible node.
*/
struct cvmx_pko3_dq *__cvmx_pko3_dq_table;
int cvmx_pko3_get_queue_base(int ipd_port)
{
struct cvmx_pko3_dq *dq_table;
int ret = -1;
unsigned int i;
struct cvmx_xport xp = cvmx_helper_ipd_port_to_xport(ipd_port);
/* get per-node table */
if (cvmx_unlikely(!__cvmx_pko3_dq_table))
__cvmx_pko3_dq_table_setup();
i = CVMX_PKO3_SWIZZLE_IPD ^ xp.port;
/* get per-node table */
dq_table = __cvmx_pko3_dq_table + CVMX_PKO3_IPD_NUM_MAX * xp.node;
if (cvmx_likely(dq_table[i].dq_count > 0))
ret = xp.node << 10 | dq_table[i].dq_base;
else if (debug)
cvmx_printf("ERROR: %s: no queues for ipd_port=%#x\n", __func__,
ipd_port);
return ret;
}
int cvmx_pko3_get_queue_num(int ipd_port)
{
struct cvmx_pko3_dq *dq_table;
int ret = -1;
unsigned int i;
struct cvmx_xport xp = cvmx_helper_ipd_port_to_xport(ipd_port);
/* get per-node table */
if (cvmx_unlikely(!__cvmx_pko3_dq_table))
__cvmx_pko3_dq_table_setup();
i = CVMX_PKO3_SWIZZLE_IPD ^ xp.port;
/* get per-node table */
dq_table = __cvmx_pko3_dq_table + CVMX_PKO3_IPD_NUM_MAX * xp.node;
if (cvmx_likely(dq_table[i].dq_count > 0))
ret = dq_table[i].dq_count;
else if (debug)
debug("ERROR: %s: no queues for ipd_port=%#x\n", __func__,
ipd_port);
return ret;
}
/**
* @INTERNAL
*
* Initialize port/dq table contents
*/
static void __cvmx_pko3_dq_table_init(void *ptr)
{
unsigned int size = sizeof(struct cvmx_pko3_dq) *
CVMX_PKO3_IPD_NUM_MAX * CVMX_MAX_NODES;
memset(ptr, 0, size);
}
/**
* @INTERNAL
*
* Find or allocate global port/dq map table
* which is a named table, contains entries for
* all possible OCI nodes.
*
* The table global pointer is stored in core-local variable
* so that every core will call this function once, on first use.
*/
int __cvmx_pko3_dq_table_setup(void)
{
void *ptr;
ptr = cvmx_bootmem_alloc_named_range_once(
/* size */
sizeof(struct cvmx_pko3_dq) * CVMX_PKO3_IPD_NUM_MAX *
CVMX_MAX_NODES,
/* min_addr, max_addr, align */
0ull, 0ull, sizeof(struct cvmx_pko3_dq),
/* name */
"cvmx_pko3_global_dq_table", __cvmx_pko3_dq_table_init);
if (debug)
debug("%s: dq_table_ptr=%p\n", __func__, ptr);
if (!ptr)
return -1;
__cvmx_pko3_dq_table = ptr;
return 0;
}
/*
* @INTERNAL
* Register a range of Descriptor Queues with an interface port
*
* This function populates the DQ-to-IPD translation table
* used by the application to retrieve the DQ range (typically ordered
* by priority) for a given IPD-port, which is either a physical port,
* or a channel on a channelized interface (i.e. ILK).
*
* @param xiface is the physical interface number
* @param index is either a physical port on an interface
* or a channel of an ILK interface
* @param dq_base is the first Descriptor Queue number in a consecutive range
* @param dq_count is the number of consecutive Descriptor Queues leading
* the same channel or port.
*
* Only a consecutive range of Descriptor Queues can be associated with any
* given channel/port, and usually they are ordered from most to least
* in terms of scheduling priority.
*
* Note: thus function only populates the node-local translation table.
* NOTE: This function would be cleaner if it had a single ipd_port argument
*
* @returns 0 on success, -1 on failure.
