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

/* SPDX-License-Identifier: GPL-2.0 */
/*
 * Copyright (C) 2020 Marvell International Ltd.
 */

#ifndef __CVMX_PKO3_QUEUE_H__
#define __CVMX_PKO3_QUEUE_H__

/**
 * @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);

/*
 * Get the base Descriptor Queue number for an IPD port on the local node
 */
int cvmx_pko3_get_queue_base(int ipd_port);

/*
 * Get the number of Descriptor Queues assigned for an IPD port
 */
int cvmx_pko3_get_queue_num(int ipd_port);

/**
 * Get L1/Port Queue number assigned to interface port.
 *
 * @param xiface is interface number.
 * @param index is port index.
 */
int cvmx_pko3_get_port_queue(int xiface, int index);

/*
 * 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 children 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 is the OCI node location for the queues to be configured
 * @param parent_level is the level of the parent queue, 2 to 5.
 * @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 parent
 * @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, unsigned int parent_level,
				 unsigned int parent_queue, unsigned int child_base,
				 unsigned int child_count, int stat_prio_count);

/*
 * @INTERNAL
 * Register a range of Descriptor Queues wth an interface port
 *
 * This function poulates 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
 * @param 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
 * @param the same channel or port.
 *
 * Only a consecurive 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.
 *
 * @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);

/**
 * @INTERNAL
 *
 * Unregister DQs associated with CHAN_E (IPD port)
 */
int __cvmx_pko3_ipd_dq_unregister(int xiface, int index);

/*
 * 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,
			   u16 channel);

int cvmx_pko3_pq_config(unsigned int node, unsigned int mac_num, unsigned int pq_num);

int cvmx_pko3_port_cir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,
			   unsigned int burst_bytes, int adj_bytes);
int cvmx_pko3_dq_cir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,
			 unsigned int burst_bytes);
int cvmx_pko3_dq_pir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,
			 unsigned int burst_bytes);
typedef enum {
	CVMX_PKO3_SHAPE_RED_STALL,
	CVMX_PKO3_SHAPE_RED_DISCARD,
	CVMX_PKO3_SHAPE_RED_PASS
} red_action_t;

void cvmx_pko3_dq_red(unsigned int node, unsigned int dq_num, red_action_t red_act,
		      int8_t len_adjust);

/**
 * Macros to deal with short floating point numbers,
 * where unsigned exponent, and an unsigned normalized
 * mantissa are represented each with a defined field width.
 *
 */
#define CVMX_SHOFT_MANT_BITS 8
#define CVMX_SHOFT_EXP_BITS  4

/**
 * Convert short-float to an unsigned integer
 * Note that it will lose precision.
 */
#define CVMX_SHOFT_TO_U64(m, e)                                                                    \
	((((1ull << CVMX_SHOFT_MANT_BITS) | (m)) << (e)) >> CVMX_SHOFT_MANT_BITS)

/**
 * Convert to short-float from an unsigned integer
 */
#define CVMX_SHOFT_FROM_U64(ui, m, e)                                                              \
	do {                                                                                       \
		unsigned long long u;                                                              \
		unsigned int k;                                                                    \
		k = (1ull << (CVMX_SHOFT_MANT_BITS + 1)) - 1;                                      \
		(e) = 0;                                                                           \
		u = (ui) << CVMX_SHOFT_MANT_BITS;                                                  \
		while ((u) > k) {                                                                  \
			u >>= 1;                                                                   \
			(e)++;                                                                     \
		}                                                                                  \
		(m) = u & (k >> 1);                                                                \
	} while (0);

#define CVMX_SHOFT_MAX()                                                                           \
	CVMX_SHOFT_TO_U64((1 << CVMX_SHOFT_MANT_BITS) - 1, (1 << CVMX_SHOFT_EXP_BITS) - 1)
#define CVMX_SHOFT_MIN() CVMX_SHOFT_TO_U64(0, 0)

#endif /* __CVMX_PKO3_QUEUE_H__ */
mips: octeon: Add misc remaining header files Import misc remaining header files from 2013 U-Boot. These will be used by the later added drivers to support PCIe and networking on the MIPS Octeon II / III platforms. Signed-off-by: Aaron Williams <awilliams@marvell.com> Signed-off-by: Stefan Roese <sr@denx.de> Cc: Aaron Williams <awilliams@marvell.com> Cc: Chandrakala Chavva <cchavva@marvell.com> Cc: Daniel Schwierzeck <daniel.schwierzeck@gmail.com> 2021-04-23 17:56:32 +00:00			`/* SPDX-License-Identifier: GPL-2.0 */`
			`/*`
			`* Copyright (C) 2020 Marvell International Ltd.`
			`*/`