*/
int __cvmx_pko3_ipd_dq_register(int xiface, int index, unsigned int dq_base,
unsigned int dq_count)
{
struct cvmx_pko3_dq *dq_table;
int ipd_port;
unsigned int i;
struct cvmx_xiface xi = cvmx_helper_xiface_to_node_interface(xiface);
struct cvmx_xport xp;
if (__cvmx_helper_xiface_is_null(xiface)) {
ipd_port = cvmx_helper_node_to_ipd_port(xi.node,
CVMX_PKO3_IPD_PORT_NULL);
} else {
int p;
p = cvmx_helper_get_ipd_port(xiface, index);
if (p < 0) {
cvmx_printf("ERROR: %s: xiface %#x has no IPD port\n",
__func__, xiface);
return -1;
}
ipd_port = p;
}
xp = cvmx_helper_ipd_port_to_xport(ipd_port);
i = CVMX_PKO3_SWIZZLE_IPD ^ xp.port;
/* get per-node table */
if (!__cvmx_pko3_dq_table)
__cvmx_pko3_dq_table_setup();
dq_table = __cvmx_pko3_dq_table + CVMX_PKO3_IPD_NUM_MAX * xi.node;
if (debug)
debug("%s: ipd_port=%#x ix=%#x dq %u cnt %u\n", __func__,
ipd_port, i, dq_base, dq_count);
/* Check the IPD port has not already been configured */
if (dq_table[i].dq_count > 0) {
cvmx_printf("%s: ERROR: IPD %#x already registered\n", __func__,
ipd_port);
return -1;
}
/* Store DQ# range in the queue lookup table */
dq_table[i].dq_base = dq_base;
dq_table[i].dq_count = dq_count;
return 0;
}
/*
* @INTERNAL
* Convert normal CHAN_E (i.e. IPD port) value to compressed channel form
* that is used to populate PKO_LUT.
*
* Note: This code may be model specific.
*/
static int cvmx_pko3_chan_2_xchan(uint16_t ipd_port)
{
u16 xchan;
u8 off;
static const u8 *xchan_base;
static const u8 xchan_base_cn78xx[16] = {
/* IPD 0x000 */ 0x3c0 >> 4, /* LBK */
/* IPD 0x100 */ 0x380 >> 4, /* DPI */
/* IPD 0x200 */ 0xfff >> 4, /* not used */
/* IPD 0x300 */ 0xfff >> 4, /* not used */
/* IPD 0x400 */ 0x000 >> 4, /* ILK0 */
/* IPD 0x500 */ 0x100 >> 4, /* ILK1 */
/* IPD 0x600 */ 0xfff >> 4, /* not used */
/* IPD 0x700 */ 0xfff >> 4, /* not used */
/* IPD 0x800 */ 0x200 >> 4, /* BGX0 */
/* IPD 0x900 */ 0x240 >> 4, /* BGX1 */
/* IPD 0xa00 */ 0x280 >> 4, /* BGX2 */
/* IPD 0xb00 */ 0x2c0 >> 4, /* BGX3 */
/* IPD 0xc00 */ 0x300 >> 4, /* BGX4 */
/* IPD 0xd00 */ 0x340 >> 4, /* BGX5 */
/* IPD 0xe00 */ 0xfff >> 4, /* not used */
/* IPD 0xf00 */ 0xfff >> 4 /* not used */
};
static const u8 xchan_base_cn73xx[16] = {
/* IPD 0x000 */ 0x0c0 >> 4, /* LBK */
/* IPD 0x100 */ 0x100 >> 4, /* DPI */
/* IPD 0x200 */ 0xfff >> 4, /* not used */
/* IPD 0x300 */ 0xfff >> 4, /* not used */
/* IPD 0x400 */ 0xfff >> 4, /* not used */
/* IPD 0x500 */ 0xfff >> 4, /* not used */
/* IPD 0x600 */ 0xfff >> 4, /* not used */
/* IPD 0x700 */ 0xfff >> 4, /* not used */
/* IPD 0x800 */ 0x000 >> 4, /* BGX0 */
/* IPD 0x900 */ 0x040 >> 4, /* BGX1 */
/* IPD 0xa00 */ 0x080 >> 4, /* BGX2 */
/* IPD 0xb00 */ 0xfff >> 4, /* not used */
/* IPD 0xc00 */ 0xfff >> 4, /* not used */
/* IPD 0xd00 */ 0xfff >> 4, /* not used */
/* IPD 0xe00 */ 0xfff >> 4, /* not used */
/* IPD 0xf00 */ 0xfff >> 4 /* not used */
};
static const u8 xchan_base_cn75xx[16] = {
/* IPD 0x000 */ 0x040 >> 4, /* LBK */
/* IPD 0x100 */ 0x080 >> 4, /* DPI */
/* IPD 0x200 */ 0xeee >> 4, /* SRIO0 noop */
/* IPD 0x300 */ 0xfff >> 4, /* not used */
/* IPD 0x400 */ 0xfff >> 4, /* not used */
/* IPD 0x500 */ 0xfff >> 4, /* not used */
/* IPD 0x600 */ 0xfff >> 4, /* not used */
/* IPD 0x700 */ 0xfff >> 4, /* not used */
/* IPD 0x800 */ 0x000 >> 4, /* BGX0 */
/* IPD 0x900 */ 0xfff >> 4, /* not used */
/* IPD 0xa00 */ 0xfff >> 4, /* not used */
/* IPD 0xb00 */ 0xfff >> 4, /* not used */
/* IPD 0xc00 */ 0xfff >> 4, /* not used */
/* IPD 0xd00 */ 0xfff >> 4, /* not used */
/* IPD 0xe00 */ 0xfff >> 4, /* not used */
/* IPD 0xf00 */ 0xfff >> 4 /* not used */
};
if (OCTEON_IS_MODEL(OCTEON_CN73XX))
xchan_base = xchan_base_cn73xx;
if (OCTEON_IS_MODEL(OCTEON_CNF75XX))
xchan_base = xchan_base_cn75xx;
if (OCTEON_IS_MODEL(OCTEON_CN78XX))
xchan_base = xchan_base_cn78xx;
if (!xchan_base)
return -1;
xchan = ipd_port >> 8;
/* ILKx, DPI has 8 bits logical channels, others just 6 */
if (((xchan & 0xfe) == 0x04) || xchan == 0x01)
off = ipd_port & 0xff;
else
off = ipd_port & 0x3f;
xchan = xchan_base[xchan & 0xf];
if (xchan == 0xff)
return -1; /* Invalid IPD_PORT */
else if (xchan == 0xee)
return -2; /* LUT not used */
else
return (xchan << 4) | off;
}
/*
* Map channel number in PKO
*
* @param node is to specify the node to which this configuration is applied.
* @param pq_num specifies the Port Queue (i.e. L1) queue number.
* @param l2_l3_q_num specifies L2/L3 queue number.
* @param channel specifies the channel number to map to the queue.
*
* The channel assignment applies to L2 or L3 Shaper Queues depending
* on the setting of channel credit level.
*
* @return returns none.
*/
void cvmx_pko3_map_channel(unsigned int node, unsigned int pq_num,
unsigned int l2_l3_q_num, uint16_t channel)
{
union cvmx_pko_l3_l2_sqx_channel sqx_channel;
cvmx_pko_lutx_t lutx;
int xchan;
sqx_channel.u64 =
csr_rd_node(node, CVMX_PKO_L3_L2_SQX_CHANNEL(l2_l3_q_num));
sqx_channel.s.cc_channel = channel;
csr_wr_node(node, CVMX_PKO_L3_L2_SQX_CHANNEL(l2_l3_q_num),
sqx_channel.u64);
/* Convert CHAN_E into compressed channel */
xchan = cvmx_pko3_chan_2_xchan(channel);
if (debug)
debug("%s: ipd_port=%#x xchan=%#x\n", __func__, channel, xchan);
if (xchan < 0) {
if (xchan == -1)
cvmx_printf("%s: ERROR: channel %#x not recognized\n",
__func__, channel);
return;
}
lutx.u64 = 0;
lutx.s.valid = 1;
lutx.s.pq_idx = pq_num;
lutx.s.queue_number = l2_l3_q_num;
csr_wr_node(node, CVMX_PKO_LUTX(xchan), lutx.u64);
if (debug)
debug("%s: channel %#x (compressed=%#x) mapped L2/L3 SQ=%u, PQ=%u\n",
__func__, channel, xchan, l2_l3_q_num, pq_num);
}
/*
* @INTERNAL
* This function configures port queue scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param port_queue is the port queue number to be configured.