			`#ifndef __CVMX_PKO3_QUEUE_H__`
			`#define __CVMX_PKO3_QUEUE_H__`

			`/**`
			`* @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);`

			`/*`
			`* Get the base Descriptor Queue number for an IPD port on the local node`
			`*/`
			`int cvmx_pko3_get_queue_base(int ipd_port);`

			`/*`
			`* Get the number of Descriptor Queues assigned for an IPD port`
			`*/`
			`int cvmx_pko3_get_queue_num(int ipd_port);`

			`/**`
			`* Get L1/Port Queue number assigned to interface port.`
			`*`
			`* @param xiface is interface number.`
			`* @param index is port index.`
			`*/`
			`int cvmx_pko3_get_port_queue(int xiface, int index);`

			`/*`
			`* 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 children 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 is the OCI node location for the queues to be configured`
			`* @param parent_level is the level of the parent queue, 2 to 5.`
			`* @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 parent`
			`* @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, unsigned int parent_level,`
			`unsigned int parent_queue, unsigned int child_base,`
			`unsigned int child_count, int stat_prio_count);`

			`/*`
			`* @INTERNAL`
			`* Register a range of Descriptor Queues wth an interface port`
			`*`
			`* This function poulates 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`
			`* @param 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`
			`* @param the same channel or port.`
			`*`
			`* Only a consecurive 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.`
			`*`
			`* @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);`

			`/**`
			`* @INTERNAL`
			`*`
			`* Unregister DQs associated with CHAN_E (IPD port)`
			`*/`
			`int __cvmx_pko3_ipd_dq_unregister(int xiface, int index);`

			`/*`
			`* 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,`
			`u16 channel);`

			`int cvmx_pko3_pq_config(unsigned int node, unsigned int mac_num, unsigned int pq_num);`

			`int cvmx_pko3_port_cir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,`
			`unsigned int burst_bytes, int adj_bytes);`
			`int cvmx_pko3_dq_cir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,`
			`unsigned int burst_bytes);`
			`int cvmx_pko3_dq_pir_set(unsigned int node, unsigned int pq_num, unsigned long rate_kbips,`
			`unsigned int burst_bytes);`
			`typedef enum {`
			`CVMX_PKO3_SHAPE_RED_STALL,`
			`CVMX_PKO3_SHAPE_RED_DISCARD,`
			`CVMX_PKO3_SHAPE_RED_PASS`
			`} red_action_t;`

			`void cvmx_pko3_dq_red(unsigned int node, unsigned int dq_num, red_action_t red_act,`
			`int8_t len_adjust);`

			`/**`
			`* Macros to deal with short floating point numbers,`
			`* where unsigned exponent, and an unsigned normalized`
			`* mantissa are represented each with a defined field width.`
			`*`
			`*/`
			`#define CVMX_SHOFT_MANT_BITS 8`
			`#define CVMX_SHOFT_EXP_BITS 4`

			`/**`
			`* Convert short-float to an unsigned integer`
			`* Note that it will lose precision.`
			`*/`
			`#define CVMX_SHOFT_TO_U64(m, e) \`
			`((((1ull << CVMX_SHOFT_MANT_BITS) \| (m)) << (e)) >> CVMX_SHOFT_MANT_BITS)`

			`/**`
			`* Convert to short-float from an unsigned integer`
			`*/`
			`#define CVMX_SHOFT_FROM_U64(ui, m, e) \`
			`do { \`
			`unsigned long long u; \`
			`unsigned int k; \`
			`k = (1ull << (CVMX_SHOFT_MANT_BITS + 1)) - 1; \`
			`(e) = 0; \`
			`u = (ui) << CVMX_SHOFT_MANT_BITS; \`
			`while ((u) > k) { \`
			`u >>= 1; \`
			`(e)++; \`
			`} \`
			`(m) = u & (k >> 1); \`
			`} while (0);`

			`#define CVMX_SHOFT_MAX() \`
			`CVMX_SHOFT_TO_U64((1 << CVMX_SHOFT_MANT_BITS) - 1, (1 << CVMX_SHOFT_EXP_BITS) - 1)`
			`#define CVMX_SHOFT_MIN() CVMX_SHOFT_TO_U64(0, 0)`

			`#endif /* __CVMX_PKO3_QUEUE_H__ */`