* @param mac_num is the mac number of the mac that will be tied to this port_queue.
*/
static void cvmx_pko_configure_port_queue(int node, int port_queue, int mac_num)
{
cvmx_pko_l1_sqx_topology_t pko_l1_topology;
cvmx_pko_l1_sqx_shape_t pko_l1_shape;
cvmx_pko_l1_sqx_link_t pko_l1_link;
pko_l1_topology.u64 = 0;
pko_l1_topology.s.link = mac_num;
csr_wr_node(node, CVMX_PKO_L1_SQX_TOPOLOGY(port_queue),
pko_l1_topology.u64);
pko_l1_shape.u64 = 0;
pko_l1_shape.s.link = mac_num;
csr_wr_node(node, CVMX_PKO_L1_SQX_SHAPE(port_queue), pko_l1_shape.u64);
pko_l1_link.u64 = 0;
pko_l1_link.s.link = mac_num;
csr_wr_node(node, CVMX_PKO_L1_SQX_LINK(port_queue), pko_l1_link.u64);
}
/*
* @INTERNAL
* This function configures level 2 queues scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param queue is the level3 queue number to be configured.
* @param parent_queue is the parent queue at next level for this l3 queue.
* @param prio is this queue's priority in parent's scheduler.
* @param rr_quantum is this queue's round robin quantum value.
* @param child_base is the first child queue number in the static prioriy children.
* @param child_rr_prio is the round robin children priority.
*/
static void cvmx_pko_configure_l2_queue(int node, int queue, int parent_queue,
int prio, int rr_quantum,
int child_base, int child_rr_prio)
{
cvmx_pko_l2_sqx_schedule_t pko_sq_sched;
cvmx_pko_l2_sqx_topology_t pko_child_topology;
cvmx_pko_l1_sqx_topology_t pko_parent_topology;
/* parent topology configuration */
pko_parent_topology.u64 =
csr_rd_node(node, CVMX_PKO_L1_SQX_TOPOLOGY(parent_queue));
pko_parent_topology.s.prio_anchor = child_base;
pko_parent_topology.s.rr_prio = child_rr_prio;
csr_wr_node(node, CVMX_PKO_L1_SQX_TOPOLOGY(parent_queue),
pko_parent_topology.u64);
if (debug > 1)
debug("CVMX_PKO_L1_SQX_TOPOLOGY(%u): PRIO_ANCHOR=%u PARENT=%u\n",
parent_queue, pko_parent_topology.s.prio_anchor,
pko_parent_topology.s.link);
/* scheduler configuration for this sq in the parent queue */
pko_sq_sched.u64 = 0;
pko_sq_sched.s.prio = prio;
pko_sq_sched.s.rr_quantum = rr_quantum;
csr_wr_node(node, CVMX_PKO_L2_SQX_SCHEDULE(queue), pko_sq_sched.u64);
/* child topology configuration */
pko_child_topology.u64 = 0;
pko_child_topology.s.parent = parent_queue;
csr_wr_node(node, CVMX_PKO_L2_SQX_TOPOLOGY(queue),
pko_child_topology.u64);
}
/*
* @INTERNAL
* This function configures level 3 queues scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param queue is the level3 queue number to be configured.
* @param parent_queue is the parent queue at next level for this l3 queue.
* @param prio is this queue's priority in parent's scheduler.
* @param rr_quantum is this queue's round robin quantum value.
* @param child_base is the first child queue number in the static prioriy children.
* @param child_rr_prio is the round robin children priority.
*/
static void cvmx_pko_configure_l3_queue(int node, int queue, int parent_queue,
int prio, int rr_quantum,
int child_base, int child_rr_prio)
{
cvmx_pko_l3_sqx_schedule_t pko_sq_sched;
cvmx_pko_l3_sqx_topology_t pko_child_topology;
cvmx_pko_l2_sqx_topology_t pko_parent_topology;
/* parent topology configuration */
pko_parent_topology.u64 =
csr_rd_node(node, CVMX_PKO_L2_SQX_TOPOLOGY(parent_queue));
pko_parent_topology.s.prio_anchor = child_base;
pko_parent_topology.s.rr_prio = child_rr_prio;
csr_wr_node(node, CVMX_PKO_L2_SQX_TOPOLOGY(parent_queue),
pko_parent_topology.u64);
if (debug > 1)
debug("CVMX_PKO_L2_SQX_TOPOLOGY(%u): PRIO_ANCHOR=%u PARENT=%u\n",
parent_queue, pko_parent_topology.s.prio_anchor,
pko_parent_topology.s.parent);
/* scheduler configuration for this sq in the parent queue */
pko_sq_sched.u64 = 0;
pko_sq_sched.s.prio = prio;
pko_sq_sched.s.rr_quantum = rr_quantum;
csr_wr_node(node, CVMX_PKO_L3_SQX_SCHEDULE(queue), pko_sq_sched.u64);
/* child topology configuration */
pko_child_topology.u64 = 0;
pko_child_topology.s.parent = parent_queue;
csr_wr_node(node, CVMX_PKO_L3_SQX_TOPOLOGY(queue),
pko_child_topology.u64);
}
/*
* @INTERNAL
* This function configures level 4 queues scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param queue is the level4 queue number to be configured.
* @param parent_queue is the parent queue at next level for this l4 queue.
* @param prio is this queue's priority in parent's scheduler.
* @param rr_quantum is this queue's round robin quantum value.
* @param child_base is the first child queue number in the static prioriy children.
* @param child_rr_prio is the round robin children priority.
*/
static void cvmx_pko_configure_l4_queue(int node, int queue, int parent_queue,
int prio, int rr_quantum,
int child_base, int child_rr_prio)
{
cvmx_pko_l4_sqx_schedule_t pko_sq_sched;
cvmx_pko_l4_sqx_topology_t pko_child_topology;
cvmx_pko_l3_sqx_topology_t pko_parent_topology;
/* parent topology configuration */
pko_parent_topology.u64 =
csr_rd_node(node, CVMX_PKO_L3_SQX_TOPOLOGY(parent_queue));
pko_parent_topology.s.prio_anchor = child_base;
pko_parent_topology.s.rr_prio = child_rr_prio;
csr_wr_node(node, CVMX_PKO_L3_SQX_TOPOLOGY(parent_queue),
pko_parent_topology.u64);
if (debug > 1)
debug("CVMX_PKO_L3_SQX_TOPOLOGY(%u): PRIO_ANCHOR=%u PARENT=%u\n",
parent_queue, pko_parent_topology.s.prio_anchor,
pko_parent_topology.s.parent);
/* scheduler configuration for this sq in the parent queue */
pko_sq_sched.u64 = 0;
pko_sq_sched.s.prio = prio;
pko_sq_sched.s.rr_quantum = rr_quantum;
csr_wr_node(node, CVMX_PKO_L4_SQX_SCHEDULE(queue), pko_sq_sched.u64);
/* topology configuration */
pko_child_topology.u64 = 0;
pko_child_topology.s.parent = parent_queue;
csr_wr_node(node, CVMX_PKO_L4_SQX_TOPOLOGY(queue),
pko_child_topology.u64);
}
/*
* @INTERNAL
* This function configures level 5 queues scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param queue is the level5 queue number to be configured.
* @param parent_queue is the parent queue at next level for this l5 queue.
* @param prio is this queue's priority in parent's scheduler.
* @param rr_quantum is this queue's round robin quantum value.
* @param child_base is the first child queue number in the static prioriy children.
* @param child_rr_prio is the round robin children priority.
*/
static void cvmx_pko_configure_l5_queue(int node, int queue, int parent_queue,
int prio, int rr_quantum,
int child_base, int child_rr_prio)
{
cvmx_pko_l5_sqx_schedule_t pko_sq_sched;
cvmx_pko_l4_sqx_topology_t pko_parent_topology;
cvmx_pko_l5_sqx_topology_t pko_child_topology;
/* parent topology configuration */
pko_parent_topology.u64 =
csr_rd_node(node, CVMX_PKO_L4_SQX_TOPOLOGY(parent_queue));
pko_parent_topology.s.prio_anchor = child_base;
pko_parent_topology.s.rr_prio = child_rr_prio;
csr_wr_node(node, CVMX_PKO_L4_SQX_TOPOLOGY(parent_queue),
pko_parent_topology.u64);
if (debug > 1)
debug("CVMX_PKO_L4_SQX_TOPOLOGY(%u): PRIO_ANCHOR=%u PARENT=%u\n",
parent_queue, pko_parent_topology.s.prio_anchor,
pko_parent_topology.s.parent);
/* scheduler configuration for this sq in the parent queue */
pko_sq_sched.u64 = 0;
pko_sq_sched.s.prio = prio;
pko_sq_sched.s.rr_quantum = rr_quantum;
csr_wr_node(node, CVMX_PKO_L5_SQX_SCHEDULE(queue), pko_sq_sched.u64);
/* topology configuration */
pko_child_topology.u64 = 0;
pko_child_topology.s.parent = parent_queue;
csr_wr_node(node, CVMX_PKO_L5_SQX_TOPOLOGY(queue),
pko_child_topology.u64);
}
/*
* @INTERNAL
* This function configures descriptor queues scheduling and topology parameters
* in hardware.
*
* @param node is to specify the node to which this configuration is applied.
* @param dq is the descriptor queue number to be configured.
* @param parent_queue is the parent queue at next level for this dq.
* @param prio is this queue's priority in parent's scheduler.
* @param rr_quantum is this queue's round robin quantum value.
* @param child_base is the first child queue number in the static prioriy children.
* @param child_rr_prio is the round robin children priority.
*/
static void cvmx_pko_configure_dq(int node, int dq, int parent_queue, int prio,
int rr_quantum, int child_base,
int child_rr_prio)
{
cvmx_pko_dqx_schedule_t pko_dq_sched;
cvmx_pko_dqx_topology_t pko_dq_topology;
cvmx_pko_l5_sqx_topology_t pko_parent_topology;
cvmx_pko_dqx_wm_ctl_t pko_dq_wm_ctl;
unsigned long long parent_topology_reg;
char lvl;
if (debug)
debug("%s: dq %u parent %u child_base %u\n", __func__, dq,
parent_queue, child_base);
if (__cvmx_pko3_sq_lvl_max() == CVMX_PKO_L5_QUEUES) {
parent_topology_reg = CVMX_PKO_L5_SQX_TOPOLOGY(parent_queue);
lvl = 5;
} else if (__cvmx_pko3_sq_lvl_max() == CVMX_PKO_L3_QUEUES) {
parent_topology_reg = CVMX_PKO_L3_SQX_TOPOLOGY(parent_queue);
lvl = 3;
} else {
return;
}
if (debug)
debug("%s: parent_topology_reg=%#llx\n", __func__,
parent_topology_reg);
/* parent topology configuration */
pko_parent_topology.u64 = csr_rd_node(node, parent_topology_reg);
pko_parent_topology.s.prio_anchor = child_base;
pko_parent_topology.s.rr_prio = child_rr_prio;
csr_wr_node(node, parent_topology_reg, pko_parent_topology.u64);
if (debug > 1)
debug("CVMX_PKO_L%d_SQX_TOPOLOGY(%u): PRIO_ANCHOR=%u PARENT=%u\n",
lvl, parent_queue, pko_parent_topology.s.prio_anchor,
pko_parent_topology.s.parent);
/* scheduler configuration for this dq in the parent queue */
pko_dq_sched.u64 = 0;
pko_dq_sched.s.prio = prio;
pko_dq_sched.s.rr_quantum = rr_quantum;
csr_wr_node(node, CVMX_PKO_DQX_SCHEDULE(dq), pko_dq_sched.u64);
/* topology configuration */
pko_dq_topology.u64 = 0;
pko_dq_topology.s.parent = parent_queue;
csr_wr_node(node, CVMX_PKO_DQX_TOPOLOGY(dq), pko_dq_topology.u64);
/* configure for counting packets, not bytes at this level */
pko_dq_wm_ctl.u64 = 0;
pko_dq_wm_ctl.s.kind = 1;
pko_dq_wm_ctl.s.enable = 0;
csr_wr_node(node, CVMX_PKO_DQX_WM_CTL(dq), pko_dq_wm_ctl.u64);
if (debug > 1) {
pko_dq_sched.u64 = csr_rd_node(node, CVMX_PKO_DQX_SCHEDULE(dq));
pko_dq_topology.u64 =
csr_rd_node(node, CVMX_PKO_DQX_TOPOLOGY(dq));
debug("CVMX_PKO_DQX_TOPOLOGY(%u)PARENT=%u CVMX_PKO_DQX_SCHEDULE(%u) PRIO=%u Q=%u\n",
dq, pko_dq_topology.s.parent, dq, pko_dq_sched.s.prio,
pko_dq_sched.s.rr_quantum);
}
}
/*
* @INTERNAL
* The following structure selects the Scheduling Queue configuration
* routine for each of the supported levels.
* The initial content of the table will be setup in accordance
* to the specific SoC model and its implemented resources
*/
struct pko3_cfg_tab_s {
/* function pointer for to configure the given level, last=DQ */
struct {
u8 parent_level;
void (*cfg_sq_func)(int node, int queue, int parent_queue,
int prio, int rr_quantum, int child_base,
int child_rr_prio);
//XXX for debugging exagerated size
} lvl[256];
};
static const struct pko3_cfg_tab_s pko3_cn78xx_cfg = {
{ [CVMX_PKO_L2_QUEUES] = { CVMX_PKO_PORT_QUEUES,
cvmx_pko_configure_l2_queue },
[CVMX_PKO_L3_QUEUES] = { CVMX_PKO_L2_QUEUES,
cvmx_pko_configure_l3_queue },
[CVMX_PKO_L4_QUEUES] = { CVMX_PKO_L3_QUEUES,
cvmx_pko_configure_l4_queue },
[CVMX_PKO_L5_QUEUES] = { CVMX_PKO_L4_QUEUES,
cvmx_pko_configure_l5_queue },
[CVMX_PKO_DESCR_QUEUES] = { CVMX_PKO_L5_QUEUES,
cvmx_pko_configure_dq } }
};
static const struct pko3_cfg_tab_s pko3_cn73xx_cfg = {
{ [CVMX_PKO_L2_QUEUES] = { CVMX_PKO_PORT_QUEUES,
cvmx_pko_configure_l2_queue },
[CVMX_PKO_L3_QUEUES] = { CVMX_PKO_L2_QUEUES,
cvmx_pko_configure_l3_queue },
[CVMX_PKO_DESCR_QUEUES] = { CVMX_PKO_L3_QUEUES,
cvmx_pko_configure_dq } }
};
/*
* Configure Port Queue and its children Scheduler Queue
*
* Port Queues (a.k.a L1) are assigned 1-to-1 to MACs.
* L2 Scheduler Queues are used for specifying channels, and thus there
* could be multiple L2 SQs attached to a single L1 PQ, either in a
* fair round-robin scheduling, or with static and/or round-robin priorities.
*
* @param node on which to operate
* @param mac_num is the LMAC number to that is associated with the Port Queue,
* @param pq_num is the number of the L1 PQ attached to the MAC
*
* @returns 0 on success, -1 on failure.
*/
int cvmx_pko3_pq_config(unsigned int node, unsigned int mac_num,
unsigned int pq_num)
{
char b1[10];
if (debug)
debug("%s: MAC%u -> %s\n", __func__, mac_num,
__cvmx_pko3_sq_str(b1, CVMX_PKO_PORT_QUEUES, pq_num));
cvmx_pko_configure_port_queue(node, pq_num, mac_num);
return 0;
}
/*
* Configure L3 through L5 Scheduler Queues and Descriptor Queues
*
* The Scheduler Queues in Levels 3 to 5 and Descriptor Queues are
* configured one-to-one or many-to-one to a single parent Scheduler
* Queues. The level of the parent SQ is specified in an argument,
* as well as the number of childer to attach to the specific parent.
* The children can have fair round-robin or priority-based scheduling
* when multiple children are assigned a single parent.
*
* @param node on which to operate
* @param child_level is the level of the child queue
* @param parent_queue is the number of the parent Scheduler Queue
* @param child_base is the number of the first child SQ or DQ to assign to
* @param child_count is the number of consecutive children to assign
* @param stat_prio_count is the priority setting for the children L2 SQs
*
* If <stat_prio_count> is -1, the Ln children will have equal Round-Robin
* relationship with eachother. If <stat_prio_count> is 0, all Ln children
* will be arranged in Weighted-Round-Robin, with the first having the most
* precedence. If <stat_prio_count> is between 1 and 8, it indicates how
* many children will have static priority settings (with the first having
* the most precedence), with the remaining Ln children having WRR scheduling.
*
* @returns 0 on success, -1 on failure.
*
* Note: this function supports the configuration of node-local unit.
*/
int cvmx_pko3_sq_config_children(unsigned int node,
enum cvmx_pko3_level_e child_level,
unsigned int parent_queue,
unsigned int child_base,
unsigned int child_count, int stat_prio_count)
{
enum cvmx_pko3_level_e parent_level;
unsigned int num_elem = 0;
unsigned int rr_quantum, rr_count;
unsigned int child, prio, rr_prio;
const struct pko3_cfg_tab_s *cfg_tbl = NULL;
char b1[10], b2[10];
if (OCTEON_IS_MODEL(OCTEON_CN78XX)) {
num_elem = NUM_ELEMENTS(pko3_cn78xx_cfg.lvl);
cfg_tbl = &pko3_cn78xx_cfg;
}
if (OCTEON_IS_MODEL(OCTEON_CN73XX) || OCTEON_IS_MODEL(OCTEON_CNF75XX)) {
num_elem = NUM_ELEMENTS(pko3_cn73xx_cfg.lvl);
cfg_tbl = &pko3_cn73xx_cfg;
}
if (!cfg_tbl || child_level >= num_elem) {
cvmx_printf("ERROR: %s: model or level %#x invalid\n", __func__,
child_level);
return -1;
}
parent_level = cfg_tbl->lvl[child_level].parent_level;
if (!cfg_tbl->lvl[child_level].cfg_sq_func ||
cfg_tbl->lvl[child_level].parent_level == 0) {
cvmx_printf("ERROR: %s: queue level %#x invalid\n", __func__,
child_level);
return -1;
}
/* First static priority is 0 - top precedence */
prio = 0;
if (stat_prio_count > (signed int)child_count)
stat_prio_count = child_count;
/* Valid PRIO field is 0..9, limit maximum static priorities */
if (stat_prio_count > 9)
stat_prio_count = 9;
/* Special case of a single child */
if (child_count == 1) {
rr_count = 0;
rr_prio = 0xF;
/* Special case for Fair-RR */
} else if (stat_prio_count < 0) {
rr_count = child_count;
rr_prio = 0;
} else {
rr_count = child_count - stat_prio_count;
rr_prio = stat_prio_count;
}
/* Compute highest RR_QUANTUM */
if (stat_prio_count > 0)
rr_quantum = CVMX_PKO3_RR_QUANTUM_MIN * rr_count;
else
rr_quantum = CVMX_PKO3_RR_QUANTUM_MIN;
if (debug)
debug("%s: Parent %s child_base %u rr_pri %u\n", __func__,
__cvmx_pko3_sq_str(b1, parent_level, parent_queue),
child_base, rr_prio);
/* Parent is configured with child */
for (child = child_base; child < (child_base + child_count); child++) {
if (debug)
debug("%s: Child %s of %s prio %u rr_quantum %#x\n",
__func__,
__cvmx_pko3_sq_str(b1, child_level, child),
__cvmx_pko3_sq_str(b2, parent_level,
parent_queue),
prio, rr_quantum);
cfg_tbl->lvl[child_level].cfg_sq_func(node, child, parent_queue,
prio, rr_quantum,
child_base, rr_prio);
if (prio < rr_prio)
prio++;
else if (stat_prio_count > 0)
rr_quantum -= CVMX_PKO3_RR_QUANTUM_MIN;
} /* for child */
return 0;
}